--- layout: global title: Monitoring and Instrumentation description: Monitoring, metrics, and instrumentation guide for Spark SPARK_VERSION_SHORT license: | 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. --- There are several ways to monitor Spark applications: web UIs, metrics, and external instrumentation. # Web Interfaces Every SparkContext launches a web UI, by default on port 4040, that displays useful information about the application. This includes: * A list of scheduler stages and tasks * A summary of RDD sizes and memory usage * Environmental information. * Information about the running executors You can access this interface by simply opening `http://:4040` in a web browser. If multiple SparkContexts are running on the same host, they will bind to successive ports beginning with 4040 (4041, 4042, etc). Note that this information is only available for the duration of the application by default. To view the web UI after the fact, set `spark.eventLog.enabled` to true before starting the application. This configures Spark to log Spark events that encode the information displayed in the UI to persisted storage. ## Viewing After the Fact It is still possible to construct the UI of an application through Spark's history server, provided that the application's event logs exist. You can start the history server by executing: ./sbin/start-history-server.sh This creates a web interface at `http://:18080` by default, listing incomplete and completed applications and attempts. When using the file-system provider class (see `spark.history.provider` below), the base logging directory must be supplied in the `spark.history.fs.logDirectory` configuration option, and should contain sub-directories that each represents an application's event logs. The spark jobs themselves must be configured to log events, and to log them to the same shared, writable directory. For example, if the server was configured with a log directory of `hdfs://namenode/shared/spark-logs`, then the client-side options would be: spark.eventLog.enabled true spark.eventLog.dir hdfs://namenode/shared/spark-logs The history server can be configured as follows: ### Environment Variables

Environment Variable	Meaning
`SPARK_DAEMON_MEMORY`	Memory to allocate to the history server (default: 1g).
`SPARK_DAEMON_JAVA_OPTS`	JVM options for the history server (default: none).
`SPARK_DAEMON_CLASSPATH`	Classpath for the history server (default: none).
`SPARK_PUBLIC_DNS`	The public address for the history server. If this is not set, links to application history may use the internal address of the server, resulting in broken links (default: none).
`SPARK_HISTORY_OPTS`	`spark.history.*` configuration options for the history server (default: none).

### Spark History Server Configuration Options Security options for the Spark History Server are covered more detail in the [Security](security.html#web-ui) page.

Property Name	Default	Meaning
spark.history.provider	`org.apache.spark.deploy.history.FsHistoryProvider`	Name of the class implementing the application history backend. Currently there is only one implementation, provided by Spark, which looks for application logs stored in the file system.
spark.history.fs.logDirectory	file:/tmp/spark-events	For the filesystem history provider, the URL to the directory containing application event logs to load. This can be a local `file://` path, an HDFS path `hdfs://namenode/shared/spark-logs` or that of an alternative filesystem supported by the Hadoop APIs.
spark.history.fs.update.interval	10s	The period at which the filesystem history provider checks for new or updated logs in the log directory. A shorter interval detects new applications faster, at the expense of more server load re-reading updated applications. As soon as an update has completed, listings of the completed and incomplete applications will reflect the changes.
spark.history.retainedApplications	50	The number of applications to retain UI data for in the cache. If this cap is exceeded, then the oldest applications will be removed from the cache. If an application is not in the cache, it will have to be loaded from disk if it is accessed from the UI.
spark.history.ui.maxApplications	Int.MaxValue	The number of applications to display on the history summary page. Application UIs are still available by accessing their URLs directly even if they are not displayed on the history summary page.
spark.history.ui.port	18080	The port to which the web interface of the history server binds.
spark.history.kerberos.enabled	false	Indicates whether the history server should use kerberos to login. This is required if the history server is accessing HDFS files on a secure Hadoop cluster. If this is true, it uses the configs `spark.history.kerberos.principal` and `spark.history.kerberos.keytab`.
spark.history.kerberos.principal	(none)	Kerberos principal name for the History Server.
spark.history.kerberos.keytab	(none)	Location of the kerberos keytab file for the History Server.
spark.history.fs.cleaner.enabled	false	Specifies whether the History Server should periodically clean up event logs from storage.
spark.history.fs.cleaner.interval	1d	How often the filesystem job history cleaner checks for files to delete. Files are deleted if at least one of two conditions holds. First, they're deleted if they're older than `spark.history.fs.cleaner.maxAge`. They are also deleted if the number of files is more than `spark.history.fs.cleaner.maxNum`, Spark tries to clean up the completed attempts from the applications based on the order of their oldest attempt time.
spark.history.fs.cleaner.maxAge	7d	Job history files older than this will be deleted when the filesystem history cleaner runs.
spark.history.fs.cleaner.maxNum	Int.MaxValue	The maximum number of files in the event log directory. Spark tries to clean up the completed attempt logs to maintain the log directory under this limit. This should be smaller than the underlying file system limit like `dfs.namenode.fs-limits.max-directory-items` in HDFS.
spark.history.fs.endEventReparseChunkSize	1m	How many bytes to parse at the end of log files looking for the end event. This is used to speed up generation of application listings by skipping unnecessary parts of event log files. It can be disabled by setting this config to 0.
spark.history.fs.inProgressOptimization.enabled	true	Enable optimized handling of in-progress logs. This option may leave finished applications that fail to rename their event logs listed as in-progress.
spark.history.fs.driverlog.cleaner.enabled	`spark.history.fs.cleaner.enabled`	Specifies whether the History Server should periodically clean up driver logs from storage.
spark.history.fs.driverlog.cleaner.interval	`spark.history.fs.cleaner.interval`	How often the filesystem driver log cleaner checks for files to delete. Files are only deleted if they are older than `spark.history.fs.driverlog.cleaner.maxAge`
spark.history.fs.driverlog.cleaner.maxAge	`spark.history.fs.cleaner.maxAge`	Driver log files older than this will be deleted when the driver log cleaner runs.
spark.history.fs.numReplayThreads	25% of available cores	Number of threads that will be used by history server to process event logs.
spark.history.store.maxDiskUsage	10g	Maximum disk usage for the local directory where the cache application history information are stored.
spark.history.store.path	(none)	Local directory where to cache application history data. If set, the history server will store application data on disk instead of keeping it in memory. The data written to disk will be re-used in the event of a history server restart.
spark.history.custom.executor.log.url	(none)	Specifies custom spark executor log URL for supporting external log service instead of using cluster managers' application log URLs in the history server. Spark will support some path variables via patterns which can vary on cluster manager. Please check the documentation for your cluster manager to see which patterns are supported, if any. This configuration has no effect on a live application, it only affects the history server. For now, only YARN mode supports this configuration
spark.history.custom.executor.log.url.applyIncompleteApplication	false	Specifies whether to apply custom spark executor log URL to incomplete applications as well. If executor logs for running applications should be provided as origin log URLs, set this to `false`. Please note that incomplete applications may include applications which didn't shutdown gracefully. Even this is set to `true`, this configuration has no effect on a live application, it only affects the history server.

Note that in all of these UIs, the tables are sortable by clicking their headers, making it easy to identify slow tasks, data skew, etc. Note 1. The history server displays both completed and incomplete Spark jobs. If an application makes multiple attempts after failures, the failed attempts will be displayed, as well as any ongoing incomplete attempt or the final successful attempt. 2. Incomplete applications are only updated intermittently. The time between updates is defined by the interval between checks for changed files (`spark.history.fs.update.interval`). On larger clusters, the update interval may be set to large values. The way to view a running application is actually to view its own web UI. 3. Applications which exited without registering themselves as completed will be listed as incomplete —even though they are no longer running. This can happen if an application crashes. 2. One way to signal the completion of a Spark job is to stop the Spark Context explicitly (`sc.stop()`), or in Python using the `with SparkContext() as sc:` construct to handle the Spark Context setup and tear down. ## REST API In addition to viewing the metrics in the UI, they are also available as JSON. This gives developers an easy way to create new visualizations and monitoring tools for Spark. The JSON is available for both running applications, and in the history server. The endpoints are mounted at `/api/v1`. Eg., for the history server, they would typically be accessible at `http://:18080/api/v1`, and for a running application, at `http://localhost:4040/api/v1`. In the API, an application is referenced by its application ID, `[app-id]`. When running on YARN, each application may have multiple attempts, but there are attempt IDs only for applications in cluster mode, not applications in client mode. Applications in YARN cluster mode can be identified by their `[attempt-id]`. In the API listed below, when running in YARN cluster mode, `[app-id]` will actually be `[base-app-id]/[attempt-id]`, where `[base-app-id]` is the YARN application ID.

Endpoint	Meaning
`/applications`	A list of all applications. `?status=[completed\|running]` list only applications in the chosen state. `?minDate=[date]` earliest start date/time to list. `?maxDate=[date]` latest start date/time to list. `?minEndDate=[date]` earliest end date/time to list. `?maxEndDate=[date]` latest end date/time to list. `?limit=[limit]` limits the number of applications listed. Examples: `?minDate=2015-02-10` `?minDate=2015-02-03T16:42:40.000GMT` `?maxDate=2015-02-11T20:41:30.000GMT` `?minEndDate=2015-02-12` `?minEndDate=2015-02-12T09:15:10.000GMT` `?maxEndDate=2015-02-14T16:30:45.000GMT` `?limit=10`
`/applications/[app-id]/jobs`	A list of all jobs for a given application. `?status=[running\|succeeded\|failed\|unknown]` list only jobs in the specific state.
`/applications/[app-id]/jobs/[job-id]`	Details for the given job.
`/applications/[app-id]/stages`	A list of all stages for a given application. `?status=[active\|complete\|pending\|failed]` list only stages in the state.
`/applications/[app-id]/stages/[stage-id]`	A list of all attempts for the given stage.
`/applications/[app-id]/stages/[stage-id]/[stage-attempt-id]`	Details for the given stage attempt.
`/applications/[app-id]/stages/[stage-id]/[stage-attempt-id]/taskSummary`	Summary metrics of all tasks in the given stage attempt. `?quantiles` summarize the metrics with the given quantiles. Example: `?quantiles=0.01,0.5,0.99`
`/applications/[app-id]/stages/[stage-id]/[stage-attempt-id]/taskList`	A list of all tasks for the given stage attempt. `?offset=[offset]&length=[len]` list tasks in the given range. `?sortBy=[runtime\|-runtime]` sort the tasks. Example: `?offset=10&length=50&sortBy=runtime`
`/applications/[app-id]/executors`	A list of all active executors for the given application.
`/applications/[app-id]/executors/[executor-id]/threads`	Stack traces of all the threads running within the given active executor. Not available via the history server.
`/applications/[app-id]/allexecutors`	A list of all(active and dead) executors for the given application.
`/applications/[app-id]/storage/rdd`	A list of stored RDDs for the given application.
`/applications/[app-id]/storage/rdd/[rdd-id]`	Details for the storage status of a given RDD.
`/applications/[base-app-id]/logs`	Download the event logs for all attempts of the given application as files within a zip file.
`/applications/[base-app-id]/[attempt-id]/logs`	Download the event logs for a specific application attempt as a zip file.
`/applications/[app-id]/streaming/statistics`	Statistics for the streaming context.
`/applications/[app-id]/streaming/receivers`	A list of all streaming receivers.
`/applications/[app-id]/streaming/receivers/[stream-id]`	Details of the given receiver.
`/applications/[app-id]/streaming/batches`	A list of all retained batches.
`/applications/[app-id]/streaming/batches/[batch-id]`	Details of the given batch.
`/applications/[app-id]/streaming/batches/[batch-id]/operations`	A list of all output operations of the given batch.
`/applications/[app-id]/streaming/batches/[batch-id]/operations/[outputOp-id]`	Details of the given operation and given batch.
`/applications/[app-id]/environment`	Environment details of the given application.
`/version`	Get the current spark version.

The number of jobs and stages which can be retrieved is constrained by the same retention mechanism of the standalone Spark UI; `"spark.ui.retainedJobs"` defines the threshold value triggering garbage collection on jobs, and `spark.ui.retainedStages` that for stages. Note that the garbage collection takes place on playback: it is possible to retrieve more entries by increasing these values and restarting the history server. ### Executor Task Metrics The REST API exposes the values of the Task Metrics collected by Spark executors with the granularity of task execution. The metrics can be used for performance troubleshooting and workload characterization. A list of the available metrics, with a short description:

Spark Executor Task Metric name	Short description
executorRunTime	Elapsed time the executor spent running this task. This includes time fetching shuffle data. The value is expressed in milliseconds.
executorCpuTime	CPU time the executor spent running this task. This includes time fetching shuffle data. The value is expressed in nanoseconds.
executorDeserializeTime	Elapsed time spent to deserialize this task. The value is expressed in milliseconds.
executorDeserializeCpuTime	CPU time taken on the executor to deserialize this task. The value is expressed in nanoseconds.
resultSize	The number of bytes this task transmitted back to the driver as the TaskResult.
jvmGCTime	Elapsed time the JVM spent in garbage collection while executing this task. The value is expressed in milliseconds.
resultSerializationTime	Elapsed time spent serializing the task result. The value is expressed in milliseconds.
memoryBytesSpilled	The number of in-memory bytes spilled by this task.
diskBytesSpilled	The number of on-disk bytes spilled by this task.
peakExecutionMemory	Peak memory used by internal data structures created during shuffles, aggregations and joins. The value of this accumulator should be approximately the sum of the peak sizes across all such data structures created in this task. For SQL jobs, this only tracks all unsafe operators and ExternalSort.
inputMetrics.*	Metrics related to reading data from [[org.apache.spark.rdd.HadoopRDD]] or from persisted data.
.bytesRead	Total number of bytes read.
.recordsRead	Total number of records read.
outputMetrics.*	Metrics related to writing data externally (e.g. to a distributed filesystem), defined only in tasks with output.
.bytesWritten	Total number of bytes written
.recordsWritten	Total number of records written
shuffleReadMetrics.*	Metrics related to shuffle read operations.
.recordsRead	Number of records read in shuffle operations
.remoteBlocksFetched	Number of remote blocks fetched in shuffle operations
.localBlocksFetched	Number of local (as opposed to read from a remote executor) blocks fetched in shuffle operations
.totalBlocksFetched	Number of blocks fetched in shuffle operations (both local and remote)
.remoteBytesRead	Number of remote bytes read in shuffle operations
.localBytesRead	Number of bytes read in shuffle operations from local disk (as opposed to read from a remote executor)
.totalBytesRead	Number of bytes read in shuffle operations (both local and remote)
.remoteBytesReadToDisk	Number of remote bytes read to disk in shuffle operations. Large blocks are fetched to disk in shuffle read operations, as opposed to being read into memory, which is the default behavior.
.fetchWaitTime	Time the task spent waiting for remote shuffle blocks. This only includes the time blocking on shuffle input data. For instance if block B is being fetched while the task is still not finished processing block A, it is not considered to be blocking on block B. The value is expressed in milliseconds.
shuffleWriteMetrics.*	Metrics related to operations writing shuffle data.
.bytesWritten	Number of bytes written in shuffle operations
.recordsWritten	Number of records written in shuffle operations
.writeTime	Time spent blocking on writes to disk or buffer cache. The value is expressed in nanoseconds.

### Executor Metrics Executor-level metrics are sent from each executor to the driver as part of the Heartbeat to describe the performance metrics of Executor itself like JVM heap memory, GC infomation. Metrics `peakExecutorMetrics.*` are only enabled if `spark.eventLog.logStageExecutorMetrics.enabled` is true. A list of the available metrics, with a short description:

Executor Level Metric name	Short description
totalGCTime	Elapsed time the JVM spent in garbage collection summed in this Executor. The value is expressed in milliseconds.
totalInputBytes	Total input bytes summed in this Executor.
totalShuffleRead	Total shuffer read bytes summed in this Executor.
totalShuffleWrite	Total shuffer write bytes summed in this Executor.
maxMemory	Total amount of memory available for storage, in bytes.
memoryMetrics.*	Current value of memory metrics:
.usedOnHeapStorageMemory	Used on heap memory currently for storage, in bytes.
.usedOffHeapStorageMemory	Used off heap memory currently for storage, in bytes.
.totalOnHeapStorageMemory	Total available on heap memory for storage, in bytes. This amount can vary over time, on the MemoryManager implementation.
.totalOffHeapStorageMemory	Total available off heap memory for storage, in bytes. This amount can vary over time, depending on the MemoryManager implementation.
peakMemoryMetrics.*	Peak value of memory (and GC) metrics:
.JVMHeapMemory	Peak memory usage of the heap that is used for object allocation. The heap consists of one or more memory pools. The used and committed size of the returned memory usage is the sum of those values of all heap memory pools whereas the init and max size of the returned memory usage represents the setting of the heap memory which may not be the sum of those of all heap memory pools. The amount of used memory in the returned memory usage is the amount of memory occupied by both live objects and garbage objects that have not been collected, if any.
.JVMOffHeapMemory	Peak memory usage of non-heap memory that is used by the Java virtual machine. The non-heap memory consists of one or more memory pools. The used and committed size of the returned memory usage is the sum of those values of all non-heap memory pools whereas the init and max size of the returned memory usage represents the setting of the non-heap memory which may not be the sum of those of all non-heap memory pools.
.OnHeapExecutionMemory	Peak on heap execution memory in use, in bytes.
.OffHeapExecutionMemory	Peak off heap execution memory in use, in bytes.
.OnHeapStorageMemory	Peak on heap storage memory in use, in bytes.
.OffHeapStorageMemory	Peak off heap storage memory in use, in bytes.
.OnHeapUnifiedMemory	Peak on heap memory (execution and storage).
.OffHeapUnifiedMemory	Peak off heap memory (execution and storage).
.DirectPoolMemory	Peak memory that the JVM is using for direct buffer pool ([[java.lang.management.BufferPoolMXBean]])
.MappedPoolMemory	Peak memory that the JVM is using for mapped buffer pool ([[java.lang.management.BufferPoolMXBean]])
.ProcessTreeJVMVMemory	Virtual memory size in bytes. Enabled if spark.eventLog.logStageExecutorProcessTreeMetrics.enabled is true.
.ProcessTreeJVMRSSMemory	Resident Set Size: number of pages the process has in real memory. This is just the pages which count toward text, data, or stack space. This does not include pages which have not been demand-loaded in, or which are swapped out. Enabled if spark.eventLog.logStageExecutorProcessTreeMetrics.enabled is true.
.ProcessTreePythonVMemory	Virtual memory size for Python in bytes. Enabled if spark.eventLog.logStageExecutorProcessTreeMetrics.enabled is true.
.ProcessTreePythonRSSMemory	Resident Set Size for Python. Enabled if spark.eventLog.logStageExecutorProcessTreeMetrics.enabled is true.
.ProcessTreeOtherVMemory	Virtual memory size for other kind of process in bytes. Enabled if spark.eventLog.logStageExecutorProcessTreeMetrics.enabled is true.
.ProcessTreeOtherRSSMemory	Resident Set Size for other kind of process. Enabled if spark.eventLog.logStageExecutorProcessTreeMetrics.enabled is true.
.MinorGCCount	Total minor GC count. For example, the garbage collector is one of Copy, PS Scavenge, ParNew, G1 Young Generation and so on.
.MinorGCTime	Elapsed total minor GC time. The value is expressed in milliseconds.
.MajorGCCount	Total major GC count. For example, the garbage collector is one of MarkSweepCompact, PS MarkSweep, ConcurrentMarkSweep, G1 Old Generation and so on.
.MajorGCTime	Elapsed total major GC time. The value is expressed in milliseconds.

The computation of RSS and Vmem are based on [proc(5)](http://man7.org/linux/man-pages/man5/proc.5.html) ### API Versioning Policy These endpoints have been strongly versioned to make it easier to develop applications on top. In particular, Spark guarantees: * Endpoints will never be removed from one version * Individual fields will never be removed for any given endpoint * New endpoints may be added * New fields may be added to existing endpoints * New versions of the api may be added in the future as a separate endpoint (eg., `api/v2`). New versions are *not* required to be backwards compatible. * Api versions may be dropped, but only after at least one minor release of co-existing with a new api version. Note that even when examining the UI of running applications, the `applications/[app-id]` portion is still required, though there is only one application available. Eg. to see the list of jobs for the running app, you would go to `http://localhost:4040/api/v1/applications/[app-id]/jobs`. This is to keep the paths consistent in both modes. # Metrics Spark has a configurable metrics system based on the [Dropwizard Metrics Library](http://metrics.dropwizard.io/). This allows users to report Spark metrics to a variety of sinks including HTTP, JMX, and CSV files. The metrics are generated by sources embedded in the Spark code base. They provide instrumentation for specific activities and Spark components. The metrics system is configured via a configuration file that Spark expects to be present at `$SPARK_HOME/conf/metrics.properties`. A custom file location can be specified via the `spark.metrics.conf` [configuration property](configuration.html#spark-properties). Instead of using the configuration file, a set of configuration parameters with prefix `spark.metrics.conf.` can be used. By default, the root namespace used for driver or executor metrics is the value of `spark.app.id`. However, often times, users want to be able to track the metrics across apps for driver and executors, which is hard to do with application ID (i.e. `spark.app.id`) since it changes with every invocation of the app. For such use cases, a custom namespace can be specified for metrics reporting using `spark.metrics.namespace` configuration property. If, say, users wanted to set the metrics namespace to the name of the application, they can set the `spark.metrics.namespace` property to a value like `${spark.app.name}`. This value is then expanded appropriately by Spark and is used as the root namespace of the metrics system. Non-driver and executor metrics are never prefixed with `spark.app.id`, nor does the `spark.metrics.namespace` property have any such affect on such metrics. Spark's metrics are decoupled into different _instances_ corresponding to Spark components. Within each instance, you can configure a set of sinks to which metrics are reported. The following instances are currently supported: * `master`: The Spark standalone master process. * `applications`: A component within the master which reports on various applications. * `worker`: A Spark standalone worker process. * `executor`: A Spark executor. * `driver`: The Spark driver process (the process in which your SparkContext is created). * `shuffleService`: The Spark shuffle service. * `applicationMaster`: The Spark ApplicationMaster when running on YARN. * `mesos_cluster`: The Spark cluster scheduler when running on Mesos. Each instance can report to zero or more _sinks_. Sinks are contained in the `org.apache.spark.metrics.sink` package: * `ConsoleSink`: Logs metrics information to the console. * `CSVSink`: Exports metrics data to CSV files at regular intervals. * `JmxSink`: Registers metrics for viewing in a JMX console. * `MetricsServlet`: Adds a servlet within the existing Spark UI to serve metrics data as JSON data. * `GraphiteSink`: Sends metrics to a Graphite node. * `Slf4jSink`: Sends metrics to slf4j as log entries. * `StatsdSink`: Sends metrics to a StatsD node. Spark also supports a Ganglia sink which is not included in the default build due to licensing restrictions: * `GangliaSink`: Sends metrics to a Ganglia node or multicast group. To install the `GangliaSink` you'll need to perform a custom build of Spark. _**Note that by embedding this library you will include [LGPL](http://www.gnu.org/copyleft/lesser.html)-licensed code in your Spark package**_. For sbt users, set the `SPARK_GANGLIA_LGPL` environment variable before building. For Maven users, enable the `-Pspark-ganglia-lgpl` profile. In addition to modifying the cluster's Spark build user applications will need to link to the `spark-ganglia-lgpl` artifact. The syntax of the metrics configuration file and the parameters available for each sink are defined in an example configuration file, `$SPARK_HOME/conf/metrics.properties.template`. When using Spark configuration parameters instead of the metrics configuration file, the relevant parameter names are composed by the prefix `spark.metrics.conf.` followed by the configuration details, i.e. the parameters take the following form: `spark.metrics.conf.[instance|*].sink.[sink_name].[parameter_name]`. This example shows a list of Spark configuration parameters for a Graphite sink: ``` "spark.metrics.conf.*.sink.graphite.class"="org.apache.spark.metrics.sink.GraphiteSink" "spark.metrics.conf.*.sink.graphite.host"="graphiteEndPoint_hostName>" "spark.metrics.conf.*.sink.graphite.port"= "spark.metrics.conf.*.sink.graphite.period"=10 "spark.metrics.conf.*.sink.graphite.unit"=seconds "spark.metrics.conf.*.sink.graphite.prefix"="optional_prefix" "spark.metrics.conf.*.sink.graphite.regex"="optional_regex_to_send_matching_metrics" ``` Default values of the Spark metrics configuration are as follows: ``` "*.sink.servlet.class" = "org.apache.spark.metrics.sink.MetricsServlet" "*.sink.servlet.path" = "/metrics/json" "master.sink.servlet.path" = "/metrics/master/json" "applications.sink.servlet.path" = "/metrics/applications/json" ``` Additional sources can be configured using the metrics configuration file or the configuration parameter `spark.metrics.conf.[component_name].source.jvm.class=[source_name]`. At present the JVM source is the only available optional source. For example the following configuration parameter activates the JVM source: `"spark.metrics.conf.*.source.jvm.class"="org.apache.spark.metrics.source.JvmSource"` ## List of available metrics providers Metrics used by Spark are of multiple types: gauge, counter, histogram, meter and timer, see [Dropwizard library documentation for details](https://metrics.dropwizard.io/3.1.0/getting-started/). The following list of components and metrics reports the name and some details about the available metrics, grouped per component instance and source namespace. The most common time of metrics used in Spark instrumentation are gauges and counters. Counters can be recognized as they have the `.count` suffix. Timers, meters and histograms are annotated in the list, the rest of the list elements are metrics of type gauge. The large majority of metrics are active as soon as their parent component instance is configured, some metrics require also to be enabled via an additional configuration parameter, the details are reported in the list. ### Component instance = Driver This is the component with the largest amount of instrumented metrics - namespace=BlockManager - disk.diskSpaceUsed_MB - memory.maxMem_MB - memory.maxOffHeapMem_MB - memory.maxOnHeapMem_MB - memory.memUsed_MB - memory.offHeapMemUsed_MB - memory.onHeapMemUsed_MB - memory.remainingMem_MB - memory.remainingOffHeapMem_MB - memory.remainingOnHeapMem_MB - namespace=HiveExternalCatalog - fileCacheHits.count - filesDiscovered.count - hiveClientCalls.count - parallelListingJobCount.count - partitionsFetched.count - namespace=CodeGenerator - compilationTime (histogram) - generatedClassSize (histogram) - generatedMethodSize (histogram) - hiveClientCalls.count - sourceCodeSize (histogram) - namespace=DAGScheduler - job.activeJobs - job.allJobs - messageProcessingTime (timer) - stage.failedStages - stage.runningStages - stage.waitingStages - namespace=LiveListenerBus - listenerProcessingTime.org.apache.spark.HeartbeatReceiver (timer) - listenerProcessingTime.org.apache.spark.scheduler.EventLoggingListener (timer) - listenerProcessingTime.org.apache.spark.status.AppStatusListener (timer) - numEventsPosted.count - queue.appStatus.listenerProcessingTime (timer) - queue.appStatus.numDroppedEvents.count - queue.appStatus.size - queue.eventLog.listenerProcessingTime (timer) - queue.eventLog.numDroppedEvents.count - queue.eventLog.size - queue.executorManagement.listenerProcessingTime (timer) - namespace=appStatus (all metrics of type=counter) - **note:** Introduced in Spark 3.0. Conditional to configuration parameter: `spark.app.status.metrics.enabled=true` (default is false) - stages.failedStages.count - stages.skippedStages.count - stages.completedStages.count - tasks.blackListedExecutors.count - tasks.completedTasks.count - tasks.failedTasks.count - tasks.killedTasks.count - tasks.skippedTasks.count - tasks.unblackListedExecutors.count - jobs.succeededJobs - jobs.failedJobs - jobDuration - namespace=AccumulatorSource - **note:** User-configurable sources to attach accumulators to metric system - DoubleAccumulatorSource - LongAccumulatorSource - namespace=spark.streaming - **note:** This applies to Spark Structured Streaming only. Conditional to a configuration parameter: `spark.sql.streaming.metricsEnabled=true` (default is false) - eventTime-watermark - inputRate-total - latency - processingRate-total - states-rowsTotal - states-usedBytes - namespace=JVMCPU - jvmCpuTime ### Component instance = Executor These metrics are exposed by Spark executors. Note, currently they are not available when running in local mode. - namespace=executor (metrics are of type counter or gauge) - bytesRead.count - bytesWritten.count - cpuTime.count - deserializeCpuTime.count - deserializeTime.count - diskBytesSpilled.count - filesystem.file.largeRead_ops - filesystem.file.read_bytes - filesystem.file.read_ops - filesystem.file.write_bytes - filesystem.file.write_ops - filesystem.hdfs.largeRead_ops - filesystem.hdfs.read_bytes - filesystem.hdfs.read_ops - filesystem.hdfs.write_bytes - filesystem.hdfs.write_ops - jvmGCTime.count - memoryBytesSpilled.count - recordsRead.count - recordsWritten.count - resultSerializationTime.count - resultSize.count - runTime.count - shuffleBytesWritten.count - shuffleFetchWaitTime.count - shuffleLocalBlocksFetched.count - shuffleLocalBytesRead.count - shuffleRecordsRead.count - shuffleRecordsWritten.count - shuffleRemoteBlocksFetched.count - shuffleRemoteBytesRead.count - shuffleRemoteBytesReadToDisk.count - shuffleTotalBytesRead.count - shuffleWriteTime.count - succeededTasks.count - threadpool.activeTasks - threadpool.completeTasks - threadpool.currentPool_size - threadpool.maxPool_size - threadpool.startedTasks - namespace=JVMCPU - jvmCpuTime - namespace=NettyBlockTransfer - shuffle-client.usedDirectMemory - shuffle-client.usedHeapMemory - shuffle-server.usedDirectMemory - shuffle-server.usedHeapMemory - namespace=HiveExternalCatalog - fileCacheHits.count - filesDiscovered.count - hiveClientCalls.count - parallelListingJobCount.count - partitionsFetched.count - namespace=CodeGenerator - compilationTime (histogram) - generatedClassSize (histogram) - generatedMethodSize (histogram) - hiveClientCalls.count - sourceCodeSize (histogram) ### Source = JVM Source Notes: - Activate this source by setting the relevant `metrics.properties` file entry or the configuration parameter:`spark.metrics.conf.*.source.jvm.class=org.apache.spark.metrics.source.JvmSource` - This source is available for driver and executor instances and is also available for other instances. - This source provides information on JVM metrics using the [Dropwizard/Codahale Metric Sets for JVM instrumentation](https://metrics.dropwizard.io/3.1.0/manual/jvm/) and in particular the metric sets BufferPoolMetricSet, GarbageCollectorMetricSet and MemoryUsageGaugeSet. ### Component instance = applicationMaster Note: applies when running on YARN - numContainersPendingAllocate - numExecutorsFailed - numExecutorsRunning - numLocalityAwareTasks - numReleasedContainers ### Component instance = mesos_cluster Note: applies when running on mesos - waitingDrivers - launchedDrivers - retryDrivers ### Component instance = master Note: applies when running in Spark standalone as master - workers - aliveWorkers - apps - waitingApps ### Component instance = ApplicationSource Note: applies when running in Spark standalone as master - status - runtime_ms - cores ### Component instance = worker Note: applies when running in Spark standalone as worker - executors - coresUsed - memUsed_MB - coresFree - memFree_MB ### Component instance = shuffleService Note: applies to the shuffle service - blockTransferRateBytes (meter) - numActiveConnections.count - numRegisteredConnections.count - numCaughtExceptions.count - openBlockRequestLatencyMillis (histogram) - registerExecutorRequestLatencyMillis (histogram) - registeredExecutorsSize - shuffle-server.usedDirectMemory - shuffle-server.usedHeapMemory # Advanced Instrumentation Several external tools can be used to help profile the performance of Spark jobs: * Cluster-wide monitoring tools, such as [Ganglia](http://ganglia.sourceforge.net/), can provide insight into overall cluster utilization and resource bottlenecks. For instance, a Ganglia dashboard can quickly reveal whether a particular workload is disk bound, network bound, or CPU bound. * OS profiling tools such as [dstat](http://dag.wieers.com/home-made/dstat/), [iostat](http://linux.die.net/man/1/iostat), and [iotop](http://linux.die.net/man/1/iotop) can provide fine-grained profiling on individual nodes. * JVM utilities such as `jstack` for providing stack traces, `jmap` for creating heap-dumps, `jstat` for reporting time-series statistics and `jconsole` for visually exploring various JVM properties are useful for those comfortable with JVM internals.