package drainer import ( "context" log "github.com/hashicorp/go-hclog" memdb "github.com/hashicorp/go-memdb" "github.com/hashicorp/nomad/helper" "github.com/hashicorp/nomad/nomad/state" "github.com/hashicorp/nomad/nomad/structs" "golang.org/x/time/rate" ) // DrainingNodeWatcher is the interface for watching for draining nodes. type DrainingNodeWatcher interface{} // TrackedNodes returns the set of tracked nodes func (n *NodeDrainer) TrackedNodes() map[string]*structs.Node { n.l.RLock() defer n.l.RUnlock() t := make(map[string]*structs.Node, len(n.nodes)) for n, d := range n.nodes { t[n] = d.GetNode() } return t } // Remove removes the given node from being tracked func (n *NodeDrainer) Remove(nodeID string) { n.l.Lock() defer n.l.Unlock() // Remove it from being tracked and remove it from the dealiner delete(n.nodes, nodeID) n.deadlineNotifier.Remove(nodeID) } // Update updates the node, either updating the tracked version or starting to // track the node. func (n *NodeDrainer) Update(node *structs.Node) { n.l.Lock() defer n.l.Unlock() if node == nil { return } draining, ok := n.nodes[node.ID] if !ok { draining = NewDrainingNode(node, n.state) n.nodes[node.ID] = draining } else { // Update it draining.Update(node) } if inf, deadline := node.DrainStrategy.DeadlineTime(); !inf { n.deadlineNotifier.Watch(node.ID, deadline) } else { // There is an infinite deadline so it shouldn't be tracked for // deadlining n.deadlineNotifier.Remove(node.ID) } // Register interest in the draining jobs. jobs, err := draining.DrainingJobs() if err != nil { n.logger.Error("error retrieving draining jobs on node", "node_id", node.ID, "error", err) return } n.logger.Trace("node has draining jobs on it", "node_id", node.ID, "num_jobs", len(jobs)) n.jobWatcher.RegisterJobs(jobs) // Check if the node is done such that if an operator drains a node with // nothing on it we unset drain done, err := draining.IsDone() if err != nil { n.logger.Error("failed to check if node is done draining", "node_id", node.ID, "error", err) return } if done { // Node is done draining. Stop remaining system allocs before marking // node as complete. remaining, err := draining.RemainingAllocs() if err != nil { n.logger.Error("error getting remaining allocs on drained node", "node_id", node.ID, "error", err) } else if len(remaining) > 0 { future := structs.NewBatchFuture() n.drainAllocs(future, remaining) if err := future.Wait(); err != nil { n.logger.Error("failed to drain remaining allocs from done node", "num_allocs", len(remaining), "node_id", node.ID, "error", err) } } // Create the node event event := structs.NewNodeEvent(). SetSubsystem(structs.NodeEventSubsystemDrain). SetMessage(NodeDrainEventComplete) index, err := n.raft.NodesDrainComplete([]string{node.ID}, event) if err != nil { n.logger.Error("failed to unset drain for node", "node_id", node.ID, "error", err) } else { n.logger.Info("node completed draining at index", "node_id", node.ID, "index", index) } } } // nodeDrainWatcher is used to watch nodes that are entering, leaving or // changing their drain strategy. type nodeDrainWatcher struct { ctx context.Context logger log.Logger // state is the state that is watched for state changes. state *state.StateStore // limiter is used to limit the rate of blocking queries limiter *rate.Limiter // tracker is the object that is tracking the nodes and provides us with the // needed callbacks tracker NodeTracker } // NewNodeDrainWatcher returns a new node drain watcher. func NewNodeDrainWatcher(ctx context.Context, limiter *rate.Limiter, state *state.StateStore, logger log.Logger, tracker NodeTracker) *nodeDrainWatcher { w := &nodeDrainWatcher{ ctx: ctx, limiter: limiter, logger: logger.Named("node_watcher"), tracker: tracker, state: state, } go w.watch() return w } // watch is the long lived watching routine that detects node changes. func (w *nodeDrainWatcher) watch() { timer, stop := helper.NewSafeTimer(stateReadErrorDelay) defer stop() nindex := uint64(1) for { timer.Reset(stateReadErrorDelay) nodes, index, err := w.getNodes(nindex) if err != nil { if err == context.Canceled { return } w.logger.Error("error watching node updates at index", "index", nindex, "error", err) select { case <-w.ctx.Done(): return case <-timer.C: continue } } // update index for next run nindex = index tracked := w.tracker.TrackedNodes() for nodeID, node := range nodes { newDraining := node.DrainStrategy != nil currentNode, tracked := tracked[nodeID] switch { case tracked && !newDraining: // If the node is tracked but not draining, untrack w.tracker.Remove(nodeID) case !tracked && newDraining: // If the node is not being tracked but is draining, track w.tracker.Update(node) case tracked && newDraining && !currentNode.DrainStrategy.Equal(node.DrainStrategy): // If the node is being tracked but has changed, update w.tracker.Update(node) default: // note that down/disconnected nodes are handled the same as any // other node here, because we don't want to stop draining a // node that might heartbeat again. The job watcher will let us // know if we can stop watching the node when all the allocs are // evicted } } for nodeID := range tracked { if _, ok := nodes[nodeID]; !ok { w.tracker.Remove(nodeID) } } } } // getNodes returns all nodes blocking until the nodes are after the given index. func (w *nodeDrainWatcher) getNodes(minIndex uint64) (map[string]*structs.Node, uint64, error) { if err := w.limiter.Wait(w.ctx); err != nil { return nil, 0, err } resp, index, err := w.state.BlockingQuery(w.getNodesImpl, minIndex, w.ctx) if err != nil { return nil, 0, err } return resp.(map[string]*structs.Node), index, nil } // getNodesImpl is used to get nodes from the state store, returning the set of // nodes and the current node table index. func (w *nodeDrainWatcher) getNodesImpl(ws memdb.WatchSet, state *state.StateStore) (interface{}, uint64, error) { iter, err := state.Nodes(ws) if err != nil { return nil, 0, err } index, err := state.Index("nodes") if err != nil { return nil, 0, err } resp := make(map[string]*structs.Node, 64) for { raw := iter.Next() if raw == nil { break } node := raw.(*structs.Node) resp[node.ID] = node } return resp, index, nil }