// Copyright 2019 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" "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/network/internal/ip" "gvisor.dev/gvisor/pkg/tcpip/stack" ) const ( // defaultMaxRtrSolicitations is the default number of Router // Solicitation messages to send when an IPv6 endpoint becomes enabled. // // Default = 3 (from RFC 4861 section 10). defaultMaxRtrSolicitations = 3 // defaultRtrSolicitationInterval is the default amount of time between // sending Router Solicitation messages. // // Default = 4s (from 4861 section 10). defaultRtrSolicitationInterval = 4 * time.Second // defaultMaxRtrSolicitationDelay is the default maximum amount of time // to wait before sending the first Router Solicitation message. // // Default = 1s (from 4861 section 10). defaultMaxRtrSolicitationDelay = time.Second // defaultHandleRAs is the default configuration for whether or not to // handle incoming Router Advertisements as a host. defaultHandleRAs = HandlingRAsEnabledWhenForwardingDisabled // defaultDiscoverDefaultRouters is the default configuration for // whether or not to discover default routers from incoming Router // Advertisements, as a host. defaultDiscoverDefaultRouters = true // defaultDiscoverOnLinkPrefixes is the default configuration for // whether or not to discover on-link prefixes from incoming Router // Advertisements' Prefix Information option, as a host. defaultDiscoverOnLinkPrefixes = true // defaultAutoGenGlobalAddresses is the default configuration for // whether or not to generate global IPv6 addresses in response to // receiving a new Prefix Information option with its Autonomous // Address AutoConfiguration flag set, as a host. // // Default = true. defaultAutoGenGlobalAddresses = true // minimumRtrSolicitationInterval is the minimum amount of time to wait // between sending Router Solicitation messages. This limit is imposed // to make sure that Router Solicitation messages are not sent all at // once, defeating the purpose of sending the initial few messages. minimumRtrSolicitationInterval = 500 * time.Millisecond // minimumMaxRtrSolicitationDelay is the minimum amount of time to wait // before sending the first Router Solicitation message. It is 0 because // we cannot have a negative delay. minimumMaxRtrSolicitationDelay = 0 // MaxDiscoveredOffLinkRoutes is the maximum number of discovered off-link // routes. The stack should stop discovering new off-link routes after // this limit is reached. // // This value MUST be at minimum 2 as per RFC 4861 section 6.3.4, and // SHOULD be more. MaxDiscoveredOffLinkRoutes = 10 // MaxDiscoveredOnLinkPrefixes is the maximum number of discovered // on-link prefixes. The stack should stop discovering new on-link // prefixes after discovering MaxDiscoveredOnLinkPrefixes on-link // prefixes. MaxDiscoveredOnLinkPrefixes = 10 // validPrefixLenForAutoGen is the expected prefix length that an // address can be generated for. Must be 64 bits as the interface // identifier (IID) is 64 bits and an IPv6 address is 128 bits, so // 128 - 64 = 64. validPrefixLenForAutoGen = 64 // defaultAutoGenTempGlobalAddresses is the default configuration for whether // or not to generate temporary SLAAC addresses. defaultAutoGenTempGlobalAddresses = true // defaultMaxTempAddrValidLifetime is the default maximum valid lifetime // for temporary SLAAC addresses generated as part of RFC 4941. // // Default = 7 days (from RFC 4941 section 5). defaultMaxTempAddrValidLifetime = 7 * 24 * time.Hour // defaultMaxTempAddrPreferredLifetime is the default preferred lifetime // for temporary SLAAC addresses generated as part of RFC 4941. // // Default = 1 day (from RFC 4941 section 5). defaultMaxTempAddrPreferredLifetime = 24 * time.Hour // defaultRegenAdvanceDuration is the default duration before the deprecation // of a temporary address when a new address will be generated. // // Default = 5s (from RFC 4941 section 5). defaultRegenAdvanceDuration = 5 * time.Second // minRegenAdvanceDuration is the minimum duration before the deprecation // of a temporary address when a new address will be generated. minRegenAdvanceDuration = time.Duration(0) // maxSLAACAddrLocalRegenAttempts is the maximum number of times to attempt // SLAAC address regenerations in response to an IPv6 endpoint-local conflict. maxSLAACAddrLocalRegenAttempts = 10 // MinPrefixInformationValidLifetimeForUpdate is the minimum Valid // Lifetime to update the valid lifetime of a generated address by // SLAAC. // // Min = 2hrs. MinPrefixInformationValidLifetimeForUpdate = 2 * time.Hour // MaxDesyncFactor is the upper bound for the preferred lifetime's desync // factor for temporary SLAAC addresses. // // Must be greater than 0. // // Max = 10m (from RFC 4941 section 5). MaxDesyncFactor = 10 * time.Minute // MinMaxTempAddrPreferredLifetime is the minimum value allowed for the // maximum preferred lifetime for temporary SLAAC addresses. // // This value guarantees that a temporary address is preferred for at // least 1hr if the SLAAC prefix is valid for at least that time. MinMaxTempAddrPreferredLifetime = defaultRegenAdvanceDuration + MaxDesyncFactor + time.Hour // MinMaxTempAddrValidLifetime is the minimum value allowed for the // maximum valid lifetime for temporary SLAAC addresses. // // This value guarantees that a temporary address is valid for at least // 2hrs if the SLAAC prefix is valid for at least that time. MinMaxTempAddrValidLifetime = 2 * time.Hour ) // NDPEndpoint is an endpoint that supports NDP. type NDPEndpoint interface { // SetNDPConfigurations sets the NDP configurations. SetNDPConfigurations(NDPConfigurations) } // DHCPv6ConfigurationFromNDPRA is a configuration available via DHCPv6 that an // NDP Router Advertisement informed the Stack about. type DHCPv6ConfigurationFromNDPRA int const ( _ DHCPv6ConfigurationFromNDPRA = iota // DHCPv6NoConfiguration indicates that no configurations are available via // DHCPv6. DHCPv6NoConfiguration // DHCPv6ManagedAddress indicates that addresses are available via DHCPv6. // // DHCPv6ManagedAddress also implies DHCPv6OtherConfigurations because DHCPv6 // returns all available configuration information when serving addresses. DHCPv6ManagedAddress // DHCPv6OtherConfigurations indicates that other configuration information is // available via DHCPv6. // // Other configurations are configurations other than addresses. Examples of // other configurations are recursive DNS server list, DNS search lists and // default gateway. DHCPv6OtherConfigurations ) // NDPDispatcher is the interface integrators of netstack must implement to // receive and handle NDP related events. type NDPDispatcher interface { // OnDuplicateAddressDetectionResult is called when the DAD process for an // address on a NIC completes. // // This function is not permitted to block indefinitely. This function // is also not permitted to call into the stack. OnDuplicateAddressDetectionResult(tcpip.NICID, tcpip.Address, stack.DADResult) // OnOffLinkRouteUpdated is called when an off-link route is updated. // // This function is not permitted to block indefinitely. This function // is also not permitted to call into the stack. OnOffLinkRouteUpdated(tcpip.NICID, tcpip.Subnet, tcpip.Address, header.NDPRoutePreference) // OnOffLinkRouteInvalidated is called when an off-link route is invalidated. // // This function is not permitted to block indefinitely. This function // is also not permitted to call into the stack. OnOffLinkRouteInvalidated(tcpip.NICID, tcpip.Subnet, tcpip.Address) // OnOnLinkPrefixDiscovered is called when a new on-link prefix is discovered. // // This function is not permitted to block indefinitely. This function // is also not permitted to call into the stack. OnOnLinkPrefixDiscovered(tcpip.NICID, tcpip.Subnet) // OnOnLinkPrefixInvalidated is called when a discovered on-link prefix that // was remembered is invalidated. // // This function is not permitted to block indefinitely. This function // is also not permitted to call into the stack. OnOnLinkPrefixInvalidated(tcpip.NICID, tcpip.Subnet) // OnAutoGenAddress is called when a new prefix with its autonomous address- // configuration flag set is received and SLAAC was performed. // // This function is not permitted to block indefinitely. It must not // call functions on the stack itself. OnAutoGenAddress(tcpip.NICID, tcpip.AddressWithPrefix) // OnAutoGenAddressDeprecated is called when an auto-generated address (SLAAC) // is deprecated, but is still considered valid. Note, if an address is // invalidated at the same ime it is deprecated, the deprecation event may not // be received. // // This function is not permitted to block indefinitely. It must not // call functions on the stack itself. OnAutoGenAddressDeprecated(tcpip.NICID, tcpip.AddressWithPrefix) // OnAutoGenAddressInvalidated is called when an auto-generated address // (SLAAC) is invalidated. // // This function is not permitted to block indefinitely. It must not // call functions on the stack itself. OnAutoGenAddressInvalidated(tcpip.NICID, tcpip.AddressWithPrefix) // OnRecursiveDNSServerOption is called when the stack learns of DNS servers // through NDP. Note, the addresses may contain link-local addresses. // // It is up to the caller to use the DNS Servers only for their valid // lifetime. OnRecursiveDNSServerOption may be called for new or // already known DNS servers. If called with known DNS servers, their // valid lifetimes must be refreshed to the lifetime (it may be increased, // decreased, or completely invalidated when the lifetime = 0). // // This function is not permitted to block indefinitely. It must not // call functions on the stack itself. OnRecursiveDNSServerOption(tcpip.NICID, []tcpip.Address, time.Duration) // OnDNSSearchListOption is called when the stack learns of DNS search lists // through NDP. // // It is up to the caller to use the domain names in the search list // for only their valid lifetime. OnDNSSearchListOption may be called // with new or already known domain names. If called with known domain // names, their valid lifetimes must be refreshed to the lifetime (it may // be increased, decreased or completely invalidated when the lifetime = 0. OnDNSSearchListOption(tcpip.NICID, []string, time.Duration) // OnDHCPv6Configuration is called with an updated configuration that is // available via DHCPv6 for the passed NIC. // // This function is not permitted to block indefinitely. It must not // call functions on the stack itself. OnDHCPv6Configuration(tcpip.NICID, DHCPv6ConfigurationFromNDPRA) } var _ fmt.Stringer = HandleRAsConfiguration(0) // HandleRAsConfiguration enumerates when RAs may be handled. type HandleRAsConfiguration int const ( // HandlingRAsDisabled indicates that Router Advertisements will not be // handled. HandlingRAsDisabled HandleRAsConfiguration = iota // HandlingRAsEnabledWhenForwardingDisabled indicates that router // advertisements will only be handled when forwarding is disabled. HandlingRAsEnabledWhenForwardingDisabled // HandlingRAsAlwaysEnabled indicates that Router Advertisements will always // be handled, even when forwarding is enabled. HandlingRAsAlwaysEnabled ) // String implements fmt.Stringer. func (c HandleRAsConfiguration) String() string { switch c { case HandlingRAsDisabled: return "HandlingRAsDisabled" case HandlingRAsEnabledWhenForwardingDisabled: return "HandlingRAsEnabledWhenForwardingDisabled" case HandlingRAsAlwaysEnabled: return "HandlingRAsAlwaysEnabled" default: return fmt.Sprintf("HandleRAsConfiguration(%d)", c) } } // enabled returns true iff Router Advertisements may be handled given the // specified forwarding status. func (c HandleRAsConfiguration) enabled(forwarding bool) bool { switch c { case HandlingRAsDisabled: return false case HandlingRAsEnabledWhenForwardingDisabled: return !forwarding case HandlingRAsAlwaysEnabled: return true default: panic(fmt.Sprintf("unhandled HandleRAsConfiguration = %d", c)) } } // NDPConfigurations is the NDP configurations for the netstack. type NDPConfigurations struct { // The number of Router Solicitation messages to send when the IPv6 endpoint // becomes enabled. // // Ignored unless configured to handle Router Advertisements. MaxRtrSolicitations uint8 // The amount of time between transmitting Router Solicitation messages. // // Must be greater than or equal to 0.5s. RtrSolicitationInterval time.Duration // The maximum amount of time before transmitting the first Router // Solicitation message. // // Must be greater than or equal to 0s. MaxRtrSolicitationDelay time.Duration // HandleRAs is the configuration for when Router Advertisements should be // handled. HandleRAs HandleRAsConfiguration // DiscoverDefaultRouters determines whether or not default routers are // discovered from Router Advertisements, as per RFC 4861 section 6. This // configuration is ignored if HandleRAs is false. DiscoverDefaultRouters bool // DiscoverOnLinkPrefixes determines whether or not on-link prefixes are // discovered from Router Advertisements' Prefix Information option, as per // RFC 4861 section 6. This configuration is ignored if HandleRAs is false. DiscoverOnLinkPrefixes bool // AutoGenGlobalAddresses determines whether or not an IPv6 endpoint performs // SLAAC to auto-generate global SLAAC addresses in response to Prefix // Information options, as per RFC 4862. // // Note, if an address was already generated for some unique prefix, as // part of SLAAC, this option does not affect whether or not the // lifetime(s) of the generated address changes; this option only // affects the generation of new addresses as part of SLAAC. AutoGenGlobalAddresses bool // AutoGenAddressConflictRetries determines how many times to attempt to retry // generation of a permanent auto-generated address in response to DAD // conflicts. // // If the method used to generate the address does not support creating // alternative addresses (e.g. IIDs based on the modified EUI64 of a NIC's // MAC address), then no attempt is made to resolve the conflict. AutoGenAddressConflictRetries uint8 // AutoGenTempGlobalAddresses determines whether or not temporary SLAAC // addresses are generated for an IPv6 endpoint as part of SLAAC privacy // extensions, as per RFC 4941. // // Ignored if AutoGenGlobalAddresses is false. AutoGenTempGlobalAddresses bool // MaxTempAddrValidLifetime is the maximum valid lifetime for temporary // SLAAC addresses. MaxTempAddrValidLifetime time.Duration // MaxTempAddrPreferredLifetime is the maximum preferred lifetime for // temporary SLAAC addresses. MaxTempAddrPreferredLifetime time.Duration // RegenAdvanceDuration is the duration before the deprecation of a temporary // address when a new address will be generated. RegenAdvanceDuration time.Duration } // DefaultNDPConfigurations returns an NDPConfigurations populated with // default values. func DefaultNDPConfigurations() NDPConfigurations { return NDPConfigurations{ MaxRtrSolicitations: defaultMaxRtrSolicitations, RtrSolicitationInterval: defaultRtrSolicitationInterval, MaxRtrSolicitationDelay: defaultMaxRtrSolicitationDelay, HandleRAs: defaultHandleRAs, DiscoverDefaultRouters: defaultDiscoverDefaultRouters, DiscoverOnLinkPrefixes: defaultDiscoverOnLinkPrefixes, AutoGenGlobalAddresses: defaultAutoGenGlobalAddresses, AutoGenTempGlobalAddresses: defaultAutoGenTempGlobalAddresses, MaxTempAddrValidLifetime: defaultMaxTempAddrValidLifetime, MaxTempAddrPreferredLifetime: defaultMaxTempAddrPreferredLifetime, RegenAdvanceDuration: defaultRegenAdvanceDuration, } } // validate modifies an NDPConfigurations with valid values. If invalid values // are present in c, the corresponding default values are used instead. func (c *NDPConfigurations) validate() { if c.RtrSolicitationInterval < minimumRtrSolicitationInterval { c.RtrSolicitationInterval = defaultRtrSolicitationInterval } if c.MaxRtrSolicitationDelay < minimumMaxRtrSolicitationDelay { c.MaxRtrSolicitationDelay = defaultMaxRtrSolicitationDelay } if c.MaxTempAddrValidLifetime < MinMaxTempAddrValidLifetime { c.MaxTempAddrValidLifetime = MinMaxTempAddrValidLifetime } if c.MaxTempAddrPreferredLifetime < MinMaxTempAddrPreferredLifetime || c.MaxTempAddrPreferredLifetime > c.MaxTempAddrValidLifetime { c.MaxTempAddrPreferredLifetime = MinMaxTempAddrPreferredLifetime } if c.RegenAdvanceDuration < minRegenAdvanceDuration { c.RegenAdvanceDuration = minRegenAdvanceDuration } } type timer struct { // done indicates to the timer that the timer was stopped. done *bool timer tcpip.Timer } type offLinkRoute struct { dest tcpip.Subnet router tcpip.Address } // ndpState is the per-Interface NDP state. type ndpState struct { // Do not allow overwriting this state. _ sync.NoCopy // The IPv6 endpoint this ndpState is for. ep *endpoint // configs is the per-interface NDP configurations. configs NDPConfigurations // The DAD timers to send the next NS message, or resolve the address. dad ip.DAD // The off-link routes discovered through Router Advertisements. offLinkRoutes map[offLinkRoute]offLinkRouteState // rtrSolicitTimer is the timer used to send the next router solicitation // message. // // rtrSolicitTimer is the zero value when NDP is not soliciting routers. rtrSolicitTimer timer // The on-link prefixes discovered through Router Advertisements' Prefix // Information option. onLinkPrefixes map[tcpip.Subnet]onLinkPrefixState // The SLAAC prefixes discovered through Router Advertisements' Prefix // Information option. slaacPrefixes map[tcpip.Subnet]slaacPrefixState // The last learned DHCPv6 configuration from an NDP RA. dhcpv6Configuration DHCPv6ConfigurationFromNDPRA // temporaryIIDHistory is the history value used to generate a new temporary // IID. temporaryIIDHistory [header.IIDSize]byte // temporaryAddressDesyncFactor is the preferred lifetime's desync factor for // temporary SLAAC addresses. temporaryAddressDesyncFactor time.Duration } // offLinkRouteState holds data associated with an off-link route discovered by // a Router Advertisement (RA). type offLinkRouteState struct { prf header.NDPRoutePreference // Job to invalidate the route. // // Must not be nil. invalidationJob *tcpip.Job } // onLinkPrefixState holds data associated with an on-link prefix discovered by // a Router Advertisement's Prefix Information option (PI) when the NDP // configurations was configured to do so. type onLinkPrefixState struct { // Job to invalidate the on-link prefix. // // Must not be nil. invalidationJob *tcpip.Job } // tempSLAACAddrState holds state associated with a temporary SLAAC address. type tempSLAACAddrState struct { // Job to deprecate the temporary SLAAC address. // // Must not be nil. deprecationJob *tcpip.Job // Job to invalidate the temporary SLAAC address. // // Must not be nil. invalidationJob *tcpip.Job // Job to regenerate the temporary SLAAC address. // // Must not be nil. regenJob *tcpip.Job createdAt tcpip.MonotonicTime // The address's endpoint. // // Must not be nil. addressEndpoint stack.AddressEndpoint // Has a new temporary SLAAC address already been regenerated? regenerated bool } // slaacPrefixState holds state associated with a SLAAC prefix. type slaacPrefixState struct { // Job to deprecate the prefix. // // Must not be nil. deprecationJob *tcpip.Job // Job to invalidate the prefix. // // Must not be nil. invalidationJob *tcpip.Job // nil iff the address is valid forever. validUntil *tcpip.MonotonicTime // nil iff the address is preferred forever. preferredUntil *tcpip.MonotonicTime // State associated with the stable address generated for the prefix. stableAddr struct { // The address's endpoint. // // May only be nil when the address is being (re-)generated. Otherwise, // must not be nil as all SLAAC prefixes must have a stable address. addressEndpoint stack.AddressEndpoint // The number of times an address has been generated locally where the IPv6 // endpoint already had the generated address. localGenerationFailures uint8 } // The temporary (short-lived) addresses generated for the SLAAC prefix. tempAddrs map[tcpip.Address]tempSLAACAddrState // The next two fields are used by both stable and temporary addresses // generated for a SLAAC prefix. This is safe as only 1 address is in the // generation and DAD process at any time. That is, no two addresses are // generated at the same time for a given SLAAC prefix. // The number of times an address has been generated and added to the IPv6 // endpoint. // // Addresses may be regenerated in reseponse to a DAD conflicts. generationAttempts uint8 // The maximum number of times to attempt regeneration of a SLAAC address // in response to DAD conflicts. maxGenerationAttempts uint8 } // startDuplicateAddressDetection performs Duplicate Address Detection. // // This function must only be called by IPv6 addresses that are currently // tentative. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) startDuplicateAddressDetection(addr tcpip.Address, addressEndpoint stack.AddressEndpoint) tcpip.Error { // addr must be a valid unicast IPv6 address. if !header.IsV6UnicastAddress(addr) { return &tcpip.ErrAddressFamilyNotSupported{} } if addressEndpoint.GetKind() != stack.PermanentTentative { // The endpoint should be marked as tentative since we are starting DAD. panic(fmt.Sprintf("ndpdad: addr %s is not tentative on NIC(%d)", addr, ndp.ep.nic.ID())) } ret := ndp.dad.CheckDuplicateAddressLocked(addr, func(r stack.DADResult) { if addressEndpoint.GetKind() != stack.PermanentTentative { // The endpoint should still be marked as tentative since we are still // performing DAD on it. panic(fmt.Sprintf("ndpdad: addr %s is no longer tentative on NIC(%d)", addr, ndp.ep.nic.ID())) } var dadSucceeded bool switch r.(type) { case *stack.DADAborted, *stack.DADError, *stack.DADDupAddrDetected: dadSucceeded = false case *stack.DADSucceeded: dadSucceeded = true default: panic(fmt.Sprintf("unrecognized DAD result = %T", r)) } if dadSucceeded { addressEndpoint.SetKind(stack.Permanent) } if ndpDisp := ndp.ep.protocol.options.NDPDisp; ndpDisp != nil { ndpDisp.OnDuplicateAddressDetectionResult(ndp.ep.nic.ID(), addr, r) } if dadSucceeded { if addressEndpoint.ConfigType() == stack.AddressConfigSlaac { // Reset the generation attempts counter as we are starting the // generation of a new address for the SLAAC prefix. ndp.regenerateTempSLAACAddr(addressEndpoint.AddressWithPrefix().Subnet(), true /* resetGenAttempts */) } ndp.ep.onAddressAssignedLocked(addr) } }) switch ret { case stack.DADStarting: case stack.DADAlreadyRunning: panic(fmt.Sprintf("ndpdad: already performing DAD for addr %s on NIC(%d)", addr, ndp.ep.nic.ID())) case stack.DADDisabled: addressEndpoint.SetKind(stack.Permanent) // Consider DAD to have resolved even if no DAD messages were actually // transmitted. if ndpDisp := ndp.ep.protocol.options.NDPDisp; ndpDisp != nil { ndpDisp.OnDuplicateAddressDetectionResult(ndp.ep.nic.ID(), addr, &stack.DADSucceeded{}) } ndp.ep.onAddressAssignedLocked(addr) } return nil } // stopDuplicateAddressDetection ends a running Duplicate Address Detection // process. Note, this may leave the DAD process for a tentative address in // such a state forever, unless some other external event resolves the DAD // process (receiving an NA from the true owner of addr, or an NS for addr // (implying another node is attempting to use addr)). It is up to the caller // of this function to handle such a scenario. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) stopDuplicateAddressDetection(addr tcpip.Address, reason stack.DADResult) { ndp.dad.StopLocked(addr, reason) } // handleRA handles a Router Advertisement message that arrived on the NIC // this ndp is for. Does nothing if the NIC is configured to not handle RAs. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) handleRA(ip tcpip.Address, ra header.NDPRouterAdvert) { // Is the IPv6 endpoint configured to handle RAs at all? // // Currently, the stack does not determine router interface status on a // per-interface basis; it is a protocol-wide configuration, so we check the // protocol's forwarding flag to determine if the IPv6 endpoint is forwarding // packets. if !ndp.configs.HandleRAs.enabled(ndp.ep.Forwarding()) { ndp.ep.stats.localStats.UnhandledRouterAdvertisements.Increment() return } // Only worry about the DHCPv6 configuration if we have an NDPDispatcher as we // only inform the dispatcher on configuration changes. We do nothing else // with the information. if ndpDisp := ndp.ep.protocol.options.NDPDisp; ndpDisp != nil { var configuration DHCPv6ConfigurationFromNDPRA switch { case ra.ManagedAddrConfFlag(): configuration = DHCPv6ManagedAddress case ra.OtherConfFlag(): configuration = DHCPv6OtherConfigurations default: configuration = DHCPv6NoConfiguration } if ndp.dhcpv6Configuration != configuration { ndp.dhcpv6Configuration = configuration ndpDisp.OnDHCPv6Configuration(ndp.ep.nic.ID(), configuration) } } // Is the IPv6 endpoint configured to discover default routers? if ndp.configs.DiscoverDefaultRouters { prf := ra.DefaultRouterPreference() if prf == header.ReservedRoutePreference { // As per RFC 4191 section 2.2, // // Prf (Default Router Preference) // // If the Reserved (10) value is received, the receiver MUST treat the // value as if it were (00). // // Note that the value 00 is the medium (default) router preference value. prf = header.MediumRoutePreference } // We represent default routers with a default (off-link) route through the // router. ndp.handleOffLinkRouteDiscovery(offLinkRoute{dest: header.IPv6EmptySubnet, router: ip}, ra.RouterLifetime(), prf) } // TODO(b/141556115): Do (RetransTimer, ReachableTime)) Parameter // Discovery. // We know the options is valid as far as wire format is concerned since // we got the Router Advertisement, as documented by this fn. Given this // we do not check the iterator for errors on calls to Next. it, _ := ra.Options().Iter(false) for opt, done, _ := it.Next(); !done; opt, done, _ = it.Next() { switch opt := opt.(type) { case header.NDPRecursiveDNSServer: if ndp.ep.protocol.options.NDPDisp == nil { continue } addrs, _ := opt.Addresses() ndp.ep.protocol.options.NDPDisp.OnRecursiveDNSServerOption(ndp.ep.nic.ID(), addrs, opt.Lifetime()) case header.NDPDNSSearchList: if ndp.ep.protocol.options.NDPDisp == nil { continue } domainNames, _ := opt.DomainNames() ndp.ep.protocol.options.NDPDisp.OnDNSSearchListOption(ndp.ep.nic.ID(), domainNames, opt.Lifetime()) case header.NDPPrefixInformation: prefix := opt.Subnet() // Is the prefix a link-local? if header.IsV6LinkLocalUnicastAddress(prefix.ID()) { // ...Yes, skip as per RFC 4861 section 6.3.4, // and RFC 4862 section 5.5.3.b (for SLAAC). continue } // Is the Prefix Length 0? if prefix.Prefix() == 0 { // ...Yes, skip as this is an invalid prefix // as all IPv6 addresses cannot be on-link. continue } if opt.OnLinkFlag() { ndp.handleOnLinkPrefixInformation(opt) } if opt.AutonomousAddressConfigurationFlag() { ndp.handleAutonomousPrefixInformation(opt) } } // TODO(b/141556115): Do (MTU) Parameter Discovery. } } // invalidateOffLinkRoute invalidates a discovered off-link route. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) invalidateOffLinkRoute(route offLinkRoute) { state, ok := ndp.offLinkRoutes[route] if !ok { return } state.invalidationJob.Cancel() delete(ndp.offLinkRoutes, route) // Let the integrator know a discovered off-link route is invalidated. if ndpDisp := ndp.ep.protocol.options.NDPDisp; ndpDisp != nil { ndpDisp.OnOffLinkRouteInvalidated(ndp.ep.nic.ID(), route.dest, route.router) } } // handleOffLinkRouteDiscovery handles the discovery of an off-link route. // // Precondition: ndp.ep.mu must be locked. func (ndp *ndpState) handleOffLinkRouteDiscovery(route offLinkRoute, lifetime time.Duration, prf header.NDPRoutePreference) { ndpDisp := ndp.ep.protocol.options.NDPDisp if ndpDisp == nil { return } state, ok := ndp.offLinkRoutes[route] switch { case !ok && lifetime != 0: // This is a new route we are discovering. // // Only remember it if we currently know about less than // MaxDiscoveredOffLinkRoutes routers. if len(ndp.offLinkRoutes) < MaxDiscoveredOffLinkRoutes { // Inform the integrator when we discovered an off-link route. ndpDisp.OnOffLinkRouteUpdated(ndp.ep.nic.ID(), route.dest, route.router, prf) state := offLinkRouteState{ prf: prf, invalidationJob: ndp.ep.protocol.stack.NewJob(&ndp.ep.mu, func() { ndp.invalidateOffLinkRoute(route) }), } state.invalidationJob.Schedule(lifetime) ndp.offLinkRoutes[route] = state } case ok && lifetime != 0: // This is an already discovered off-link route. Update the lifetime. state.invalidationJob.Cancel() state.invalidationJob.Schedule(lifetime) if prf != state.prf { state.prf = prf // Inform the integrator about route preference updates. ndpDisp.OnOffLinkRouteUpdated(ndp.ep.nic.ID(), route.dest, route.router, prf) } ndp.offLinkRoutes[route] = state case ok && lifetime == 0: // The already discovered off-link route is no longer considered valid so we // invalidate it immediately. ndp.invalidateOffLinkRoute(route) } } // rememberOnLinkPrefix remembers a newly discovered on-link prefix with IPv6 // address with prefix prefix with lifetime l. // // The prefix identified by prefix MUST NOT already be known. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) rememberOnLinkPrefix(prefix tcpip.Subnet, l time.Duration) { ndpDisp := ndp.ep.protocol.options.NDPDisp if ndpDisp == nil { return } // Inform the integrator when we discovered an on-link prefix. ndpDisp.OnOnLinkPrefixDiscovered(ndp.ep.nic.ID(), prefix) state := onLinkPrefixState{ invalidationJob: ndp.ep.protocol.stack.NewJob(&ndp.ep.mu, func() { ndp.invalidateOnLinkPrefix(prefix) }), } if l < header.NDPInfiniteLifetime { state.invalidationJob.Schedule(l) } ndp.onLinkPrefixes[prefix] = state } // invalidateOnLinkPrefix invalidates a discovered on-link prefix. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) invalidateOnLinkPrefix(prefix tcpip.Subnet) { s, ok := ndp.onLinkPrefixes[prefix] // Is the on-link prefix still discovered? if !ok { // ...Nope, do nothing further. return } s.invalidationJob.Cancel() delete(ndp.onLinkPrefixes, prefix) // Let the integrator know a discovered on-link prefix is invalidated. if ndpDisp := ndp.ep.protocol.options.NDPDisp; ndpDisp != nil { ndpDisp.OnOnLinkPrefixInvalidated(ndp.ep.nic.ID(), prefix) } } // handleOnLinkPrefixInformation handles a Prefix Information option with // its on-link flag set, as per RFC 4861 section 6.3.4. // // handleOnLinkPrefixInformation assumes that the prefix this pi is for is // not the link-local prefix and the on-link flag is set. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) handleOnLinkPrefixInformation(pi header.NDPPrefixInformation) { prefix := pi.Subnet() prefixState, ok := ndp.onLinkPrefixes[prefix] vl := pi.ValidLifetime() if !ok && vl == 0 { // Don't know about this prefix but it has a zero valid // lifetime, so just ignore. return } if !ok && vl != 0 { // This is a new on-link prefix we are discovering // // Only remember it if we currently know about less than // MaxDiscoveredOnLinkPrefixes on-link prefixes. if ndp.configs.DiscoverOnLinkPrefixes && len(ndp.onLinkPrefixes) < MaxDiscoveredOnLinkPrefixes { ndp.rememberOnLinkPrefix(prefix, vl) } return } if ok && vl == 0 { // We know about the on-link prefix, but it is // no longer to be considered on-link, so // invalidate it. ndp.invalidateOnLinkPrefix(prefix) return } // This is an already discovered on-link prefix with a // new non-zero valid lifetime. // // Update the invalidation job. prefixState.invalidationJob.Cancel() if vl < header.NDPInfiniteLifetime { // Prefix is valid for a finite lifetime, schedule the job to execute after // the new valid lifetime. prefixState.invalidationJob.Schedule(vl) } ndp.onLinkPrefixes[prefix] = prefixState } // handleAutonomousPrefixInformation handles a Prefix Information option with // its autonomous flag set, as per RFC 4862 section 5.5.3. // // handleAutonomousPrefixInformation assumes that the prefix this pi is for is // not the link-local prefix and the autonomous flag is set. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) handleAutonomousPrefixInformation(pi header.NDPPrefixInformation) { vl := pi.ValidLifetime() pl := pi.PreferredLifetime() // If the preferred lifetime is greater than the valid lifetime, // silently ignore the Prefix Information option, as per RFC 4862 // section 5.5.3.c. if pl > vl { return } prefix := pi.Subnet() // Check if we already maintain SLAAC state for prefix. if state, ok := ndp.slaacPrefixes[prefix]; ok { // As per RFC 4862 section 5.5.3.e, refresh prefix's SLAAC lifetimes. ndp.refreshSLAACPrefixLifetimes(prefix, &state, pl, vl) ndp.slaacPrefixes[prefix] = state return } // prefix is a new SLAAC prefix. Do the work as outlined by RFC 4862 section // 5.5.3.d if ndp is configured to auto-generate new addresses via SLAAC. if !ndp.configs.AutoGenGlobalAddresses { return } ndp.doSLAAC(prefix, pl, vl) } // doSLAAC generates a new SLAAC address with the provided lifetimes // for prefix. // // pl is the new preferred lifetime. vl is the new valid lifetime. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) doSLAAC(prefix tcpip.Subnet, pl, vl time.Duration) { // If we do not already have an address for this prefix and the valid // lifetime is 0, no need to do anything further, as per RFC 4862 // section 5.5.3.d. if vl == 0 { return } // Make sure the prefix is valid (as far as its length is concerned) to // generate a valid IPv6 address from an interface identifier (IID), as // per RFC 4862 sectiion 5.5.3.d. if prefix.Prefix() != validPrefixLenForAutoGen { return } state := slaacPrefixState{ deprecationJob: ndp.ep.protocol.stack.NewJob(&ndp.ep.mu, func() { state, ok := ndp.slaacPrefixes[prefix] if !ok { panic(fmt.Sprintf("ndp: must have a slaacPrefixes entry for the deprecated SLAAC prefix %s", prefix)) } ndp.deprecateSLAACAddress(state.stableAddr.addressEndpoint) }), invalidationJob: ndp.ep.protocol.stack.NewJob(&ndp.ep.mu, func() { state, ok := ndp.slaacPrefixes[prefix] if !ok { panic(fmt.Sprintf("ndp: must have a slaacPrefixes entry for the invalidated SLAAC prefix %s", prefix)) } ndp.invalidateSLAACPrefix(prefix, state) }), tempAddrs: make(map[tcpip.Address]tempSLAACAddrState), maxGenerationAttempts: ndp.configs.AutoGenAddressConflictRetries + 1, } now := ndp.ep.protocol.stack.Clock().NowMonotonic() // The time an address is preferred until is needed to properly generate the // address. if pl < header.NDPInfiniteLifetime { t := now.Add(pl) state.preferredUntil = &t } if !ndp.generateSLAACAddr(prefix, &state) { // We were unable to generate an address for the prefix, we do not nothing // further as there is no reason to maintain state or jobs for a prefix we // do not have an address for. return } // Setup the initial jobs to deprecate and invalidate prefix. if pl < header.NDPInfiniteLifetime && pl != 0 { state.deprecationJob.Schedule(pl) } if vl < header.NDPInfiniteLifetime { state.invalidationJob.Schedule(vl) t := now.Add(vl) state.validUntil = &t } // If the address is assigned (DAD resolved), generate a temporary address. if state.stableAddr.addressEndpoint.GetKind() == stack.Permanent { // Reset the generation attempts counter as we are starting the generation // of a new address for the SLAAC prefix. ndp.generateTempSLAACAddr(prefix, &state, true /* resetGenAttempts */) } ndp.slaacPrefixes[prefix] = state } // addAndAcquireSLAACAddr adds a SLAAC address to the IPv6 endpoint. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) addAndAcquireSLAACAddr(addr tcpip.AddressWithPrefix, configType stack.AddressConfigType, deprecated bool) stack.AddressEndpoint { // Inform the integrator that we have a new SLAAC address. ndpDisp := ndp.ep.protocol.options.NDPDisp if ndpDisp == nil { return nil } addressEndpoint, err := ndp.ep.addAndAcquirePermanentAddressLocked(addr, stack.FirstPrimaryEndpoint, configType, deprecated) if err != nil { panic(fmt.Sprintf("ndp: error when adding SLAAC address %+v: %s", addr, err)) } ndpDisp.OnAutoGenAddress(ndp.ep.nic.ID(), addr) return addressEndpoint } // generateSLAACAddr generates a SLAAC address for prefix. // // Returns true if an address was successfully generated. // // Panics if the prefix is not a SLAAC prefix or it already has an address. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) generateSLAACAddr(prefix tcpip.Subnet, state *slaacPrefixState) bool { if addressEndpoint := state.stableAddr.addressEndpoint; addressEndpoint != nil { panic(fmt.Sprintf("ndp: SLAAC prefix %s already has a permenant address %s", prefix, addressEndpoint.AddressWithPrefix())) } // If we have already reached the maximum address generation attempts for the // prefix, do not generate another address. if state.generationAttempts == state.maxGenerationAttempts { return false } var generatedAddr tcpip.AddressWithPrefix addrBytes := []byte(prefix.ID()) for i := 0; ; i++ { // If we were unable to generate an address after the maximum SLAAC address // local regeneration attempts, do nothing further. if i == maxSLAACAddrLocalRegenAttempts { return false } dadCounter := state.generationAttempts + state.stableAddr.localGenerationFailures if oIID := ndp.ep.protocol.options.OpaqueIIDOpts; oIID.NICNameFromID != nil { addrBytes = header.AppendOpaqueInterfaceIdentifier( addrBytes[:header.IIDOffsetInIPv6Address], prefix, oIID.NICNameFromID(ndp.ep.nic.ID(), ndp.ep.nic.Name()), dadCounter, oIID.SecretKey, ) } else if dadCounter == 0 { // Modified-EUI64 based IIDs have no way to resolve DAD conflicts, so if // the DAD counter is non-zero, we cannot use this method. // // Only attempt to generate an interface-specific IID if we have a valid // link address. // // TODO(b/141011931): Validate a LinkEndpoint's link address (provided by // LinkEndpoint.LinkAddress) before reaching this point. linkAddr := ndp.ep.nic.LinkAddress() if !header.IsValidUnicastEthernetAddress(linkAddr) { return false } // Generate an address within prefix from the modified EUI-64 of ndp's // NIC's Ethernet MAC address. header.EthernetAdddressToModifiedEUI64IntoBuf(linkAddr, addrBytes[header.IIDOffsetInIPv6Address:]) } else { // We have no way to regenerate an address in response to an address // conflict when addresses are not generated with opaque IIDs. return false } generatedAddr = tcpip.AddressWithPrefix{ Address: tcpip.Address(addrBytes), PrefixLen: validPrefixLenForAutoGen, } if !ndp.ep.hasPermanentAddressRLocked(generatedAddr.Address) { break } state.stableAddr.localGenerationFailures++ } deprecated := state.preferredUntil != nil && !state.preferredUntil.After(ndp.ep.protocol.stack.Clock().NowMonotonic()) if addressEndpoint := ndp.addAndAcquireSLAACAddr(generatedAddr, stack.AddressConfigSlaac, deprecated); addressEndpoint != nil { state.stableAddr.addressEndpoint = addressEndpoint state.generationAttempts++ return true } return false } // regenerateSLAACAddr regenerates an address for a SLAAC prefix. // // If generating a new address for the prefix fails, the prefix is invalidated. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) regenerateSLAACAddr(prefix tcpip.Subnet) { state, ok := ndp.slaacPrefixes[prefix] if !ok { panic(fmt.Sprintf("ndp: SLAAC prefix state not found to regenerate address for %s", prefix)) } if ndp.generateSLAACAddr(prefix, &state) { ndp.slaacPrefixes[prefix] = state return } // We were unable to generate a permanent address for the SLAAC prefix so // invalidate the prefix as there is no reason to maintain state for a // SLAAC prefix we do not have an address for. ndp.invalidateSLAACPrefix(prefix, state) } // generateTempSLAACAddr generates a new temporary SLAAC address. // // If resetGenAttempts is true, the prefix's generation counter is reset. // // Returns true if a new address was generated. func (ndp *ndpState) generateTempSLAACAddr(prefix tcpip.Subnet, prefixState *slaacPrefixState, resetGenAttempts bool) bool { // Are we configured to auto-generate new temporary global addresses for the // prefix? if !ndp.configs.AutoGenTempGlobalAddresses || prefix == header.IPv6LinkLocalPrefix.Subnet() { return false } if resetGenAttempts { prefixState.generationAttempts = 0 prefixState.maxGenerationAttempts = ndp.configs.AutoGenAddressConflictRetries + 1 } // If we have already reached the maximum address generation attempts for the // prefix, do not generate another address. if prefixState.generationAttempts == prefixState.maxGenerationAttempts { return false } stableAddr := prefixState.stableAddr.addressEndpoint.AddressWithPrefix().Address now := ndp.ep.protocol.stack.Clock().NowMonotonic() // As per RFC 4941 section 3.3 step 4, the valid lifetime of a temporary // address is the lower of the valid lifetime of the stable address or the // maximum temporary address valid lifetime. vl := ndp.configs.MaxTempAddrValidLifetime if prefixState.validUntil != nil { if prefixVL := prefixState.validUntil.Sub(now); vl > prefixVL { vl = prefixVL } } if vl <= 0 { // Cannot create an address without a valid lifetime. return false } // As per RFC 4941 section 3.3 step 4, the preferred lifetime of a temporary // address is the lower of the preferred lifetime of the stable address or the // maximum temporary address preferred lifetime - the temporary address desync // factor. pl := ndp.configs.MaxTempAddrPreferredLifetime - ndp.temporaryAddressDesyncFactor if prefixState.preferredUntil != nil { if prefixPL := prefixState.preferredUntil.Sub(now); pl > prefixPL { // Respect the preferred lifetime of the prefix, as per RFC 4941 section // 3.3 step 4. pl = prefixPL } } // As per RFC 4941 section 3.3 step 5, a temporary address is created only if // the calculated preferred lifetime is greater than the advance regeneration // duration. In particular, we MUST NOT create a temporary address with a zero // Preferred Lifetime. if pl <= ndp.configs.RegenAdvanceDuration { return false } // Attempt to generate a new address that is not already assigned to the IPv6 // endpoint. var generatedAddr tcpip.AddressWithPrefix for i := 0; ; i++ { // If we were unable to generate an address after the maximum SLAAC address // local regeneration attempts, do nothing further. if i == maxSLAACAddrLocalRegenAttempts { return false } generatedAddr = header.GenerateTempIPv6SLAACAddr(ndp.temporaryIIDHistory[:], stableAddr) if !ndp.ep.hasPermanentAddressRLocked(generatedAddr.Address) { break } } // As per RFC RFC 4941 section 3.3 step 5, we MUST NOT create a temporary // address with a zero preferred lifetime. The checks above ensure this // so we know the address is not deprecated. addressEndpoint := ndp.addAndAcquireSLAACAddr(generatedAddr, stack.AddressConfigSlaacTemp, false /* deprecated */) if addressEndpoint == nil { return false } state := tempSLAACAddrState{ deprecationJob: ndp.ep.protocol.stack.NewJob(&ndp.ep.mu, func() { prefixState, ok := ndp.slaacPrefixes[prefix] if !ok { panic(fmt.Sprintf("ndp: must have a slaacPrefixes entry for %s to deprecate temporary address %s", prefix, generatedAddr)) } tempAddrState, ok := prefixState.tempAddrs[generatedAddr.Address] if !ok { panic(fmt.Sprintf("ndp: must have a tempAddr entry to deprecate temporary address %s", generatedAddr)) } ndp.deprecateSLAACAddress(tempAddrState.addressEndpoint) }), invalidationJob: ndp.ep.protocol.stack.NewJob(&ndp.ep.mu, func() { prefixState, ok := ndp.slaacPrefixes[prefix] if !ok { panic(fmt.Sprintf("ndp: must have a slaacPrefixes entry for %s to invalidate temporary address %s", prefix, generatedAddr)) } tempAddrState, ok := prefixState.tempAddrs[generatedAddr.Address] if !ok { panic(fmt.Sprintf("ndp: must have a tempAddr entry to invalidate temporary address %s", generatedAddr)) } ndp.invalidateTempSLAACAddr(prefixState.tempAddrs, generatedAddr.Address, tempAddrState) }), regenJob: ndp.ep.protocol.stack.NewJob(&ndp.ep.mu, func() { prefixState, ok := ndp.slaacPrefixes[prefix] if !ok { panic(fmt.Sprintf("ndp: must have a slaacPrefixes entry for %s to regenerate temporary address after %s", prefix, generatedAddr)) } tempAddrState, ok := prefixState.tempAddrs[generatedAddr.Address] if !ok { panic(fmt.Sprintf("ndp: must have a tempAddr entry to regenerate temporary address after %s", generatedAddr)) } // If an address has already been regenerated for this address, don't // regenerate another address. if tempAddrState.regenerated { return } // Reset the generation attempts counter as we are starting the generation // of a new address for the SLAAC prefix. tempAddrState.regenerated = ndp.generateTempSLAACAddr(prefix, &prefixState, true /* resetGenAttempts */) prefixState.tempAddrs[generatedAddr.Address] = tempAddrState ndp.slaacPrefixes[prefix] = prefixState }), createdAt: now, addressEndpoint: addressEndpoint, } state.deprecationJob.Schedule(pl) state.invalidationJob.Schedule(vl) state.regenJob.Schedule(pl - ndp.configs.RegenAdvanceDuration) prefixState.generationAttempts++ prefixState.tempAddrs[generatedAddr.Address] = state return true } // regenerateTempSLAACAddr regenerates a temporary address for a SLAAC prefix. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) regenerateTempSLAACAddr(prefix tcpip.Subnet, resetGenAttempts bool) { state, ok := ndp.slaacPrefixes[prefix] if !ok { panic(fmt.Sprintf("ndp: SLAAC prefix state not found to regenerate temporary address for %s", prefix)) } ndp.generateTempSLAACAddr(prefix, &state, resetGenAttempts) ndp.slaacPrefixes[prefix] = state } // refreshSLAACPrefixLifetimes refreshes the lifetimes of a SLAAC prefix. // // pl is the new preferred lifetime. vl is the new valid lifetime. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) refreshSLAACPrefixLifetimes(prefix tcpip.Subnet, prefixState *slaacPrefixState, pl, vl time.Duration) { // If the preferred lifetime is zero, then the prefix should be deprecated. deprecated := pl == 0 if deprecated { ndp.deprecateSLAACAddress(prefixState.stableAddr.addressEndpoint) } else { prefixState.stableAddr.addressEndpoint.SetDeprecated(false) } // If prefix was preferred for some finite lifetime before, cancel the // deprecation job so it can be reset. prefixState.deprecationJob.Cancel() now := ndp.ep.protocol.stack.Clock().NowMonotonic() // Schedule the deprecation job if prefix has a finite preferred lifetime. if pl < header.NDPInfiniteLifetime { if !deprecated { prefixState.deprecationJob.Schedule(pl) } t := now.Add(pl) prefixState.preferredUntil = &t } else { prefixState.preferredUntil = nil } // As per RFC 4862 section 5.5.3.e, update the valid lifetime for prefix: // // 1) If the received Valid Lifetime is greater than 2 hours or greater than // RemainingLifetime, set the valid lifetime of the prefix to the // advertised Valid Lifetime. // // 2) If RemainingLifetime is less than or equal to 2 hours, ignore the // advertised Valid Lifetime. // // 3) Otherwise, reset the valid lifetime of the prefix to 2 hours. if vl >= header.NDPInfiniteLifetime { // Handle the infinite valid lifetime separately as we do not schedule a // job in this case. prefixState.invalidationJob.Cancel() prefixState.validUntil = nil } else { var effectiveVl time.Duration var rl time.Duration // If the prefix was originally set to be valid forever, assume the // remaining time to be the maximum possible value. if prefixState.validUntil == nil { rl = header.NDPInfiniteLifetime } else { rl = prefixState.validUntil.Sub(now) } if vl > MinPrefixInformationValidLifetimeForUpdate || vl > rl { effectiveVl = vl } else if rl > MinPrefixInformationValidLifetimeForUpdate { effectiveVl = MinPrefixInformationValidLifetimeForUpdate } if effectiveVl != 0 { prefixState.invalidationJob.Cancel() prefixState.invalidationJob.Schedule(effectiveVl) t := now.Add(effectiveVl) prefixState.validUntil = &t } } // If DAD is not yet complete on the stable address, there is no need to do // work with temporary addresses. if prefixState.stableAddr.addressEndpoint.GetKind() != stack.Permanent { return } // Note, we do not need to update the entries in the temporary address map // after updating the jobs because the jobs are held as pointers. var regenForAddr tcpip.Address allAddressesRegenerated := true for tempAddr, tempAddrState := range prefixState.tempAddrs { // As per RFC 4941 section 3.3 step 4, the valid lifetime of a temporary // address is the lower of the valid lifetime of the stable address or the // maximum temporary address valid lifetime. Note, the valid lifetime of a // temporary address is relative to the address's creation time. validUntil := tempAddrState.createdAt.Add(ndp.configs.MaxTempAddrValidLifetime) if prefixState.validUntil != nil && prefixState.validUntil.Before(validUntil) { validUntil = *prefixState.validUntil } // If the address is no longer valid, invalidate it immediately. Otherwise, // reset the invalidation job. newValidLifetime := validUntil.Sub(now) if newValidLifetime <= 0 { ndp.invalidateTempSLAACAddr(prefixState.tempAddrs, tempAddr, tempAddrState) continue } tempAddrState.invalidationJob.Cancel() tempAddrState.invalidationJob.Schedule(newValidLifetime) // As per RFC 4941 section 3.3 step 4, the preferred lifetime of a temporary // address is the lower of the preferred lifetime of the stable address or // the maximum temporary address preferred lifetime - the temporary address // desync factor. Note, the preferred lifetime of a temporary address is // relative to the address's creation time. preferredUntil := tempAddrState.createdAt.Add(ndp.configs.MaxTempAddrPreferredLifetime - ndp.temporaryAddressDesyncFactor) if prefixState.preferredUntil != nil && prefixState.preferredUntil.Before(preferredUntil) { preferredUntil = *prefixState.preferredUntil } // If the address is no longer preferred, deprecate it immediately. // Otherwise, schedule the deprecation job again. newPreferredLifetime := preferredUntil.Sub(now) tempAddrState.deprecationJob.Cancel() if newPreferredLifetime <= 0 { ndp.deprecateSLAACAddress(tempAddrState.addressEndpoint) } else { tempAddrState.addressEndpoint.SetDeprecated(false) tempAddrState.deprecationJob.Schedule(newPreferredLifetime) } tempAddrState.regenJob.Cancel() if tempAddrState.regenerated { } else { allAddressesRegenerated = false if newPreferredLifetime <= ndp.configs.RegenAdvanceDuration { // The new preferred lifetime is less than the advance regeneration // duration so regenerate an address for this temporary address // immediately after we finish iterating over the temporary addresses. regenForAddr = tempAddr } else { tempAddrState.regenJob.Schedule(newPreferredLifetime - ndp.configs.RegenAdvanceDuration) } } } // Generate a new temporary address if all of the existing temporary addresses // have been regenerated, or we need to immediately regenerate an address // due to an update in preferred lifetime. // // If each temporay address has already been regenerated, no new temporary // address is generated. To ensure continuation of temporary SLAAC addresses, // we manually try to regenerate an address here. if len(regenForAddr) != 0 || allAddressesRegenerated { // Reset the generation attempts counter as we are starting the generation // of a new address for the SLAAC prefix. if state, ok := prefixState.tempAddrs[regenForAddr]; ndp.generateTempSLAACAddr(prefix, prefixState, true /* resetGenAttempts */) && ok { state.regenerated = true prefixState.tempAddrs[regenForAddr] = state } } } // deprecateSLAACAddress marks the address as deprecated and notifies the NDP // dispatcher that address has been deprecated. // // deprecateSLAACAddress does nothing if the address is already deprecated. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) deprecateSLAACAddress(addressEndpoint stack.AddressEndpoint) { if addressEndpoint.Deprecated() { return } addressEndpoint.SetDeprecated(true) if ndpDisp := ndp.ep.protocol.options.NDPDisp; ndpDisp != nil { ndpDisp.OnAutoGenAddressDeprecated(ndp.ep.nic.ID(), addressEndpoint.AddressWithPrefix()) } } // invalidateSLAACPrefix invalidates a SLAAC prefix. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) invalidateSLAACPrefix(prefix tcpip.Subnet, state slaacPrefixState) { ndp.cleanupSLAACPrefixResources(prefix, state) if addressEndpoint := state.stableAddr.addressEndpoint; addressEndpoint != nil { if ndpDisp := ndp.ep.protocol.options.NDPDisp; ndpDisp != nil { ndpDisp.OnAutoGenAddressInvalidated(ndp.ep.nic.ID(), addressEndpoint.AddressWithPrefix()) } if err := ndp.ep.removePermanentEndpointInnerLocked(addressEndpoint, &stack.DADAborted{}); err != nil { panic(fmt.Sprintf("ndp: error removing stable SLAAC address %s: %s", addressEndpoint.AddressWithPrefix(), err)) } } } // cleanupSLAACAddrResourcesAndNotify cleans up an invalidated SLAAC address's // resources. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) cleanupSLAACAddrResourcesAndNotify(addr tcpip.AddressWithPrefix, invalidatePrefix bool) { if ndpDisp := ndp.ep.protocol.options.NDPDisp; ndpDisp != nil { ndpDisp.OnAutoGenAddressInvalidated(ndp.ep.nic.ID(), addr) } prefix := addr.Subnet() state, ok := ndp.slaacPrefixes[prefix] if !ok || state.stableAddr.addressEndpoint == nil || addr.Address != state.stableAddr.addressEndpoint.AddressWithPrefix().Address { return } if !invalidatePrefix { // If the prefix is not being invalidated, disassociate the address from the // prefix and do nothing further. state.stableAddr.addressEndpoint.DecRef() state.stableAddr.addressEndpoint = nil ndp.slaacPrefixes[prefix] = state return } ndp.cleanupSLAACPrefixResources(prefix, state) } // cleanupSLAACPrefixResources cleans up a SLAAC prefix's jobs and entry. // // Panics if the SLAAC prefix is not known. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) cleanupSLAACPrefixResources(prefix tcpip.Subnet, state slaacPrefixState) { // Invalidate all temporary addresses. for tempAddr, tempAddrState := range state.tempAddrs { ndp.invalidateTempSLAACAddr(state.tempAddrs, tempAddr, tempAddrState) } if state.stableAddr.addressEndpoint != nil { state.stableAddr.addressEndpoint.DecRef() state.stableAddr.addressEndpoint = nil } state.deprecationJob.Cancel() state.invalidationJob.Cancel() delete(ndp.slaacPrefixes, prefix) } // invalidateTempSLAACAddr invalidates a temporary SLAAC address. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) invalidateTempSLAACAddr(tempAddrs map[tcpip.Address]tempSLAACAddrState, tempAddr tcpip.Address, tempAddrState tempSLAACAddrState) { ndp.cleanupTempSLAACAddrResourcesAndNotifyInner(tempAddrs, tempAddr, tempAddrState) if err := ndp.ep.removePermanentEndpointInnerLocked(tempAddrState.addressEndpoint, &stack.DADAborted{}); err != nil { panic(fmt.Sprintf("error removing temporary SLAAC address %s: %s", tempAddrState.addressEndpoint.AddressWithPrefix(), err)) } } // cleanupTempSLAACAddrResourcesAndNotify cleans up an invalidated temporary // SLAAC address's resources from ndp and notifies the NDP dispatcher that the // address was invalidated. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) cleanupTempSLAACAddrResourcesAndNotify(addr tcpip.AddressWithPrefix) { prefix := addr.Subnet() state, ok := ndp.slaacPrefixes[prefix] if !ok { panic(fmt.Sprintf("ndp: must have a slaacPrefixes entry to clean up temp addr %s resources", addr)) } tempAddrState, ok := state.tempAddrs[addr.Address] if !ok { panic(fmt.Sprintf("ndp: must have a tempAddr entry to clean up temp addr %s resources", addr)) } ndp.cleanupTempSLAACAddrResourcesAndNotifyInner(state.tempAddrs, addr.Address, tempAddrState) } // cleanupTempSLAACAddrResourcesAndNotifyInner is like // cleanupTempSLAACAddrResourcesAndNotify except it does not lookup the // temporary address's state in ndp - it assumes the passed state is valid. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) cleanupTempSLAACAddrResourcesAndNotifyInner(tempAddrs map[tcpip.Address]tempSLAACAddrState, tempAddr tcpip.Address, tempAddrState tempSLAACAddrState) { if ndpDisp := ndp.ep.protocol.options.NDPDisp; ndpDisp != nil { ndpDisp.OnAutoGenAddressInvalidated(ndp.ep.nic.ID(), tempAddrState.addressEndpoint.AddressWithPrefix()) } tempAddrState.addressEndpoint.DecRef() tempAddrState.addressEndpoint = nil tempAddrState.deprecationJob.Cancel() tempAddrState.invalidationJob.Cancel() tempAddrState.regenJob.Cancel() delete(tempAddrs, tempAddr) } // cleanupState cleans up ndp's state. // // This function invalidates all discovered on-link prefixes, discovered // routers, and auto-generated addresses. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) cleanupState() { for prefix, state := range ndp.slaacPrefixes { ndp.invalidateSLAACPrefix(prefix, state) } for prefix := range ndp.onLinkPrefixes { ndp.invalidateOnLinkPrefix(prefix) } if got := len(ndp.onLinkPrefixes); got != 0 { panic(fmt.Sprintf("ndp: still have discovered on-link prefixes after cleaning up; found = %d", got)) } for route := range ndp.offLinkRoutes { ndp.invalidateOffLinkRoute(route) } if got := len(ndp.offLinkRoutes); got != 0 { panic(fmt.Sprintf("ndp: still have discovered off-link routes after cleaning up; found = %d", got)) } ndp.dhcpv6Configuration = 0 } // startSolicitingRouters starts soliciting routers, as per RFC 4861 section // 6.3.7. If routers are already being solicited, this function does nothing. // // If ndp is not configured to handle Router Advertisements, routers will not // be solicited as there is no point soliciting routers if we don't handle their // advertisements. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) startSolicitingRouters() { if ndp.rtrSolicitTimer.timer != nil { // We are already soliciting routers. return } remaining := ndp.configs.MaxRtrSolicitations if remaining == 0 { return } if !ndp.configs.HandleRAs.enabled(ndp.ep.Forwarding()) { return } // Calculate the random delay before sending our first RS, as per RFC // 4861 section 6.3.7. var delay time.Duration if ndp.configs.MaxRtrSolicitationDelay > 0 { delay = time.Duration(ndp.ep.protocol.stack.Rand().Int63n(int64(ndp.configs.MaxRtrSolicitationDelay))) } // Protected by ndp.ep.mu. done := false ndp.rtrSolicitTimer = timer{ done: &done, timer: ndp.ep.protocol.stack.Clock().AfterFunc(delay, func() { // As per RFC 4861 section 4.1: // // IP Fields: // Source Address // An IP address assigned to the sending interface, or // the unspecified address if no address is assigned // to the sending interface. localAddr := header.IPv6Any if addressEndpoint := ndp.ep.AcquireOutgoingPrimaryAddress(header.IPv6AllRoutersLinkLocalMulticastAddress, false); addressEndpoint != nil { localAddr = addressEndpoint.AddressWithPrefix().Address addressEndpoint.DecRef() } // As per RFC 4861 section 4.1, an NDP RS SHOULD include the source // link-layer address option if the source address of the NDP RS is // specified. This option MUST NOT be included if the source address is // unspecified. // // TODO(b/141011931): Validate a LinkEndpoint's link address (provided by // LinkEndpoint.LinkAddress) before reaching this point. var optsSerializer header.NDPOptionsSerializer linkAddress := ndp.ep.nic.LinkAddress() if localAddr != header.IPv6Any && header.IsValidUnicastEthernetAddress(linkAddress) { optsSerializer = header.NDPOptionsSerializer{ header.NDPSourceLinkLayerAddressOption(linkAddress), } } payloadSize := header.ICMPv6HeaderSize + header.NDPRSMinimumSize + optsSerializer.Length() icmpData := header.ICMPv6(buffer.NewView(payloadSize)) icmpData.SetType(header.ICMPv6RouterSolicit) rs := header.NDPRouterSolicit(icmpData.MessageBody()) rs.Options().Serialize(optsSerializer) icmpData.SetChecksum(header.ICMPv6Checksum(header.ICMPv6ChecksumParams{ Header: icmpData, Src: localAddr, Dst: header.IPv6AllRoutersLinkLocalMulticastAddress, })) pkt := stack.NewPacketBuffer(stack.PacketBufferOptions{ ReserveHeaderBytes: int(ndp.ep.MaxHeaderLength()), Data: buffer.View(icmpData).ToVectorisedView(), }) sent := ndp.ep.stats.icmp.packetsSent if err := addIPHeader(localAddr, header.IPv6AllRoutersLinkLocalMulticastAddress, pkt, stack.NetworkHeaderParams{ Protocol: header.ICMPv6ProtocolNumber, TTL: header.NDPHopLimit, }, nil /* extensionHeaders */); err != nil { panic(fmt.Sprintf("failed to add IP header: %s", err)) } if err := ndp.ep.nic.WritePacketToRemote(header.EthernetAddressFromMulticastIPv6Address(header.IPv6AllRoutersLinkLocalMulticastAddress), ProtocolNumber, pkt); err != nil { sent.dropped.Increment() // Don't send any more messages if we had an error. remaining = 0 } else { sent.routerSolicit.Increment() remaining-- } ndp.ep.mu.Lock() defer ndp.ep.mu.Unlock() if done { // Router solicitation was stopped. return } if remaining == 0 { // We are done soliciting routers. ndp.stopSolicitingRouters() return } ndp.rtrSolicitTimer.timer.Reset(ndp.configs.RtrSolicitationInterval) }), } } // forwardingChanged handles a change in forwarding configuration. // // If transitioning to a host, router solicitation will be started. Otherwise, // router solicitation will be stopped if NDP is not configured to handle RAs // as a router. // // Precondition: ndp.ep.mu must be locked. func (ndp *ndpState) forwardingChanged(forwarding bool) { if forwarding { if ndp.configs.HandleRAs.enabled(forwarding) { return } ndp.stopSolicitingRouters() return } // Solicit routers when transitioning to a host. // // If the endpoint is not currently enabled, routers will be solicited when // the endpoint becomes enabled (if it is still a host). if ndp.ep.Enabled() { ndp.startSolicitingRouters() } } // stopSolicitingRouters stops soliciting routers. If routers are not currently // being solicited, this function does nothing. // // The IPv6 endpoint that ndp belongs to MUST be locked. func (ndp *ndpState) stopSolicitingRouters() { if ndp.rtrSolicitTimer.timer == nil { // Nothing to do. return } ndp.rtrSolicitTimer.timer.Stop() *ndp.rtrSolicitTimer.done = true ndp.rtrSolicitTimer = timer{} } func (ndp *ndpState) init(ep *endpoint, dadOptions ip.DADOptions) { if ndp.offLinkRoutes != nil { panic("attempted to initialize NDP state twice") } ndp.ep = ep ndp.configs = ep.protocol.options.NDPConfigs ndp.dad.Init(&ndp.ep.mu, ep.protocol.options.DADConfigs, dadOptions) ndp.offLinkRoutes = make(map[offLinkRoute]offLinkRouteState) ndp.onLinkPrefixes = make(map[tcpip.Subnet]onLinkPrefixState) ndp.slaacPrefixes = make(map[tcpip.Subnet]slaacPrefixState) header.InitialTempIID(ndp.temporaryIIDHistory[:], ndp.ep.protocol.options.TempIIDSeed, ndp.ep.nic.ID()) ndp.temporaryAddressDesyncFactor = time.Duration(ep.protocol.stack.Rand().Int63n(int64(MaxDesyncFactor))) } func (ndp *ndpState) SendDADMessage(addr tcpip.Address, nonce []byte) tcpip.Error { snmc := header.SolicitedNodeAddr(addr) return ndp.ep.sendNDPNS(header.IPv6Any, snmc, addr, header.EthernetAddressFromMulticastIPv6Address(snmc), header.NDPOptionsSerializer{ header.NDPNonceOption(nonce), }) } func (e *endpoint) sendNDPNS(srcAddr, dstAddr, targetAddr tcpip.Address, remoteLinkAddr tcpip.LinkAddress, opts header.NDPOptionsSerializer) tcpip.Error { icmp := header.ICMPv6(buffer.NewView(header.ICMPv6NeighborSolicitMinimumSize + opts.Length())) icmp.SetType(header.ICMPv6NeighborSolicit) ns := header.NDPNeighborSolicit(icmp.MessageBody()) ns.SetTargetAddress(targetAddr) ns.Options().Serialize(opts) icmp.SetChecksum(header.ICMPv6Checksum(header.ICMPv6ChecksumParams{ Header: icmp, Src: srcAddr, Dst: dstAddr, })) pkt := stack.NewPacketBuffer(stack.PacketBufferOptions{ ReserveHeaderBytes: int(e.MaxHeaderLength()), Data: buffer.View(icmp).ToVectorisedView(), }) if err := addIPHeader(srcAddr, dstAddr, pkt, stack.NetworkHeaderParams{ Protocol: header.ICMPv6ProtocolNumber, TTL: header.NDPHopLimit, }, nil /* extensionHeaders */); err != nil { panic(fmt.Sprintf("failed to add IP header: %s", err)) } sent := e.stats.icmp.packetsSent err := e.nic.WritePacketToRemote(remoteLinkAddr, ProtocolNumber, pkt) if err != nil { sent.dropped.Increment() } else { sent.neighborSolicit.Increment() } return err }