package consul import ( "context" "errors" "math/rand" "sort" "sync" "time" "github.com/hashicorp/consul/agent/consul/state" "github.com/hashicorp/consul/agent/structs" "github.com/hashicorp/consul/api" "github.com/hashicorp/consul/ipaddr" "github.com/hashicorp/consul/lib/stringslice" "github.com/hashicorp/consul/logging" "github.com/hashicorp/go-hclog" memdb "github.com/hashicorp/go-memdb" ) // GatewayLocator assists in selecting an appropriate mesh gateway when wan // federation via mesh gateways is enabled. // // This is exclusively used by the consul server itself when it needs to tunnel // RPC or gossip through a mesh gateway to reach its ultimate destination. // // During secondary datacenter bootstrapping there is a phase where it is // impossible for mesh gateways in the secondary datacenter to register // themselves into the catalog to be discovered by the servers, so the servers // maintain references for the mesh gateways in the primary in addition to its // own local mesh gateways. // // After initial datacenter federation the primary mesh gateways are only used // in extreme fallback situations (basically re-bootstrapping). // // For all other operations a consul server will ALWAYS contact a local mesh // gateway to ultimately forward the request through a remote mesh gateway to // reach its destination. type GatewayLocator struct { logger hclog.Logger srv serverDelegate datacenter string // THIS dc primaryDatacenter string // these ONLY contain ones that have the wanfed:1 meta gatewaysLock sync.Mutex primaryGateways []string // WAN addrs localGateways []string // LAN addrs populatedGateways bool // primaryMeshGatewayDiscoveredAddresses is the current fallback addresses // for the mesh gateways in the primary datacenter. primaryMeshGatewayDiscoveredAddresses []string primaryMeshGatewayDiscoveredAddressesLock sync.Mutex // This will be closed the FIRST time we get some gateways populated primaryGatewaysReadyCh chan struct{} primaryGatewaysReadyOnce sync.Once // these are a collection of measurements that factor into deciding if we // should directly dial the primary's mesh gateways or if we should try to // route through our local gateways (if they are up). lastReplLock sync.Mutex lastReplSuccess time.Time lastReplFailure time.Time lastReplSuccesses uint64 lastReplFailures uint64 useReplicationSignal bool // this should be set to true on the leader } // SetLastFederationStateReplicationError is used to indicate if the federation // state replication loop has succeeded (nil) or failed during the last // execution. // // Rather than introduce a completely new mechanism to periodically probe that // our chosen mesh-gateway configuration can reach the primary's servers (like // a ping or status RPC) we cheat and use the federation state replicator // goroutine's success or failure as a proxy. func (g *GatewayLocator) SetLastFederationStateReplicationError(err error, fromReplication bool) { if g == nil { return } g.lastReplLock.Lock() defer g.lastReplLock.Unlock() oldChoice := g.dialPrimaryThroughLocalGateway() if err == nil { g.lastReplSuccess = time.Now().UTC() g.lastReplSuccesses++ g.lastReplFailures = 0 if fromReplication { // If we get info from replication, assume replication is operating. g.useReplicationSignal = true } } else { g.lastReplFailure = time.Now().UTC() g.lastReplFailures++ g.lastReplSuccesses = 0 } newChoice := g.dialPrimaryThroughLocalGateway() if oldChoice != newChoice { g.logPrimaryDialingMessage(newChoice) } } func (g *GatewayLocator) SetUseReplicationSignal(newValue bool) { if g == nil { return } g.lastReplLock.Lock() g.useReplicationSignal = newValue g.lastReplLock.Unlock() } func (g *GatewayLocator) logPrimaryDialingMessage(useLocal bool) { if g.datacenter == g.primaryDatacenter { // These messages are useless when the server is in the primary // datacenter. return } if useLocal { g.logger.Info("will dial the primary datacenter using our local mesh gateways if possible") } else { g.logger.Info("will dial the primary datacenter through its mesh gateways") } } // DialPrimaryThroughLocalGateway determines if we should dial the primary's // mesh gateways directly or use our local mesh gateways (if they are up). // // Generally the system has three states: // // 1. Servers dial primary MGWs using fallback addresses from the agent config. // 2. Servers dial primary MGWs using replicated federation state data. // 3. Servers dial primary MGWs indirectly through local MGWs. // // After initial bootstrapping most communication should go through (3). If the // local mesh gateways are not coming up for chicken/egg problems (mostly the // kind that arise from secondary datacenter bootstrapping) then (2) is useful // to solve the chicken/egg problem and get back to (3). In the worst case // where we completely lost communication with the primary AND all of their old // mesh gateway addresses are changed then we need to go all the way back to // square one and re-bootstrap via (1). // // Since both (1) and (2) are meant to be temporary we simplify things and make // the system only consider two overall configurations: (1+2, with the // addresses being unioned) or (3). // // This method returns true if in state (3) and false if in state (1+2). func (g *GatewayLocator) DialPrimaryThroughLocalGateway() bool { if g.datacenter == g.primaryDatacenter { return false // not important } g.lastReplLock.Lock() defer g.lastReplLock.Unlock() return g.dialPrimaryThroughLocalGateway() } const localFederationStateReplicatorFailuresBeforeDialingDirectly = 3 func (g *GatewayLocator) dialPrimaryThroughLocalGateway() bool { if !g.useReplicationSignal { // Followers should blindly assume these gateways work. The leader will // try to bypass them and correct the replicated federation state info // that the followers will eventually pick up on. return true } if g.lastReplSuccess.IsZero() && g.lastReplFailure.IsZero() { return false // no data yet } if g.lastReplSuccess.After(g.lastReplFailure) { return true // we have viable data } if g.lastReplFailures < localFederationStateReplicatorFailuresBeforeDialingDirectly { return true // maybe it's just a little broken } return false } // PrimaryMeshGatewayAddressesReadyCh returns a channel that will be closed // when federation state replication ships back at least one primary mesh // gateway (not via fallback config). func (g *GatewayLocator) PrimaryMeshGatewayAddressesReadyCh() <-chan struct{} { return g.primaryGatewaysReadyCh } // PickGateway returns the address for a gateway suitable for reaching the // provided datacenter. func (g *GatewayLocator) PickGateway(dc string) string { item := g.pickGateway(dc == g.primaryDatacenter) g.logger.Trace("picking gateway for transit", "gateway", item, "source_datacenter", g.datacenter, "dest_datacenter", dc) return item } func (g *GatewayLocator) pickGateway(primary bool) string { addrs := g.listGateways(primary) return getRandomItem(addrs) } func (g *GatewayLocator) listGateways(primary bool) []string { g.gatewaysLock.Lock() defer g.gatewaysLock.Unlock() if !g.populatedGateways { return nil // don't even do anything yet } var addrs []string if primary { if g.datacenter == g.primaryDatacenter { addrs = g.primaryGateways } else if g.DialPrimaryThroughLocalGateway() && len(g.localGateways) > 0 { addrs = g.localGateways } else { // Note calling StringSliceMergeSorted only works because both // inputs are pre-sorted. If for some reason one of the lists has // *duplicates* (which shouldn't happen) it's not great but it // won't break anything other than biasing our eventual random // choice a little bit. addrs = stringslice.MergeSorted(g.primaryGateways, g.PrimaryGatewayFallbackAddresses()) } } else { addrs = g.localGateways } return addrs } // RefreshPrimaryGatewayFallbackAddresses is used to update the list of current // fallback addresses for locating mesh gateways in the primary datacenter. func (g *GatewayLocator) RefreshPrimaryGatewayFallbackAddresses(addrs []string) { sort.Strings(addrs) g.primaryMeshGatewayDiscoveredAddressesLock.Lock() defer g.primaryMeshGatewayDiscoveredAddressesLock.Unlock() if !stringslice.Equal(addrs, g.primaryMeshGatewayDiscoveredAddresses) { g.primaryMeshGatewayDiscoveredAddresses = addrs g.logger.Info("updated fallback list of primary mesh gateways", "mesh_gateways", addrs) } } // PrimaryGatewayFallbackAddresses returns the current set of discovered // fallback addresses for the mesh gateways in the primary datacenter. func (g *GatewayLocator) PrimaryGatewayFallbackAddresses() []string { g.primaryMeshGatewayDiscoveredAddressesLock.Lock() defer g.primaryMeshGatewayDiscoveredAddressesLock.Unlock() out := make([]string, len(g.primaryMeshGatewayDiscoveredAddresses)) copy(out, g.primaryMeshGatewayDiscoveredAddresses) return out } func getRandomItem(items []string) string { switch len(items) { case 0: return "" case 1: return items[0] default: idx := int(rand.Int31n(int32(len(items)))) return items[idx] } } type serverDelegate interface { blockingQuery(queryOpts structs.QueryOptionsCompat, queryMeta structs.QueryMetaCompat, fn queryFn) error IsLeader() bool LeaderLastContact() time.Time setDatacenterSupportsFederationStates() } func NewGatewayLocator( logger hclog.Logger, srv serverDelegate, datacenter string, primaryDatacenter string, ) *GatewayLocator { g := &GatewayLocator{ logger: logger.Named(logging.GatewayLocator), srv: srv, datacenter: datacenter, primaryDatacenter: primaryDatacenter, primaryGatewaysReadyCh: make(chan struct{}), } g.logPrimaryDialingMessage(g.DialPrimaryThroughLocalGateway()) // initialize g.SetLastFederationStateReplicationError(nil, false) return g } var errGatewayLocalStateNotInitialized = errors.New("local state not initialized") func (g *GatewayLocator) Run(ctx context.Context) { var lastFetchIndex uint64 retryLoopBackoff(ctx, func() error { idx, err := g.runOnce(lastFetchIndex) if errors.Is(err, errGatewayLocalStateNotInitialized) { // don't do exponential backoff for something that's not broken return nil } else if err != nil { return err } lastFetchIndex = idx return nil }, func(err error) { g.logger.Error("error tracking primary and local mesh gateways", "error", err) }) } func (g *GatewayLocator) runOnce(lastFetchIndex uint64) (uint64, error) { if err := g.checkLocalStateIsReady(); err != nil { return 0, err } // NOTE: we can't do RPC here because we won't have a token so we'll just // mostly assume that our FSM is caught up enough to answer locally. If // this has drifted it's no different than a cache that drifts or an // inconsistent read. queryOpts := &structs.QueryOptions{ MinQueryIndex: lastFetchIndex, RequireConsistent: false, } var ( results []*structs.FederationState queryMeta structs.QueryMeta ) err := g.srv.blockingQuery( queryOpts, &queryMeta, func(ws memdb.WatchSet, state *state.Store) error { // Get the existing stored version of this config that has replicated down. // We could phone home to get this but that would incur extra WAN traffic // when we already have enough information locally to figure it out // (assuming that our replicator is still functioning). idx, all, err := state.FederationStateList(ws) if err != nil { return err } queryMeta.Index = idx results = all return nil }) if err != nil { return 0, err } g.updateFromState(results) return queryMeta.Index, nil } // checkLocalStateIsReady is inlined a bit from (*Server).ForwardRPC(). We need to // wait until our own state machine is safe to read from. func (g *GatewayLocator) checkLocalStateIsReady() error { // Check if we can allow a stale read, ensure our local DB is initialized if !g.srv.LeaderLastContact().IsZero() { return nil // the raft leader talked to us } if g.srv.IsLeader() { return nil // we are the leader } return errGatewayLocalStateNotInitialized } func (g *GatewayLocator) updateFromState(results []*structs.FederationState) { if len(results) > 0 { g.srv.setDatacenterSupportsFederationStates() } var ( local structs.CheckServiceNodes primary structs.CheckServiceNodes ) for _, config := range results { retained := retainGateways(config.MeshGateways) if config.Datacenter == g.datacenter { local = retained } // NOT else-if because conditionals are not mutually exclusive if config.Datacenter == g.primaryDatacenter { primary = retained } } primaryAddrs := renderGatewayAddrs(primary, true) localAddrs := renderGatewayAddrs(local, false) g.gatewaysLock.Lock() defer g.gatewaysLock.Unlock() g.populatedGateways = true changed := false primaryReady := false if !stringslice.Equal(g.primaryGateways, primaryAddrs) { g.primaryGateways = primaryAddrs primaryReady = len(g.primaryGateways) > 0 changed = true } if !stringslice.Equal(g.localGateways, localAddrs) { g.localGateways = localAddrs changed = true } if changed { g.logger.Info( "new cached locations of mesh gateways", "primary", primaryAddrs, "local", localAddrs, ) } if primaryReady { g.primaryGatewaysReadyOnce.Do(func() { close(g.primaryGatewaysReadyCh) }) } } func retainGateways(full structs.CheckServiceNodes) structs.CheckServiceNodes { out := make([]structs.CheckServiceNode, 0, len(full)) for _, csn := range full { if csn.Service.Meta[structs.MetaWANFederationKey] != "1" { continue } // only keep healthy ones ok := true for _, chk := range csn.Checks { if chk.Status == api.HealthCritical { ok = false } } if ok { out = append(out, csn) } } return out } func renderGatewayAddrs(gateways structs.CheckServiceNodes, wan bool) []string { out := make([]string, 0, len(gateways)) for _, csn := range gateways { addr, port := csn.BestAddress(wan) completeAddr := ipaddr.FormatAddressPort(addr, port) out = append(out, completeAddr) } sort.Strings(out) return out }