// Copyright (C) 2014-2016 Nippon Telegraph and Telephone Corporation. // // 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 server import ( "fmt" "net" "time" "github.com/osrg/gobgp/internal/pkg/config" "github.com/osrg/gobgp/internal/pkg/table" "github.com/osrg/gobgp/pkg/packet/bgp" log "github.com/sirupsen/logrus" ) const ( flopThreshold = time.Second * 30 ) type peerGroup struct { Conf *config.PeerGroup members map[string]config.Neighbor dynamicNeighbors map[string]*config.DynamicNeighbor } func newPeerGroup(c *config.PeerGroup) *peerGroup { return &peerGroup{ Conf: c, members: make(map[string]config.Neighbor), dynamicNeighbors: make(map[string]*config.DynamicNeighbor), } } func (pg *peerGroup) AddMember(c config.Neighbor) { pg.members[c.State.NeighborAddress] = c } func (pg *peerGroup) DeleteMember(c config.Neighbor) { delete(pg.members, c.State.NeighborAddress) } func (pg *peerGroup) AddDynamicNeighbor(c *config.DynamicNeighbor) { pg.dynamicNeighbors[c.Config.Prefix] = c } func newDynamicPeer(g *config.Global, neighborAddress string, pg *config.PeerGroup, loc *table.TableManager, policy *table.RoutingPolicy) *peer { conf := config.Neighbor{ Config: config.NeighborConfig{ PeerGroup: pg.Config.PeerGroupName, }, State: config.NeighborState{ NeighborAddress: neighborAddress, }, Transport: config.Transport{ Config: config.TransportConfig{ PassiveMode: true, }, }, } if err := config.OverwriteNeighborConfigWithPeerGroup(&conf, pg); err != nil { log.WithFields(log.Fields{ "Topic": "Peer", "Key": neighborAddress, }).Debugf("Can't overwrite neighbor config: %s", err) return nil } if err := config.SetDefaultNeighborConfigValues(&conf, pg, g); err != nil { log.WithFields(log.Fields{ "Topic": "Peer", "Key": neighborAddress, }).Debugf("Can't set default config: %s", err) return nil } peer := newPeer(g, &conf, loc, policy) peer.fsm.lock.Lock() peer.fsm.state = bgp.BGP_FSM_ACTIVE peer.fsm.lock.Unlock() return peer } type peer struct { tableId string fsm *fsm adjRibIn *table.AdjRib policy *table.RoutingPolicy localRib *table.TableManager prefixLimitWarned map[bgp.RouteFamily]bool llgrEndChs []chan struct{} } func newPeer(g *config.Global, conf *config.Neighbor, loc *table.TableManager, policy *table.RoutingPolicy) *peer { peer := &peer{ localRib: loc, policy: policy, fsm: newFSM(g, conf), prefixLimitWarned: make(map[bgp.RouteFamily]bool), } if peer.isRouteServerClient() { peer.tableId = conf.State.NeighborAddress } else { peer.tableId = table.GLOBAL_RIB_NAME } rfs, _ := config.AfiSafis(conf.AfiSafis).ToRfList() peer.adjRibIn = table.NewAdjRib(rfs) return peer } func (peer *peer) AS() uint32 { peer.fsm.lock.RLock() defer peer.fsm.lock.RUnlock() return peer.fsm.pConf.State.PeerAs } func (peer *peer) ID() string { peer.fsm.lock.RLock() defer peer.fsm.lock.RUnlock() return peer.fsm.pConf.State.NeighborAddress } func (peer *peer) TableID() string { return peer.tableId } func (peer *peer) isIBGPPeer() bool { peer.fsm.lock.RLock() defer peer.fsm.lock.RUnlock() return peer.fsm.pConf.State.PeerType == config.PEER_TYPE_INTERNAL } func (peer *peer) isRouteServerClient() bool { peer.fsm.lock.RLock() defer peer.fsm.lock.RUnlock() return peer.fsm.pConf.RouteServer.Config.RouteServerClient } func (peer *peer) isSecondaryRouteEnabled() bool { peer.fsm.lock.RLock() defer peer.fsm.lock.RUnlock() return peer.fsm.pConf.RouteServer.Config.RouteServerClient && peer.fsm.pConf.RouteServer.Config.SecondaryRoute } func (peer *peer) isRouteReflectorClient() bool { peer.fsm.lock.RLock() defer peer.fsm.lock.RUnlock() return peer.fsm.pConf.RouteReflector.Config.RouteReflectorClient } func (peer *peer) isGracefulRestartEnabled() bool { peer.fsm.lock.RLock() defer peer.fsm.lock.RUnlock() return peer.fsm.pConf.GracefulRestart.State.Enabled } func (peer *peer) getAddPathMode(family bgp.RouteFamily) bgp.BGPAddPathMode { peer.fsm.lock.RLock() defer peer.fsm.lock.RUnlock() if mode, y := peer.fsm.rfMap[family]; y { return mode } return bgp.BGP_ADD_PATH_NONE } func (peer *peer) isAddPathReceiveEnabled(family bgp.RouteFamily) bool { return (peer.getAddPathMode(family) & bgp.BGP_ADD_PATH_RECEIVE) > 0 } func (peer *peer) isAddPathSendEnabled(family bgp.RouteFamily) bool { return (peer.getAddPathMode(family) & bgp.BGP_ADD_PATH_SEND) > 0 } func (peer *peer) isDynamicNeighbor() bool { peer.fsm.lock.RLock() defer peer.fsm.lock.RUnlock() return peer.fsm.pConf.Config.NeighborAddress == "" && peer.fsm.pConf.Config.NeighborInterface == "" } func (peer *peer) recvedAllEOR() bool { peer.fsm.lock.RLock() defer peer.fsm.lock.RUnlock() for _, a := range peer.fsm.pConf.AfiSafis { if s := a.MpGracefulRestart.State; s.Enabled && !s.EndOfRibReceived { return false } } return true } func (peer *peer) configuredRFlist() []bgp.RouteFamily { peer.fsm.lock.RLock() defer peer.fsm.lock.RUnlock() rfs, _ := config.AfiSafis(peer.fsm.pConf.AfiSafis).ToRfList() return rfs } func (peer *peer) negotiatedRFList() []bgp.RouteFamily { peer.fsm.lock.RLock() defer peer.fsm.lock.RUnlock() l := make([]bgp.RouteFamily, 0, len(peer.fsm.rfMap)) for family := range peer.fsm.rfMap { l = append(l, family) } return l } func (peer *peer) toGlobalFamilies(families []bgp.RouteFamily) []bgp.RouteFamily { id := peer.ID() peer.fsm.lock.RLock() defer peer.fsm.lock.RUnlock() if peer.fsm.pConf.Config.Vrf != "" { fs := make([]bgp.RouteFamily, 0, len(families)) for _, f := range families { switch f { case bgp.RF_IPv4_UC: fs = append(fs, bgp.RF_IPv4_VPN) case bgp.RF_IPv6_UC: fs = append(fs, bgp.RF_IPv6_VPN) case bgp.RF_FS_IPv4_UC: fs = append(fs, bgp.RF_FS_IPv4_VPN) case bgp.RF_FS_IPv6_UC: fs = append(fs, bgp.RF_FS_IPv6_VPN) default: log.WithFields(log.Fields{ "Topic": "Peer", "Key": id, "Family": f, "VRF": peer.fsm.pConf.Config.Vrf, }).Warn("invalid family configured for neighbor with vrf") } } families = fs } return families } func classifyFamilies(all, part []bgp.RouteFamily) ([]bgp.RouteFamily, []bgp.RouteFamily) { a := []bgp.RouteFamily{} b := []bgp.RouteFamily{} for _, f := range all { p := true for _, g := range part { if f == g { p = false a = append(a, f) break } } if p { b = append(b, f) } } return a, b } func (peer *peer) forwardingPreservedFamilies() ([]bgp.RouteFamily, []bgp.RouteFamily) { peer.fsm.lock.RLock() list := []bgp.RouteFamily{} for _, a := range peer.fsm.pConf.AfiSafis { if s := a.MpGracefulRestart.State; s.Enabled && s.Received { list = append(list, a.State.Family) } } peer.fsm.lock.RUnlock() return classifyFamilies(peer.configuredRFlist(), list) } func (peer *peer) llgrFamilies() ([]bgp.RouteFamily, []bgp.RouteFamily) { peer.fsm.lock.RLock() list := []bgp.RouteFamily{} for _, a := range peer.fsm.pConf.AfiSafis { if a.LongLivedGracefulRestart.State.Enabled { list = append(list, a.State.Family) } } peer.fsm.lock.RUnlock() return classifyFamilies(peer.configuredRFlist(), list) } func (peer *peer) isLLGREnabledFamily(family bgp.RouteFamily) bool { peer.fsm.lock.RLock() llgrEnabled := peer.fsm.pConf.GracefulRestart.Config.LongLivedEnabled peer.fsm.lock.RUnlock() if !llgrEnabled { return false } fs, _ := peer.llgrFamilies() for _, f := range fs { if f == family { return true } } return false } func (peer *peer) llgrRestartTime(family bgp.RouteFamily) uint32 { peer.fsm.lock.RLock() defer peer.fsm.lock.RUnlock() for _, a := range peer.fsm.pConf.AfiSafis { if a.State.Family == family { return a.LongLivedGracefulRestart.State.PeerRestartTime } } return 0 } func (peer *peer) llgrRestartTimerExpired(family bgp.RouteFamily) bool { peer.fsm.lock.RLock() defer peer.fsm.lock.RUnlock() all := true for _, a := range peer.fsm.pConf.AfiSafis { if a.State.Family == family { a.LongLivedGracefulRestart.State.PeerRestartTimerExpired = true } s := a.LongLivedGracefulRestart.State if s.Received && !s.PeerRestartTimerExpired { all = false } } return all } func (peer *peer) markLLGRStale(fs []bgp.RouteFamily) []*table.Path { return peer.adjRibIn.MarkLLGRStaleOrDrop(fs) } func (peer *peer) stopPeerRestarting() { peer.fsm.lock.Lock() defer peer.fsm.lock.Unlock() peer.fsm.pConf.GracefulRestart.State.PeerRestarting = false for _, ch := range peer.llgrEndChs { close(ch) } peer.llgrEndChs = make([]chan struct{}, 0) } func (peer *peer) filterPathFromSourcePeer(path, old *table.Path) *table.Path { if peer.ID() != path.GetSource().Address.String() { return path } // Note: Multiple paths having the same prefix could exist the withdrawals // list in the case of Route Server setup with import policies modifying // paths. In such case, gobgp sends duplicated update messages; withdraw // messages for the same prefix. if !peer.isRouteServerClient() { if peer.isRouteReflectorClient() && path.GetRouteFamily() == bgp.RF_RTC_UC { // When the peer is a Route Reflector client and the given path // contains the Route Tartget Membership NLRI, the path should not // be withdrawn in order to signal the client to distribute routes // with the specific RT to Route Reflector. return path } else if !path.IsWithdraw && old != nil && old.GetSource().Address.String() != peer.ID() { // Say, peer A and B advertized same prefix P, and best path // calculation chose a path from B as best. When B withdraws prefix // P, best path calculation chooses the path from A as best. For // peers other than A, this path should be advertised (as implicit // withdrawal). However for A, we should advertise the withdrawal // path. Thing is same when peer A and we advertized prefix P (as // local route), then, we withdraws the prefix. return old.Clone(true) } } log.WithFields(log.Fields{ "Topic": "Peer", "Key": peer.ID(), "Data": path, }).Debug("From me, ignore.") return nil } func (peer *peer) doPrefixLimit(k bgp.RouteFamily, c *config.PrefixLimitConfig) *bgp.BGPMessage { if maxPrefixes := int(c.MaxPrefixes); maxPrefixes > 0 { count := peer.adjRibIn.Count([]bgp.RouteFamily{k}) pct := int(c.ShutdownThresholdPct) if pct > 0 && !peer.prefixLimitWarned[k] && count > (maxPrefixes*pct/100) { peer.prefixLimitWarned[k] = true log.WithFields(log.Fields{ "Topic": "Peer", "Key": peer.ID(), "AddressFamily": k.String(), }).Warnf("prefix limit %d%% reached", pct) } if count > maxPrefixes { log.WithFields(log.Fields{ "Topic": "Peer", "Key": peer.ID(), "AddressFamily": k.String(), }).Warnf("prefix limit reached") return bgp.NewBGPNotificationMessage(bgp.BGP_ERROR_CEASE, bgp.BGP_ERROR_SUB_MAXIMUM_NUMBER_OF_PREFIXES_REACHED, nil) } } return nil } func (peer *peer) updatePrefixLimitConfig(c []config.AfiSafi) error { peer.fsm.lock.RLock() x := peer.fsm.pConf.AfiSafis peer.fsm.lock.RUnlock() y := c if len(x) != len(y) { return fmt.Errorf("changing supported afi-safi is not allowed") } m := make(map[bgp.RouteFamily]config.PrefixLimitConfig) for _, e := range x { m[e.State.Family] = e.PrefixLimit.Config } for _, e := range y { if p, ok := m[e.State.Family]; !ok { return fmt.Errorf("changing supported afi-safi is not allowed") } else if !p.Equal(&e.PrefixLimit.Config) { log.WithFields(log.Fields{ "Topic": "Peer", "Key": peer.ID(), "AddressFamily": e.Config.AfiSafiName, "OldMaxPrefixes": p.MaxPrefixes, "NewMaxPrefixes": e.PrefixLimit.Config.MaxPrefixes, "OldShutdownThresholdPct": p.ShutdownThresholdPct, "NewShutdownThresholdPct": e.PrefixLimit.Config.ShutdownThresholdPct, }).Warnf("update prefix limit configuration") peer.prefixLimitWarned[e.State.Family] = false if msg := peer.doPrefixLimit(e.State.Family, &e.PrefixLimit.Config); msg != nil { sendfsmOutgoingMsg(peer, nil, msg, true) } } } peer.fsm.lock.Lock() peer.fsm.pConf.AfiSafis = c peer.fsm.lock.Unlock() return nil } func (peer *peer) handleUpdate(e *fsmMsg) ([]*table.Path, []bgp.RouteFamily, *bgp.BGPMessage) { m := e.MsgData.(*bgp.BGPMessage) update := m.Body.(*bgp.BGPUpdate) log.WithFields(log.Fields{ "Topic": "Peer", "Key": peer.fsm.pConf.State.NeighborAddress, "nlri": update.NLRI, "withdrawals": update.WithdrawnRoutes, "attributes": update.PathAttributes, }).Debug("received update") peer.fsm.lock.Lock() peer.fsm.pConf.Timers.State.UpdateRecvTime = time.Now().Unix() peer.fsm.lock.Unlock() if len(e.PathList) > 0 { paths := make([]*table.Path, 0, len(e.PathList)) eor := []bgp.RouteFamily{} for _, path := range e.PathList { if path.IsEOR() { family := path.GetRouteFamily() log.WithFields(log.Fields{ "Topic": "Peer", "Key": peer.ID(), "AddressFamily": family, }).Debug("EOR received") eor = append(eor, family) continue } // RFC4271 9.1.2 Phase 2: Route Selection // // If the AS_PATH attribute of a BGP route contains an AS loop, the BGP // route should be excluded from the Phase 2 decision function. if aspath := path.GetAsPath(); aspath != nil { peer.fsm.lock.RLock() localAS := peer.fsm.peerInfo.LocalAS allowOwnAS := int(peer.fsm.pConf.AsPathOptions.Config.AllowOwnAs) peer.fsm.lock.RUnlock() if hasOwnASLoop(localAS, allowOwnAS, aspath) { path.SetRejected(true) continue } } // RFC4456 8. Avoiding Routing Information Loops // A router that recognizes the ORIGINATOR_ID attribute SHOULD // ignore a route received with its BGP Identifier as the ORIGINATOR_ID. isIBGPPeer := peer.isIBGPPeer() peer.fsm.lock.RLock() routerId := peer.fsm.gConf.Config.RouterId peer.fsm.lock.RUnlock() if isIBGPPeer { if id := path.GetOriginatorID(); routerId == id.String() { log.WithFields(log.Fields{ "Topic": "Peer", "Key": peer.ID(), "OriginatorID": id, "Data": path, }).Debug("Originator ID is mine, ignore") path.SetRejected(true) continue } } paths = append(paths, path) } peer.adjRibIn.Update(e.PathList) peer.fsm.lock.RLock() peerAfiSafis := peer.fsm.pConf.AfiSafis peer.fsm.lock.RUnlock() for _, af := range peerAfiSafis { if msg := peer.doPrefixLimit(af.State.Family, &af.PrefixLimit.Config); msg != nil { return nil, nil, msg } } return paths, eor, nil } return nil, nil, nil } func (peer *peer) startFSMHandler() { handler := newFSMHandler(peer.fsm, peer.fsm.outgoingCh) peer.fsm.lock.Lock() peer.fsm.h = handler peer.fsm.lock.Unlock() } func (peer *peer) StaleAll(rfList []bgp.RouteFamily) []*table.Path { return peer.adjRibIn.StaleAll(rfList) } func (peer *peer) PassConn(conn *net.TCPConn) { select { case peer.fsm.connCh <- conn: default: conn.Close() log.WithFields(log.Fields{ "Topic": "Peer", "Key": peer.ID(), }).Warn("accepted conn is closed to avoid be blocked") } } func (peer *peer) DropAll(rfList []bgp.RouteFamily) []*table.Path { return peer.adjRibIn.Drop(rfList) }