zookeeper的Leader选举源码解析

京东云开发者
• 阅读 302

作者:京东物流 梁吉超

zookeeper是一个分布式服务框架,主要解决分布式应用中常见的多种数据问题,例如集群管理,状态同步等。为解决这些问题zookeeper需要Leader选举进行保障数据的强一致性机制和稳定性。本文通过集群的配置,对leader选举源进行解析,让读者们了解如何利用BIO通信机制,多线程多层队列实现高性能架构。****

01Leader选举机制

Leader选举机制采用半数选举算法。

每一个zookeeper服务端称之为一个节点,每


个节点都有投票权,把其选票投向每一个有选举权的节点,当其中一个节点选举出票数过半,这个节点就会成为Leader,其它节点成为Follower。

02Leader选举集群配置

  1. 重命名zoo_sample.cfg文件为zoo1.cfg ,zoo2.cfg,zoo3.cfg,zoo4.cfg

  2. 修改zoo.cfg文件,修改值如下:

【plain】
zoo1.cfg文件内容:
dataDir=/export/data/zookeeper-1
clientPort=2181
server.1=127.0.0.1:2001:3001
server.2=127.0.0.1:2002:3002:participant
server.3=127.0.0.1:2003:3003:participant
server.4=127.0.0.1:2004:3004:observer


zoo2.cfg文件内容:
dataDir=/export/data/zookeeper-2
clientPort=2182
server.1=127.0.0.1:2001:3001
server.2=127.0.0.1:2002:3002:participant
server.3=127.0.0.1:2003:3003:participant
server.4=127.0.0.1:2004:3004:observer


zoo3.cfg文件内容:
dataDir=/export/data/zookeeper-3
clientPort=2183
server.1=127.0.0.1:2001:3001
server.2=127.0.0.1:2002:3002:participant
server.3=127.0.0.1:2003:3003:participant
server.4=127.0.0.1:2004:3004:observer


zoo4.cfg文件内容:
dataDir=/export/data/zookeeper-4
clientPort=2184
server.1=127.0.0.1:2001:3001
server.2=127.0.0.1:2002:3002:participant
server.3=127.0.0.1:2003:3003:participant
server.4=127.0.0.1:2004:3004:observer





  1. server.第几号服务器(对应myid文件内容)=ip:数据同步端口:选举端口:选举标识
  • participant默认参与选举标识,可不写. observer不参与选举

4.在/export/data/zookeeper-1,/export/data/zookeeper-2,/export/data/zookeeper-3,/export/data/zookeeper-4目录下创建myid文件,文件内容分别写1 ,2,3,4,用于标识sid(全称:Server ID)赋值。

  1. 启动三个zookeeper实例:
  • bin/zkServer.sh start conf/zoo1.cfg
  • bin/zkServer.sh start conf/zoo2.cfg
  • bin/zkServer.sh start conf/zoo3.cfg
  1. 每启动一个实例,都会读取启动参数配置zoo.cfg文件,这样实例就可以知道其作为服务端身份信息sid以及集群中有多少个实例参与选举。

03Leader选举流程

zookeeper的Leader选举源码解析

图1 第一轮到第二轮投票流程

前提:

设定票据数据格式vote(sid,zxid,epoch)

  • sid是Server ID每台服务的唯一标识,是myid文件内容;
  • zxid是数据事务id号;
  • epoch为选举周期,为方便理解下面讲解内容暂定为1初次选举,不写入下面内容里。

按照顺序启动sid=1,sid=2节点

第一轮投票:

  1. sid=1节点:初始选票为自己,将选票vote(1,0)发送给sid=2节点;

  2. sid=2节点:初始选票为自己,将选票vote(2,0)发送给sid=1节点;

  3. sid=1节点:收到sid=2节点选票vote(2,0)和当前自己的选票vote(1,0),首先比对zxid值,zxid越大代表数据最新,优先选择zxid最大的选票,如果zxid相同,选举最大sid。当前投票选举结果为vote(2,0),sid=1节点的选票变为vote(2,0);

  4. sid=2节点:收到sid=1节点选票vote(1,0)和当前自己的选票vote(2,0),参照上述选举方式,选举结果为vote(2,0),sid=2节点的选票不变;

  5. 第一轮投票选举结束。

第二轮投票:

  1. sid=1节点:当前自己的选票为vote(2,0),将选票vote(2,0)发送给sid=2节点;

  2. sid=2节点:当前自己的选票为vote(2,0),将选票vote(2,0)发送给sid=1节点;

  3. sid=1节点:收到sid=2节点选票vote(2,0)和自己的选票vote(2,0), 按照半数选举算法,总共3个节点参与选举,已有2个节点选举出相同选票,推举sid=2节点为Leader,自己角色变为Follower;

  4. sid=2节点:收到sid=1节点选票vote(2,0)和自己的选票vote(2,0),按照半数选举算法推举sid=2节点为Leader,自己角色变为Leader。

这时启动sid=3节点后,集群里已经选举出leader,sid=1和sid=2节点会将自己的leader选票发回给sid=3节点,通过半数选举结果还是sid=2节点为leader。

3.1 Leader选举采用多层队列架构

zookeeper选举底层主要分为选举应用层和消息传输队列层,第一层应用层队列统一接收和发送选票,而第二层传输层队列,是按照服务端sid分成了多个队列,是为了避免给每台服务端发送消息互相影响。比如对某台机器发送不成功不会影响正常服务端的发送。

zookeeper的Leader选举源码解析

图2 多层队列上下关系交互流程图

04解析代码入口类

通过查看zkServer.sh文件内容找到服务启动类:

org.apache.zookeeper.server.quorum.QuorumPeerMain

05选举流程代码解析

zookeeper的Leader选举源码解析

图3 选举代码实现流程图

  1. 加载配置文件QuorumPeerConfig.parse(path);

针对 Leader选举关键配置信息如下:

  • 读取dataDir目录找到myid文件内容,设置当前应用sid标识,做为投票人身份信息。下面遇到myid变量为当前节点自己sid标识。
    • 设置peerType当前应用是否参与选举
  • new QuorumMaj()解析server.前缀加载集群成员信息,加载allMembers所有成员,votingMembers参与选举成员,observingMembers观察者成员,设置half值votingMembers.size()/2.
【Java】
public QuorumMaj(Properties props) throws ConfigException {
        for (Entry<Object, Object> entry : props.entrySet()) {
            String key = entry.getKey().toString();
            String value = entry.getValue().toString();
            //读取集群配置文件中的server.开头的应用实例配置信息
            if (key.startsWith("server.")) {
                int dot = key.indexOf('.');
                long sid = Long.parseLong(key.substring(dot + 1));
                QuorumServer qs = new QuorumServer(sid, value);
                allMembers.put(Long.valueOf(sid), qs);
                if (qs.type == LearnerType.PARTICIPANT)
//应用实例绑定的角色为PARTICIPANT意为参与选举
                    votingMembers.put(Long.valueOf(sid), qs);
                else {
                    //观察者成员
                    observingMembers.put(Long.valueOf(sid), qs);
                }
            } else if (key.equals("version")) {
                version = Long.parseLong(value, 16);
            }
        }
        //过半基数
        half = votingMembers.size() / 2;
    }





  1. QuorumPeerMain.runFromConfig(config) 启动服务;

  2. QuorumPeer.startLeaderElection() 开启选举服务;

  • 设置当前选票new Vote(sid,zxid,epoch)
【plain】
synchronized public void startLeaderElection(){
try {
           if (getPeerState() == ServerState.LOOKING) {
               //首轮:当前节点默认投票对象为自己
               currentVote = new Vote(myid, getLastLoggedZxid(), getCurrentEpoch());
           }
       } catch(IOException e) {
           RuntimeException re = new RuntimeException(e.getMessage());
           re.setStackTrace(e.getStackTrace());
           throw re;
       }
//........
}





  • 创建选举管理类:QuorumCnxnManager;
  • 初始化recvQueue<Message(sid,ByteBuffer)>接收投票队列(第二层传输队列);
  • 初始化queueSendMap<sid,queue>按sid发送投票队列(第二层传输队列);
  • 初始化senderWorkerMap<sid,SendWorker>发送投票工作线程容器,表示着与sid投票节点已连接;
  • 初始化选举监听线程类QuorumCnxnManager.Listener。
【Java】
//QuorumPeer.createCnxnManager()
public QuorumCnxManager(QuorumPeer self,
                        final long mySid,
                        Map<Long,QuorumPeer.QuorumServer> view,
                        QuorumAuthServer authServer,
                        QuorumAuthLearner authLearner,
                        int socketTimeout,
                        boolean listenOnAllIPs,
                        int quorumCnxnThreadsSize,
                        boolean quorumSaslAuthEnabled) {
    //接收投票队列(第二层传输队列)
    this.recvQueue = new ArrayBlockingQueue<Message>(RECV_CAPACITY);
    //按sid发送投票队列(第二层传输队列)
    this.queueSendMap = new ConcurrentHashMap<Long, ArrayBlockingQueue<ByteBuffer>>();
    //发送投票工作线程容器,表示着与sid投票节点已连接 
    this.senderWorkerMap = new ConcurrentHashMap<Long, SendWorker>();
    this.lastMessageSent = new ConcurrentHashMap<Long, ByteBuffer>();


    String cnxToValue = System.getProperty("zookeeper.cnxTimeout");
    if(cnxToValue != null){
        this.cnxTO = Integer.parseInt(cnxToValue);
    }


    this.self = self;


    this.mySid = mySid;
    this.socketTimeout = socketTimeout;
    this.view = view;
    this.listenOnAllIPs = listenOnAllIPs;


    initializeAuth(mySid, authServer, authLearner, quorumCnxnThreadsSize,
            quorumSaslAuthEnabled);
    // Starts listener thread that waits for connection requests 
    //创建选举监听线程 接收选举投票请求
    listener = new Listener();
    listener.setName("QuorumPeerListener");
}
//QuorumPeer.createElectionAlgorithm
protected Election createElectionAlgorithm(int electionAlgorithm){
    Election le=null;
    //TODO: use a factory rather than a switch
    switch (electionAlgorithm) {
    case 0:
        le = new LeaderElection(this);
        break;
    case 1:
        le = new AuthFastLeaderElection(this);
        break;
    case 2:
        le = new AuthFastLeaderElection(this, true);
        break;
    case 3:
        qcm = createCnxnManager();// new QuorumCnxManager(... new Listener())
        QuorumCnxManager.Listener listener = qcm.listener;
        if(listener != null){
            listener.start();//启动选举监听线程
            FastLeaderElection fle = new FastLeaderElection(this, qcm);
            fle.start();
            le = fle;
        } else {
            LOG.error("Null listener when initializing cnx manager");
        }
        break;
    default:
        assert false;
    }
return le;}





  1. 开启选举监听线程QuorumCnxnManager.Listener;
  • 创建ServerSockket等待大于自己sid节点连接,连接信息存储到senderWorkerMap<sid,SendWorker>;
  • sid>self.sid才可以连接过来。
【Java】
//上面的listener.start()执行后,选择此方法
public void run() {
    int numRetries = 0;
    InetSocketAddress addr;
    Socket client = null;
    while((!shutdown) && (numRetries < 3)){
        try {
            ss = new ServerSocket();
            ss.setReuseAddress(true);
            if (self.getQuorumListenOnAllIPs()) {
                int port = self.getElectionAddress().getPort();
                addr = new InetSocketAddress(port);
            } else {
                // Resolve hostname for this server in case the
                // underlying ip address has changed.
                self.recreateSocketAddresses(self.getId());
                addr = self.getElectionAddress();
            }
            LOG.info("My election bind port: " + addr.toString());
            setName(addr.toString());
            ss.bind(addr);
            while (!shutdown) {
                client = ss.accept();
                setSockOpts(client);
                LOG.info("Received connection request "
                        + client.getRemoteSocketAddress());
                // Receive and handle the connection request
                // asynchronously if the quorum sasl authentication is
                // enabled. This is required because sasl server
                // authentication process may take few seconds to finish,
                // this may delay next peer connection requests.
                if (quorumSaslAuthEnabled) {
                    receiveConnectionAsync(client);
                } else {
//接收连接信息
                    receiveConnection(client);
                }
                numRetries = 0;
            }
        } catch (IOException e) {
            if (shutdown) {
                break;
            }
            LOG.error("Exception while listening", e);
            numRetries++;
            try {
                ss.close();
                Thread.sleep(1000);
            } catch (IOException ie) {
                LOG.error("Error closing server socket", ie);
            } catch (InterruptedException ie) {
                LOG.error("Interrupted while sleeping. " +
                    "Ignoring exception", ie);
            }
            closeSocket(client);
        }
    }
    LOG.info("Leaving listener");
    if (!shutdown) {
        LOG.error("As I'm leaving the listener thread, "
                + "I won't be able to participate in leader "
                + "election any longer: "
                + self.getElectionAddress());
    } else if (ss != null) {
        // Clean up for shutdown.
        try {
            ss.close();
        } catch (IOException ie) {
            // Don't log an error for shutdown.
            LOG.debug("Error closing server socket", ie);
        }
    }
}


//代码执行路径:receiveConnection()->handleConnection(...)
private void handleConnection(Socket sock, DataInputStream din)
            throws IOException {
//...省略
     if (sid < self.getId()) {
            /*
             * This replica might still believe that the connection to sid is
             * up, so we have to shut down the workers before trying to open a
             * new connection.
             */
            SendWorker sw = senderWorkerMap.get(sid);
            if (sw != null) {
                sw.finish();
            }


            /*
             * Now we start a new connection
             */
            LOG.debug("Create new connection to server: {}", sid);
            closeSocket(sock);


            if (electionAddr != null) {
                connectOne(sid, electionAddr);
            } else {
                connectOne(sid);
            }


        } else { // Otherwise start worker threads to receive data.
            SendWorker sw = new SendWorker(sock, sid);
            RecvWorker rw = new RecvWorker(sock, din, sid, sw);
            sw.setRecv(rw);


            SendWorker vsw = senderWorkerMap.get(sid);


            if (vsw != null) {
                vsw.finish();
            }
  //存储连接信息<sid,SendWorker>
            senderWorkerMap.put(sid, sw);


            queueSendMap.putIfAbsent(sid,
                    new ArrayBlockingQueue<ByteBuffer>(SEND_CAPACITY));


            sw.start();
            rw.start();
     }
}





  1. 创建FastLeaderElection快速选举服务;
  • 初始选票发送队列sendqueue(第一层队列)
  • 初始选票接收队列recvqueue(第一层队列)
  • 创建线程WorkerSender
  • 创建线程WorkerReceiver
【Java】
//FastLeaderElection.starter
private void starter(QuorumPeer self, QuorumCnxManager manager) {
    this.self = self;
    proposedLeader = -1;
    proposedZxid = -1;
    //发送队列sendqueue(第一层队列)
    sendqueue = new LinkedBlockingQueue<ToSend>();
    //接收队列recvqueue(第一层队列)
    recvqueue = new LinkedBlockingQueue<Notification>();
    this.messenger = new Messenger(manager);
}
//new Messenger(manager)
Messenger(QuorumCnxManager manager) {
    //创建线程WorkerSender
    this.ws = new WorkerSender(manager);


    this.wsThread = new Thread(this.ws,
            "WorkerSender[myid=" + self.getId() + "]");
    this.wsThread.setDaemon(true);
    //创建线程WorkerReceiver
    this.wr = new WorkerReceiver(manager);


    this.wrThread = new Thread(this.wr,
            "WorkerReceiver[myid=" + self.getId() + "]");
    this.wrThread.setDaemon(true);
}





  1. 开启WorkerSender和WorkerReceiver线程。

WorkerSender线程自旋获取sendqueue第一层队列元素

  • sendqueue队列元素内容为相关选票信息详见ToSend类;
  • 首先判断选票sid是否和自己sid值相同,相等直接放入到recvQueue队列中;
  • 不相同将sendqueue队列元素转储到queueSendMap<sid,queue>第二层传输队列中。
【Java】//FastLeaderElection.Messenger.WorkerSenderclass WorkerSender extends ZooKeeperThread{
//...
  public void run() {
    while (!stop) {
        try {
            ToSend m = sendqueue.poll(3000, TimeUnit.MILLISECONDS);
            if(m == null) continue;
  //将投票信息发送出去
            process(m);
        } catch (InterruptedException e) {
            break;
        }
    }
    LOG.info("WorkerSender is down");
  }
}
//QuorumCnxManager#toSend
public void toSend(Long sid, ByteBuffer b) {
    /*
     * If sending message to myself, then simply enqueue it (loopback).
     */
    if (this.mySid == sid) {
         b.position(0);
         addToRecvQueue(new Message(b.duplicate(), sid));
        /*
         * Otherwise send to the corresponding thread to send.
         */
    } else {
         /*
          * Start a new connection if doesn't have one already.
          */
         ArrayBlockingQueue<ByteBuffer> bq = new ArrayBlockingQueue<ByteBuffer>(
            SEND_CAPACITY);
         ArrayBlockingQueue<ByteBuffer> oldq = queueSendMap.putIfAbsent(sid, bq);
         //转储到queueSendMap<sid,queue>第二层传输队列中
         if (oldq != null) {
             addToSendQueue(oldq, b);
         } else {
             addToSendQueue(bq, b);
         }
         connectOne(sid);     
    }
}





WorkerReceiver线程自旋获取recvQueue第二层传输队列元素转存到recvqueue第一层队列中。

【Java】
//WorkerReceiver
public void run() {
    Message response;
    while (!stop) {
      // Sleeps on receive
      try {
          //自旋获取recvQueue第二层传输队列元素
          response = manager.pollRecvQueue(3000, TimeUnit.MILLISECONDS);
          if(response == null) continue;
          // The current protocol and two previous generations all send at least 28 bytes
          if (response.buffer.capacity() < 28) {
              LOG.error("Got a short response: " + response.buffer.capacity());
              continue;
          }
          //...
  if(self.getPeerState() == QuorumPeer.ServerState.LOOKING){
         //第二层传输队列元素转存到recvqueue第一层队列中
         recvqueue.offer(n);
         //...
      }
    }
//...
}





06选举核心逻辑

  1. 启动线程QuorumPeer

开始Leader选举投票makeLEStrategy().lookForLeader();

sendNotifications()向其它节点发送选票信息,选票信息存储到sendqueue队列中。sendqueue队列由WorkerSender线程处理。

【plain】
//QuorunPeer.run
//...
try {
   reconfigFlagClear();
    if (shuttingDownLE) {
       shuttingDownLE = false;
       startLeaderElection();
       }
    //makeLEStrategy().lookForLeader() 发送投票
    setCurrentVote(makeLEStrategy().lookForLeader());
} catch (Exception e) {
    LOG.warn("Unexpected exception", e);
    setPeerState(ServerState.LOOKING);
}  
//...
//FastLeaderElection.lookLeader
public Vote lookForLeader() throws InterruptedException {
//...
  //向其他应用发送投票
sendNotifications();
//...
}


private void sendNotifications() {
    //获取应用节点
    for (long sid : self.getCurrentAndNextConfigVoters()) {
        QuorumVerifier qv = self.getQuorumVerifier();
        ToSend notmsg = new ToSend(ToSend.mType.notification,
                proposedLeader,
                proposedZxid,
                logicalclock.get(),
                QuorumPeer.ServerState.LOOKING,
                sid,
                proposedEpoch, qv.toString().getBytes());
        if(LOG.isDebugEnabled()){
            LOG.debug("Sending Notification: " + proposedLeader + " (n.leader), 0x"  +
                  Long.toHexString(proposedZxid) + " (n.zxid), 0x" + Long.toHexString(logicalclock.get())  +
                  " (n.round), " + sid + " (recipient), " + self.getId() +
                  " (myid), 0x" + Long.toHexString(proposedEpoch) + " (n.peerEpoch)");
        }
        //储存投票信息
        sendqueue.offer(notmsg);
    }
}


class WorkerSender extends ZooKeeperThread {
    //...
    public void run() {
    while (!stop) {
        try {
//提取已储存的投票信息
            ToSend m = sendqueue.poll(3000, TimeUnit.MILLISECONDS);
            if(m == null) continue;


            process(m);
        } catch (InterruptedException e) {
            break;
        }
    }
    LOG.info("WorkerSender is down");
  }
//...
}





自旋recvqueue队列元素获取投票过来的选票信息:

【Java】
public Vote lookForLeader() throws InterruptedException {
//...
/*
 * Loop in which we exchange notifications until we find a leader
 */
while ((self.getPeerState() == ServerState.LOOKING) &&
        (!stop)){
    /*
     * Remove next notification from queue, times out after 2 times
     * the termination time
     */
    //提取投递过来的选票信息
    Notification n = recvqueue.poll(notTimeout,
            TimeUnit.MILLISECONDS);
/*
 * Sends more notifications if haven't received enough.
 * Otherwise processes new notification.
 */
if(n == null){
    if(manager.haveDelivered()){
        //已全部连接成功,并且前一轮投票都完成,需要再次发起投票
        sendNotifications();
    } else {
        //如果未收到选票信息,manager.contentAll()自动连接其它socket节点
        manager.connectAll();
    }
    /*
     * Exponential backoff
     */
    int tmpTimeOut = notTimeout*2;
    notTimeout = (tmpTimeOut < maxNotificationInterval?
            tmpTimeOut : maxNotificationInterval);
    LOG.info("Notification time out: " + notTimeout);
         }
     //....
    }
  //...
}





【Java】
//manager.connectAll()->connectOne(sid)->initiateConnection(...)->startConnection(...)


private boolean startConnection(Socket sock, Long sid)
        throws IOException {
    DataOutputStream dout = null;
    DataInputStream din = null;
    try {
        // Use BufferedOutputStream to reduce the number of IP packets. This is
        // important for x-DC scenarios.
        BufferedOutputStream buf = new BufferedOutputStream(sock.getOutputStream());
        dout = new DataOutputStream(buf);


        // Sending id and challenge
        // represents protocol version (in other words - message type)
        dout.writeLong(PROTOCOL_VERSION);
        dout.writeLong(self.getId());
        String addr = self.getElectionAddress().getHostString() + ":" + self.getElectionAddress().getPort();
        byte[] addr_bytes = addr.getBytes();
        dout.writeInt(addr_bytes.length);
        dout.write(addr_bytes);
        dout.flush();


        din = new DataInputStream(
                new BufferedInputStream(sock.getInputStream()));
    } catch (IOException e) {
        LOG.warn("Ignoring exception reading or writing challenge: ", e);
        closeSocket(sock);
        return false;
    }


    // authenticate learner
    QuorumPeer.QuorumServer qps = self.getVotingView().get(sid);
    if (qps != null) {
        // TODO - investigate why reconfig makes qps null.
        authLearner.authenticate(sock, qps.hostname);
    }


    // If lost the challenge, then drop the new connection
    //保证集群中所有节点之间只有一个通道连接
    if (sid > self.getId()) {
        LOG.info("Have smaller server identifier, so dropping the " +
                "connection: (" + sid + ", " + self.getId() + ")");
        closeSocket(sock);
        // Otherwise proceed with the connection
    } else {
        SendWorker sw = new SendWorker(sock, sid);
        RecvWorker rw = new RecvWorker(sock, din, sid, sw);
        sw.setRecv(rw);


        SendWorker vsw = senderWorkerMap.get(sid);


        if(vsw != null)
            vsw.finish();


        senderWorkerMap.put(sid, sw);
        queueSendMap.putIfAbsent(sid, new ArrayBlockingQueue<ByteBuffer>(
                SEND_CAPACITY));


        sw.start();
        rw.start();


        return true;


    }
    return false;
}





如上述代码中所示,sid>self.sid才可以创建连接Socket和SendWorker,RecvWorker线程,存储到senderWorkerMap<sid,SendWorker>中。对应第2步中的sid<self.sid逻辑,保证集群中所有节点之间只有一个通道连接。

zookeeper的Leader选举源码解析

图4 节点之间连接方式

【Java】


public Vote lookForLeader() throws InterruptedException {
//...
    if (n.electionEpoch > logicalclock.get()) {
        //当前选举周期小于选票周期,重置recvset选票池
        //大于当前周期更新当前选票信息,再次发送投票
        logicalclock.set(n.electionEpoch);
        recvset.clear();
        if(totalOrderPredicate(n.leader, n.zxid, n.peerEpoch,
                getInitId(), getInitLastLoggedZxid(), getPeerEpoch())) {
            updateProposal(n.leader, n.zxid, n.peerEpoch);
        } else {
            updateProposal(getInitId(),
                    getInitLastLoggedZxid(),
                    getPeerEpoch());
        }
        sendNotifications();
    } else if (n.electionEpoch < logicalclock.get()) {
        if(LOG.isDebugEnabled()){
            LOG.debug("Notification election epoch is smaller than logicalclock. n.electionEpoch = 0x"
                    + Long.toHexString(n.electionEpoch)
                    + ", logicalclock=0x" + Long.toHexString(logicalclock.get()));
        }
        break;
    } else if (totalOrderPredicate(n.leader, n.zxid, n.peerEpoch,
            proposedLeader, proposedZxid, proposedEpoch)) {//相同选举周期
        //接收的选票与当前选票PK成功后,替换当前选票
        updateProposal(n.leader, n.zxid, n.peerEpoch);
        sendNotifications();
    }
//...


}





在上代码中,自旋从recvqueue队列中获取到选票信息。开始进行选举:

  • 判断当前选票和接收过来的选票周期是否一致
  • 大于当前周期更新当前选票信息,再次发送投票
  • 周期相等:当前选票信息和接收的选票信息进行PK
【Java】
//接收的选票与当前选票PK
protected boolean totalOrderPredicate(long newId, long newZxid, long newEpoch, long curId, long curZxid, long curEpoch) {
        LOG.debug("id: " + newId + ", proposed id: " + curId + ", zxid: 0x" +
                Long.toHexString(newZxid) + ", proposed zxid: 0x" + Long.toHexString(curZxid));
        if(self.getQuorumVerifier().getWeight(newId) == 0){
            return false;
        }


        /*
         * We return true if one of the following three cases hold:
         * 1- New epoch is higher
         * 2- New epoch is the same as current epoch, but new zxid is higher
         * 3- New epoch is the same as current epoch, new zxid is the same
         *  as current zxid, but server id is higher.
         */
        return ((newEpoch > curEpoch) ||
                ((newEpoch == curEpoch) &&
                ((newZxid > curZxid) || ((newZxid == curZxid) && (newId > curId)))));wId > curId)))));
  }





在上述代码中的totalOrderPredicate方法逻辑如下:

  • 竞选周期大于当前周期为true
  • 竞选周期相等,竞选zxid大于当前zxid为true
  • 竞选周期相等,竞选zxid等于当前zxid,竞选sid大于当前sid为true
  • 经过上述条件判断为true将当前选票信息替换为竞选成功的选票,同时再次将新的选票投出去。
【Java】
public Vote lookForLeader() throws InterruptedException {
//...
   //存储节点对应的选票信息
    // key:选票来源sid  value:选票推举的Leader sid
    recvset.put(n.sid, new Vote(n.leader, n.zxid, n.electionEpoch, n.peerEpoch));


    //半数选举开始
    if (termPredicate(recvset,
            new Vote(proposedLeader, proposedZxid,
                    logicalclock.get(), proposedEpoch))) {
        // Verify if there is any change in the proposed leader
        while((n = recvqueue.poll(finalizeWait,
                TimeUnit.MILLISECONDS)) != null){
            if(totalOrderPredicate(n.leader, n.zxid, n.peerEpoch,
                    proposedLeader, proposedZxid, proposedEpoch)){
                recvqueue.put(n);
                break;
            }
        }
        /*WorkerSender
         * This predicate is true once we don't read any new
         * relevant message from the reception queue
         */
        if (n == null) {
            //已选举出leader 更新当前节点是否为leader 
            self.setPeerState((proposedLeader == self.getId()) ?
                    ServerState.LEADING: learningState());


            Vote endVote = new Vote(proposedLeader,
                    proposedZxid, proposedEpoch);
            leaveInstance(endVote);
            return endVote;
        }
    }
//...
}
/**
     * Termination predicate. Given a set of votes, determines if have
     * sufficient to declare the end of the election round.
     *
     * @param votes
     *            Set of votes
     * @param vote
     *            Identifier of the vote received last  PK后的选票
     */
private boolean termPredicate(HashMap<Long, Vote> votes, Vote vote) {
    SyncedLearnerTracker voteSet = new SyncedLearnerTracker();
    voteSet.addQuorumVerifier(self.getQuorumVerifier());
    if (self.getLastSeenQuorumVerifier() != null
            && self.getLastSeenQuorumVerifier().getVersion() > self
                    .getQuorumVerifier().getVersion()) {
        voteSet.addQuorumVerifier(self.getLastSeenQuorumVerifier());
    }
    /*
     * First make the views consistent. Sometimes peers will have different
     * zxids for a server depending on timing.
     */
    //votes 来源于recvset 存储各个节点推举出来的选票信息
    for (Map.Entry<Long, Vote> entry : votes.entrySet()) {
//选举出的sid和其它节点选择的sid相同存储到voteSet变量中。
        if (vote.equals(entry.getValue())) {
//保存推举出来的sid
            voteSet.addAck(entry.getKey());
        }
    }
    //判断选举出来的选票数量是否过半
    return voteSet.hasAllQuorums();
}
//QuorumMaj#containsQuorum
public boolean containsQuorum(Set<Long> ackSet) {
    return (ackSet.size() > half);
   }





在上述代码中:recvset是存储每个sid推举的选票信息。

第一轮 sid1:vote(1,0,1) ,sid2:vote(2,0,1);

第二轮 sid1:vote(2,0,1) ,sid2:vote(2,0,1)。

最终经过选举信息vote(2,0,1)为推荐leader,并用推荐leader在recvset选票池里比对持相同票数量为2个。因为总共有3个节点参与选举,sid1和sid2都选举sid2为leader,满足票数过半要求,故确认sid2为leader。

  • setPeerState更新当前节点角色;
  • proposedLeader选举出来的sid和自己sid相等,设置为Leader;
  • 上述条件不相等,设置为Follower或Observing;
  • 更新currentVote当前选票为Leader的选票vote(2,0,1)。

07总结

通过对Leader选举源码的解析,可以了解到:

  1. 多个应用节点之间网络通信采用BIO方式进行相互投票,同时保证每个节点之间只使用一个通道,减少网络资源的消耗,足以见得在BIO分布式中间件开发中的技术重要性。

  2. 基于BIO的基础上,灵活运用多线程和内存消息队列完好实现多层队列架构,每层队列由不同的线程分工协作,提高快速选举性能目的。

  3. 为BIO在多线程技术上的实践带来了宝贵的经验。

点赞
收藏
评论区
推荐文章
Prodan Labs Prodan Labs
3年前
Kubernetes自定义调度器 — 初窥门径
通过上一篇文章对schedulerframework调度框架已经有了大致了解,根据我们的实际生产的一些问题(如计算服务没有被调度到实际CPU最优的节点)和需求,来实现一个简单的基于CPU指标的自定义调度器。自定义调度器通过kubernetes资源指标服务metricsserver来获取各节点的当前的资源情况,并进行打分,然后把Pod调度到分数最高的节
应用健康度隐患刨析解决系列之数据库时区设置
应用健康度是反馈应用健康程度的指标,它将系统指标分类为基础资源、容器、应用、报警配置、链路这几项,收集了一系列系统应用的指标,并对指标进行打分。
搜索EE场景排序链路升级
EE模块是搜索系统中改善生态、探索商品的重要链路,其目标是缓解数据马太效应导致模型对商品排序丰富性、探索性不足,带来的系统非最优解问题。以下分别从模型迭代、在线实验指标、离线评估体系介绍相应模块的优化。
Wesley13 Wesley13
3年前
APM监控
一,基础知识储备分布式跟踪的目标一个分布式系统由若干分布式服务构成,每一个请求会经过多个业务系统并留下足迹,但是这些分散的数据对于问题排查,或是流程优化都很有限,要能做到追踪每个请求的完整链路调用,收集链路调用上每个服务的性能数据,计算性能数据和比对性能指标(SLA),甚至能够再反馈到服务治理中,那么这就是分布式跟踪的目标。分布式跟踪的目的
Stella981 Stella981
3年前
Prometheus监控学习笔记之PromQL简单示例
0x00简单的时间序列选择返回度量指标http_requests_total的所有时间序列样本数据:http_requests_total返回度量指标名称为http_requests_total,标签分别是job"apiserver",handler"/api/comments"
Wesley13 Wesley13
3年前
Java内嵌Groovy脚本引擎进行业务规则剥离(四)
前三篇文章已从groovy脚本的基本使用到java解析,json对象结合作了一基础铺垫。这篇文章是本系列的最后一篇文章。在第二篇文章中,说到用groovy编写的规则脚本,然后采用文件字符串的形式加载到java中,解析并运行。在我的应用场景中,每一条规则就是一个业务指标项。每一个指标项能够单独维护,而不是把所有指标项统一放到一个文件中。那么,我需
Wesley13 Wesley13
3年前
Java 应用发布后,需要关注的7个性能指标
在某个重大发布之后,都需要记录相应的指标,本文介绍了最重要的几个Java性能指标,包括响应时间和平均负载等。为理解应用程序在生产环境中如何运行,就需要遵循一些Java性能指标。在以前,当软件被发布后,开发者是没有方法去了解它在生产环境中的运行情况;而现在,几乎任一个你可以想到的指标都可以被监测和报告。时下,开发者面临的问题并不是缺乏信息,
【稳定性】关于缩短MTTR的探索 | 京东物流技术团队
一、什么是MTTR?当系统出现系统故障时,我们需要通过一些指标来衡量故障的严重程度和影响范围。其中MTTR(MeanTimeToRepair名为平均修复时间)是一个非常重要的指标,它可以帮助我们了解修复系统所需的平均时间。花费太长时间来修复系统是不可取的,
京东云开发者 京东云开发者
10个月前
CDN静态资源加速&Lighthouse性能监测
本文主要介绍了cdn加速在项目中的实现,以及使用Lighthouse对前端性能指标进行监测打分。Lighthouse简介Lighthouse是谷歌开发并开源的web性能测试工具,用于改进网络应用的质量,可以将其作为一个Chrome扩展程序运行,或从命令行运
敏捷开发 敏捷开发
7个月前
哪些无用敏捷指标正在破坏敏捷转型?
无用的敏捷指标有可能破坏任何敏捷转型,详细了解如何识别和避免不良指标。