// Copyright 2018 Google LLC // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. package stack import ( "strings" "sync" "sync/atomic" "gvisor.googlesource.com/gvisor/pkg/ilist" "gvisor.googlesource.com/gvisor/pkg/tcpip" "gvisor.googlesource.com/gvisor/pkg/tcpip/buffer" "gvisor.googlesource.com/gvisor/pkg/tcpip/header" ) // NIC represents a "network interface card" to which the networking stack is // attached. type NIC struct { stack *Stack id tcpip.NICID name string linkEP LinkEndpoint demux *transportDemuxer mu sync.RWMutex spoofing bool promiscuous bool primary map[tcpip.NetworkProtocolNumber]*ilist.List endpoints map[NetworkEndpointID]*referencedNetworkEndpoint subnets []tcpip.Subnet } // PrimaryEndpointBehavior is an enumeration of an endpoint's primacy behavior. type PrimaryEndpointBehavior int const ( // CanBePrimaryEndpoint indicates the endpoint can be used as a primary // endpoint for new connections with no local address. This is the // default when calling NIC.AddAddress. CanBePrimaryEndpoint PrimaryEndpointBehavior = iota // FirstPrimaryEndpoint indicates the endpoint should be the first // primary endpoint considered. If there are multiple endpoints with // this behavior, the most recently-added one will be first. FirstPrimaryEndpoint // NeverPrimaryEndpoint indicates the endpoint should never be a // primary endpoint. NeverPrimaryEndpoint ) func newNIC(stack *Stack, id tcpip.NICID, name string, ep LinkEndpoint) *NIC { return &NIC{ stack: stack, id: id, name: name, linkEP: ep, demux: newTransportDemuxer(stack), primary: make(map[tcpip.NetworkProtocolNumber]*ilist.List), endpoints: make(map[NetworkEndpointID]*referencedNetworkEndpoint), } } // attachLinkEndpoint attaches the NIC to the endpoint, which will enable it // to start delivering packets. func (n *NIC) attachLinkEndpoint() { n.linkEP.Attach(n) } // setPromiscuousMode enables or disables promiscuous mode. func (n *NIC) setPromiscuousMode(enable bool) { n.mu.Lock() n.promiscuous = enable n.mu.Unlock() } func (n *NIC) isPromiscuousMode() bool { n.mu.RLock() rv := n.promiscuous n.mu.RUnlock() return rv } // setSpoofing enables or disables address spoofing. func (n *NIC) setSpoofing(enable bool) { n.mu.Lock() n.spoofing = enable n.mu.Unlock() } func (n *NIC) getMainNICAddress(protocol tcpip.NetworkProtocolNumber) (tcpip.Address, tcpip.Subnet, *tcpip.Error) { n.mu.RLock() defer n.mu.RUnlock() var r *referencedNetworkEndpoint // Check for a primary endpoint. if list, ok := n.primary[protocol]; ok { for e := list.Front(); e != nil; e = e.Next() { ref := e.(*referencedNetworkEndpoint) if ref.holdsInsertRef && ref.tryIncRef() { r = ref break } } } if r == nil { return "", tcpip.Subnet{}, tcpip.ErrNoLinkAddress } address := r.ep.ID().LocalAddress r.decRef() // Find the least-constrained matching subnet for the address, if one // exists, and return it. var subnet tcpip.Subnet for _, s := range n.subnets { if s.Contains(address) && !subnet.Contains(s.ID()) { subnet = s } } return address, subnet, nil } // primaryEndpoint returns the primary endpoint of n for the given network // protocol. func (n *NIC) primaryEndpoint(protocol tcpip.NetworkProtocolNumber) *referencedNetworkEndpoint { n.mu.RLock() defer n.mu.RUnlock() list := n.primary[protocol] if list == nil { return nil } for e := list.Front(); e != nil; e = e.Next() { r := e.(*referencedNetworkEndpoint) // TODO: allow broadcast address when SO_BROADCAST is set. switch r.ep.ID().LocalAddress { case header.IPv4Broadcast, header.IPv4Any: continue } if r.tryIncRef() { return r } } return nil } // findEndpoint finds the endpoint, if any, with the given address. func (n *NIC) findEndpoint(protocol tcpip.NetworkProtocolNumber, address tcpip.Address, peb PrimaryEndpointBehavior) *referencedNetworkEndpoint { id := NetworkEndpointID{address} n.mu.RLock() ref := n.endpoints[id] if ref != nil && !ref.tryIncRef() { ref = nil } spoofing := n.spoofing n.mu.RUnlock() if ref != nil || !spoofing { return ref } // Try again with the lock in exclusive mode. If we still can't get the // endpoint, create a new "temporary" endpoint. It will only exist while // there's a route through it. n.mu.Lock() ref = n.endpoints[id] if ref == nil || !ref.tryIncRef() { ref, _ = n.addAddressLocked(protocol, address, peb, true) if ref != nil { ref.holdsInsertRef = false } } n.mu.Unlock() return ref } func (n *NIC) addAddressLocked(protocol tcpip.NetworkProtocolNumber, addr tcpip.Address, peb PrimaryEndpointBehavior, replace bool) (*referencedNetworkEndpoint, *tcpip.Error) { netProto, ok := n.stack.networkProtocols[protocol] if !ok { return nil, tcpip.ErrUnknownProtocol } // Create the new network endpoint. ep, err := netProto.NewEndpoint(n.id, addr, n.stack, n, n.linkEP) if err != nil { return nil, err } id := *ep.ID() if ref, ok := n.endpoints[id]; ok { if !replace { return nil, tcpip.ErrDuplicateAddress } n.removeEndpointLocked(ref) } ref := &referencedNetworkEndpoint{ refs: 1, ep: ep, nic: n, protocol: protocol, holdsInsertRef: true, } // Set up cache if link address resolution exists for this protocol. if n.linkEP.Capabilities()&CapabilityResolutionRequired != 0 { if _, ok := n.stack.linkAddrResolvers[protocol]; ok { ref.linkCache = n.stack } } n.endpoints[id] = ref l, ok := n.primary[protocol] if !ok { l = &ilist.List{} n.primary[protocol] = l } switch peb { case CanBePrimaryEndpoint: l.PushBack(ref) case FirstPrimaryEndpoint: l.PushFront(ref) } return ref, nil } // AddAddress adds a new address to n, so that it starts accepting packets // targeted at the given address (and network protocol). func (n *NIC) AddAddress(protocol tcpip.NetworkProtocolNumber, addr tcpip.Address) *tcpip.Error { return n.AddAddressWithOptions(protocol, addr, CanBePrimaryEndpoint) } // AddAddressWithOptions is the same as AddAddress, but allows you to specify // whether the new endpoint can be primary or not. func (n *NIC) AddAddressWithOptions(protocol tcpip.NetworkProtocolNumber, addr tcpip.Address, peb PrimaryEndpointBehavior) *tcpip.Error { // Add the endpoint. n.mu.Lock() _, err := n.addAddressLocked(protocol, addr, peb, false) n.mu.Unlock() return err } // Addresses returns the addresses associated with this NIC. func (n *NIC) Addresses() []tcpip.ProtocolAddress { n.mu.RLock() defer n.mu.RUnlock() addrs := make([]tcpip.ProtocolAddress, 0, len(n.endpoints)) for nid, ep := range n.endpoints { addrs = append(addrs, tcpip.ProtocolAddress{ Protocol: ep.protocol, Address: nid.LocalAddress, }) } return addrs } // AddSubnet adds a new subnet to n, so that it starts accepting packets // targeted at the given address and network protocol. func (n *NIC) AddSubnet(protocol tcpip.NetworkProtocolNumber, subnet tcpip.Subnet) { n.mu.Lock() n.subnets = append(n.subnets, subnet) n.mu.Unlock() } // RemoveSubnet removes the given subnet from n. func (n *NIC) RemoveSubnet(subnet tcpip.Subnet) { n.mu.Lock() // Use the same underlying array. tmp := n.subnets[:0] for _, sub := range n.subnets { if sub != subnet { tmp = append(tmp, sub) } } n.subnets = tmp n.mu.Unlock() } // ContainsSubnet reports whether this NIC contains the given subnet. func (n *NIC) ContainsSubnet(subnet tcpip.Subnet) bool { for _, s := range n.Subnets() { if s == subnet { return true } } return false } // Subnets returns the Subnets associated with this NIC. func (n *NIC) Subnets() []tcpip.Subnet { n.mu.RLock() defer n.mu.RUnlock() sns := make([]tcpip.Subnet, 0, len(n.subnets)+len(n.endpoints)) for nid := range n.endpoints { sn, err := tcpip.NewSubnet(nid.LocalAddress, tcpip.AddressMask(strings.Repeat("\xff", len(nid.LocalAddress)))) if err != nil { // This should never happen as the mask has been carefully crafted to // match the address. panic("Invalid endpoint subnet: " + err.Error()) } sns = append(sns, sn) } return append(sns, n.subnets...) } func (n *NIC) removeEndpointLocked(r *referencedNetworkEndpoint) { id := *r.ep.ID() // Nothing to do if the reference has already been replaced with a // different one. if n.endpoints[id] != r { return } if r.holdsInsertRef { panic("Reference count dropped to zero before being removed") } delete(n.endpoints, id) wasInList := r.Next() != nil || r.Prev() != nil || r == n.primary[r.protocol].Front() if wasInList { n.primary[r.protocol].Remove(r) } r.ep.Close() } func (n *NIC) removeEndpoint(r *referencedNetworkEndpoint) { n.mu.Lock() n.removeEndpointLocked(r) n.mu.Unlock() } // RemoveAddress removes an address from n. func (n *NIC) RemoveAddress(addr tcpip.Address) *tcpip.Error { n.mu.Lock() r := n.endpoints[NetworkEndpointID{addr}] if r == nil || !r.holdsInsertRef { n.mu.Unlock() return tcpip.ErrBadLocalAddress } r.holdsInsertRef = false n.mu.Unlock() r.decRef() return nil } // DeliverNetworkPacket finds the appropriate network protocol endpoint and // hands the packet over for further processing. This function is called when // the NIC receives a packet from the physical interface. // Note that the ownership of the slice backing vv is retained by the caller. // This rule applies only to the slice itself, not to the items of the slice; // the ownership of the items is not retained by the caller. func (n *NIC) DeliverNetworkPacket(linkEP LinkEndpoint, remote, _ tcpip.LinkAddress, protocol tcpip.NetworkProtocolNumber, vv buffer.VectorisedView) { netProto, ok := n.stack.networkProtocols[protocol] if !ok { n.stack.stats.UnknownProtocolRcvdPackets.Increment() return } if netProto.Number() == header.IPv4ProtocolNumber || netProto.Number() == header.IPv6ProtocolNumber { n.stack.stats.IP.PacketsReceived.Increment() } if len(vv.First()) < netProto.MinimumPacketSize() { n.stack.stats.MalformedRcvdPackets.Increment() return } src, dst := netProto.ParseAddresses(vv.First()) if ref := n.getRef(protocol, dst); ref != nil { r := makeRoute(protocol, dst, src, linkEP.LinkAddress(), ref) r.RemoteLinkAddress = remote ref.ep.HandlePacket(&r, vv) ref.decRef() return } // This NIC doesn't care about the packet. Find a NIC that cares about the // packet and forward it to the NIC. // // TODO: Should we be forwarding the packet even if promiscuous? if n.stack.Forwarding() { r, err := n.stack.FindRoute(0, "", dst, protocol) if err != nil { n.stack.stats.IP.InvalidAddressesReceived.Increment() return } defer r.Release() r.LocalLinkAddress = n.linkEP.LinkAddress() r.RemoteLinkAddress = remote // Found a NIC. n := r.ref.nic n.mu.RLock() ref, ok := n.endpoints[NetworkEndpointID{dst}] n.mu.RUnlock() if ok && ref.tryIncRef() { ref.ep.HandlePacket(&r, vv) ref.decRef() } else { // n doesn't have a destination endpoint. // Send the packet out of n. hdr := buffer.NewPrependableFromView(vv.First()) vv.RemoveFirst() n.linkEP.WritePacket(&r, hdr, vv, protocol) } return } n.stack.stats.IP.InvalidAddressesReceived.Increment() } func (n *NIC) getRef(protocol tcpip.NetworkProtocolNumber, dst tcpip.Address) *referencedNetworkEndpoint { id := NetworkEndpointID{dst} n.mu.RLock() if ref, ok := n.endpoints[id]; ok && ref.tryIncRef() { n.mu.RUnlock() return ref } promiscuous := n.promiscuous // Check if the packet is for a subnet this NIC cares about. if !promiscuous { for _, sn := range n.subnets { if sn.Contains(dst) { promiscuous = true break } } } n.mu.RUnlock() if promiscuous { // Try again with the lock in exclusive mode. If we still can't // get the endpoint, create a new "temporary" one. It will only // exist while there's a route through it. n.mu.Lock() if ref, ok := n.endpoints[id]; ok && ref.tryIncRef() { n.mu.Unlock() return ref } ref, err := n.addAddressLocked(protocol, dst, CanBePrimaryEndpoint, true) n.mu.Unlock() if err == nil { ref.holdsInsertRef = false return ref } } return nil } // DeliverTransportPacket delivers the packets to the appropriate transport // protocol endpoint. func (n *NIC) DeliverTransportPacket(r *Route, protocol tcpip.TransportProtocolNumber, vv buffer.VectorisedView) { state, ok := n.stack.transportProtocols[protocol] if !ok { n.stack.stats.UnknownProtocolRcvdPackets.Increment() return } transProto := state.proto if len(vv.First()) < transProto.MinimumPacketSize() { n.stack.stats.MalformedRcvdPackets.Increment() return } srcPort, dstPort, err := transProto.ParsePorts(vv.First()) if err != nil { n.stack.stats.MalformedRcvdPackets.Increment() return } id := TransportEndpointID{dstPort, r.LocalAddress, srcPort, r.RemoteAddress} if n.demux.deliverPacket(r, protocol, vv, id) { return } if n.stack.demux.deliverPacket(r, protocol, vv, id) { return } // Try to deliver to per-stack default handler. if state.defaultHandler != nil { if state.defaultHandler(r, id, vv) { return } } // We could not find an appropriate destination for this packet, so // deliver it to the global handler. if !transProto.HandleUnknownDestinationPacket(r, id, vv) { n.stack.stats.MalformedRcvdPackets.Increment() } } // DeliverTransportControlPacket delivers control packets to the appropriate // transport protocol endpoint. func (n *NIC) DeliverTransportControlPacket(local, remote tcpip.Address, net tcpip.NetworkProtocolNumber, trans tcpip.TransportProtocolNumber, typ ControlType, extra uint32, vv buffer.VectorisedView) { state, ok := n.stack.transportProtocols[trans] if !ok { return } transProto := state.proto // ICMPv4 only guarantees that 8 bytes of the transport protocol will // be present in the payload. We know that the ports are within the // first 8 bytes for all known transport protocols. if len(vv.First()) < 8 { return } srcPort, dstPort, err := transProto.ParsePorts(vv.First()) if err != nil { return } id := TransportEndpointID{srcPort, local, dstPort, remote} if n.demux.deliverControlPacket(net, trans, typ, extra, vv, id) { return } if n.stack.demux.deliverControlPacket(net, trans, typ, extra, vv, id) { return } } // ID returns the identifier of n. func (n *NIC) ID() tcpip.NICID { return n.id } type referencedNetworkEndpoint struct { ilist.Entry refs int32 ep NetworkEndpoint nic *NIC protocol tcpip.NetworkProtocolNumber // linkCache is set if link address resolution is enabled for this // protocol. Set to nil otherwise. linkCache LinkAddressCache // holdsInsertRef is protected by the NIC's mutex. It indicates whether // the reference count is biased by 1 due to the insertion of the // endpoint. It is reset to false when RemoveAddress is called on the // NIC. holdsInsertRef bool } // decRef decrements the ref count and cleans up the endpoint once it reaches // zero. func (r *referencedNetworkEndpoint) decRef() { if atomic.AddInt32(&r.refs, -1) == 0 { r.nic.removeEndpoint(r) } } // incRef increments the ref count. It must only be called when the caller is // known to be holding a reference to the endpoint, otherwise tryIncRef should // be used. func (r *referencedNetworkEndpoint) incRef() { atomic.AddInt32(&r.refs, 1) } // tryIncRef attempts to increment the ref count from n to n+1, but only if n is // not zero. That is, it will increment the count if the endpoint is still // alive, and do nothing if it has already been clean up. func (r *referencedNetworkEndpoint) tryIncRef() bool { for { v := atomic.LoadInt32(&r.refs) if v == 0 { return false } if atomic.CompareAndSwapInt32(&r.refs, v, v+1) { return true } } }