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这篇文章将为大家详细讲解有关如何解析Hystrix核心原理和断路器源码,文章内容质量较高,因此小编分享给大家做个参考,希望大家阅读完这篇文章后对相关知识有一定的了解。
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构造一个HystrixCommand或HystrixObservableCommand对象
执行命令。
检查是否已命中缓存,如果命中直接返回。
检查断路器开关是否打开,如果打开,直接熔断,走fallback
逻辑。
检查线程池/队列/信号量是否已满,如果已满,直接拒绝请求,走fallback
逻辑。
上面条件都不满足,调用HystrixObservableCommand.construct()
方法HystrixCommand.run()
方法,执行业务逻辑。
判断运行业务逻辑方法是否出现异常或者超时,如果出现,直接降级,走fallback
逻辑。
上报统计数据,用户计算断路器状态。
返回结果
从流程图可以发现,只有出现
5
和7
两种情况时,才会上报错误统计数据。
断路器的开关控制逻辑如下:
在一个统计时间窗口内(HystrixCommandProperties.metricsRollingStatisticalWindowInMilliseconds()
),处理的请求数量达到设定的最小阈值(HystrixCommandProperties.circuitBreakerRequestVolumeThreshold()
),并且错误百分比超过设定的最大阈值(HystrixCommandProperties.circuitBreakerErrorThresholdPercentage()
),这时断路器开关就会打开,断路器状态从转换CLOSED
切换为OPEN
。
当断路器为打开状态时,它他会直接熔断所有请求(快速失败),走fallback
逻辑。
经过一个睡眠窗口时间后(HystrixCommandProperties.circuitBreakerSleepWindowInMilliseconds()
),Hystrix会放行一个请到后续服务,并将断路器开关切换为半开状态(HALF-OPEN
)。如果该请求失败,则断路器会将熔断开关切换为打开状态(OPEN
),继续熔断所有请求,直到下一个睡眠时间窗口的到来;如果该请求成功,则断路器会切换到关闭状态(CLOSED
),这时将允许所有请求通过,直到出现1
步骤的情况,断路器开关会切换为打开状态(OPEN
)。
Hystrix断路器的实现类是HystrixCircuitBreaker,源码如下:
/** * Circuit-breaker logic that is hooked into {@link HystrixCommand} execution and will stop allowing executions if failures have gone past the defined threshold. * 断路器,在HystrixCommand执行时会调用断路器逻辑,如果故障超过定义的阈值,断路器熔断开关将会打开,这时将阻止任务执行。 ** The default (and only) implementation will then allow a single retry after a defined sleepWindow until the execution * succeeds at which point it will again close the circuit and allow executions again. *
* 默认(且唯一)实现将允许在定义的sleepWindow之后进行单次重试,直到执行成功,此时它将再次关闭电路并允许再次执行。 */ public interface HystrixCircuitBreaker { /** * Every {@link HystrixCommand} requests asks this if it is allowed to proceed or not. It is idempotent and does * not modify any internal state, and takes into account the half-open logic which allows some requests through * after the circuit has been opened *
* 每个HystrixCommand请求都会询问是否允许继续(当断路器开关为OPEN和HALF_OPEN都时返回false,当断路器开关是CLOSE时或者到了下一个睡眠窗口时返回true)。 * 它是幂等的,不会修改任何内部状态,并考虑到半开逻辑,当一个睡眠窗口到来时他会放行一些请求到后续逻辑 * * @return boolean whether a request should be permitted (是否应允许请求) */ boolean allowRequest(); /** * Whether the circuit is currently open (tripped). * 判断熔断开关是否打开(如果是OPEN或HALF_OPEN时都返回true,如果为CLOSE时返回false,无副作用,是幂等方式)。 * * @return boolean state of circuit breaker(返回断路器的状态) */ boolean isOpen(); /** * Invoked on successful executions from {@link HystrixCommand} as part of feedback mechanism when in a half-open state. *
* 断路器在处于半开状态时,作为反馈机制的一部分,从HystrixCommand成功执行时调用。 */ void markSuccess(); /** * Invoked on unsuccessful executions from {@link HystrixCommand} as part of feedback mechanism when in a half-open state. * 断路器当处于半开状态时,作为反馈机制的一部分,从HystrixCommand执行不成功的调用。 */ void markNonSuccess(); /** * Invoked at start of command execution to attempt an execution. This is non-idempotent - it may modify internal * state. *
* 在命令执行开始时调用以尝试执行,主要所用时判断该请求是否可以执行。这是非幂等的 - 它可能会修改内部状态。 */ boolean attemptExecution(); }
断路器的默认实现就是它的一个内部类:
/** * @ExcludeFromJavadoc * @ThreadSafe */ class Factory { // String is HystrixCommandKey.name() (we can't use HystrixCommandKey directly as we can't guarantee it implements hashcode/equals correctly) // key是HystrixCommandKey.name()(我们不能直接使用HystrixCommandKey,因为我们无法保证它正确实现hashcode / equals) private static ConcurrentHashMapcircuitBreakersByCommand = new ConcurrentHashMap (); /** * 根据HystrixCommandKey获取HystrixCircuitBreaker * Get the {@link HystrixCircuitBreaker} instance for a given {@link HystrixCommandKey}. * * This is thread-safe and ensures only 1 {@link HystrixCircuitBreaker} per {@link HystrixCommandKey}. * * @param key {@link HystrixCommandKey} of {@link HystrixCommand} instance requesting the {@link HystrixCircuitBreaker} * @param group Pass-thru to {@link HystrixCircuitBreaker} * @param properties Pass-thru to {@link HystrixCircuitBreaker} * @param metrics Pass-thru to {@link HystrixCircuitBreaker} * @return {@link HystrixCircuitBreaker} for {@link HystrixCommandKey} */ public static HystrixCircuitBreaker getInstance(HystrixCommandKey key, HystrixCommandGroupKey group, HystrixCommandProperties properties, HystrixCommandMetrics metrics) { // this should find it for all but the first time // 根据HystrixCommandKey获取断路器 HystrixCircuitBreaker previouslyCached = circuitBreakersByCommand.get(key.name()); if (previouslyCached != null) { return previouslyCached; } // if we get here this is the first time so we need to initialize // Create and add to the map ... use putIfAbsent to atomically handle the possible race-condition of // 2 threads hitting this point at the same time and let ConcurrentHashMap provide us our thread-safety // If 2 threads hit here only one will get added and the other will get a non-null response instead. // 第一次没有获取到断路器,那么我们需要取初始化它 // 这里直接利用ConcurrentHashMap的putIfAbsent方法,它是原子操作,加入有两个线程执行到这里,将会只有一个线程将值放到容器中 // 让我们省掉了加锁的步骤 HystrixCircuitBreaker cbForCommand = circuitBreakersByCommand.putIfAbsent(key.name(), new HystrixCircuitBreakerImpl(key, group, properties, metrics)); if (cbForCommand == null) { // this means the putIfAbsent step just created a new one so let's retrieve and return it return circuitBreakersByCommand.get(key.name()); } else { // this means a race occurred and while attempting to 'put' another one got there before // and we instead retrieved it and will now return it return cbForCommand; } } /** * 根据HystrixCommandKey获取HystrixCircuitBreaker,如果没有返回NULL * Get the {@link HystrixCircuitBreaker} instance for a given {@link HystrixCommandKey} or null if none exists. * * @param key {@link HystrixCommandKey} of {@link HystrixCommand} instance requesting the {@link HystrixCircuitBreaker} * @return {@link HystrixCircuitBreaker} for {@link HystrixCommandKey} */ public static HystrixCircuitBreaker getInstance(HystrixCommandKey key) { return circuitBreakersByCommand.get(key.name()); } /** * Clears all circuit breakers. If new requests come in instances will be recreated. * 清除所有断路器。如果有新的请求将会重新创建断路器放到容器。 */ /* package */ static void reset() { circuitBreakersByCommand.clear(); } } /** * 默认的断路器实现 * The default production implementation of {@link HystrixCircuitBreaker}. * * @ExcludeFromJavadoc * @ThreadSafe */ /* package */class HystrixCircuitBreakerImpl implements HystrixCircuitBreaker { private final HystrixCommandProperties properties; private final HystrixCommandMetrics metrics; enum Status { // 断路器状态,关闭,打开,半开 CLOSED, OPEN, HALF_OPEN; } // 赋值操作不是线程安全的。若想不用锁来实现,可以用AtomicReference
这个类,实现对象引用的原子更新。 // AtomicReference 原子引用,保证Status原子性修改 private final AtomicReference status = new AtomicReference (Status.CLOSED); // 记录断路器打开的时间点(时间戳),如果这个时间大于0表示断路器处于打开状态或半开状态 private final AtomicLong circuitOpened = new AtomicLong(-1); private final AtomicReference activeSubscription = new AtomicReference (null); protected HystrixCircuitBreakerImpl(HystrixCommandKey key, HystrixCommandGroupKey commandGroup, final HystrixCommandProperties properties, HystrixCommandMetrics metrics) { this.properties = properties; this.metrics = metrics; //On a timer, this will set the circuit between OPEN/CLOSED as command executions occur // 在定时器上,当命令执行发生时,这将在OPEN / CLOSED之间设置电路 Subscription s = subscribeToStream(); activeSubscription.set(s); } private Subscription subscribeToStream() { /* * This stream will recalculate the OPEN/CLOSED status on every onNext from the health stream * 此流将重新计算运行状况流中每个onNext上的OPEN / CLOSED状态 */ return metrics.getHealthCountsStream() .observe() .subscribe(new Subscriber () { @Override public void onCompleted() { } @Override public void onError(Throwable e) { } @Override public void onNext(HealthCounts hc) { // check if we are past the statisticalWindowVolumeThreshold // 检查一个时间窗口内的最小请求数 if (hc.getTotalRequests() < properties.circuitBreakerRequestVolumeThreshold().get()) { // we are not past the minimum volume threshold for the stat window, // so no change to circuit status. // if it was CLOSED, it stays CLOSED // IF IT WAS HALF-OPEN, WE NEED TO WAIT FOR A SUCCESSFUL COMMAND EXECUTION // if it was open, we need to wait for sleep window to elapse // 我们没有超过统计窗口的最小音量阈值,所以我们不会去改变断路器状态,如果是closed状态,他将保持这个状态 // 如果是半开状态,那么她需要等到一个成功的 Command执行 // 如果是打开状态,那么它需要等到这个时间窗口过去 } else { // 检查错误比例阀值 if (hc.getErrorPercentage() < properties.circuitBreakerErrorThresholdPercentage().get()) { //we are not past the minimum error threshold for the stat window, // so no change to circuit status. // if it was CLOSED, it stays CLOSED // if it was half-open, we need to wait for a successful command execution // if it was open, we need to wait for sleep window to elapse } else { // our failure rate is too high, we need to set the state to OPEN // 我们的失败率太高,我们需要将状态设置为OPEN if (status.compareAndSet(Status.CLOSED, Status.OPEN)) { circuitOpened.set(System.currentTimeMillis()); } } } } }); } @Override public void markSuccess() { // 断路器是处理半开并且HystrixCommand执行成功,将状态设置成关闭 if (status.compareAndSet(Status.HALF_OPEN, Status.CLOSED)) { //This thread wins the race to close the circuit - it resets the stream to start it over from 0 //该线程赢得了关闭电路的竞争 - 它重置流以从0开始 metrics.resetStream(); Subscription previousSubscription = activeSubscription.get(); if (previousSubscription != null) { previousSubscription.unsubscribe(); } Subscription newSubscription = subscribeToStream(); activeSubscription.set(newSubscription); circuitOpened.set(-1L); } } @Override public void markNonSuccess() { // 断路器是处理半开并且HystrixCommand执行成功,将状态设置成打开 if (status.compareAndSet(Status.HALF_OPEN, Status.OPEN)) { //This thread wins the race to re-open the circuit - it resets the start time for the sleep window // 该线程赢得了重新打开电路的竞争 - 它重置了睡眠窗口的开始时间 circuitOpened.set(System.currentTimeMillis()); } } @Override public boolean isOpen() { // 获取配置判断断路器是否强制打开 if (properties.circuitBreakerForceOpen().get()) { return true; } // 获取配置判断断路器是否强制关闭 if (properties.circuitBreakerForceClosed().get()) { return false; } return circuitOpened.get() >= 0; } @Override public boolean allowRequest() { // 获取配置判断断路器是否强制打开 if (properties.circuitBreakerForceOpen().get()) { return false; } // 获取配置判断断路器是否强制关闭 if (properties.circuitBreakerForceClosed().get()) { return true; } if (circuitOpened.get() == -1) { return true; } else { // 如果是半开状态则返回不允许Command执行 if (status.get().equals(Status.HALF_OPEN)) { return false; } else { // 检查睡眠窗口是否过了 return isAfterSleepWindow(); } } } private boolean isAfterSleepWindow() { final long circuitOpenTime = circuitOpened.get(); final long currentTime = System.currentTimeMillis(); // 获取配置的一个睡眠的时间窗口 final long sleepWindowTime = properties.circuitBreakerSleepWindowInMilliseconds().get(); return currentTime > circuitOpenTime + sleepWindowTime; } @Override public boolean attemptExecution() { // 获取配置判断断路器是否强制打开 if (properties.circuitBreakerForceOpen().get()) { return false; } // 获取配置判断断路器是否强制关闭 if (properties.circuitBreakerForceClosed().get()) { return true; } if (circuitOpened.get() == -1) { return true; } else { if (isAfterSleepWindow()) { //only the first request after sleep window should execute //if the executing command succeeds, the status will transition to CLOSED //if the executing command fails, the status will transition to OPEN //if the executing command gets unsubscribed, the status will transition to OPEN // 只有一个睡眠窗口后的第一个请求会被执行 // 如果执行命令成功,状态将转换为CLOSED // 如果执行命令失败,状态将转换为OPEN // 如果执行命令取消订阅,状态将过渡到OPEN if (status.compareAndSet(Status.OPEN, Status.HALF_OPEN)) { return true; } else { return false; } } else { return false; } } } }
isOpen()
:判断熔断开关是否打开(该方法是否幂等和Hystrix版本相关)。
allowRequest()
:每个HystrixCommand请求都会询问是否允许继续执行(当断路器开关为OPEN
和HALF_OPEN
都时返回false,当断路器开关是CLOSE
或到了下一个睡眠窗口时返回true),它是幂等的,不会修改任何内部状态,并考虑到半开逻辑,当一个睡眠窗口到来时他会放行一些请求到后续逻辑。
attemptExecution()
:在命令执行开始时调用以尝试执行,主要所用时判断该请求是否可以执行。这是非幂等的,它可能会修改内部状态。
这里需要注意的是
allowRequest()
方法时幂等的,可以重复调用;attemptExecution()
方法是有副作用的,不可以重复调用;isOpen()
是否幂等和Hystrix版本有关。
关于如何解析Hystrix核心原理和断路器源码就分享到这里了,希望以上内容可以对大家有一定的帮助,可以学到更多知识。如果觉得文章不错,可以把它分享出去让更多的人看到。