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// Copyright 2018 The gVisor Authors.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package stack
import (
"fmt"
"gvisor.dev/gvisor/pkg/sync"
"gvisor.dev/gvisor/pkg/tcpip"
"gvisor.dev/gvisor/pkg/tcpip/header"
)
// Route represents a route through the networking stack to a given destination.
//
// It is safe to call Route's methods from multiple goroutines.
//
// The exported fields are immutable.
//
// TODO(gvisor.dev/issue/4902): Unexpose immutable fields.
type Route struct {
routeInfo
// localAddressNIC is the interface the address is associated with.
// TODO(gvisor.dev/issue/4548): Remove this field once we can query the
// address's assigned status without the NIC.
localAddressNIC *NIC
mu struct {
sync.RWMutex
// localAddressEndpoint is the local address this route is associated with.
localAddressEndpoint AssignableAddressEndpoint
// remoteLinkAddress is the link-layer (MAC) address of the next hop in the
// route.
remoteLinkAddress tcpip.LinkAddress
}
// outgoingNIC is the interface this route uses to write packets.
outgoingNIC *NIC
// linkRes is set if link address resolution is enabled for this protocol on
// the route's NIC.
linkRes LinkAddressResolver
}
type routeInfo struct {
// RemoteAddress is the final destination of the route.
RemoteAddress tcpip.Address
// LocalAddress is the local address where the route starts.
LocalAddress tcpip.Address
// LocalLinkAddress is the link-layer (MAC) address of the
// where the route starts.
LocalLinkAddress tcpip.LinkAddress
// NextHop is the next node in the path to the destination.
NextHop tcpip.Address
// NetProto is the network-layer protocol.
NetProto tcpip.NetworkProtocolNumber
// Loop controls where WritePacket should send packets.
Loop PacketLooping
}
// RouteInfo contains all of Route's exported fields.
type RouteInfo struct {
routeInfo
// RemoteLinkAddress is the link-layer (MAC) address of the next hop in the
// route.
RemoteLinkAddress tcpip.LinkAddress
}
// Fields returns a RouteInfo with all of the known values for the route's
// fields.
//
// If any fields are unknown (e.g. remote link address when it is waiting for
// link address resolution), they will be unset.
func (r *Route) Fields() RouteInfo {
r.mu.RLock()
defer r.mu.RUnlock()
return r.fieldsLocked()
}
func (r *Route) fieldsLocked() RouteInfo {
return RouteInfo{
routeInfo: r.routeInfo,
RemoteLinkAddress: r.mu.remoteLinkAddress,
}
}
// constructAndValidateRoute validates and initializes a route. It takes
// ownership of the provided local address.
//
// Returns an empty route if validation fails.
func constructAndValidateRoute(netProto tcpip.NetworkProtocolNumber, addressEndpoint AssignableAddressEndpoint, localAddressNIC, outgoingNIC *NIC, gateway, localAddr, remoteAddr tcpip.Address, handleLocal, multicastLoop bool) *Route {
if len(localAddr) == 0 {
localAddr = addressEndpoint.AddressWithPrefix().Address
}
if localAddressNIC != outgoingNIC && header.IsV6LinkLocalAddress(localAddr) {
addressEndpoint.DecRef()
return nil
}
// If no remote address is provided, use the local address.
if len(remoteAddr) == 0 {
remoteAddr = localAddr
}
r := makeRoute(
netProto,
gateway,
localAddr,
remoteAddr,
outgoingNIC,
localAddressNIC,
addressEndpoint,
handleLocal,
multicastLoop,
)
return r
}
// makeRoute initializes a new route. It takes ownership of the provided
// AssignableAddressEndpoint.
func makeRoute(netProto tcpip.NetworkProtocolNumber, gateway, localAddr, remoteAddr tcpip.Address, outgoingNIC, localAddressNIC *NIC, localAddressEndpoint AssignableAddressEndpoint, handleLocal, multicastLoop bool) *Route {
if localAddressNIC.stack != outgoingNIC.stack {
panic(fmt.Sprintf("cannot create a route with NICs from different stacks"))
}
if len(localAddr) == 0 {
localAddr = localAddressEndpoint.AddressWithPrefix().Address
}
loop := PacketOut
// TODO(gvisor.dev/issue/4689): Loopback interface loops back packets at the
// link endpoint level. We can remove this check once loopback interfaces
// loop back packets at the network layer.
if !outgoingNIC.IsLoopback() {
if handleLocal && localAddr != "" && remoteAddr == localAddr {
loop = PacketLoop
} else if multicastLoop && (header.IsV4MulticastAddress(remoteAddr) || header.IsV6MulticastAddress(remoteAddr)) {
loop |= PacketLoop
} else if remoteAddr == header.IPv4Broadcast {
loop |= PacketLoop
} else if subnet := localAddressEndpoint.AddressWithPrefix().Subnet(); subnet.IsBroadcast(remoteAddr) {
loop |= PacketLoop
}
}
r := makeRouteInner(netProto, localAddr, remoteAddr, outgoingNIC, localAddressNIC, localAddressEndpoint, loop)
if r.Loop&PacketOut == 0 {
// Packet will not leave the stack, no need for a gateway or a remote link
// address.
return r
}
if r.outgoingNIC.LinkEndpoint.Capabilities()&CapabilityResolutionRequired != 0 {
if linkRes, ok := r.outgoingNIC.stack.linkAddrResolvers[r.NetProto]; ok {
r.linkRes = linkRes
}
}
if len(gateway) > 0 {
r.NextHop = gateway
return r
}
if r.linkRes == nil {
return r
}
if linkAddr, ok := r.linkRes.ResolveStaticAddress(r.RemoteAddress); ok {
r.ResolveWith(linkAddr)
return r
}
if subnet := localAddressEndpoint.Subnet(); subnet.IsBroadcast(remoteAddr) {
r.ResolveWith(header.EthernetBroadcastAddress)
return r
}
if r.RemoteAddress == r.LocalAddress {
// Local link address is already known.
r.ResolveWith(r.LocalLinkAddress)
}
return r
}
func makeRouteInner(netProto tcpip.NetworkProtocolNumber, localAddr, remoteAddr tcpip.Address, outgoingNIC, localAddressNIC *NIC, localAddressEndpoint AssignableAddressEndpoint, loop PacketLooping) *Route {
r := &Route{
routeInfo: routeInfo{
NetProto: netProto,
LocalAddress: localAddr,
LocalLinkAddress: outgoingNIC.LinkEndpoint.LinkAddress(),
RemoteAddress: remoteAddr,
Loop: loop,
},
localAddressNIC: localAddressNIC,
outgoingNIC: outgoingNIC,
}
r.mu.Lock()
r.mu.localAddressEndpoint = localAddressEndpoint
r.mu.Unlock()
return r
}
// makeLocalRoute initializes a new local route. It takes ownership of the
// provided AssignableAddressEndpoint.
//
// A local route is a route to a destination that is local to the stack.
func makeLocalRoute(netProto tcpip.NetworkProtocolNumber, localAddr, remoteAddr tcpip.Address, outgoingNIC, localAddressNIC *NIC, localAddressEndpoint AssignableAddressEndpoint) *Route {
loop := PacketLoop
// TODO(gvisor.dev/issue/4689): Loopback interface loops back packets at the
// link endpoint level. We can remove this check once loopback interfaces
// loop back packets at the network layer.
if outgoingNIC.IsLoopback() {
loop = PacketOut
}
return makeRouteInner(netProto, localAddr, remoteAddr, outgoingNIC, localAddressNIC, localAddressEndpoint, loop)
}
// RemoteLinkAddress returns the link-layer (MAC) address of the next hop in
// the route.
func (r *Route) RemoteLinkAddress() tcpip.LinkAddress {
r.mu.RLock()
defer r.mu.RUnlock()
return r.mu.remoteLinkAddress
}
// NICID returns the id of the NIC from which this route originates.
func (r *Route) NICID() tcpip.NICID {
return r.outgoingNIC.ID()
}
// MaxHeaderLength forwards the call to the network endpoint's implementation.
func (r *Route) MaxHeaderLength() uint16 {
return r.outgoingNIC.getNetworkEndpoint(r.NetProto).MaxHeaderLength()
}
// Stats returns a mutable copy of current stats.
func (r *Route) Stats() tcpip.Stats {
return r.outgoingNIC.stack.Stats()
}
// PseudoHeaderChecksum forwards the call to the network endpoint's
// implementation.
func (r *Route) PseudoHeaderChecksum(protocol tcpip.TransportProtocolNumber, totalLen uint16) uint16 {
return header.PseudoHeaderChecksum(protocol, r.LocalAddress, r.RemoteAddress, totalLen)
}
// RequiresTXTransportChecksum returns false if the route does not require
// transport checksums to be populated.
func (r *Route) RequiresTXTransportChecksum() bool {
if r.local() {
return false
}
return r.outgoingNIC.LinkEndpoint.Capabilities()&CapabilityTXChecksumOffload == 0
}
// HasSoftwareGSOCapability returns true if the route supports software GSO.
func (r *Route) HasSoftwareGSOCapability() bool {
return r.outgoingNIC.LinkEndpoint.Capabilities()&CapabilitySoftwareGSO != 0
}
// HasHardwareGSOCapability returns true if the route supports hardware GSO.
func (r *Route) HasHardwareGSOCapability() bool {
return r.outgoingNIC.LinkEndpoint.Capabilities()&CapabilityHardwareGSO != 0
}
// HasSaveRestoreCapability returns true if the route supports save/restore.
func (r *Route) HasSaveRestoreCapability() bool {
return r.outgoingNIC.LinkEndpoint.Capabilities()&CapabilitySaveRestore != 0
}
// HasDisconncetOkCapability returns true if the route supports disconnecting.
func (r *Route) HasDisconncetOkCapability() bool {
return r.outgoingNIC.LinkEndpoint.Capabilities()&CapabilityDisconnectOk != 0
}
// GSOMaxSize returns the maximum GSO packet size.
func (r *Route) GSOMaxSize() uint32 {
if gso, ok := r.outgoingNIC.LinkEndpoint.(GSOEndpoint); ok {
return gso.GSOMaxSize()
}
return 0
}
// ResolveWith immediately resolves a route with the specified remote link
// address.
func (r *Route) ResolveWith(addr tcpip.LinkAddress) {
r.mu.Lock()
defer r.mu.Unlock()
r.mu.remoteLinkAddress = addr
}
// ResolvedFieldsResult is the result of a route resolution attempt.
type ResolvedFieldsResult struct {
RouteInfo RouteInfo
Success bool
}
// ResolvedFields attempts to resolve the remote link address if it is not
// known.
//
// If a callback is provided, it will be called before ResolvedFields returns
// when address resolution is not required. If address resolution is required,
// the callback will be called once address resolution is complete, regardless
// of success or failure.
//
// Note, the route will not cache the remote link address when address
// resolution completes.
func (r *Route) ResolvedFields(afterResolve func(ResolvedFieldsResult)) tcpip.Error {
_, _, err := r.resolvedFields(afterResolve)
return err
}
// resolvedFields is like ResolvedFields but also returns a notification channel
// when address resolution is required. This channel will become readable once
// address resolution is complete.
//
// The route's fields will also be returned, regardless of whether address
// resolution is required or not.
func (r *Route) resolvedFields(afterResolve func(ResolvedFieldsResult)) (RouteInfo, <-chan struct{}, tcpip.Error) {
r.mu.RLock()
fields := r.fieldsLocked()
resolutionRequired := r.isResolutionRequiredRLocked()
r.mu.RUnlock()
if !resolutionRequired {
if afterResolve != nil {
afterResolve(ResolvedFieldsResult{RouteInfo: fields, Success: true})
}
return fields, nil, nil
}
// If specified, the local address used for link address resolution must be an
// address on the outgoing interface.
var linkAddressResolutionRequestLocalAddr tcpip.Address
if r.localAddressNIC == r.outgoingNIC {
linkAddressResolutionRequestLocalAddr = r.LocalAddress
}
afterResolveFields := fields
linkAddr, ch, err := r.outgoingNIC.getNeighborLinkAddress(r.nextHop(), linkAddressResolutionRequestLocalAddr, r.linkRes, func(r LinkResolutionResult) {
if afterResolve != nil {
if r.Success {
afterResolveFields.RemoteLinkAddress = r.LinkAddress
}
afterResolve(ResolvedFieldsResult{RouteInfo: afterResolveFields, Success: r.Success})
}
})
if err == nil {
fields.RemoteLinkAddress = linkAddr
}
return fields, ch, err
}
func (r *Route) nextHop() tcpip.Address {
if len(r.NextHop) == 0 {
return r.RemoteAddress
}
return r.NextHop
}
// local returns true if the route is a local route.
func (r *Route) local() bool {
return r.Loop == PacketLoop || r.outgoingNIC.IsLoopback()
}
// IsResolutionRequired returns true if Resolve() must be called to resolve
// the link address before the route can be written to.
//
// The NICs the route is associated with must not be locked.
func (r *Route) IsResolutionRequired() bool {
r.mu.RLock()
defer r.mu.RUnlock()
return r.isResolutionRequiredRLocked()
}
func (r *Route) isResolutionRequiredRLocked() bool {
return len(r.mu.remoteLinkAddress) == 0 && r.linkRes != nil && r.isValidForOutgoingRLocked() && !r.local()
}
func (r *Route) isValidForOutgoing() bool {
r.mu.RLock()
defer r.mu.RUnlock()
return r.isValidForOutgoingRLocked()
}
func (r *Route) isValidForOutgoingRLocked() bool {
if !r.outgoingNIC.Enabled() {
return false
}
localAddressEndpoint := r.mu.localAddressEndpoint
if localAddressEndpoint == nil || !r.localAddressNIC.isValidForOutgoing(localAddressEndpoint) {
return false
}
// If the source NIC and outgoing NIC are different, make sure the stack has
// forwarding enabled, or the packet will be handled locally.
if r.outgoingNIC != r.localAddressNIC && !r.outgoingNIC.stack.Forwarding(r.NetProto) && (!r.outgoingNIC.stack.handleLocal || !r.outgoingNIC.hasAddress(r.NetProto, r.RemoteAddress)) {
return false
}
return true
}
// WritePacket writes the packet through the given route.
func (r *Route) WritePacket(gso *GSO, params NetworkHeaderParams, pkt *PacketBuffer) tcpip.Error {
if !r.isValidForOutgoing() {
return &tcpip.ErrInvalidEndpointState{}
}
return r.outgoingNIC.getNetworkEndpoint(r.NetProto).WritePacket(r, gso, params, pkt)
}
// WritePackets writes a list of n packets through the given route and returns
// the number of packets written.
func (r *Route) WritePackets(gso *GSO, pkts PacketBufferList, params NetworkHeaderParams) (int, tcpip.Error) {
if !r.isValidForOutgoing() {
return 0, &tcpip.ErrInvalidEndpointState{}
}
return r.outgoingNIC.getNetworkEndpoint(r.NetProto).WritePackets(r, gso, pkts, params)
}
// WriteHeaderIncludedPacket writes a packet already containing a network
// header through the given route.
func (r *Route) WriteHeaderIncludedPacket(pkt *PacketBuffer) tcpip.Error {
if !r.isValidForOutgoing() {
return &tcpip.ErrInvalidEndpointState{}
}
return r.outgoingNIC.getNetworkEndpoint(r.NetProto).WriteHeaderIncludedPacket(r, pkt)
}
// DefaultTTL returns the default TTL of the underlying network endpoint.
func (r *Route) DefaultTTL() uint8 {
return r.outgoingNIC.getNetworkEndpoint(r.NetProto).DefaultTTL()
}
// MTU returns the MTU of the underlying network endpoint.
func (r *Route) MTU() uint32 {
return r.outgoingNIC.getNetworkEndpoint(r.NetProto).MTU()
}
// Release decrements the reference counter of the resources associated with the
// route.
func (r *Route) Release() {
r.mu.Lock()
defer r.mu.Unlock()
if ep := r.mu.localAddressEndpoint; ep != nil {
ep.DecRef()
}
}
// Acquire increments the reference counter of the resources associated with the
// route.
func (r *Route) Acquire() {
r.mu.RLock()
defer r.mu.RUnlock()
r.acquireLocked()
}
func (r *Route) acquireLocked() {
if ep := r.mu.localAddressEndpoint; ep != nil {
if !ep.IncRef() {
panic(fmt.Sprintf("failed to increment reference count for local address endpoint = %s", r.LocalAddress))
}
}
}
// Stack returns the instance of the Stack that owns this route.
func (r *Route) Stack() *Stack {
return r.outgoingNIC.stack
}
func (r *Route) isV4Broadcast(addr tcpip.Address) bool {
if addr == header.IPv4Broadcast {
return true
}
r.mu.RLock()
localAddressEndpoint := r.mu.localAddressEndpoint
r.mu.RUnlock()
if localAddressEndpoint == nil {
return false
}
subnet := localAddressEndpoint.Subnet()
return subnet.IsBroadcast(addr)
}
// IsOutboundBroadcast returns true if the route is for an outbound broadcast
// packet.
func (r *Route) IsOutboundBroadcast() bool {
// Only IPv4 has a notion of broadcast.
return r.isV4Broadcast(r.RemoteAddress)
}
// ConfirmReachable informs the network/link layer that the neighbour used for
// the route is reachable.
//
// "Reachable" is defined as having full-duplex communication between the
// local and remote ends of the route.
func (r *Route) ConfirmReachable() {
r.outgoingNIC.confirmReachable(r.nextHop())
}
|