package autopilot import ( "fmt" "sync" "github.com/btcsuite/btcd/btcec" "github.com/btcsuite/btcd/wire" "github.com/lightningnetwork/lnd/lnwallet" "github.com/lightningnetwork/lnd/lnwire" "github.com/lightningnetwork/lnd/routing" ) // ManagerCfg houses a set of values and methods that is passed to the Manager // for it to properly manage its autopilot agent. type ManagerCfg struct { // Self is the public key of the lnd instance. It is used to making // sure the autopilot is not opening channels to itself. Self *btcec.PublicKey // PilotCfg is the config of the autopilot agent managed by the // Manager. PilotCfg *Config // ChannelState is a function closure that returns the current set of // channels managed by this node. ChannelState func() ([]LocalChannel, error) // ChannelInfo is a function closure that returns the channel managed // by the node given by the passed channel point. ChannelInfo func(wire.OutPoint) (*LocalChannel, error) // SubscribeTransactions is used to get a subscription for transactions // relevant to this node's wallet. SubscribeTransactions func() (lnwallet.TransactionSubscription, error) // SubscribeTopology is used to get a subscription for topology changes // on the network. SubscribeTopology func() (*routing.TopologyClient, error) } // Manager is struct that manages an autopilot agent, making it possible to // enable and disable it at will, and hand it relevant external information. // It implements the autopilot grpc service, which is used to get data about // the running autopilot, and gives it relevant information. type Manager struct { started sync.Once stopped sync.Once cfg *ManagerCfg // pilot is the current autopilot agent. It will be nil if the agent is // disabled. pilot *Agent quit chan struct{} wg sync.WaitGroup sync.Mutex } // NewManager creates a new instance of the Manager from the passed config. func NewManager(cfg *ManagerCfg) (*Manager, error) { return &Manager{ cfg: cfg, quit: make(chan struct{}), }, nil } // Start starts the Manager. func (m *Manager) Start() error { m.started.Do(func() {}) return nil } // Stop stops the Manager. If an autopilot agent is active, it will also be // stopped. func (m *Manager) Stop() error { m.stopped.Do(func() { if err := m.StopAgent(); err != nil { log.Errorf("Unable to stop pilot: %v", err) } close(m.quit) m.wg.Wait() }) return nil } // IsActive returns whether the autopilot agent is currently active. func (m *Manager) IsActive() bool { m.Lock() defer m.Unlock() return m.pilot != nil } // StartAgent creates and starts an autopilot agent from the Manager's // config. func (m *Manager) StartAgent() error { m.Lock() defer m.Unlock() // Already active. if m.pilot != nil { return nil } // Next, we'll fetch the current state of open channels from the // database to use as initial state for the auto-pilot agent. initialChanState, err := m.cfg.ChannelState() if err != nil { return err } // Now that we have all the initial dependencies, we can create the // auto-pilot instance itself. pilot, err := New(*m.cfg.PilotCfg, initialChanState) if err != nil { return err } if err := pilot.Start(); err != nil { return err } // Finally, we'll need to subscribe to two things: incoming // transactions that modify the wallet's balance, and also any graph // topology updates. txnSubscription, err := m.cfg.SubscribeTransactions() if err != nil { pilot.Stop() return err } graphSubscription, err := m.cfg.SubscribeTopology() if err != nil { txnSubscription.Cancel() pilot.Stop() return err } m.pilot = pilot // We'll launch a goroutine to provide the agent with notifications // whenever the balance of the wallet changes. // TODO(halseth): can lead to panic if in process of shutting down. m.wg.Add(1) go func() { defer txnSubscription.Cancel() defer m.wg.Done() for { select { case <-txnSubscription.ConfirmedTransactions(): pilot.OnBalanceChange() // We won't act upon new unconfirmed transaction, as // we'll only use confirmed outputs when funding. // However, we will still drain this request in order // to avoid goroutine leaks, and ensure we promptly // read from the channel if available. case <-txnSubscription.UnconfirmedTransactions(): case <-pilot.quit: return case <-m.quit: return } } }() // We'll also launch a goroutine to provide the agent with // notifications for when the graph topology controlled by the node // changes. m.wg.Add(1) go func() { defer graphSubscription.Cancel() defer m.wg.Done() for { select { case topChange, ok := <-graphSubscription.TopologyChanges: // If the router is shutting down, then we will // as well. if !ok { return } for _, edgeUpdate := range topChange.ChannelEdgeUpdates { // If this isn't an advertisement by // the backing lnd node, then we'll // continue as we only want to add // channels that we've created // ourselves. if !edgeUpdate.AdvertisingNode.IsEqual(m.cfg.Self) { continue } // If this is indeed a channel we // opened, then we'll convert it to the // autopilot.Channel format, and notify // the pilot of the new channel. cp := edgeUpdate.ChanPoint edge, err := m.cfg.ChannelInfo(cp) if err != nil { log.Errorf("Unable to fetch "+ "channel info for %v: "+ "%v", cp, err) continue } pilot.OnChannelOpen(*edge) } // For each closed channel, we'll obtain // the chanID of the closed channel and send it // to the pilot. for _, chanClose := range topChange.ClosedChannels { chanID := lnwire.NewShortChanIDFromInt( chanClose.ChanID, ) pilot.OnChannelClose(chanID) } // If new nodes were added to the graph, or // node information has changed, we'll poke // autopilot to see if it can make use of them. if len(topChange.NodeUpdates) > 0 { pilot.OnNodeUpdates() } case <-pilot.quit: return case <-m.quit: return } } }() log.Debugf("Manager started autopilot agent") return nil } // StopAgent stops any active autopilot agent. func (m *Manager) StopAgent() error { m.Lock() defer m.Unlock() // Not active, so we can return early. if m.pilot == nil { return nil } if err := m.pilot.Stop(); err != nil { return err } // Make sure to nil the current agent, indicating it is no longer // active. m.pilot = nil log.Debugf("Manager stopped autopilot agent") return nil } // QueryHeuristics queries the available autopilot heuristics for node scores. func (m *Manager) QueryHeuristics(nodes []NodeID, localState bool) ( HeuristicScores, error) { m.Lock() defer m.Unlock() n := make(map[NodeID]struct{}) for _, node := range nodes { n[node] = struct{}{} } log.Debugf("Querying heuristics for %d nodes", len(n)) return m.queryHeuristics(n, localState) } // HeuristicScores is an alias for a map that maps heuristic names to a map of // scores for pubkeys. type HeuristicScores map[string]map[NodeID]float64 // queryHeuristics gets node scores from all available simple heuristics, and // the agent's current active heuristic. // // NOTE: Must be called with the manager's lock. func (m *Manager) queryHeuristics(nodes map[NodeID]struct{}, localState bool) ( HeuristicScores, error) { // If we want to take the local state into action when querying the // heuristics, we fetch it. If not we'll just pass an emply slice to // the heuristic. var totalChans []LocalChannel var err error if localState { // Fetch the current set of channels. totalChans, err = m.cfg.ChannelState() if err != nil { return nil, err } // If the agent is active, we can merge the channel state with // the channels pending open. if m.pilot != nil { m.pilot.chanStateMtx.Lock() m.pilot.pendingMtx.Lock() totalChans = mergeChanState( m.pilot.pendingOpens, m.pilot.chanState, ) m.pilot.pendingMtx.Unlock() m.pilot.chanStateMtx.Unlock() } } // As channel size we'll use the maximum size. chanSize := m.cfg.PilotCfg.Constraints.MaxChanSize() // We'll start by getting the scores from each available sub-heuristic, // in addition the current agent heuristic. var heuristics []AttachmentHeuristic heuristics = append(heuristics, availableHeuristics...) heuristics = append(heuristics, m.cfg.PilotCfg.Heuristic) report := make(HeuristicScores) for _, h := range heuristics { name := h.Name() // If the agent heuristic is among the simple heuristics it // might get queried more than once. As an optimization we'll // just skip it the second time. if _, ok := report[name]; ok { continue } s, err := h.NodeScores( m.cfg.PilotCfg.Graph, totalChans, chanSize, nodes, ) if err != nil { return nil, fmt.Errorf("unable to get sub score: %v", err) } log.Debugf("Heuristic \"%v\" scored %d nodes", name, len(s)) scores := make(map[NodeID]float64) for nID, score := range s { scores[nID] = score.Score } report[name] = scores } return report, nil } // SetNodeScores is used to set the scores of the given heuristic, if it is // active, and ScoreSettable. func (m *Manager) SetNodeScores(name string, scores map[NodeID]float64) error { m.Lock() defer m.Unlock() // It must be ScoreSettable to be available for external // scores. s, ok := m.cfg.PilotCfg.Heuristic.(ScoreSettable) if !ok { return fmt.Errorf("current heuristic doesn't support " + "external scoring") } // Heuristic was found, set its node scores. applied, err := s.SetNodeScores(name, scores) if err != nil { return err } if !applied { return fmt.Errorf("heuristic with name %v not found", name) } // If the autopilot agent is active, notify about the updated // heuristic. if m.pilot != nil { m.pilot.OnHeuristicUpdate(m.cfg.PilotCfg.Heuristic) } return nil }