Spring Boot Actuator includes a metrics service with ‘gauge’ and ‘counter’ support.
A ‘gauge’ records a single value; and a ‘counter’ records a delta (an increment or
decrement). Spring Boot Actuator also provides a
PublicMetrics interface that
you can implement to expose metrics that you cannot record via one of those two
mechanisms. Look at SystemPublicMetrics
for an example.
Metrics for all HTTP requests are automatically recorded, so if you hit the metrics
endpoint you should see a response similar to this:
{ "counter.status.200.root": 20, "counter.status.200.metrics": 3, "counter.status.200.star-star": 5, "counter.status.401.root": 4, "gauge.response.star-star": 6, "gauge.response.root": 2, "gauge.response.metrics": 3, "classes": 5808, "classes.loaded": 5808, "classes.unloaded": 0, "heap": 3728384, "heap.committed": 986624, "heap.init": 262144, "heap.used": 52765, "mem": 986624, "mem.free": 933858, "processors": 8, "threads": 15, "threads.daemon": 11, "threads.peak": 15, "uptime": 494836, "instance.uptime": 489782, "datasource.primary.active": 5, "datasource.primary.usage": 0.25 }
Here we can see basic memory, heap, class loading, processor and thread pool
information along with some HTTP metrics. In this instance the root (‘/’) and /metrics
URLs have returned HTTP 200 responses 20 and 3 times respectively. It also appears
that the root URL returned HTTP 401 (unauthorized) 4 times. The double asterix (star-star)
comes from a request matched by Spring MVC as /** (normally a static resource).
The gauge shows the last response time for a request. So the last request to root took
2ms to respond and the last to /metrics took 3ms.
![[Note]](images/note.png) | Note |
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In this example we are actually accessing the endpoint over HTTP using the
|
The following system metrics are exposed by Spring Boot:
- The total system memory in KB (
mem) - The amount of free memory in KB (
mem.free) - The number of processors (
processors) - The system uptime in milliseconds (
uptime) - The application context uptime in milliseconds (
instance.uptime) - The average system load (
systemload.average) - Heap information in KB (
heap,heap.committed,heap.init,heap.used) - Thread information (
threads,thread.peak,thead.daemon) - Class load information (
classes,classes.loaded,classes.unloaded) - Garbage collection information (
gc.xxx.count,gc.xxx.time)
The following metrics are exposed for each supported DataSource defined in your
application:
- The number of active connections (
datasource.xxx.active) - The current usage of the connection pool (
datasource.xxx.usage).
All data source metrics share the datasource. prefix. The prefix is further qualified
for each data source:
- If the data source is the primary data source (that is either the only available data
source or the one flagged
@Primaryamongst the existing ones), the prefix isdatasource.primary. - If the data source bean name ends with
DataSource, the prefix is the name of the bean withoutDataSource(i.e.datasource.batchforbatchDataSource). - In all other cases, the name of the bean is used.
It is possible to override part or all of those defaults by registering a bean with a
customized version of DataSourcePublicMetrics. By default, Spring Boot provides metadata
for all supported data sources; you can add additional DataSourcePoolMetadataProvider
beans if your favorite data source isn’t supported out of the box. See
DataSourcePoolMetadataProvidersConfiguration for examples.
If you are using Tomcat as your embedded servlet container, session metrics will
automatically be exposed. The httpsessions.active and httpsessions.max keys provide
the number of active and maximum sessions.
To record your own metrics inject a
CounterService and/or
GaugeService into
your bean. The CounterService exposes increment, decrement and reset methods; the
GaugeService provides a submit method.
Here is a simple example that counts the number of times that a method is invoked:
import org.springframework.beans.factory.annotation.Autowired; import org.springframework.boot.actuate.metrics.CounterService; import org.springframework.stereotype.Service; @Service public class MyService { private final CounterService counterService; @Autowired public MyService(CounterService counterService) { this.counterService = counterService; } public void exampleMethod() { this.counterService.increment("services.system.myservice.invoked"); } }
![[Tip]](images/tip.png) | Tip |
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You can use any string as a metric name but you should follow guidelines of your chosen store/graphing technology. Some good guidelines for Graphite are available on Matt Aimonetti’s Blog. |
To add additional metrics that are computed every time the metrics endpoint is invoked,
simply register additional PublicMetrics implementation bean(s). By default, all such
beans are gathered by the endpoint. You can easily change that by defining your own
MetricsEndpoint.
Metric service implementations are usually bound to a
MetricRepository.
A MetricRepository is responsible for storing and retrieving metric information. Spring
Boot provides an InMemoryMetricRepository and a RedisMetricRepository out of the
box (the in-memory repository is the default) but you can also write your own. The
MetricRepository interface is actually composed of higher level MetricReader and
MetricWriter interfaces. For full details refer to the
Javadoc.
There’s nothing to stop you hooking a MetricRepository with back-end storage directly
into your app, but we recommend using the default InMemoryMetricRepository
(possibly with a custom Map instance if you are worried about heap usage) and
populating a back-end repository through a scheduled export job. In that way you get
some buffering in memory of the metric values and you can reduce the network
chatter by exporting less frequently or in batches. Spring Boot provides
an Exporter interface and a few basic implementations for you to get started with that.
User of the Dropwizard ‘Metrics’ library will
automatically find that Spring Boot metrics are published to
com.codahale.metrics.MetricRegistry. A default com.codahale.metrics.MetricRegistry
Spring bean will be created when you declare a dependency to the
io.dropwizard.metrics:metrics-core library; you can also register you own @Bean
instance if you need customizations. Metrics from the MetricRegistry are also
automatically exposed via the /metrics endpoint.
Users can create Dropwizard metrics by prefixing their metric names with the appropriate
type (e.g. histogram.*, meter.*).
If the ‘Spring Messaging’ jar is on your classpath a MessageChannel called
metricsChannel is automatically created (unless one already exists). All metric update
events are additionally published as ‘messages’ on that channel. Additional analysis or
actions can be taken by clients subscribing to that channel.