| //// |
| Licensed to the Apache Software Foundation (ASF) under one or more |
| contributor license agreements. See the NOTICE file distributed with |
| this work for additional information regarding copyright ownership. |
| The ASF licenses this file to You under the Apache License, Version 2.0 |
| (the "License"); you may not use this file except in compliance with |
| the License. You may obtain a copy of the License at |
| |
| http://www.apache.org/licenses/LICENSE-2.0 |
| |
| Unless required by applicable law or agreed to in writing, software |
| distributed under the License is distributed on an "AS IS" BASIS, |
| WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. |
| See the License for the specific language governing permissions and |
| limitations under the License. |
| //// |
| = Lock-free Asynchronous Loggers for Low-Latency Logging |
| Remko Popma <rpopma@apache.org> |
| |
| Asynchronous logging can improve your application's performance by |
| executing the I/O operations in a separate thread. Log4j 2 makes a |
| number of improvements in this area. |
| |
| * *Asynchronous Loggers* are a new addition in Log4j 2. Their aim is to |
| return from the call to Logger.log to the application as soon as |
| possible. You can choose between making all Loggers asynchronous or |
| using a mixture of synchronous and asynchronous Loggers. Making all |
| Loggers asynchronous will give the best performance, while mixing gives |
| you more flexibility. |
| * *LMAX Disruptor technology*. Asynchronous Loggers internally use the |
| link:#UnderTheHood[Disruptor], a lock-free inter-thread communication |
| library, instead of queues, resulting in higher throughput and lower |
| latency. |
| * As part of the work for Async Loggers, *Asynchronous Appenders* have |
| been enhanced to flush to disk at the end of a batch (when the queue is |
| empty). This produces the same result as configuring |
| "immediateFlush=true", that is, all received log events are always |
| available on disk, but is more efficient because it does not need to |
| touch the disk on each and every log event. (Async Appenders use |
| ArrayBlockingQueue internally and do not need the disruptor jar on the |
| classpath.) |
| |
| [#Trade-offs] |
| == Trade-offs |
| |
| Although asynchronous logging can give significant performance benefits, |
| there are situations where you may want to choose synchronous logging. |
| This section describes some of the trade-offs of asynchronous logging. |
| |
| === Benefits |
| |
| * Higher peak link:#Performance[throughput]. With an asynchronous logger |
| your application can log messages at 6 - 68 times the rate of a |
| synchronous logger. |
| + |
| This is especially interesting for applications that occasionally need |
| to log bursts of messages. Async logging can help prevent or dampen |
| latency spikes by shortening the wait time until the next message can be |
| logged. If the queue size is configured large enough to handle the |
| burst, asynchronous logging will help prevent your application from |
| falling behind (as much) during a sudden increase of activity. |
| * Lower logging response time link:#Latency[latency]. Response time |
| latency is the time it takes for a call to Logger.log to return under a |
| given workload. Asynchronous Loggers have consistently lower latency |
| than synchronous loggers or even queue-based asynchronous appenders. |
| |
| === Drawbacks |
| |
| * Error handling. If a problem happens during the logging process and an |
| exception is thrown, it is less easy for an asynchronous logger or |
| appender to signal this problem to the application. This can partly be |
| alleviated by configuring an `ExceptionHandler`, but this may still not |
| cover all cases. For this reason, if logging is part of your business |
| logic, for example if you are using Log4j as an audit logging framework, |
| we would recommend to synchronously log those audit messages. (Note that |
| you can still link:#MixedSync-Async[combine] them and use asynchronous |
| logging for debug/trace logging in addition to synchronous logging for |
| the audit trail.) |
| * In some rare cases, care must be taken with mutable messages. Most of |
| the time you don't need to worry about this. Log4 will ensure that log |
| messages like `logger.debug("My object is {}", myObject)` will use the |
| state of the `myObject` parameter at the time of the call to |
| `logger.debug()`. The log message will not change even if `myObject` is |
| modified later. It is safe to asynchronously log mutable objects because |
| most |
| link:../javadoc/log4j-api/org/apache/logging/log4j/message/Message.html[`Message`] |
| implementations built-in to Log4j take a snapshot of the parameters. |
| There are some exceptions however: |
| link:../javadoc/log4j-api/org/apache/logging/log4j/message/MapMessage.html[`MapMessage`] |
| and |
| link:../javadoc/log4j-api/org/apache/logging/log4j/message/StructuredDataMessage.html[`StructuredDataMessage`] |
| are mutable by design: fields can be added to these messages after the |
| message object was created. These messages should not be modified after |
| they are logged with asynchronous loggers or asynchronous appenders; you |
| may or may not see the modifications in the resulting log output. |
| Similarly, custom |
| link:../javadoc/log4j-api/org/apache/logging/log4j/message/Message.html[`Message`] |
| implementations should be designed with asynchronous use in mind, and |
| either take a snapshot of their parameters at construction time, or |
| document their thread-safety characteristics. |
| * If your application is running in an environment where CPU resources |
| are scarce, like a machine with one CPU with a single core, starting |
| another thread is not likely to give better performance. |
| * If the _sustained rate_ at which your application is logging messages |
| is faster than the maximum sustained throughput of the underlying |
| appender, the queue will fill up and the application will end up logging |
| at the speed of the slowest appender. If this happens, consider |
| selecting a xref:manual/performance.adoc#whichAppender[faster appender], or |
| logging less. If neither of these is an option, you may get better |
| throughput and fewer latency spikes by logging synchronously. |
| |
| [#AllAsync] |
| == Making All Loggers Asynchronous |
| |
| NOTE: _Log4j-2.9 and higher require disruptor-3.3.4.jar or higher on the |
| classpath. Prior to Log4j-2.9, disruptor-3.0.0.jar or higher was |
| required._ |
| |
| This is simplest to configure and gives the best performance. To make |
| all loggers asynchronous, add the disruptor jar to the classpath and set |
| the system property `log4j2.contextSelector` to |
| `org.apache.logging.log4j.core.async.AsyncLoggerContextSelector` or |
| `org.apache.logging.log4j.core.async.BasicAsyncLoggerContextSelector`. |
| |
| By default, link:#Location[location] is not passed to the I/O thread by |
| asynchronous loggers. If one of your layouts or custom filters needs |
| location information, you need to set "includeLocation=true" in the |
| configuration of all relevant loggers, including the root logger. |
| |
| A configuration that does not require location might look like: |
| |
| [source,xml] |
| ---- |
| <?xml version="1.0" encoding="UTF-8"?> |
| |
| <!-- Don't forget to set system property |
| -Dlog4j2.contextSelector=org.apache.logging.log4j.core.async.AsyncLoggerContextSelector |
| or |
| -Dlog4j2.contextSelector=org.apache.logging.log4j.core.async.BasicAsyncLoggerContextSelector |
| to make all loggers asynchronous. --> |
| |
| <Configuration status="WARN"> |
| <Appenders> |
| <!-- Async Loggers will auto-flush in batches, so switch off immediateFlush. --> |
| <RandomAccessFile name="RandomAccessFile" fileName="async.log" immediateFlush="false" append="false"> |
| <PatternLayout> |
| <Pattern>%d %p %c{1.} [%t] %m %ex%n</Pattern> |
| </PatternLayout> |
| </RandomAccessFile> |
| </Appenders> |
| <Loggers> |
| <Root level="info" includeLocation="false"> |
| <AppenderRef ref="RandomAccessFile"/> |
| </Root> |
| </Loggers> |
| </Configuration> |
| ---- |
| |
| When `AsyncLoggerContextSelector` or |
| `BasicAsyncLoggerContextSelector` is used to make all loggers |
| asynchronous, make sure to use normal `<root>` and `<logger>` elements |
| in the configuration. The context selector will ensure that |
| all loggers are asynchronous, using a mechanism that is different from |
| what happens when you configure `<asyncRoot>` or `<asyncLogger>`. The |
| latter elements are intended for mixing async with sync loggers. If you |
| use both mechanisms together you will end up with two background |
| threads, where your application passes the log message to thread A, |
| which passes the message to thread B, which then finally logs the |
| message to disk. This works, but there will be an unnecessary step in |
| the middle. |
| |
| There are a few system properties you can use to control aspects of the |
| asynchronous logging subsystem. Some of these can be used to tune |
| logging performance. |
| |
| The below properties can also be specified by creating a file named |
| `log4j2.component.properties` and including this file in the classpath |
| of the application. |
| |
| NOTE: System properties were renamed into a more consistent style in |
| Log4j 2.10.0. All old property names are still supported which are |
| documented xref:manual/configuration.adoc#SystemProperties[here]. |
| |
| [[SysPropsAllAsync]] |
| |
| .System Properties to configure all asynchronous loggers |
| [cols="1,1,5"] |
| |=== |
| h| Java Property |
| |
| (Environment Variable) |
| h| Default Value |
| h| Description |
| |
| | [[log4j2.asyncLoggerExceptionHandler]]`log4j2.asyncLogger{zwsp}ExceptionHandler` |
| |
| (`LOG4J_ASYNC_LOGGER_{zwsp}EXCEPTION_HANDLER`) |
| | link:../javadoc/log4j-core/org/apache/logging/log4j/core/async/AsyncLoggerDefaultExceptionHandler[AsyncLogger{zwsp}DefaultExceptionHandler] |
| | |
| Fully qualified name of a class that implements the https://lmax-exchange.github.io/disruptor/javadoc/com.lmax.disruptor/com/lmax/disruptor/ExceptionHandler.html[ExceptionHandler] interface, which will be notified when an exception occurs while logging messages. |
| The class needs to have a public zero-argument constructor. |
| |
| The default exception handler will print a message and |
| stack trace to the standard error output stream. |
| |
| | [[log4j2.asyncLoggerRingBufferSize]]`log4j2.asyncLogger{zwsp}RingBufferSize` |
| |
| (`LOG4J_ASYNC_LOGGER_{zwsp}RING_BUFFER_SIZE`) |
| | `256 × 1024` |
| |
| `4 × 1024` (GC mode) |
| | |
| Size (number of slots) in the RingBuffer used by the asynchronous |
| logging subsystem. |
| Make this value large enough to deal with bursts of |
| activity. |
| The minimum size is 128. |
| The RingBuffer will be pre-allocated at first use and will never grow or shrink during the life of the system. |
| |
| When the application is logging faster than the underlying appender can keep up with for a long enough time to fill |
| up the queue, the behaviour is determined by the link:../javadoc/log4j-core/org/apache/logging/log4j/core/async/AsyncQueueFullPolicy.html[AsyncQueueFullPolicy]. |
| |
| | [[log4j2.asyncLoggerWaitStrategy]]`log4j2.asyncLogger{zwsp}WaitStrategy` |
| |
| (`LOG4J_ASYNC_LOGGER_{zwsp}WAIT_STRATEGY`) |
| | `Timeout` |
| a| Specifies the https://lmax-exchange.github.io/disruptor/javadoc/com.lmax.disruptor/com/lmax/disruptor/WaitStrategy.html[WaitStrategy] used by the LMAX Disruptor. |
| |
| Valid values: |
| |
| * `Block`: a strategy that uses a lock and condition variable for the I/O thread waiting for log events. |
| Block can be used when throughput and low-latency are not as important as CPU resource. |
| Recommended for resource constrained/virtualised environments. |
| |
| * `Timeout`: a variation of the `Block` strategy that will periodically wake up from the lock condition `await()` call. |
| This ensures that if a notification is missed somehow the consumer thread is not stuck but will recover with a small latency delay (see <<log4j2.asyncLoggerTimeout>>) |
| |
| * `Sleep`: a strategy that initially spins, then uses a `Thread.yield()`, and eventually parks for the minimum number of nanos the OS and JVM will allow while the I/O thread is waiting for log events (see <<log4j2.asyncLoggerRetries>> and <<log4j2.asyncLoggerSleepTimeNs>>). |
| Sleep is a good compromise between performance and CPU resource. |
| This strategy has very low impact on the application thread, in exchange for some additional latency for actually getting the message logged. |
| |
| * `Yield`: is a strategy that uses a `Thread.yield()` for waiting for log events after an initially spinning. |
| Yield is a good compromise between performance and CPU resource, but may use more CPU than `Sleep` in order to get the message logged to disk sooner. |
| |
| * a <<Custom WaitStrategy>>. |
| |
| |[[log4j2.asyncLoggerTimeout]]`log4j2.asyncLogger{zwsp}Timeout` |
| |
| (`LOG4J_ASYNC_LOGGER_{zwsp}TIMEOUT`) |
| |`10` |
| |Timeout in milliseconds of `Timeout` wait strategy (see <<log4j2.asyncLoggerWaitStrategy>>). |
| |
| | [[log4j2.asyncLoggerSleepTimeNs]]`log4j2.asyncLogger{zwsp}SleepTimeNs` |
| |
| (`LOG4J_ASYNC_LOGGER_{zwsp}SLEEP_TIME_NS`) |
| | `100` |
| | Sleep time in nanoseconds of `Sleep` wait strategy (see <<log4j2.asyncLoggerWaitStrategy>>). |
| |
| | [[log4j2.asyncLoggerRetries]]`log4j2.asyncLogger{zwsp}Retries` |
| |
| (`LOG4J_ASYNC_LOGGER_{zwsp}RETRIES`) |
| | `200` |
| | Total number of spin cycles and `Thread.yield()` cycles of `Sleep` (see <<log4j2.asyncLoggerWaitStrategy>>). |
| |
| | [[log4j2.asyncLoggerSynchronizeEnqueueWhenQueueFull]]`log4j2.asyncLogger{zwsp}SynchronizeEnqueueWhenQueueFull` |
| |
| (`LOG4J_ASYNC_LOGGER_{zwsp}SYNCHRONIZE_ENQUEUE_WHEN_QUEUE_FULL`) |
| | `true` |
| |Synchronizes access to the Disruptor ring buffer for blocking enqueue operations when the queue is full. |
| Users encountered excessive CPU utilization with Disruptor v3.4.2 when the application was logging more than the underlying appender could keep up with and the ring buffer became full, especially when the number of application threads vastly outnumbered the number of cores. |
| CPU utilization is significantly reduced by restricting access to the enqueue operation. |
| Setting this value to `false` may lead to very high CPU utilization when the async logging queue is full. |
| |
| | [[log4j2.asyncLoggerThreadNameStrategy]]`log4j2.asyncLogger{zwsp}ThreadNameStrategy` |
| |
| (`LOG4J_ASYNC_LOGGER_{zwsp}HREAD_NAME_STRATEGY`) |
| | `UNCACHED` for JRE 8u102 or later, `CACHED` otherwise |
| | Specifies the link:../javadoc/log4j-core/org/apache/logging/log4j/core/async/ThreadNameCachingStrategy to use to cache the result of https://docs.oracle.com/javase/{java-target-version}/docs/api/java/lang/Thread.html#getName()[Thread.getName()]. |
| |
| This setting allows to cache the result of `Thread.getName()` calls: |
| |
| * a value of `CACHED` stores the name of the current thread in a `ThreadLocal` field, |
| * a value of `UNCACHED` disable caching. |
| |
| **Remark**: Since JRE 8u102 the `Thread.getName()` method does not allocate a new object. |
| |
| |=== |
| |
| There are also a few system properties that can be used to maintain |
| application throughput even when the underlying appender cannot keep up |
| with the logging rate and the queue is filling up. See the details for |
| system properties |
| xref:manual/configuration.adoc#asyncQueueFullPolicy[`log4j2.asyncQueueFullPolicy` |
| and `log4j2.discardThreshold`]. |
| |
| [#MixedSync-Async] |
| == Mixing Synchronous and Asynchronous Loggers |
| |
| NOTE: _Log4j-2.9 and higher require disruptor-3.3.4.jar or higher on the |
| classpath. Prior to Log4j-2.9, disruptor-3.0.0.jar or higher was |
| required. There is no need to set system property "Log4jContextSelector" |
| to any value._ |
| |
| Synchronous and asynchronous loggers can be combined in configuration. |
| This gives you more flexibility at the cost of a slight loss in |
| performance (compared to making all loggers asynchronous). Use the |
| `<asyncRoot>` or `<asyncLogger>` configuration elements to specify the |
| loggers that need to be asynchronous. A configuration can contain only |
| one root logger (either a `<root>` or an `<asyncRoot>` element), but |
| otherwise async and non-async loggers may be combined. For example, a |
| configuration file containing `<asyncLogger>` elements can also contain |
| `<root>` and `<logger>` elements for the synchronous loggers. |
| |
| By default, link:#Location[location] is not passed to the I/O thread by |
| asynchronous loggers. If one of your layouts or custom filters needs |
| location information, you need to set "includeLocation=true" in the |
| configuration of all relevant loggers, including the root logger. |
| |
| A configuration that mixes asynchronous loggers might look like: |
| |
| [source,xml] |
| ---- |
| <?xml version="1.0" encoding="UTF-8"?> |
| |
| <!-- No need to set system property "log4j2.contextSelector" to any value |
| when using <asyncLogger> or <asyncRoot>. --> |
| |
| <Configuration status="WARN"> |
| <Appenders> |
| <!-- Async Loggers will auto-flush in batches, so switch off immediateFlush. --> |
| <RandomAccessFile name="RandomAccessFile" fileName="asyncWithLocation.log" |
| immediateFlush="false" append="false"> |
| <PatternLayout> |
| <Pattern>%d %p %class{1.} [%t] %location %m %ex%n</Pattern> |
| </PatternLayout> |
| </RandomAccessFile> |
| </Appenders> |
| <Loggers> |
| <!-- pattern layout actually uses location, so we need to include it --> |
| <AsyncLogger name="com.foo.Bar" level="trace" includeLocation="true"> |
| <AppenderRef ref="RandomAccessFile"/> |
| </AsyncLogger> |
| <Root level="info" includeLocation="true"> |
| <AppenderRef ref="RandomAccessFile"/> |
| </Root> |
| </Loggers> |
| </Configuration> |
| ---- |
| |
| There are a few system properties you can use to control aspects of the |
| asynchronous logging subsystem. Some of these can be used to tune |
| logging performance. |
| |
| The below properties can also be specified by creating a file named |
| `log4j2.component.properties` and including this file in the classpath |
| of the application. |
| |
| NOTE: All system properties were renamed into a more consistent style in |
| Log4j 2.10. All old property names are still supported which are |
| documented xref:manual/configuration.adoc#SystemProperties[here]. |
| |
| [[SysPropsMixedSync-Async]] |
| |
| .System Properties to configure mixed asynchronous and normal loggers |
| [cols="1,1,5"] |
| |=== |
| h| Java Property |
| |
| (Environment Variable) |
| h| Default Value |
| h| Description |
| |
| | [[log4j2.asyncLoggerConfigExceptionHandler]]`log4j2.asyncLoggerConfig{zwsp}ExceptionHandler` |
| |
| (`LOG4J_ASYNC_LOGGER_CONFIG_{zwsp}EXCEPTION_HANDLER`) |
| | link:../javadoc/log4j-core/org/apache/logging/log4j/core/async/AsyncLoggerConfigDefaultExceptionHandler[AsyncLoggerConfig{zwsp}DefaultExceptionHandler] |
| | |
| Fully qualified name of a class that implements the https://lmax-exchange.github.io/disruptor/javadoc/com.lmax.disruptor/com/lmax/disruptor/ExceptionHandler.html[ExceptionHandler] interface, which will be notified when an exception occurs while logging messages. |
| The class needs to have a public zero-argument constructor. |
| |
| The default exception handler will print a message and |
| stack trace to the standard error output stream. |
| |
| | [[log4j2.asyncLoggerConfigRingBufferSize]]`log4j2.asyncLoggerConfig{zwsp}RingBufferSize` |
| |
| (`LOG4J_ASYNC_LOGGER_CONFIG_{zwsp}RING_BUFFER_SIZE`) |
| | `256 × 1024` |
| |
| `4 × 1024` (GC mode) |
| | |
| Size (number of slots) in the RingBuffer used by the asynchronous |
| logging subsystem. |
| Make this value large enough to deal with bursts of |
| activity. |
| The minimum size is 128. |
| The RingBuffer will be pre-allocated at first use and will never grow or shrink during the life of the system. |
| |
| When the application is logging faster than the underlying appender can keep up with for a long enough time to fill |
| up the queue, the behaviour is determined by the link:../javadoc/log4j-core/org/apache/logging/log4j/core/async/AsyncQueueFullPolicy.html[AsyncQueueFullPolicy]. |
| |
| | [[log4j2.asyncLoggerConfigWaitStrategy]]`log4j2.asyncLoggerConfig{zwsp}WaitStrategy` |
| |
| (`LOG4J_ASYNC_LOGGER_CONFIG_{zwsp}WAIT_STRATEGY`) |
| | `Timeout` |
| a| Specifies the https://lmax-exchange.github.io/disruptor/javadoc/com.lmax.disruptor/com/lmax/disruptor/WaitStrategy.html[WaitStrategy] used by the LMAX Disruptor. |
| |
| Valid values: |
| |
| * `Block`: a strategy that uses a lock and condition variable for the I/O thread waiting for log events. |
| Block can be used when throughput and low-latency are not as important as CPU resource. |
| Recommended for resource constrained/virtualised environments. |
| |
| * `Timeout`: a variation of the `Block` strategy that will periodically wake up from the lock condition `await()` call. |
| This ensures that if a notification is missed somehow the consumer thread is not stuck but will recover with a small latency delay (see <<log4j2.asyncLoggerConfigTimeout>>) |
| |
| * `Sleep`: a strategy that initially spins, then uses a `Thread.yield()`, and eventually parks for the minimum number of nanos the OS and JVM will allow while the I/O thread is waiting for log events (see <<log4j2.asyncLoggerConfigRetries>> and <<log4j2.asyncLoggerConfigSleepTimeNs>>). |
| Sleep is a good compromise between performance and CPU resource. |
| This strategy has very low impact on the application thread, in exchange for some additional latency for actually getting the message logged. |
| |
| * `Yield`: is a strategy that uses a `Thread.yield()` for waiting for log events after an initially spinning. |
| Yield is a good compromise between performance and CPU resource, but may use more CPU than `Sleep` in order to get the message logged to disk sooner. |
| |
| * a <<Custom WaitStrategy>>. |
| |
| |[[log4j2.asyncLoggerConfigTimeout]]`log4j2.asyncLoggerConfig{zwsp}Timeout` |
| |
| (`LOG4J_ASYNC_LOGGER_CONFIG_{zwsp}TIMEOUT`) |
| | `10` |
| | Timeout in milliseconds of `Timeout` wait strategy (see <<log4j2.asyncLoggerConfigWaitStrategy>>). |
| |
| | [[log4j2.asyncLoggerConfigSleepTimeNs]]`log4j2.asyncLoggerConfig{zwsp}SleepTimeNs` |
| |
| (`LOG4J_ASYNC_LOGGER_CONFIG_{zwsp}SLEEP_TIME_NS`) |
| | `100` |
| | Sleep time in nanoseconds of `Sleep` wait strategy (see <<log4j2.asyncLoggerConfigWaitStrategy>>)). |
| |
| | [[log4j2.asyncLoggerConfigRetries]]`log4j2.asyncLoggerConfig{zwsp}Retries` |
| |
| (`LOG4J_ASYNC_LOGGER_CONFIG_{zwsp}RETRIES`) |
| | `200` |
| | Total number of spin cycles and `Thread.yield()` cycles of `Sleep` (see <<log4j2.asyncLoggerConfigWaitStrategy>>)). |
| |
| | [[log4j2.asyncLoggerConfigSynchronizeEnqueueWhenQueueFull]]`log4j2.asyncLoggerConfig{zwsp}SynchronizeEnqueueWhenQueueFull` |
| |
| (`LOG4J_ASYNC_LOGGER_CONFIG_{zwsp}SYNCHRONIZE_ENQUEUE_WHEN_QUEUE_FULL`) |
| | `true` |
| |Synchronizes access to the Disruptor ring buffer for blocking enqueue operations when the queue is full. |
| Users encountered excessive CPU utilization with Disruptor v3.4.2 when the application was logging more than the underlying appender could keep up with and the ring buffer became full, especially when the number of application threads vastly outnumbered the number of cores. |
| CPU utilization is significantly reduced by restricting access to the enqueue operation. |
| Setting this value to `false` may lead to very high CPU utilization when the async logging queue is full. |
| |
| |=== |
| |
| There are also a few system properties that can be used to maintain |
| application throughput even when the underlying appender cannot keep up |
| with the logging rate and the queue is filling up. See the details for |
| system properties |
| xref:manual/configuration.adoc#asyncQueueFullPolicy[`log4j2.asyncQueueFullPolicy` |
| and `log4j2.discardThreshold`]. |
| |
| [#WaitStrategy] |
| == Custom WaitStrategy |
| The system properties mentioned above allow only choice from among a fixed set of predefined WaitStrategies. |
| There may be cases where you want to configure a custom WaitStrategy that is not in this list. |
| This is possible by using a `AsyncWaitStrategyFactory` element in the Log4j configuration. |
| |
| A configuration that configures a custom WaitStrategy can look as follows: |
| |
| [source,xml] |
| ---- |
| <?xml version="1.0" encoding="UTF-8"?> |
| <Configuration status="WARN"> |
| |
| <AsyncWaitStrategyFactory |
| class="my.custom.AsyncWaitStrategyFactory" /> |
| |
| <Appenders> |
| <File name="MyFile" fileName="logs/app.log"> |
| <PatternLayout pattern="%d %p %c{1.} [%t] %m%n" /> |
| </File> |
| </Appenders> |
| <Loggers> |
| <AsyncRoot level="info"> |
| <AppenderRef ref="MyFile"/> |
| </AsyncRoot> |
| </Loggers> |
| </Configuration> |
| ---- |
| |
| The specified class must implement the |
| `org.apache.logging.log4j.core.async.AsyncWaitStrategyFactory` interface, which is defined as follows: |
| |
| [source,java] |
| ---- |
| public interface AsyncWaitStrategyFactory { |
| /** |
| * Returns a non-null implementation of the LMAX Disruptor's WaitStrategy interface. |
| * This WaitStrategy will be used by Log4j Async Loggers and Async LoggerConfigs. |
| * |
| * @return the WaitStrategy instance to be used by Async Loggers and Async LoggerConfigs |
| */ |
| WaitStrategy createWaitStrategy(); |
| } |
| ---- |
| |
| The specified class must also have a public no-argument constructor; |
| Log4j will instantiate an instance of the specified factory class and use this factory to create the WaitStrategy used by all Async Loggers. |
| |
| WaitStrategy-related system properties are ignored if a `AsyncWaitStrategyFactory` is configured. |
| |
| |
| [#Location] |
| == Location, location, location... |
| |
| If one of the layouts is configured with a location-related attribute |
| like HTML xref:manual/layouts.adoc#HtmlLocationInfo[locationInfo], or one of |
| the patterns xref:manual/layouts.adoc#PatternClass[%C or $class], |
| xref:manual/layouts.adoc#PatternFile[%F or %file], |
| xref:manual/layouts.adoc#PatternLocation[%l or %location], |
| xref:manual/layouts.adoc#PatternLine[%L or %line], |
| xref:manual/layouts.adoc#PatternMethod[%M or %method], Log4j will take a |
| snapshot of the stack, and walk the stack trace to find the location |
| information. |
| |
| This is an expensive operation: 1.3 - 5 times slower for synchronous |
| loggers. Synchronous loggers wait as long as possible before they take |
| this stack snapshot. If no location is required, the snapshot will never |
| be taken. |
| |
| However, asynchronous loggers need to make this decision before passing |
| the log message to another thread; the location information will be lost |
| after that point. The |
| xref:manual/performance.adoc#asyncLoggingWithLocation[performance impact] of |
| taking a stack trace snapshot is even higher for asynchronous loggers: |
| logging with location is 30-100 times slower than without location. For |
| this reason, asynchronous loggers and asynchronous appenders do not |
| include location information by default. |
| |
| You can override the default behaviour in your logger or asynchronous |
| appender configuration by specifying `includeLocation="true"`. |
| |
| [#Performance] |
| == Asynchronous Logging Performance |
| |
| The throughput performance results below were derived from running the |
| PerfTest, MTPerfTest and PerfTestDriver classes which can be found in |
| the Log4j 2 unit test source directory. For throughput tests, the |
| methodology used was: |
| |
| * First, warm up the JVM by logging 200,000 log messages of 500 |
| characters. |
| * Repeat the warm-up 10 times, then wait 10 seconds for the I/O thread |
| to catch up and buffers to drain. |
| * Measure how long it takes to execute 256 * 1024 / threadCount calls to |
| Logger.log and express the result in messages per second. |
| * Repeat the test 5 times and average the results. |
| |
| The results below were obtained with log4j-2.0-beta5, |
| disruptor-3.0.0.beta3, log4j-1.2.17 and logback-1.0.10. |
| |
| === Logging Peak Throughput |
| |
| The graph below compares the throughput of synchronous loggers, |
| asynchronous appenders and asynchronous loggers. This is the total |
| throughput of all threads together. In the test with 64 threads, |
| asynchronous loggers are 12 times faster than asynchronous appenders, |
| and 68 times faster than synchronous loggers. |
| |
| Asynchronous loggers' throughput increases with the number of threads, |
| whereas both synchronous loggers and asynchronous appenders have more or |
| less constant throughput regardless of the number of threads that are |
| doing the logging. |
| |
| image:async-vs-sync-throughput.png[Async loggers have much |
| higher throughput than sync loggers.] |
| |
| === Asynchronous Throughput Comparison with Other Logging Packages |
| |
| We also compared peak throughput of asynchronous loggers to the |
| synchronous loggers and asynchronous appenders available in other |
| logging packages, specifically log4j-1.2.17 and logback-1.0.10, with |
| similar results. For asynchronous appenders, total logging throughput of |
| all threads together remains roughly constant when adding more threads. |
| Asynchronous loggers make more effective use of the multiple cores |
| available on the machine in multi-threaded scenarios. |
| |
| image:async-throughput-comparison.png[Async loggers have the |
| highest throughput.] |
| |
| On Solaris 10 (64bit) with JDK1.7.0_06, 4-core Xeon X5570 dual CPU |
| @2.93Ghz with hyperthreading switched on (16 virtual cores): |
| |
| .Throughput per thread in messages/second |
| [cols="h,>,>,>,>,>,>,>",options="header",] |
| |======================================================================= |
| |Logger |1 thread |2 threads |4 threads |8 threads |16 threads |32 |
| threads |64 threads |
| |Log4j 2: Loggers all asynchronous |2,652,412 |909,119 |776,993 |516,365 |
| |239,246 |253,791 |288,997 |
| |
| |Log4j 2: Loggers mixed sync/async |2,454,358 |839,394 |854,578 |597,913 |
| |261,003 |216,863 |218,937 |
| |
| |Log4j 2: Async Appender |1,713,429 |603,019 |331,506 |149,408 |86,107 |
| |45,529 |23,980 |
| |
| |Log4j1: Async Appender |2,239,664 |494,470 |221,402 |109,314 |60,580 |
| |31,706 |14,072 |
| |
| |Logback: Async Appender |2,206,907 |624,082 |307,500 |160,096 |85,701 |
| |43,422 |21,303 |
| |
| |Log4j 2: Synchronous |273,536 |136,523 |67,609 |34,404 |15,373 |7,903 |
| |4,253 |
| |
| |Log4j1: Synchronous |326,894 |105,591 |57,036 |30,511 |13,900 |7,094 |
| |3,509 |
| |
| |Logback: Synchronous |178,063 |65,000 |34,372 |16,903 |8,334 |3,985 |
| |1,967 |
| |======================================================================= |
| |
| On Windows 7 (64bit) with JDK1.7.0_11, 2-core Intel i5-3317u CPU |
| @1.70Ghz with hyperthreading switched on (4 virtual cores): |
| |
| .Throughput per thread in messages/second |
| [cols="h,>,>,>,>,>,>",options="header",] |
| |======================================================================= |
| |Logger |1 thread |2 threads |4 threads |8 threads |16 threads |32 |
| threads |
| |Log4j 2: Loggers all asynchronous |1,715,344 |928,951 |1,045,265 |
| |1,509,109 |1,708,989 |773,565 |
| |
| |Log4j 2: Loggers mixed sync/async |571,099 |1,204,774 |1,632,204 |
| |1,368,041 |462,093 |908,529 |
| |
| |Log4j 2: Async Appender |1,236,548 |1,006,287 |511,571 |302,230 |
| |160,094 |60,152 |
| |
| |Log4j1: Async Appender |1,373,195 |911,657 |636,899 |406,405 |202,777 |
| |162,964 |
| |
| |Logback: Async Appender |1,979,515 |783,722 |582,935 |289,905 |172,463 |
| |133,435 |
| |
| |Log4j 2: Synchronous |281,250 |225,731 |129,015 |66,590 |34,401 |17,347 |
| |
| |Log4j1: Synchronous |147,824 |72,383 |32,865 |18,025 |8,937 |4,440 |
| |
| |Logback: Synchronous |149,811 |66,301 |32,341 |16,962 |8,431 |3,610 |
| |======================================================================= |
| |
| [#Latency] |
| === Response Time Latency |
| |
| This section has been rewritten with the Log4j 2.6 release. The |
| previous version only reported _service time_ instead of _response |
| time_. See the xref:manual/performance.adoc#responseTime[response time] side |
| bar on the performance page on why this is too optimistic. Furthermore |
| the previous version reported average latency, which does not make sense |
| since latency is not a normal distribution. Finally, the previous |
| version of this section only reported the maximum latency of up to |
| 99.99% of the measurements, which does not tell you how bad the worst |
| 0.01% were. This is unfortunate because often the "outliers" are all |
| that matter when it comes to response time. From this release we will |
| try to do better and report response time latency across the full range |
| of percentages, including all the outliers. Our thanks to Gil Tene for |
| his http://www.infoq.com/presentations/latency-response-time[How NOT to |
| measure latency] presentation. (Now we know why this is also known as |
| the "Oh s#@t!" presentation.) |
| |
| xref:manual/performance.adoc#responseTime[Response time] is how long it |
| takes to log a message under a certain load. What is often reported as |
| latency is actually _service time_: how long it took to perform the |
| operation. This hides the fact that a single spike in service time adds |
| queueing delay for many of the subsequent operations. Service time is |
| easy to measure (and often looks good on paper) but is irrelevant for |
| users since it omits the time spent waiting for service. For this reason |
| we report response time: service time plus wait time. |
| |
| The response time test results below were all derived from running the |
| ResponseTimeTest class which can be found in the Log4j 2 unit test |
| source directory. If you want to run these tests yourself, here are the |
| command line options we used: |
| |
| * -Xms1G -Xmx1G (prevent heap resizing during the test) |
| * -DLog4jContextSelector=org.apache.logging.log4j.core.async.AsyncLoggerContextSelector |
| -DAsyncLogger.WaitStrategy=busyspin (to use Async Loggers. The BusySpin |
| wait strategy reduces some jitter.) |
| * *classic mode:* -Dlog4j2.enable.direct.encoders=false + |
| *garbage-free mode:* -Dlog4j2.enable.direct.encoders=true |
| * -XX:CompileCommand=dontinline,org.apache.logging.log4j.core.async.perftest.NoOpIdleStrategy::idle |
| * -verbose:gc -XX:+PrintGCDetails -XX:+PrintGCDateStamps |
| -XX:+PrintTenuringDistribution -XX:+PrintGCApplicationConcurrentTime |
| -XX:+PrintGCApplicationStoppedTime (to eyeball GC and safepoint pauses) |
| |
| The graph below compares response time latency of the |
| ArrayBlockingQueue-based asynchronous appenders in Logback 1.1.7, Log4j |
| 1.2.17 to the various options for asynchronous logging that Log4j 2.6 |
| offers. Under a workload of 128,000 messages per second, using 16 |
| threads (each logging at a rate of 8,000 messages per second), we see |
| that Logback 1.1.7, Log4j 1.2.17 experience latency spikes that are |
| orders of magnitude larger than Log4j 2. |
| |
| image:ResponseTimeAsyncLogging16Threads_8kEach.png[When 16 |
| threads generate a total workload of 128,000 msg/sec, Logback 1.1.7 and |
| Log4j 1.2.17 experience latency spikes that are orders of magnitude |
| larger than Log4j 2] |
| |
| The graph below zooms in on the Log4j 2 results for the same test. We |
| see that the worst-case response time is highest for the |
| ArrayBlockingQueue-based Async Appender. |
| xref:manual/garbagefree.adoc[Garbage-free] async loggers have the best response |
| time behaviour. |
| |
| image:ResponseTimeAsyncLogging16Threads_8kEachLog4j2Only-labeled.png[image] |
| |
| [#UnderTheHood] |
| == Under The Hood |
| |
| Asynchronous Loggers are implemented using the |
| https://lmax-exchange.github.io/disruptor/[LMAX Disruptor] inter-thread |
| messaging library. From the LMAX web site: |
| |
| ____ |
| ...using queues to pass data between stages of the system was |
| introducing latency, so we focused on optimising this area. The |
| Disruptor is the result of our research and testing. We found that cache |
| misses at the CPU-level, and locks requiring kernel arbitration are both |
| extremely costly, so we created a framework which has "mechanical |
| sympathy" for the hardware it's running on, and that's lock-free. |
| ____ |
| |
| LMAX Disruptor internal performance comparisons with |
| `java.util.concurrent.ArrayBlockingQueue` can be found |
| https://github.com/LMAX-Exchange/disruptor/wiki/Performance-Results[here]. |