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Disruptor-06 中有哪些等待策略 ,相信很多没有经验的人对此束手无策,为此本文总结了问题出现的原因和解决方法,通过这篇文章希望你能解决这个问题。
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//..... // Construct the Disruptor with a SingleProducerSequencer Disruptordisruptor = new Disruptor( factory, bufferSize, DaemonThreadFactory.INSTANCE, ProducerType.SINGLE, new BlockingWaitStrategy()); //.....
BlockingWaitStrategy
The default wait strategy used by the Disruptor is the BlockingWaitStrategy. Internally the BlockingWaitStrategy uses a typical lock and condition variable to handle thread wake-up. The BlockingWaitStrategy is the slowest of the available wait strategies, but is the most conservative with the respect to CPU usage and will give the most consistent behaviour across the widest variety of deployment options. However, again knowledge of the deployed system can allow for additional performance.
Like the BlockingWaitStrategy the SleepingWaitStrategy it attempts to be conservative with CPU usage, by using a simple busy wait loop, but uses a call to LockSupport.parkNanos(1)
in the middle of the loop. On a typical Linux system this will pause the thread for around 60µs. However it has the benefit that the producing thread does not need to take any action other increment the appropriate counter and does not require the cost of signalling a condition variable. However, the mean latency of moving the event between the producer and consumer threads will be higher. It works best in situations where low latency is not required, but a low impact on the producing thread is desired. A common use case is for asynchronous logging.
The YieldingWaitStrategy is one of 2 Wait Strategies that can be use in low latency systems, where there is the option to burn CPU cycles with the goal of improving latency. The YieldingWaitStrategy will busy spin waiting for the sequence to increment to the appropriate value. Inside the body of the loop Thread.yield()
will be called allowing other queued threads to run. This is the recommended wait strategy when need very high performance and the number of Event Handler threads is less than the total number of logical cores, e.g. you have hyper-threading enabled.
The BusySpinWaitStrategy is the highest performing Wait Strategy, but puts the highest constraints on the deployment environment. This wait strategy should only be used if the number of Event Handler threads is smaller than the number of physicalcores on the box. E.g. hyper-threading should be disabled.
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