Spring Cloud Bus links the nodes of a distributed system with a lightweight message broker. This broker can then be used to broadcast state changes (such as configuration changes) or other management instructions. A key idea is that the bus is like a distributed actuator for a Spring Boot application that is scaled out. However, it can also be used as a communication channel between apps. This project provides starters for either an AMQP broker or Kafka as the transport.
Spring Cloud is released under the non-restrictive Apache 2.0 license. If you would like to contribute to this section of the documentation or if you find an error, please find the source code and issue trackers in the project at {docslink}[github]. |
1. Quick Start
Spring Cloud Bus works by adding Spring Boot autconfiguration if it detects itself on the
classpath. To enable the bus, add spring-cloud-starter-bus-amqp
or
spring-cloud-starter-bus-kafka
to your dependency management. Spring Cloud takes care of
the rest. Make sure the broker (RabbitMQ or Kafka) is available and configured. When
running on localhost, you need not do anything. If you run remotely, use Spring Cloud
Connectors or Spring Boot conventions to define the broker credentials, as shown in the
following example for Rabbit:
spring: rabbitmq: host: mybroker.com port: 5672 username: user password: secret
The bus currently supports sending messages to all nodes listening or all nodes for a
particular service (as defined by Eureka). The /bus/*
actuator namespace has some HTTP
endpoints. Currently, two are implemented. The first, /bus/env
, sends key/value pairs to
update each node’s Spring Environment. The second, /bus/refresh
, reloads each
application’s configuration, as though they had all been pinged on their /refresh
endpoint.
The Spring Cloud Bus starters cover Rabbit and Kafka, because those are the two most
common implementations. However, Spring Cloud Stream is quite flexible, and the binder
works with spring-cloud-bus .
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2. Bus Endpoints
Spring Cloud Bus provides two endpoints, /actuator/bus-refresh
and /actuator/bus-env
that correspond to individual actuator endpoints in Spring Cloud Commons,
/actuator/refresh
and /actuator/env
respectively.
2.1. Bus Refresh Endpoint
The /actuator/bus-refresh
endpoint clears the RefreshScope
cache and rebinds
@ConfigurationProperties
. See the Refresh Scope documentation for
more information.
To expose the /actuator/bus-refresh
endpoint, you need to add following configuration to your
application:
management.endpoints.web.exposure.include=bus-refresh
2.2. Bus Env Endpoint
The /actuator/bus-env
endpoint updates each instances environment with the specified
key/value pair across multiple instances.
To expose the /actuator/bus-env
endpoint, you need to add following configuration to your
application:
management.endpoints.web.exposure.include=bus-env
The /actuator/bus-env
endpoint accepts POST
requests with the following shape:
{
"name": "key1",
"value": "value1"
}
3. Addressing an Instance
Each instance of the application has a service ID, whose value can be set with
spring.cloud.bus.id
and whose value is expected to be a colon-separated list of
identifiers, in order from least specific to most specific. The default value is
constructed from the environment as a combination of the spring.application.name
and
server.port
(or spring.application.index
, if set). The default value of the ID is
constructed in the form of app:index:id
, where:
-
app
is thevcap.application.name
, if it exists, orspring.application.name
-
index
is thevcap.application.instance_index
, if it exists,spring.application.index
,local.server.port
,server.port
, or0
(in that order). -
id
is thevcap.application.instance_id
, if it exists, or a random value.
The HTTP endpoints accept a “destination” path parameter, such as
/bus-refresh/customers:9000
, where destination
is a service ID. If the ID
is owned by an instance on the bus, it processes the message, and all other instances
ignore it.
4. Addressing All Instances of a Service
The “destination” parameter is used in a Spring PathMatcher
(with the path separator
as a colon — :
) to determine if an instance processes the message. Using the example
from earlier, /bus-env/customers:**
targets all instances of the
“customers” service regardless of the rest of the service ID.
5. Service ID Must Be Unique
The bus tries twice to eliminate processing an event — once from the original
ApplicationEvent
and once from the queue. To do so, it checks the sending service ID
against the current service ID. If multiple instances of a service have the same ID,
events are not processed. When running on a local machine, each service is on a different
port, and that port is part of the ID. Cloud Foundry supplies an index to differentiate.
To ensure that the ID is unique outside Cloud Foundry, set spring.application.index
to
something unique for each instance of a service.
6. Customizing the Message Broker
Spring Cloud Bus uses Spring Cloud Stream to
broadcast the messages. So, to get messages to flow, you need only include the binder
implementation of your choice in the classpath. There are convenient starters for the bus
with AMQP (RabbitMQ) and Kafka (spring-cloud-starter-bus-[amqp|kafka]
). Generally
speaking, Spring Cloud Stream relies on Spring Boot autoconfiguration conventions for
configuring middleware. For instance, the AMQP broker address can be changed with
spring.rabbitmq.*
configuration properties. Spring Cloud Bus has a handful of
native configuration properties in spring.cloud.bus.*
(for example,
spring.cloud.bus.destination
is the name of the topic to use as the external
middleware). Normally, the defaults suffice.
To learn more about how to customize the message broker settings, consult the Spring Cloud Stream documentation.
7. Tracing Bus Events
Bus events (subclasses of RemoteApplicationEvent
) can be traced by setting
spring.cloud.bus.trace.enabled=true
. If you do so, the Spring Boot TraceRepository
(if it is present) shows each event sent and all the acks from each service instance. The
following example comes from the /trace
endpoint:
{
"timestamp": "2015-11-26T10:24:44.411+0000",
"info": {
"signal": "spring.cloud.bus.ack",
"type": "RefreshRemoteApplicationEvent",
"id": "c4d374b7-58ea-4928-a312-31984def293b",
"origin": "stores:8081",
"destination": "*:**"
}
},
{
"timestamp": "2015-11-26T10:24:41.864+0000",
"info": {
"signal": "spring.cloud.bus.sent",
"type": "RefreshRemoteApplicationEvent",
"id": "c4d374b7-58ea-4928-a312-31984def293b",
"origin": "customers:9000",
"destination": "*:**"
}
},
{
"timestamp": "2015-11-26T10:24:41.862+0000",
"info": {
"signal": "spring.cloud.bus.ack",
"type": "RefreshRemoteApplicationEvent",
"id": "c4d374b7-58ea-4928-a312-31984def293b",
"origin": "customers:9000",
"destination": "*:**"
}
}
The preceding trace shows that a RefreshRemoteApplicationEvent
was sent from
customers:9000
, broadcast to all services, and received (acked) by customers:9000
and
stores:8081
.
To handle the ack signals yourself, you could add an @EventListener
for the
AckRemoteApplicationEvent
and SentApplicationEvent
types to your app (and enable
tracing). Alternatively, you could tap into the TraceRepository
and mine the data from
there.
Any Bus application can trace acks. However, sometimes, it is useful to do this in a central service that can do more complex queries on the data or forward it to a specialized tracing service. |
8. Broadcasting Your Own Events
The Bus can carry any event of type RemoteApplicationEvent
. The default transport is
JSON, and the deserializer needs to know which types are going to be used ahead of time.
To register a new type, you must put it in a subpackage of
org.springframework.cloud.bus.event
.
To customise the event name, you can use @JsonTypeName
on your custom class or rely on
the default strategy, which is to use the simple name of the class.
Both the producer and the consumer need access to the class definition. |
8.1. Registering events in custom packages
If you cannot or do not want to use a subpackage of org.springframework.cloud.bus.event
for your custom events, you must specify which packages to scan for events of type
RemoteApplicationEvent
by using the @RemoteApplicationEventScan
annotation. Packages
specified with @RemoteApplicationEventScan
include subpackages.
For example, consider the following custom event, called MyEvent
:
package com.acme;
public class MyEvent extends RemoteApplicationEvent {
...
}
You can register that event with the deserializer in the following way:
package com.acme;
@Configuration
@RemoteApplicationEventScan
public class BusConfiguration {
...
}
Without specifying a value, the package of the class where @RemoteApplicationEventScan
is used is registered. In this example, com.acme
is registered by using the package of
BusConfiguration
.
You can also explicitly specify the packages to scan by using the value
, basePackages
or basePackageClasses
properties on @RemoteApplicationEventScan
, as shown in the
following example:
package com.acme;
@Configuration
//@RemoteApplicationEventScan({"com.acme", "foo.bar"})
//@RemoteApplicationEventScan(basePackages = {"com.acme", "foo.bar", "fizz.buzz"})
@RemoteApplicationEventScan(basePackageClasses = BusConfiguration.class)
public class BusConfiguration {
...
}
All of the preceding examples of @RemoteApplicationEventScan
are equivalent, in that the
com.acme
package is registered by explicitly specifying the packages on
@RemoteApplicationEventScan
.
You can specify multiple base packages to scan. |
9. Configuration properties
To see the list of all Bus related configuration properties please check the Appendix page.