core/store/dist/src/main/java/org/onosproject/store/cluster/impl/DistributedClusterStore.java - onos - Gitiles

 /*
  * Copyright 2014-present Open Networking Laboratory
  *
  * 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 org.onosproject.store.cluster.impl;

 import com.google.common.base.MoreObjects;
 import com.google.common.collect.ImmutableSet;
 import com.google.common.collect.Maps;
 import org.apache.felix.scr.annotations.Activate;
 import org.apache.felix.scr.annotations.Component;
 import org.apache.felix.scr.annotations.Deactivate;
 import org.apache.felix.scr.annotations.Modified;
 import org.apache.felix.scr.annotations.Property;
 import org.apache.felix.scr.annotations.Reference;
 import org.apache.felix.scr.annotations.ReferenceCardinality;
 import org.apache.felix.scr.annotations.Service;
 import org.joda.time.DateTime;
 import org.onlab.packet.IpAddress;
 import org.onlab.util.KryoNamespace;
 import org.onlab.util.Tools;
 import org.onosproject.cluster.ClusterEvent;
 import org.onosproject.cluster.ClusterMetadataService;
 import org.onosproject.cluster.ClusterStore;
 import org.onosproject.cluster.ClusterStoreDelegate;
 import org.onosproject.cluster.ControllerNode;
 import org.onosproject.cluster.ControllerNode.State;
 import org.onosproject.cluster.DefaultControllerNode;
 import org.onosproject.cluster.NodeId;
 import org.onosproject.store.AbstractStore;
 import org.onosproject.store.cluster.messaging.Endpoint;
 import org.onosproject.store.cluster.messaging.MessagingService;
 import org.onosproject.store.serializers.KryoNamespaces;
 import org.onosproject.store.serializers.KryoSerializer;
 import org.osgi.service.component.ComponentContext;
 import org.slf4j.Logger;

 import java.util.Dictionary;
 import java.util.Map;
 import java.util.Objects;
 import java.util.Set;
 import java.util.concurrent.ExecutorService;
 import java.util.concurrent.Executors;
 import java.util.concurrent.ScheduledExecutorService;
 import java.util.concurrent.TimeUnit;
 import java.util.function.BiConsumer;
 import java.util.stream.Collectors;

 import static com.google.common.base.Preconditions.checkArgument;
 import static com.google.common.base.Preconditions.checkNotNull;
 import static org.onlab.util.Tools.groupedThreads;
 import static org.onosproject.cluster.ClusterEvent.Type.INSTANCE_ACTIVATED;
 import static org.onosproject.cluster.ClusterEvent.Type.INSTANCE_DEACTIVATED;
 import static org.onosproject.cluster.ClusterEvent.Type.INSTANCE_READY;
 import static org.slf4j.LoggerFactory.getLogger;

 @Component(immediate = true)
 @Service
 /**
  * Distributed cluster nodes store that employs an accrual failure
  * detector to identify cluster member up/down status.
  */
 public class DistributedClusterStore
         extends AbstractStore<ClusterEvent, ClusterStoreDelegate>
         implements ClusterStore {

     private static final Logger log = getLogger(DistributedClusterStore.class);

     public static final String HEARTBEAT_MESSAGE = "onos-cluster-heartbeat";

     private static final int DEFAULT_HEARTBEAT_INTERVAL = 100;
     @Property(name = "heartbeatInterval", intValue = DEFAULT_HEARTBEAT_INTERVAL,
             label = "Interval time to send heartbeat to other controller nodes (millisecond)")
     private int heartbeatInterval = DEFAULT_HEARTBEAT_INTERVAL;

     private static final int DEFAULT_PHI_FAILURE_THRESHOLD = 10;
     @Property(name = "phiFailureThreshold", intValue = DEFAULT_PHI_FAILURE_THRESHOLD,
             label = "the value of Phi threshold to detect accrual failure")
     private int phiFailureThreshold = DEFAULT_PHI_FAILURE_THRESHOLD;

     private static final KryoSerializer SERIALIZER = new KryoSerializer() {
         @Override
         protected void setupKryoPool() {
             serializerPool = KryoNamespace.newBuilder()
                     .register(KryoNamespaces.API)
                     .register(HeartbeatMessage.class)
                     .build()
                     .populate(1);
         }
     };

     private static final String INSTANCE_ID_NULL = "Instance ID cannot be null";

     private final Map<NodeId, ControllerNode> allNodes = Maps.newConcurrentMap();
     private final Map<NodeId, State> nodeStates = Maps.newConcurrentMap();
     private final Map<NodeId, DateTime> nodeStateLastUpdatedTimes = Maps.newConcurrentMap();

     private ScheduledExecutorService heartBeatSender = Executors.newSingleThreadScheduledExecutor(
             groupedThreads("onos/cluster/membership", "heartbeat-sender", log));
     private ExecutorService heartBeatMessageHandler = Executors.newSingleThreadExecutor(
             groupedThreads("onos/cluster/membership", "heartbeat-receiver", log));

     private PhiAccrualFailureDetector failureDetector;

     private ControllerNode localNode;

     @Reference(cardinality = ReferenceCardinality.MANDATORY_UNARY)
     protected ClusterMetadataService clusterMetadataService;

     @Reference(cardinality = ReferenceCardinality.MANDATORY_UNARY)
     protected MessagingService messagingService;

     @Activate
     public void activate() {
         localNode = clusterMetadataService.getLocalNode();

         messagingService.registerHandler(HEARTBEAT_MESSAGE,
                                          new HeartbeatMessageHandler(), heartBeatMessageHandler);

         failureDetector = new PhiAccrualFailureDetector();

         heartBeatSender.scheduleWithFixedDelay(this::heartbeat, 0,
                                                heartbeatInterval, TimeUnit.MILLISECONDS);

         log.info("Started");
     }

     @Deactivate
     public void deactivate() {
         messagingService.unregisterHandler(HEARTBEAT_MESSAGE);
         heartBeatSender.shutdownNow();
         heartBeatMessageHandler.shutdownNow();

         log.info("Stopped");
     }

     @Modified
     public void modified(ComponentContext context) {
         readComponentConfiguration(context);
         restartHeartbeatSender();
     }

     @Override
     public void setDelegate(ClusterStoreDelegate delegate) {
         checkNotNull(delegate, "Delegate cannot be null");
         this.delegate = delegate;
     }

     @Override
     public void unsetDelegate(ClusterStoreDelegate delegate) {
         this.delegate = null;
     }

     @Override
     public boolean hasDelegate() {
         return this.delegate != null;
     }

     @Override
     public ControllerNode getLocalNode() {
         return localNode;
     }

     @Override
     public Set<ControllerNode> getNodes() {
         return ImmutableSet.copyOf(allNodes.values());
     }

     @Override
     public ControllerNode getNode(NodeId nodeId) {
         checkNotNull(nodeId, INSTANCE_ID_NULL);
         return allNodes.get(nodeId);
     }

     @Override
     public State getState(NodeId nodeId) {
         checkNotNull(nodeId, INSTANCE_ID_NULL);
         return MoreObjects.firstNonNull(nodeStates.get(nodeId), State.INACTIVE);
     }

     @Override
     public void markFullyStarted(boolean started) {
         updateState(localNode.id(), started ? State.READY : State.ACTIVE);
     }

     @Override
     public ControllerNode addNode(NodeId nodeId, IpAddress ip, int tcpPort) {
         checkNotNull(nodeId, INSTANCE_ID_NULL);
         ControllerNode node = new DefaultControllerNode(nodeId, ip, tcpPort);
         addNode(node);
         return node;
     }

     @Override
     public void removeNode(NodeId nodeId) {
         checkNotNull(nodeId, INSTANCE_ID_NULL);
         ControllerNode node = allNodes.remove(nodeId);
         if (node != null) {
             nodeStates.remove(nodeId);
             notifyDelegate(new ClusterEvent(ClusterEvent.Type.INSTANCE_REMOVED, node));
         }
     }

     private void addNode(ControllerNode node) {
         allNodes.put(node.id(), node);
         updateState(node.id(), node.equals(localNode) ? State.ACTIVE : State.INACTIVE);
         notifyDelegate(new ClusterEvent(ClusterEvent.Type.INSTANCE_ADDED, node));
     }

     private void updateState(NodeId nodeId, State newState) {
         State currentState = nodeStates.get(nodeId);
         if (!Objects.equals(currentState, newState)) {
             nodeStates.put(nodeId, newState);
             nodeStateLastUpdatedTimes.put(nodeId, DateTime.now());
             notifyStateChange(nodeId, currentState, newState);
         }
     }

     private void heartbeat() {
         try {
             Set<ControllerNode> peers = allNodes.values()
                     .stream()
                     .filter(node -> !(node.id().equals(localNode.id())))
                     .collect(Collectors.toSet());
             State state = nodeStates.get(localNode.id());
             byte[] hbMessagePayload = SERIALIZER.encode(new HeartbeatMessage(localNode, state, peers));
             peers.forEach((node) -> {
                 heartbeatToPeer(hbMessagePayload, node);
                 State currentState = nodeStates.get(node.id());
                 double phi = failureDetector.phi(node.id());
                 if (phi >= phiFailureThreshold) {
                     if (currentState.isActive()) {
                         updateState(node.id(), State.INACTIVE);
                     }
                 } else {
                     if (currentState == State.INACTIVE) {
                         updateState(node.id(), State.ACTIVE);
                     }
                 }
             });
         } catch (Exception e) {
             log.debug("Failed to send heartbeat", e);
         }
     }

     private void notifyStateChange(NodeId nodeId, State oldState, State newState) {
         if (oldState != newState) {
             ControllerNode node = allNodes.get(nodeId);
             ClusterEvent.Type type = newState == State.READY ? INSTANCE_READY :
                     newState == State.ACTIVE ? INSTANCE_ACTIVATED :
                             INSTANCE_DEACTIVATED;
             notifyDelegate(new ClusterEvent(type, node));
         }
     }

     private void heartbeatToPeer(byte[] messagePayload, ControllerNode peer) {
         Endpoint remoteEp = new Endpoint(peer.ip(), peer.tcpPort());
         messagingService.sendAsync(remoteEp, HEARTBEAT_MESSAGE, messagePayload).whenComplete((result, error) -> {
             if (error != null) {
                 log.trace("Sending heartbeat to {} failed", remoteEp, error);
             }
         });
     }

     private class HeartbeatMessageHandler implements BiConsumer<Endpoint, byte[]> {
         @Override
         public void accept(Endpoint sender, byte[] message) {
             HeartbeatMessage hb = SERIALIZER.decode(message);
             failureDetector.report(hb.source().id());
             updateState(hb.source().id(), hb.state);
             hb.knownPeers().forEach(node -> {
                 allNodes.put(node.id(), node);
             });
         }
     }

     private static class HeartbeatMessage {
         private ControllerNode source;
         private State state;
         private Set<ControllerNode> knownPeers;

         public HeartbeatMessage(ControllerNode source, State state, Set<ControllerNode> members) {
             this.source = source;
             this.state = state != null ? state : State.ACTIVE;
             this.knownPeers = ImmutableSet.copyOf(members);
         }

         public ControllerNode source() {
             return source;
         }

         public Set<ControllerNode> knownPeers() {
             return knownPeers;
         }
     }

     @Override
     public DateTime getLastUpdated(NodeId nodeId) {
         return nodeStateLastUpdatedTimes.get(nodeId);
     }

     /**
      * Extracts properties from the component configuration context.
      *
      * @param context the component context
      */
     private void readComponentConfiguration(ComponentContext context) {
         Dictionary<?, ?> properties = context.getProperties();

         Integer newHeartbeatInterval = Tools.getIntegerProperty(properties,
                                                                 "heartbeatInterval");
         if (newHeartbeatInterval == null) {
             setHeartbeatInterval(DEFAULT_HEARTBEAT_INTERVAL);
             log.info("Heartbeat interval time is not configured, default value is {}",
                      DEFAULT_HEARTBEAT_INTERVAL);
         } else {
             setHeartbeatInterval(newHeartbeatInterval);
             log.info("Configured. Heartbeat interval time is configured to {}",
                      heartbeatInterval);
         }

         Integer newPhiFailureThreshold = Tools.getIntegerProperty(properties,
                                                                   "phiFailureThreshold");
         if (newPhiFailureThreshold == null) {
             setPhiFailureThreshold(DEFAULT_PHI_FAILURE_THRESHOLD);
             log.info("Phi failure threshold is not configured, default value is {}",
                      DEFAULT_PHI_FAILURE_THRESHOLD);
         } else {
             setPhiFailureThreshold(newPhiFailureThreshold);
             log.info("Configured. Phi failure threshold is configured to {}",
                      phiFailureThreshold);
         }
     }

     /**
      * Sets heartbeat interval between the termination of one execution of heartbeat
      * and the commencement of the next.
      *
      * @param interval term between each heartbeat
      */
     private void setHeartbeatInterval(int interval) {
         try {
             checkArgument(interval > 0, "Interval must be greater than zero");
             heartbeatInterval = interval;
         } catch (IllegalArgumentException e) {
             log.warn(e.getMessage());
             heartbeatInterval = DEFAULT_HEARTBEAT_INTERVAL;
         }
     }

     /**
      * Sets Phi failure threshold.
      * Phi is based on a paper titled: "The φ Accrual Failure Detector" by Hayashibara, et al.
      *
      * @param threshold
      */
     private void setPhiFailureThreshold(int threshold) {
         phiFailureThreshold = threshold;
     }

     /**
      * Restarts heartbeatSender executor.
      *
      */
     private void restartHeartbeatSender() {
         try {
             ScheduledExecutorService prevSender = heartBeatSender;
             heartBeatSender = Executors.newSingleThreadScheduledExecutor(
                     groupedThreads("onos/cluster/membership", "heartbeat-sender-%d", log));
             heartBeatSender.scheduleWithFixedDelay(this::heartbeat, 0,
                                                    heartbeatInterval, TimeUnit.MILLISECONDS);
             prevSender.shutdown();
         } catch (Exception e) {
             log.warn(e.getMessage());
         }
     }

     /**
      * Gets current heartbeat interval.
      *
      * @return heartbeatInterval
      */
     private int getHeartbeatInterval() {
         return heartbeatInterval;
     }

     /**
      * Gets current Phi failure threshold for Accrual Failure Detector.
      *
      * @return phiFailureThreshold
      */
     private int getPhiFailureThreshold() {
         return phiFailureThreshold;
     }

 }
	/*
	* Copyright 2014-present Open Networking Laboratory
	*
	* 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 org.onosproject.store.cluster.impl;

	import com.google.common.base.MoreObjects;
	import com.google.common.collect.ImmutableSet;
	import com.google.common.collect.Maps;
	import org.apache.felix.scr.annotations.Activate;
	import org.apache.felix.scr.annotations.Component;
	import org.apache.felix.scr.annotations.Deactivate;
	import org.apache.felix.scr.annotations.Modified;
	import org.apache.felix.scr.annotations.Property;
	import org.apache.felix.scr.annotations.Reference;
	import org.apache.felix.scr.annotations.ReferenceCardinality;
	import org.apache.felix.scr.annotations.Service;
	import org.joda.time.DateTime;
	import org.onlab.packet.IpAddress;
	import org.onlab.util.KryoNamespace;
	import org.onlab.util.Tools;
	import org.onosproject.cluster.ClusterEvent;
	import org.onosproject.cluster.ClusterMetadataService;
	import org.onosproject.cluster.ClusterStore;
	import org.onosproject.cluster.ClusterStoreDelegate;
	import org.onosproject.cluster.ControllerNode;
	import org.onosproject.cluster.ControllerNode.State;
	import org.onosproject.cluster.DefaultControllerNode;
	import org.onosproject.cluster.NodeId;
	import org.onosproject.store.AbstractStore;
	import org.onosproject.store.cluster.messaging.Endpoint;
	import org.onosproject.store.cluster.messaging.MessagingService;
	import org.onosproject.store.serializers.KryoNamespaces;
	import org.onosproject.store.serializers.KryoSerializer;
	import org.osgi.service.component.ComponentContext;
	import org.slf4j.Logger;

	import java.util.Dictionary;
	import java.util.Map;
	import java.util.Objects;
	import java.util.Set;
	import java.util.concurrent.ExecutorService;
	import java.util.concurrent.Executors;
	import java.util.concurrent.ScheduledExecutorService;
	import java.util.concurrent.TimeUnit;
	import java.util.function.BiConsumer;
	import java.util.stream.Collectors;

	import static com.google.common.base.Preconditions.checkArgument;
	import static com.google.common.base.Preconditions.checkNotNull;
	import static org.onlab.util.Tools.groupedThreads;
	import static org.onosproject.cluster.ClusterEvent.Type.INSTANCE_ACTIVATED;
	import static org.onosproject.cluster.ClusterEvent.Type.INSTANCE_DEACTIVATED;
	import static org.onosproject.cluster.ClusterEvent.Type.INSTANCE_READY;
	import static org.slf4j.LoggerFactory.getLogger;

	@Component(immediate = true)
	@Service
	/**
	* Distributed cluster nodes store that employs an accrual failure
	* detector to identify cluster member up/down status.
	*/
	public class DistributedClusterStore
	extends AbstractStore<ClusterEvent, ClusterStoreDelegate>
	implements ClusterStore {

	private static final Logger log = getLogger(DistributedClusterStore.class);

	public static final String HEARTBEAT_MESSAGE = "onos-cluster-heartbeat";

	private static final int DEFAULT_HEARTBEAT_INTERVAL = 100;
	@Property(name = "heartbeatInterval", intValue = DEFAULT_HEARTBEAT_INTERVAL,
	label = "Interval time to send heartbeat to other controller nodes (millisecond)")
	private int heartbeatInterval = DEFAULT_HEARTBEAT_INTERVAL;

	private static final int DEFAULT_PHI_FAILURE_THRESHOLD = 10;
	@Property(name = "phiFailureThreshold", intValue = DEFAULT_PHI_FAILURE_THRESHOLD,
	label = "the value of Phi threshold to detect accrual failure")
	private int phiFailureThreshold = DEFAULT_PHI_FAILURE_THRESHOLD;

	private static final KryoSerializer SERIALIZER = new KryoSerializer() {
	@Override
	protected void setupKryoPool() {
	serializerPool = KryoNamespace.newBuilder()
	.register(KryoNamespaces.API)
	.register(HeartbeatMessage.class)
	.build()
	.populate(1);
	}
	};

	private static final String INSTANCE_ID_NULL = "Instance ID cannot be null";

	private final Map<NodeId, ControllerNode> allNodes = Maps.newConcurrentMap();
	private final Map<NodeId, State> nodeStates = Maps.newConcurrentMap();
	private final Map<NodeId, DateTime> nodeStateLastUpdatedTimes = Maps.newConcurrentMap();

	private ScheduledExecutorService heartBeatSender = Executors.newSingleThreadScheduledExecutor(
	groupedThreads("onos/cluster/membership", "heartbeat-sender", log));
	private ExecutorService heartBeatMessageHandler = Executors.newSingleThreadExecutor(
	groupedThreads("onos/cluster/membership", "heartbeat-receiver", log));

	private PhiAccrualFailureDetector failureDetector;

	private ControllerNode localNode;

	@Reference(cardinality = ReferenceCardinality.MANDATORY_UNARY)
	protected ClusterMetadataService clusterMetadataService;

	@Reference(cardinality = ReferenceCardinality.MANDATORY_UNARY)
	protected MessagingService messagingService;

	@Activate
	public void activate() {
	localNode = clusterMetadataService.getLocalNode();

	messagingService.registerHandler(HEARTBEAT_MESSAGE,
	new HeartbeatMessageHandler(), heartBeatMessageHandler);

	failureDetector = new PhiAccrualFailureDetector();

	heartBeatSender.scheduleWithFixedDelay(this::heartbeat, 0,
	heartbeatInterval, TimeUnit.MILLISECONDS);

	log.info("Started");
	}

	@Deactivate
	public void deactivate() {
	messagingService.unregisterHandler(HEARTBEAT_MESSAGE);
	heartBeatSender.shutdownNow();
	heartBeatMessageHandler.shutdownNow();

	log.info("Stopped");
	}

	@Modified
	public void modified(ComponentContext context) {
	readComponentConfiguration(context);
	restartHeartbeatSender();
	}

	@Override
	public void setDelegate(ClusterStoreDelegate delegate) {
	checkNotNull(delegate, "Delegate cannot be null");
	this.delegate = delegate;
	}

	@Override
	public void unsetDelegate(ClusterStoreDelegate delegate) {
	this.delegate = null;
	}

	@Override
	public boolean hasDelegate() {
	return this.delegate != null;
	}

	@Override
	public ControllerNode getLocalNode() {
	return localNode;
	}

	@Override
	public Set<ControllerNode> getNodes() {
	return ImmutableSet.copyOf(allNodes.values());
	}

	@Override
	public ControllerNode getNode(NodeId nodeId) {
	checkNotNull(nodeId, INSTANCE_ID_NULL);
	return allNodes.get(nodeId);
	}

	@Override
	public State getState(NodeId nodeId) {
	checkNotNull(nodeId, INSTANCE_ID_NULL);
	return MoreObjects.firstNonNull(nodeStates.get(nodeId), State.INACTIVE);
	}

	@Override
	public void markFullyStarted(boolean started) {
	updateState(localNode.id(), started ? State.READY : State.ACTIVE);
	}

	@Override
	public ControllerNode addNode(NodeId nodeId, IpAddress ip, int tcpPort) {
	checkNotNull(nodeId, INSTANCE_ID_NULL);
	ControllerNode node = new DefaultControllerNode(nodeId, ip, tcpPort);
	addNode(node);
	return node;
	}

	@Override
	public void removeNode(NodeId nodeId) {
	checkNotNull(nodeId, INSTANCE_ID_NULL);
	ControllerNode node = allNodes.remove(nodeId);
	if (node != null) {
	nodeStates.remove(nodeId);
	notifyDelegate(new ClusterEvent(ClusterEvent.Type.INSTANCE_REMOVED, node));
	}
	}

	private void addNode(ControllerNode node) {
	allNodes.put(node.id(), node);
	updateState(node.id(), node.equals(localNode) ? State.ACTIVE : State.INACTIVE);
	notifyDelegate(new ClusterEvent(ClusterEvent.Type.INSTANCE_ADDED, node));
	}

	private void updateState(NodeId nodeId, State newState) {
	State currentState = nodeStates.get(nodeId);
	if (!Objects.equals(currentState, newState)) {
	nodeStates.put(nodeId, newState);
	nodeStateLastUpdatedTimes.put(nodeId, DateTime.now());
	notifyStateChange(nodeId, currentState, newState);
	}
	}

	private void heartbeat() {
	try {
	Set<ControllerNode> peers = allNodes.values()
	.stream()
	.filter(node -> !(node.id().equals(localNode.id())))
	.collect(Collectors.toSet());
	State state = nodeStates.get(localNode.id());
	byte[] hbMessagePayload = SERIALIZER.encode(new HeartbeatMessage(localNode, state, peers));
	peers.forEach((node) -> {
	heartbeatToPeer(hbMessagePayload, node);
	State currentState = nodeStates.get(node.id());
	double phi = failureDetector.phi(node.id());
	if (phi >= phiFailureThreshold) {
	if (currentState.isActive()) {
	updateState(node.id(), State.INACTIVE);
	}
	} else {
	if (currentState == State.INACTIVE) {
	updateState(node.id(), State.ACTIVE);
	}
	}
	});
	} catch (Exception e) {
	log.debug("Failed to send heartbeat", e);
	}
	}

	private void notifyStateChange(NodeId nodeId, State oldState, State newState) {
	if (oldState != newState) {
	ControllerNode node = allNodes.get(nodeId);
	ClusterEvent.Type type = newState == State.READY ? INSTANCE_READY :
	newState == State.ACTIVE ? INSTANCE_ACTIVATED :
	INSTANCE_DEACTIVATED;
	notifyDelegate(new ClusterEvent(type, node));
	}
	}

	private void heartbeatToPeer(byte[] messagePayload, ControllerNode peer) {
	Endpoint remoteEp = new Endpoint(peer.ip(), peer.tcpPort());
	messagingService.sendAsync(remoteEp, HEARTBEAT_MESSAGE, messagePayload).whenComplete((result, error) -> {
	if (error != null) {
	log.trace("Sending heartbeat to {} failed", remoteEp, error);
	}
	});
	}

	private class HeartbeatMessageHandler implements BiConsumer<Endpoint, byte[]> {
	@Override
	public void accept(Endpoint sender, byte[] message) {
	HeartbeatMessage hb = SERIALIZER.decode(message);
	failureDetector.report(hb.source().id());
	updateState(hb.source().id(), hb.state);
	hb.knownPeers().forEach(node -> {
	allNodes.put(node.id(), node);
	});
	}
	}

	private static class HeartbeatMessage {
	private ControllerNode source;
	private State state;
	private Set<ControllerNode> knownPeers;

	public HeartbeatMessage(ControllerNode source, State state, Set<ControllerNode> members) {
	this.source = source;
	this.state = state != null ? state : State.ACTIVE;
	this.knownPeers = ImmutableSet.copyOf(members);
	}

	public ControllerNode source() {
	return source;
	}

	public Set<ControllerNode> knownPeers() {
	return knownPeers;
	}
	}

	@Override
	public DateTime getLastUpdated(NodeId nodeId) {
	return nodeStateLastUpdatedTimes.get(nodeId);
	}

	/**
	* Extracts properties from the component configuration context.
	*
	* @param context the component context
	*/
	private void readComponentConfiguration(ComponentContext context) {
	Dictionary<?, ?> properties = context.getProperties();

	Integer newHeartbeatInterval = Tools.getIntegerProperty(properties,
	"heartbeatInterval");
	if (newHeartbeatInterval == null) {
	setHeartbeatInterval(DEFAULT_HEARTBEAT_INTERVAL);
	log.info("Heartbeat interval time is not configured, default value is {}",
	DEFAULT_HEARTBEAT_INTERVAL);
	} else {
	setHeartbeatInterval(newHeartbeatInterval);
	log.info("Configured. Heartbeat interval time is configured to {}",
	heartbeatInterval);
	}

	Integer newPhiFailureThreshold = Tools.getIntegerProperty(properties,
	"phiFailureThreshold");
	if (newPhiFailureThreshold == null) {
	setPhiFailureThreshold(DEFAULT_PHI_FAILURE_THRESHOLD);
	log.info("Phi failure threshold is not configured, default value is {}",
	DEFAULT_PHI_FAILURE_THRESHOLD);
	} else {
	setPhiFailureThreshold(newPhiFailureThreshold);
	log.info("Configured. Phi failure threshold is configured to {}",
	phiFailureThreshold);
	}
	}

	/**
	* Sets heartbeat interval between the termination of one execution of heartbeat
	* and the commencement of the next.
	*
	* @param interval term between each heartbeat
	*/
	private void setHeartbeatInterval(int interval) {
	try {
	checkArgument(interval > 0, "Interval must be greater than zero");
	heartbeatInterval = interval;
	} catch (IllegalArgumentException e) {
	log.warn(e.getMessage());
	heartbeatInterval = DEFAULT_HEARTBEAT_INTERVAL;
	}
	}

	/**
	* Sets Phi failure threshold.
	* Phi is based on a paper titled: "The φ Accrual Failure Detector" by Hayashibara, et al.
	*
	* @param threshold
	*/
	private void setPhiFailureThreshold(int threshold) {
	phiFailureThreshold = threshold;
	}

	/**
	* Restarts heartbeatSender executor.
	*
	*/
	private void restartHeartbeatSender() {
	try {
	ScheduledExecutorService prevSender = heartBeatSender;
	heartBeatSender = Executors.newSingleThreadScheduledExecutor(
	groupedThreads("onos/cluster/membership", "heartbeat-sender-%d", log));
	heartBeatSender.scheduleWithFixedDelay(this::heartbeat, 0,
	heartbeatInterval, TimeUnit.MILLISECONDS);
	prevSender.shutdown();
	} catch (Exception e) {
	log.warn(e.getMessage());
	}
	}

	/**
	* Gets current heartbeat interval.
	*
	* @return heartbeatInterval
	*/
	private int getHeartbeatInterval() {
	return heartbeatInterval;
	}

	/**
	* Gets current Phi failure threshold for Accrual Failure Detector.
	*
	* @return phiFailureThreshold
	*/
	private int getPhiFailureThreshold() {
	return phiFailureThreshold;
	}

	}