上一节我们挖了个坑，还剩下 poolUpdater 还没讲，我们这期接着讲一下这个点，我们同样也是从初始化方法开始：

 public void init() {
        if (inited) {
            return;
        }
        synchronized (this) {
            if (inited) {
                return;
            }
            if (intervalSeconds < 10) {
                LOG.warn("CAUTION: Purge interval has been set to " + intervalSeconds
                        + ". This value should NOT be too small.");
            }
            if (intervalSeconds <= 0) {
                intervalSeconds = DEFAULT_INTERVAL;
            }
            executor = Executors.newScheduledThreadPool(1);
            executor.scheduleAtFixedRate(new Runnable() {
                @Override
                public void run() {
                    LOG.debug("Purging the DataSource Pool every " + intervalSeconds + "s.");
                    try {
                        removeDataSources();
                    } catch (Exception e) {
                        LOG.error("Exception occurred while removing DataSources.", e);
                    }
                }
            }, intervalSeconds, intervalSeconds, TimeUnit.SECONDS);
        }
    }

这里逻辑很简单，显示检查了 intervalSeconds 这个参数，是否符合预期，假如不是改为默认值，然后启动一个定时任务，这个任务会在 intervalSeconds 时间间隔里面调动 removeDataSources 方法，进行检查线程的存活情况，我们接下来看一下 removeDataSources 方法：

 public void removeDataSources() {
        if (nodesToDel == null || nodesToDel.isEmpty()) {
            return;
        }
        try {
            lock.lock();
            Map<String, DataSource> map = highAvailableDataSource.getDataSourceMap();
            Set<String> copySet = new HashSet<String>(nodesToDel);
            for (String nodeName : copySet) {
                LOG.info("Start removing Node " + nodeName + ".");
                if (!map.containsKey(nodeName)) {
                    LOG.info("Node " + nodeName + " is NOT existed in the map.");
                    cancelBlacklistNode(nodeName);
                    continue;
                }
                DataSource ds = map.get(nodeName);
                if (ds instanceof DruidDataSource) {
                    DruidDataSource dds = (DruidDataSource) ds;
                    int activeCount = dds.getActiveCount(); // CAUTION, activeCount MAYBE changed!
                    if (activeCount > 0) {
                        LOG.warn("Node " + nodeName + " is still running [activeCount=" + activeCount
                                + "], try next time.");
                        continue;
                    } else {
                        LOG.info("Close Node " + nodeName + " and remove it.");
                        try {
                            dds.close();
                        } catch (Exception e) {
                            LOG.error("Exception occurred while closing Node " + nodeName
                                    + ", just remove it.", e);
                        }
                    }
                }
                map.remove(nodeName); // Remove the node directly if it is NOT a DruidDataSource.
                cancelBlacklistNode(nodeName);
            }
        } catch (Exception e) {
            LOG.error("Exception occurred while removing DataSources.", e);
        } finally {
            lock.unlock();
        }
    }

我们可以看到，他主要的逻辑就是遍历 nodesToDel 列表，调用 DruidDataSource 的 getActiveCount 方法获取活动的连接数量，假如数量为 0 ，就调用其 close 方法。除了 poolUpdater 外我们还漏了个方法，就是 createNodeMap，我们接下来看一下这个方法：

  private void createNodeMap() {
        if (nodeListener == null) {
            // Compatiable with the old version.
            // Create a FileNodeListener to watch the dataSourceFile.
            FileNodeListener listener = new FileNodeListener();
            listener.setFile(dataSourceFile);
            listener.setPrefix(propertyPrefix);
            nodeListener = listener;
        }
        nodeListener.setObserver(poolUpdater);
        nodeListener.init();
        nodeListener.update(); // Do update in the current Thread at the startup
    }

这里主要是设置 HighAvailableDataSource 的 nodeListener ,我们先看一下默认的 Lisenter FileNodeListener ，其主要就是设置一下dataSourceFile , 然后是 setObserver 方法，我们可以看到，这是一个观察者模式， nodeListener 是一个被观察者，poolUpdater 是观察者，我们可以看一下 nodeListener 的 update 方法。

    public void update(List<NodeEvent> events) {
        if (events != null && !events.isEmpty()) {
            this.lastUpdateTime = new Date();
            NodeEvent[] arr = new NodeEvent[events.size()];
            for (int i = 0; i < events.size(); i++) {
                arr[i] = events.get(i);
            }
            this.setChanged();
            this.notifyObservers(arr);
        }
    }

我们着重看一下最后两行，其实就是通过调用 notifyObservers 方法会通知所有的观察者时间变话，并通过 events 传递给观察者，我们再看一下观察者的 update 方法：

 /**
     * Process the given NodeEvent[]. Maybe add / delete some nodes.
     */
    @Override
    public void update(Observable o, Object arg) {
        if (!(o instanceof NodeListener)) {
            return;
        }
        if (arg == null || !(arg instanceof NodeEvent[])) {
            return;
        }
        NodeEvent[] events = (NodeEvent[]) arg;

        if (events.length <= 0) {
            return;
        }

        try {
            LOG.info("Waiting for Lock to start processing NodeEvents.");
            lock.lock();
            LOG.info("Start processing the NodeEvent[" + events.length + "].");
            for (NodeEvent e : events) {
                if (e.getType() == NodeEventTypeEnum.ADD) {
                    addNode(e);
                } else if (e.getType() == NodeEventTypeEnum.DELETE) {
                    deleteNode(e);
                }
            }
        } catch (Exception e) {
            LOG.error("Exception occurred while updating Pool.", e);
        } finally {
            lock.unlock();
        }
    }

这里会拿到刚才传过来的 events ，然后解析这些 Event , 然后更新 HighAvailableDataSource 的 DataSourceMa 。 接下来我们看一下默认的 nodeListener 的实现， FileNodeListener , 我们先看一下他的 init 方法：

@Override
    public void init() {
        super.init();
        if (intervalSeconds <= 0) {
            intervalSeconds = 60;
        }
        executor = Executors.newScheduledThreadPool(1);
        executor.scheduleAtFixedRate(new Runnable() {
            @Override
            public void run() {
                LOG.debug("Checking file " + file + " every " + intervalSeconds + "s.");
                if (!lock.tryLock()) {
                    LOG.info("Can not acquire the lock, skip this time.");
                    return;
                }
                try {
                    update();
                } catch (Exception e) {
                    LOG.error("Can NOT update the node list.", e);
                } finally {
                    lock.unlock();
                }
            }
        }, intervalSeconds, intervalSeconds, TimeUnit.SECONDS);
    }

这里和 poolUpdater 比较接近，这里会启动一个定时任务，不断地调用update 方法，update 方法，会先调用 refresh 方法，生成 events ，然后再调用刚才的 update 方法，去通知观察者。我们先看一下 refresh 的逻辑：

@Override
    public List<NodeEvent> refresh() {
        Properties originalProperties = PropertiesUtils.loadProperties(file);
        List<String> nameList = PropertiesUtils.loadNameList(originalProperties, getPrefix());
        Properties properties = new Properties();
        for (String n : nameList) {
            String url = originalProperties.getProperty(n + ".url");
            String username = originalProperties.getProperty(n + ".username");
            String password = originalProperties.getProperty(n + ".password");
            if (url == null || url.isEmpty()) {
                LOG.warn(n + ".url is EMPTY! IGNORE!");
                continue;
            } else {
                properties.setProperty(n + ".url", url);
            }
            if (username == null || username.isEmpty()) {
                LOG.debug(n + ".username is EMPTY. Maybe you should check the config.");
            } else {
                properties.setProperty(n + ".username", username);
            }
            if (password == null || password.isEmpty()) {
                LOG.debug(n + ".password is EMPTY. Maybe you should check the config.");
            } else {
                properties.setProperty(n + ".password", password);
            }
        }

        List<NodeEvent> events = NodeEvent.getEventsByDiffProperties(getProperties(), properties);
        if (events != null && !events.isEmpty()) {
            LOG.info(events.size() + " different(s) detected.");
            setProperties(properties);
        }
        return events;
    }

这里先去获取所有收据有的nameList ，具体的获取逻辑如下，先解析所有初始化的Properties中，包含 url 的属性，然后截取前的名字，如下我们能获取到 aaa 和 bbb 这个 nameList 。

aaa.url=***
bbb.url=***

接下来是遍历所有的 nameList ，解析出所有 name 对应的配置信息，然后放到新的 properties 中，最后调用 NodeEvent.getEventsByDiffProperties 方法来生成 Events。类似我们也可以看一下 ZookeeperNodeListener ,我们先看一下他的 init 方法。

@Override
    public void init() {
        checkParameters();
        super.init();
        if (client == null) {
            client = CuratorFrameworkFactory.builder()
                    .canBeReadOnly(true)
                    .connectionTimeoutMs(5000)
                    .connectString(zkConnectString)
                    .retryPolicy(new RetryForever(10000))
                    .sessionTimeoutMs(30000)
                    .build();
            client.start();
            privateZkClient = true;
        }
        cache = new PathChildrenCache(client, path, true);
        cache.getListenable().addListener(new PathChildrenCacheListener() {
            @Override
            public void childEvent(CuratorFramework client, PathChildrenCacheEvent event) throws Exception {
                try {
                    LOG.info("Receive an event: " + event.getType());
                    lock.lock();
                    PathChildrenCacheEvent.Type eventType = event.getType();
                    switch (eventType) {
                        case CHILD_REMOVED:
                            updateSingleNode(event, NodeEventTypeEnum.DELETE);
                            break;
                        case CHILD_ADDED:
                            updateSingleNode(event, NodeEventTypeEnum.ADD);
                            break;
                        case CONNECTION_RECONNECTED:
                            refreshAllNodes();
                            break;
                        default:
                            // CHILD_UPDATED
                            // INITIALIZED
                            // CONNECTION_LOST
                            // CONNECTION_SUSPENDED
                            LOG.info("Received a PathChildrenCacheEvent, IGNORE it: " + event);
                    }
                } finally {
                    lock.unlock();
                    LOG.info("Finish the processing of event: " + event.getType());
                }
            }
        });
        try {
            // Use BUILD_INITIAL_CACHE to force build cache in the current Thread.
            // We don't use POST_INITIALIZED_EVENT, so there's no INITIALIZED event.
            cache.start(PathChildrenCache.StartMode.BUILD_INITIAL_CACHE);
        } catch (Exception e) {
            LOG.error("Can't start PathChildrenCache", e);
        }
    }

druid 是通过 curator 的包，对 zookeeper 的几点进行操作，首先他会注册监听节点的事件监听器，监听 CHILD_REMOVED,CHILD_ADDED,CONNECTION_RECONNECTED 这三个事件，当 CHILD_REMOVED 发生，会调用如下方法：

private void updateSingleNode(PathChildrenCacheEvent event, NodeEventTypeEnum type) {
        ChildData data = event.getData();
        String nodeName = getNodeName(data);
        List<String> names = new ArrayList<String>();
        names.add(getPrefix() + "." + nodeName);
        Properties properties = getPropertiesFromChildData(data);
        List<NodeEvent> events = NodeEvent.generateEvents(properties, names, type);

        if (events.isEmpty()) {
            return;
        }
        if (type == NodeEventTypeEnum.ADD) {
            getProperties().putAll(properties);
        } else {
            for (String n : properties.stringPropertyNames()) {
                getProperties().remove(n);
            }
        }
        super.update(events);
    }

这里传入会包括 type 和 PathChildrenCacheEvent， 接着我们根据 type 和 PathChildrenCacheEvent 生成 Druid 自己定义的 events , 最后通知所有的观察者。