Elasticsearch 6.3.2 启动过程
Elasticsearch 6.3.2 启动过程
前言
本文探究Elasticsearch 6.3.2的启动流程
环境准备
使用工具:IDEA,XMind
关于ES调试环境的搭建,可以参考前面的文章 《教你编译调试Elasticsearch 6.3.2源码》
然后通过设置断点,从 org.elasticsearch.bootstrap.ElasticSearch 的入口函数开始,一步一步调试
IDEA 2018.2 调试按钮
上图为使用 IDEA 2018.2 进行调试的一个截图,左上角84行出红点为一个断点,1、2、3编号的3个按钮是较为常用的按钮,作用如下:
- 按钮1:step over,执行到下一行,遇到方法不进入方法内部
- 按钮2:step into,执行到下一句代码,遇到方法则进入方法内部
- 按钮3:Run to cursor,执行到下一个断点处,后面没有断点则执行到结束
通过XMind记录ES启动流程的整个过程
ES 6.3.2 启动流程
根据上图,作者大概地把ES启动流程分为四个阶段:
- Elasticsearch 解析 Command,加载配置
- Bootstrap 初始化,资源检查
- Node 创建节点
- Bootstrap 启动节点和保活线程
Elasticsearch 解析 Command,加载配置
首先可以看一下入口方法 Elasticsearch.main:
public static void main(final String[] args) throws Exception {
System.setSecurityManager(new SecurityManager() {
@Override
public void checkPermission(Permission perm) {
// grant all permissions so that we can later set the security manager to the one that we want
}
});
LogConfigurator.registerErrorListener();
final Elasticsearch elasticsearch = new Elasticsearch();
int status = main(args, elasticsearch, Terminal.DEFAULT);
if (status != ExitCodes.OK) {
exit(status);
}
}1.1, 创建 SecurityManager 安全管理器
关于 SecurityManager: 安全管理器在Java语言中的作用就是检查操作是否有权限执行,通过则顺序进行,否则抛出一个异常 网上一篇文章:Java安全——安全管理器、访问控制器和类装载器
1.2, LogConfigurator.registerErrorListener() 注册侦听器
1.3, 创建Elasticsearch对象
Elasticsearch 入口类的继承关系如下:
Elasticsearch 入口类的继承关系
可以看到Elasticsearch继承了EnvironmentAwareCommand,Command,这几个类的功能简要介绍如下:
- Elasticsearch: This class starts elasticsearch.
- EnvironmentAwareCommand: A cli command which requires an
org.elasticsearch.env.Environmentto use current paths and settings - Command: An action to execute within a cli.
可以看出Elasticsearch的一个重要作用是解析命令参数
执行带 -h 参数的Elasticsearch启动命令
带参数的Elasticsearch启动命令
可以发现这几个参数与 Cammand 类 和 Elasticsearch 的几个私有变量是对应的
Elasticsearch的构造函数如下:
Elasticsearch() {
super("starts elasticsearch", () -> {}); // we configure logging later so we override the base class from configuring logging
versionOption = parser.acceptsAll(Arrays.asList("V", "version"), "Prints elasticsearch version information and exits");
daemonizeOption = parser.acceptsAll(Arrays.asList("d", "daemonize"), "Starts Elasticsearch in the background")
.availableUnless(versionOption);
pidfileOption = parser.acceptsAll(Arrays.asList("p", "pidfile"), "Creates a pid file in the specified path on start")
.availableUnless(versionOption).withRequiredArg().withValuesConvertedBy(new PathConverter());
quietOption = parser.acceptsAll(Arrays.asList("q", "quiet"), "Turns off standard output/error streams logging in console")
.availableUnless(versionOption).availableUnless(daemonizeOption);
}1.4, 接着进入 Command.main 方法
该方法给当前Runtime类添加一个hook线程,该线程作用是:当Runtime异常关闭时打印异常信息
1.5, Command.mainWithoutErrorHandling 方法,根据命令行参数,打印或者设置参数,然后执行命令,有异常则抛出所有异常
1.6, EnvironmentAwareCommand.execute,确保 es.path.data, es.path.home, es.path.logs 等参数已设置,否则从 System.properties 中读取
putSystemPropertyIfSettingIsMissing(settings, "path.data", "es.path.data");
putSystemPropertyIfSettingIsMissing(settings, "path.home", "es.path.home");
putSystemPropertyIfSettingIsMissing(settings, "path.logs", "es.path.logs");
execute(terminal, options, createEnv(terminal, settings));1.7, EnvironmentAwareCommand.createEnv,读取config下的配置文件elasticsearch.yml内容,收集plugins,bin,lib,modules等目录下的文件信息
createEnv最后返回一个 Environment 对象,执行结果如下
EnvironmentAwareCommand.createEnv
1.8, Elasticsearch.execute ,读取daemonize, pidFile,quiet 的值,并 确保配置的临时目录(temp)是有效目录
进入Bootstrap初始化阶段
Bootstrap.init(!daemonize, pidFile, quiet, initialEnv);Bootstrap初始化阶段
Bootstrap.init
2.1, 进入 Bootstrap.init, This method is invoked by Elasticsearch#main(String[]) to startup elasticsearch.
INSTANCE = new Bootstrap();, 创建一个Bootstrap对象作为类对象,该类构造函数会创建一个用户线程,添加到Runtime Hook中,进行 countDown 操作
private final CountDownLatch keepAliveLatch = new CountDownLatch(1);
/** creates a new instance */
Bootstrap() {
keepAliveThread = new Thread(new Runnable() {
@Override
public void run() {
try {
keepAliveLatch.await();
} catch (InterruptedException e) {
}
}
}, "elasticsearch[keepAlive/" + Version.CURRENT + "]");
keepAliveThread.setDaemon(false);
// keep this thread alive (non daemon thread) until we shutdown
Runtime.getRuntime().addShutdownHook(new Thread() {
@Override
public void run() {
keepAliveLatch.countDown();
}
});
}CountDownLatch是一个同步工具类,它允许一个或多个线程一直等待,直到其他线程执行完后再执行。例如,应用程序的主线程希望在负责启动框架服务的线程已经启动所有框架服务之后执行。 CountDownLatch是通过一个计数器来实现的,计数器的初始化值为线程的数量。每当一个线程完成了自己的任务后,计数器的值就相应得减1。当计数器到达0时,表示所有的线程都已完成任务,然后在闭锁上等待的线程就可以恢复执行任务。 更多介绍请看文章:并发工具类 CountDownLatch
2.2, 加载 keystore 安全配置,keystore文件不存在则创建,保存;存在则解密,更新keystore
2.3, 根据已有的配置信息,创建一个Environment对象
2.4, LogConfigurator log4j日志配置
2.5, 检查pid文件是否存在,不存在则创建
关于 pid 文件: (1) pid文件的内容:pid文件为文本文件,内容只有一行,记录了该进程的ID,用cat命令可以看到。 (2) pid文件的作用:防止进程启动多个副本。只有获得pid文件(固定路径固定文件名)写入权限(F_WRLCK)的进程才能正常启动并把自身的PID写入该文件中,其它同一个程序的多余进程则自动退出。
2.6, 检查Lucene版本与实际的Lucene Jar文件的版本是否一致,不一致则抛异常
2.7, 设置未捕获异常的处理 Thread.setDefaultUncaughtExceptionHandler
在Thread ApI中提供了UncaughtExceptionHandle,它能检测出某个由于未捕获的异常而终结的情况
朱小厮 JAVA多线程之UncaughtExceptionHandler——处理非正常的线程中止
INSTANCE.setup(true, environment);
3.1,spawner.spawnNativeControllers(environment);
遍历每个模块,生成本机控制类(native Controller):读取modules文件夹下所有的文件夹中的模块信息,保存为一个 PluginInfo 对象,为合适的模块生成控制类,通过 Files.isRegularFile(spawnPath) 来判断
尝试为给定模块生成控制器(native Controller)守护程序。 生成的进程将通过其stdin,stdout和stderr流保持与此JVM的连接,但对此包之外的代码不能使用对这些流的引用。
3.2, initializeNatives(Path tmpFile, boolean mlockAll, boolean systemCallFilter, boolean ctrlHandler)初始化本地资源
检查用户是否为root用户,是则抛异常; 尝试启用 系统调用过滤器 system call filter; 如果设置了则进行 mlockall Windows关闭事件监听器 init lucene random seed.
这个过程中使用到了 Natives 类: Natives类是一个包装类,用于检查调用本机方法所需的类是否在启动时可用。如果它们不可用,则此类将避免调用加载这些类的代码
3.3, 添加一个Hook: Runtime.getRuntime().addShutdownHook,当ES退出时用于关闭必要的IO流,日志器上下文和配置器等
3.4, 使用 JarHell 检查重复的 jar 文件
3.5, 初始化 SecurityManager
// install SM after natives, shutdown hooks, etc.
Security.configure(environment, BootstrapSettings.SECURITY_FILTER_BAD_DEFAULTS_SETTING.get(settings));创建 node 节点
node = new Node(environment) {
@Override
protected void validateNodeBeforeAcceptingRequests(
final BootstrapContext context,
final BoundTransportAddress boundTransportAddress, List<BootstrapCheck> checks) throws NodeValidationException {
BootstrapChecks.check(context, boundTransportAddress, checks);
}
};4.1, 这里直接贴一下代码(前半部分)(限于篇幅,完整文章请点击阅读原文)
这里进行的主要操作有:
- 生命周期Lifecycle设置为 初始化状态 INITIALIZED
- 创建一个 NodeEnvironment 对象保存节点环境信息,如各种数据文件的路径
- 读取JVM信息
- 创建 PluginsService 对象,创建过程中会读取并加载所有的模块和插件
- 创建一个最终的 Environment 对象
- 创建线程池 ThreadPool 后面各类对象基本都是通过线程来提供服务,这个线程池可以管理各类线程
- 创建 节点客户端 NodeClient
这里重点介绍 PluginsService 和 ThreadPool 这两个类
PluginsService
在构造该类对象是传入的参数如下:
PluginsService 构造方法的参数
在构造方法中加载所有的模块
Set<Bundle> seenBundles = new LinkedHashSet<>();
List<PluginInfo> modulesList = new ArrayList<>();
Set<Bundle> modules = getModuleBundles(modulesDirectory);
for (Bundle bundle : modules) {
modulesList.add(bundle.plugin);
}
seenBundles.addAll(modules);
/** Get bundles for plugins installed in the given modules directory. */
static Set<Bundle> getModuleBundles(Path modulesDirectory) throws IOException {
return findBundles(modulesDirectory, "module").stream().flatMap(b -> b.bundles().stream()).collect(Collectors.toSet());
}其中的 Bundle是一个内部类(a "bundle" is a group of plugins in a single classloader) 而 PluginInfo 则是 An in-memory representation of the plugin descriptor. 存在内存中的用来描述一个 plugin 的类
插件加载的实际代码如下:
/**
* Reads the plugin descriptor file.
*
* @param path the path to the root directory for the plugin
* @return the plugin info
* @throws IOException if an I/O exception occurred reading the plugin descriptor
*/
public static PluginInfo readFromProperties(final Path path) throws IOException {
final Path descriptor = path.resolve(ES_PLUGIN_PROPERTIES);
final Map<String, String> propsMap;
{
final Properties props = new Properties();
try (InputStream stream = Files.newInputStream(descriptor)) {
props.load(stream);
}
propsMap = props.stringPropertyNames().stream().collect(Collectors.toMap(Function.identity(), props::getProperty));
}
final String name = propsMap.remove("name");
if (name == null || name.isEmpty()) {
throw new IllegalArgumentException(
"property [name] is missing in [" + descriptor + "]");
}
final String description = propsMap.remove("description");
if (description == null) {
throw new IllegalArgumentException(
"property [description] is missing for plugin [" + name + "]");
}
final String version = propsMap.remove("version");
if (version == null) {
throw new IllegalArgumentException(
"property [version] is missing for plugin [" + name + "]");
}
final String esVersionString = propsMap.remove("elasticsearch.version");
if (esVersionString == null) {
throw new IllegalArgumentException(
"property [elasticsearch.version] is missing for plugin [" + name + "]");
}
final Version esVersion = Version.fromString(esVersionString);
final String javaVersionString = propsMap.remove("java.version");
if (javaVersionString == null) {
throw new IllegalArgumentException(
"property [java.version] is missing for plugin [" + name + "]");
}
JarHell.checkVersionFormat(javaVersionString);
final String classname = propsMap.remove("classname");
if (classname == null) {
throw new IllegalArgumentException(
"property [classname] is missing for plugin [" + name + "]");
}
final String extendedString = propsMap.remove("extended.plugins");
final List<String> extendedPlugins;
if (extendedString == null) {
extendedPlugins = Collections.emptyList();
} else {
extendedPlugins = Arrays.asList(Strings.delimitedListToStringArray(extendedString, ","));
}
final String hasNativeControllerValue = propsMap.remove("has.native.controller");
final boolean hasNativeController;
if (hasNativeControllerValue == null) {
hasNativeController = false;
} else {
switch (hasNativeControllerValue) {
case "true":
hasNativeController = true;
break;
case "false":
hasNativeController = false;
break;
default:
final String message = String.format(
Locale.ROOT,
"property [%s] must be [%s], [%s], or unspecified but was [%s]",
"has_native_controller",
"true",
"false",
hasNativeControllerValue);
throw new IllegalArgumentException(message);
}
}
if (esVersion.before(Version.V_6_3_0) && esVersion.onOrAfter(Version.V_6_0_0_beta2)) {
propsMap.remove("requires.keystore");
}
if (propsMap.isEmpty() == false) {
throw new IllegalArgumentException("Unknown properties in plugin descriptor: " + propsMap.keySet());
}
return new PluginInfo(name, description, version, esVersion, javaVersionString,
classname, extendedPlugins, hasNativeController);
}其中的两个常量的值
public static final String ES_PLUGIN_PROPERTIES = "plugin-descriptor.properties";
public static final String ES_PLUGIN_POLICY = "plugin-security.policy";从以上代码可以看出模块的加载过程:
- 读取模块的配置文件
plugin-descriptor.properties,解析出内容并存储到 Map 中 - 分别校验
name,description,version,elasticsearch.version,java.version,classname,extended.plugins,has.native.controller,requires.keystore这些配置项,缺失或者不按要求则抛出异常 - 根据配置项构造一个 PluginInfo 对象返回
举例:读取出的 aggs-matrix-stats 模块的配置项信息如下
读取插件配置文件并解析文件内容
加载插件与加载模块调用的是相同的方法
ThreadPool 线程池
线程池的构造方法如下:
public ThreadPool(final Settings settings, final ExecutorBuilder<?>... customBuilders) {
super(settings);
assert Node.NODE_NAME_SETTING.exists(settings);
final Map<String, ExecutorBuilder> builders = new HashMap<>();
final int availableProcessors = EsExecutors.numberOfProcessors(settings);
final int halfProcMaxAt5 = halfNumberOfProcessorsMaxFive(availableProcessors);
final int halfProcMaxAt10 = halfNumberOfProcessorsMaxTen(availableProcessors);
final int genericThreadPoolMax = boundedBy(4 * availableProcessors, 128, 512);
builders.put(Names.GENERIC, new ScalingExecutorBuilder(Names.GENERIC, 4, genericThreadPoolMax, TimeValue.timeValueSeconds(30)));
builders.put(Names.INDEX, new FixedExecutorBuilder(settings, Names.INDEX, availableProcessors, 200, true));
builders.put(Names.WRITE, new FixedExecutorBuilder(settings, Names.WRITE, "bulk", availableProcessors, 200));
builders.put(Names.GET, new FixedExecutorBuilder(settings, Names.GET, availableProcessors, 1000));
builders.put(Names.ANALYZE, new FixedExecutorBuilder(settings, Names.ANALYZE, 1, 16));
builders.put(Names.SEARCH, new AutoQueueAdjustingExecutorBuilder(settings,
Names.SEARCH, searchThreadPoolSize(availableProcessors), 1000, 1000, 1000, 2000));
builders.put(Names.MANAGEMENT, new ScalingExecutorBuilder(Names.MANAGEMENT, 1, 5, TimeValue.timeValueMinutes(5)));
// no queue as this means clients will need to handle rejections on listener queue even if the operation succeeded
// the assumption here is that the listeners should be very lightweight on the listeners side
builders.put(Names.LISTENER, new FixedExecutorBuilder(settings, Names.LISTENER, halfProcMaxAt10, -1));
builders.put(Names.FLUSH, new ScalingExecutorBuilder(Names.FLUSH, 1, halfProcMaxAt5, TimeValue.timeValueMinutes(5)));
builders.put(Names.REFRESH, new ScalingExecutorBuilder(Names.REFRESH, 1, halfProcMaxAt10, TimeValue.timeValueMinutes(5)));
builders.put(Names.WARMER, new ScalingExecutorBuilder(Names.WARMER, 1, halfProcMaxAt5, TimeValue.timeValueMinutes(5)));
builders.put(Names.SNAPSHOT, new ScalingExecutorBuilder(Names.SNAPSHOT, 1, halfProcMaxAt5, TimeValue.timeValueMinutes(5)));
builders.put(Names.FETCH_SHARD_STARTED, new ScalingExecutorBuilder(Names.FETCH_SHARD_STARTED, 1, 2 * availableProcessors, TimeValue.timeValueMinutes(5)));
builders.put(Names.FORCE_MERGE, new FixedExecutorBuilder(settings, Names.FORCE_MERGE, 1, -1));
builders.put(Names.FETCH_SHARD_STORE, new ScalingExecutorBuilder(Names.FETCH_SHARD_STORE, 1, 2 * availableProcessors, TimeValue.timeValueMinutes(5)));
for (final ExecutorBuilder<?> builder : customBuilders) {
if (builders.containsKey(builder.name())) {
throw new IllegalArgumentException("builder with name [" + builder.name() + "] already exists");
}
builders.put(builder.name(), builder);
}
this.builders = Collections.unmodifiableMap(builders);
threadContext = new ThreadContext(settings);
final Map<String, ExecutorHolder> executors = new HashMap<>();
for (@SuppressWarnings("unchecked") final Map.Entry<String, ExecutorBuilder> entry : builders.entrySet()) {
final ExecutorBuilder.ExecutorSettings executorSettings = entry.getValue().getSettings(settings);
final ExecutorHolder executorHolder = entry.getValue().build(executorSettings, threadContext);
if (executors.containsKey(executorHolder.info.getName())) {
throw new IllegalStateException("duplicate executors with name [" + executorHolder.info.getName() + "] registered");
}
logger.debug("created thread pool: {}", entry.getValue().formatInfo(executorHolder.info));
executors.put(entry.getKey(), executorHolder);
}
executors.put(Names.SAME, new ExecutorHolder(DIRECT_EXECUTOR, new Info(Names.SAME, ThreadPoolType.DIRECT)));
this.executors = unmodifiableMap(executors);
this.scheduler = Scheduler.initScheduler(settings);
TimeValue estimatedTimeInterval = ESTIMATED_TIME_INTERVAL_SETTING.get(settings);
this.cachedTimeThread = new CachedTimeThread(EsExecutors.threadName(settings, "[timer]"), estimatedTimeInterval.millis());
this.cachedTimeThread.start();
}参考着文档来理解这里的代码:Elasticsearch Reference [6.4] » Modules » Thread Pool 和 apachecn 线程池
线程池类型 ThreadPoolType
fixed(固定):fixed线程池拥有固定数量的线程来处理请求,在没有空闲线程时请求将被挂在队列中。queue_size参数可以控制在没有空闲线程时,能排队挂起的请求数
fixed_auto_queue_size:此类型为实验性的,将被更改或删除,不关注
scaling(弹性):scaling线程池拥有的线程数量是动态的,这个数字介于core和max参数的配置之间变化。keep_alive参数用来控制线程在线程池中空闲的最长时间
direct:此类线程是一种不支持关闭的线程,就意味着一旦使用,则会一直存活下去.
一些重要的线程池
generic:用于通用的请求(例如:后台节点发现),线程池类型为 scaling。
index:用于index/delete请求,线程池类型为 fixed, 大小的为处理器数量,队列大小为200,最大线程数为 1 + 处理器数量。
search:用于count/search/suggest请求。线程池类型为 fixed, 大小的为 int((处理器数量 3) / 2) +1,队列大小为1000。*
get:用于get请求。线程池类型为 fixed,大小的为处理器数量,队列大小为1000。
analyze:用于analyze请求。线程池类型为 fixed,大小的1,队列大小为16
write:用于单个文档的 index/delete/update 请求以及 bulk 请求,线程池类型为 fixed,大小的为处理器数量,队列大小为200,最大线程数为 1 + 处理器数量。
snapshot:用于snaphost/restore请求。线程池类型为 scaling,线程保持存活时间为5分钟,最大线程数为min(5, (处理器数量)/2)。
warmer:用于segment warm-up请求。线程池类型为 scaling,线程保持存活时间为5分钟,最大线程数为min(5, (处理器数量)/2)。
refresh:用于refresh请求。线程池类型为 scaling,线程空闲保持存活时间为5分钟,最大线程数为min(10, (处理器数量)/2)。
listener:主要用于Java客户端线程监听器被设置为true时执行动作。线程池类型为 scaling,最大线程数为min(10, (处理器数量)/2)。
ThreadPool 类中除了以上线程队列,还可以看到有 CachedTimeThread(缓存系统时间)、ExecutorService(在当前线程上执行提交的任务)、ThreadContext(线程上下文)、ScheduledThreadPoolExecutor(Java任务调度)等
参考文章:Java并发编程14-ScheduledThreadPoolExecutor详解 Java线程池原理分析ScheduledThreadPoolExecutor篇 关于 ScheduledThreadPoolExecutor 更多的细节应该看书或者官方文档
关于线程
了解了线程池,继续深究ES线程是什么样子的
在 ScalingExecutorBuilder.build 中可以发现 ExecutorService 对象是由 EsExecutors.newScaling 创建的
public static EsThreadPoolExecutor newScaling(String name, int min, int max, long keepAliveTime, TimeUnit unit, ThreadFactory threadFactory, ThreadContext contextHolder) {
ExecutorScalingQueue<Runnable> queue = new ExecutorScalingQueue<>();
EsThreadPoolExecutor executor = new EsThreadPoolExecutor(name, min, max, keepAliveTime, unit, queue, threadFactory, new ForceQueuePolicy(), contextHolder);
queue.executor = executor;
return executor;
}再看看 EsThreadPoolExecutor 这个类的继承关系,其是扩展自Java的线程池 ThreadPoolExecutor
EsThreadPoolExecutor的继承链
EsThreadPoolExecutor(String name, int corePoolSize, int maximumPoolSize, long keepAliveTime, TimeUnit unit,
BlockingQueue<Runnable> workQueue, ThreadFactory threadFactory, XRejectedExecutionHandler handler,
ThreadContext contextHolder) {
super(corePoolSize, maximumPoolSize, keepAliveTime, unit, workQueue, threadFactory, handler);
this.name = name;
this.contextHolder = contextHolder;
}回到 Node 节点的创建
4.2, 创建各种服务类对象 ResourceWatcherService、NetworkService、ClusterService、IngestService、ClusterInfoService、UsageService、MonitorService、CircuitBreakerService、MetaStateService、IndicesService、MetaDataIndexUpgradeService、TemplateUpgradeService、TransportService、ResponseCollectorService、SearchTransportService、NodeService、SearchService、PersistentTasksClusterService
这些服务类是的功能可以根据名称做一个大概的判断,具体还需要看文档和源码,限于篇幅,在此不做探究
4.3, ModulesBuilder类加入各种模块 ScriptModule、AnalysisModule、SettingsModule、pluginModule、ClusterModule、IndicesModule、SearchModule、GatewayModule、RepositoriesModule、ActionModule、NetworkModule、DiscoveryModule
4.4, guice 绑定依赖以及依赖注入
关于 guice 可以参考之前的文章: Google Guice 快速入门 Elasticsearch 中的 Guice
elasticsearch里面的组件基本都进行进行了模块化管理,elasticsearch对guice进行了封装,通过ModulesBuilder类构建es的模块(一般包括的模块在 4.3 中列举了)
// 依赖绑定
modules.add(b -> {
b.bind(Node.class).toInstance(this);
b.bind(NodeService.class).toInstance(nodeService);
b.bind(NamedXContentRegistry.class).toInstance(xContentRegistry);
b.bind(PluginsService.class).toInstance(pluginsService);
b.bind(Client.class).toInstance(client);
b.bind(NodeClient.class).toInstance(client);
b.bind(Environment.class).toInstance(this.environment);
b.bind(ThreadPool.class).toInstance(threadPool);
b.bind(NodeEnvironment.class).toInstance(nodeEnvironment);
b.bind(ResourceWatcherService.class).toInstance(resourceWatcherService);
b.bind(CircuitBreakerService.class).toInstance(circuitBreakerService);
b.bind(BigArrays.class).toInstance(bigArrays);
b.bind(ScriptService.class).toInstance(scriptModule.getScriptService());
b.bind(AnalysisRegistry.class).toInstance(analysisModule.getAnalysisRegistry());
b.bind(IngestService.class).toInstance(ingestService);
b.bind(UsageService.class).toInstance(usageService);
b.bind(NamedWriteableRegistry.class).toInstance(namedWriteableRegistry);
b.bind(MetaDataUpgrader.class).toInstance(metaDataUpgrader);
b.bind(MetaStateService.class).toInstance(metaStateService);
b.bind(IndicesService.class).toInstance(indicesService);
b.bind(SearchService.class).toInstance(searchService);
b.bind(SearchTransportService.class).toInstance(searchTransportService);
b.bind(SearchPhaseController.class).toInstance(new SearchPhaseController(settings,
searchService::createReduceContext));
b.bind(Transport.class).toInstance(transport);
b.bind(TransportService.class).toInstance(transportService);
b.bind(NetworkService.class).toInstance(networkService);
b.bind(UpdateHelper.class).toInstance(new UpdateHelper(settings, scriptModule.getScriptService()));
b.bind(MetaDataIndexUpgradeService.class).toInstance(metaDataIndexUpgradeService);
b.bind(ClusterInfoService.class).toInstance(clusterInfoService);
b.bind(GatewayMetaState.class).toInstance(gatewayMetaState);
b.bind(Discovery.class).toInstance(discoveryModule.getDiscovery());
{
RecoverySettings recoverySettings = new RecoverySettings(settings, settingsModule.getClusterSettings());
processRecoverySettings(settingsModule.getClusterSettings(), recoverySettings);
b.bind(PeerRecoverySourceService.class).toInstance(new PeerRecoverySourceService(settings, transportService,
indicesService, recoverySettings));
b.bind(PeerRecoveryTargetService.class).toInstance(new PeerRecoveryTargetService(settings, threadPool,
transportService, recoverySettings, clusterService));
}
httpBind.accept(b);
pluginComponents.stream().forEach(p -> b.bind((Class) p.getClass()).toInstance(p));
b.bind(PersistentTasksService.class).toInstance(persistentTasksService);
b.bind(PersistentTasksClusterService.class).toInstance(persistentTasksClusterService);
b.bind(PersistentTasksExecutorRegistry.class).toInstance(registry);
}
);
injector = modules.createInjector();Bootstrap 启动
5.1, 通过 injector 获取各个类的对象,调用 start() 方法启动(实际进入各个类的中 doStart 方法): LifecycleComponent、IndicesService、IndicesClusterStateService、SnapshotsService、SnapshotShardsService、RoutingService、SearchService、MonitorService、NodeConnectionsService、ResourceWatcherService、GatewayService、Discovery、TransportService
这里简要介绍一下各个服务类的职能:
IndicesService:索引管理 IndicesClusterStateService:跨集群同步 SnapshotsService:负责创建快照 SnapshotShardsService:此服务在数据和主节点上运行,并控制这些节点上当前快照的分片。 它负责启动和停止分片级别快照 RoutingService:侦听集群状态,当它收到ClusterChangedEvent(集群改变事件)将验证集群状态,路由表可能会更新 SearchService:搜索服务 MonitorService:监控 NodeConnectionsService:此组件负责在节点添加到群集状态后连接到节点,并在删除它们时断开连接。 此外,它会定期检查所有连接是否仍处于打开状态,并在需要时还原它们。 请注意,如果节点断开/不响应ping,则此组件不负责从群集中删除节点。 这是由NodesFaultDetection完成的。 主故障检测由链接MasterFaultDetection完成。 ResourceWatcherService:通用资源观察器服务 GatewayService:网关
如果该节点是主节点或数据节点,还需要进行相关的职能操作
5.2, 集群发现与监控等,启动 HttpServerTransport, 绑定服务端口
5.3, 启动保活线程 keepAliveThread.start 进行心跳检测
小结
过程很漫长,后面很多类的功能未了解,之后补上