Spring features integration classes for remoting support using various technologies. The remoting support eases the development of remote-enabled services, implemented by your usual (Spring) POJOs. Currently, Spring supports the following remoting technologies:
RmiProxyFactoryBean
and
the RmiServiceExporter
Spring supports both traditional RMI (with java.rmi.Remote
interfaces and java.rmi.RemoteException
) and transparent remoting via RMI invokers
(with any Java interface).
HttpInvokerProxyFactoryBean
and
HttpInvokerServiceExporter
.
HessianProxyFactoryBean
and the
HessianServiceExporter
you can transparently expose your services using the
lightweight binary HTTP-based protocol provided by Caucho.
BurlapProxyFactoryBean
and BurlapServiceExporter
.
JmsInvokerServiceExporter
and JmsInvokerProxyFactoryBean
classes.
While discussing the remoting capabilities of Spring, we’ll use the following domain model and corresponding services:
public class Account implements Serializable{ private String name; public String getName(){ return name; } public void setName(String name) { this.name = name; } }
public interface AccountService { public void insertAccount(Account account); public List<Account> getAccounts(String name); }
public interface RemoteAccountService extends Remote { public void insertAccount(Account account) throws RemoteException; public List<Account> getAccounts(String name) throws RemoteException; }
// the implementation doing nothing at the moment public class AccountServiceImpl implements AccountService { public void insertAccount(Account acc) { // do something... } public List<Account> getAccounts(String name) { // do something... } }
We will start exposing the service to a remote client by using RMI and talk a bit about the drawbacks of using RMI. We’ll then continue to show an example using Hessian as the protocol.
Using Spring’s support for RMI, you can transparently expose your services through the RMI infrastructure. After having this set up, you basically have a configuration similar to remote EJBs, except for the fact that there is no standard support for security context propagation or remote transaction propagation. Spring does provide hooks for such additional invocation context when using the RMI invoker, so you can for example plug in security frameworks or custom security credentials here.
Using the RmiServiceExporter
, we can expose the interface of our AccountService object
as RMI object. The interface can be accessed by using RmiProxyFactoryBean
, or via
plain RMI in case of a traditional RMI service. The RmiServiceExporter
explicitly
supports the exposing of any non-RMI services via RMI invokers.
Of course, we first have to set up our service in the Spring container:
<bean id="accountService" class="example.AccountServiceImpl"> <!-- any additional properties, maybe a DAO? --> </bean>
Next we’ll have to expose our service using the RmiServiceExporter
:
<bean class="org.springframework.remoting.rmi.RmiServiceExporter"> <!-- does not necessarily have to be the same name as the bean to be exported --> <property name="serviceName" value="AccountService"/> <property name="service" ref="accountService"/> <property name="serviceInterface" value="example.AccountService"/> <!-- defaults to 1099 --> <property name="registryPort" value="1199"/> </bean>
As you can see, we’re overriding the port for the RMI registry. Often, your application
server also maintains an RMI registry and it is wise to not interfere with that one.
Furthermore, the service name is used to bind the service under. So right now, the
service will be bound at 'rmi://HOST:1199/AccountService'
. We’ll use the URL later on
to link in the service at the client side.
Note | |
---|---|
The |
Our client is a simple object using the AccountService
to manage accounts:
public class SimpleObject { private AccountService accountService; public void setAccountService(AccountService accountService) { this.accountService = accountService; } // additional methods using the accountService }
To link in the service on the client, we’ll create a separate Spring container, containing the simple object and the service linking configuration bits:
<bean class="example.SimpleObject"> <property name="accountService" ref="accountService"/> </bean> <bean id="accountService" class="org.springframework.remoting.rmi.RmiProxyFactoryBean"> <property name="serviceUrl" value="rmi://HOST:1199/AccountService"/> <property name="serviceInterface" value="example.AccountService"/> </bean>
That’s all we need to do to support the remote account service on the client. Spring
will transparently create an invoker and remotely enable the account service through the
RmiServiceExporter
. At the client we’re linking it in using the RmiProxyFactoryBean
.
Hessian offers a binary HTTP-based remoting protocol. It is developed by Caucho and more information about Hessian itself can be found at http://www.caucho.com.
Hessian communicates via HTTP and does so using a custom servlet. Using Spring’s
DispatcherServlet
principles, as known from Spring Web MVC usage, you can easily wire
up such a servlet exposing your services. First we’ll have to create a new servlet in
your application (this is an excerpt from 'web.xml'
):
<servlet> <servlet-name>remoting</servlet-name> <servlet-class>org.springframework.web.servlet.DispatcherServlet</servlet-class> <load-on-startup>1</load-on-startup> </servlet> <servlet-mapping> <servlet-name>remoting</servlet-name> <url-pattern>/remoting/*</url-pattern> </servlet-mapping>
You’re probably familiar with Spring’s DispatcherServlet
principles and if so, you
know that now you’ll have to create a Spring container configuration resource named
'remoting-servlet.xml'
(after the name of your servlet) in the 'WEB-INF'
directory.
The application context will be used in the next section.
Alternatively, consider the use of Spring’s simpler HttpRequestHandlerServlet
. This
allows you to embed the remote exporter definitions in your root application context (by
default in 'WEB-INF/applicationContext.xml'
), with individual servlet definitions
pointing to specific exporter beans. Each servlet name needs to match the bean name of
its target exporter in this case.
In the newly created application context called remoting-servlet.xml
, we’ll create a
HessianServiceExporter
exporting your services:
<bean id="accountService" class="example.AccountServiceImpl"> <!-- any additional properties, maybe a DAO? --> </bean> <bean name="/AccountService" class="org.springframework.remoting.caucho.HessianServiceExporter"> <property name="service" ref="accountService"/> <property name="serviceInterface" value="example.AccountService"/> </bean>
Now we’re ready to link in the service at the client. No explicit handler mapping is
specified, mapping request URLs onto services, so BeanNameUrlHandlerMapping
will be
used: Hence, the service will be exported at the URL indicated through its bean name
within the containing DispatcherServlet
's mapping (as defined above):
'http://HOST:8080/remoting/AccountService'
.
Alternatively, create a HessianServiceExporter
in your root application context (e.g.
in 'WEB-INF/applicationContext.xml'
):
<bean name="accountExporter" class="org.springframework.remoting.caucho.HessianServiceExporter"> <property name="service" ref="accountService"/> <property name="serviceInterface" value="example.AccountService"/> </bean>
In the latter case, define a corresponding servlet for this exporter in 'web.xml'
,
with the same end result: The exporter getting mapped to the request path
/remoting/AccountService
. Note that the servlet name needs to match the bean name of
the target exporter.
<servlet> <servlet-name>accountExporter</servlet-name> <servlet-class>org.springframework.web.context.support.HttpRequestHandlerServlet</servlet-class> </servlet> <servlet-mapping> <servlet-name>accountExporter</servlet-name> <url-pattern>/remoting/AccountService</url-pattern> </servlet-mapping>
Using the HessianProxyFactoryBean
we can link in the service at the client. The same
principles apply as with the RMI example. We’ll create a separate bean factory or
application context and mention the following beans where the SimpleObject
is using
the AccountService
to manage accounts:
<bean class="example.SimpleObject"> <property name="accountService" ref="accountService"/> </bean> <bean id="accountService" class="org.springframework.remoting.caucho.HessianProxyFactoryBean"> <property name="serviceUrl" value="http://remotehost:8080/remoting/AccountService"/> <property name="serviceInterface" value="example.AccountService"/> </bean>
We won’t discuss Burlap, the XML-based equivalent of Hessian, in detail here, since it
is configured and set up in exactly the same way as the Hessian variant explained above.
Just replace the word Hessian
with Burlap
and you’re all set to go.
One of the advantages of Hessian and Burlap is that we can easily apply HTTP basic
authentication, because both protocols are HTTP-based. Your normal HTTP server security
mechanism can easily be applied through using the web.xml
security features, for
example. Usually, you don’t use per-user security credentials here, but rather shared
credentials defined at the Hessian/BurlapProxyFactoryBean
level (similar to a JDBC
DataSource
).
<bean class="org.springframework.web.servlet.handler.BeanNameUrlHandlerMapping"> <property name="interceptors" ref="authorizationInterceptor"/> </bean> <bean id="authorizationInterceptor" class="org.springframework.web.servlet.handler.UserRoleAuthorizationInterceptor"> <property name="authorizedRoles" value="administrator,operator"/> </bean>
This is an example where we explicitly mention the BeanNameUrlHandlerMapping
and set
an interceptor allowing only administrators and operators to call the beans mentioned in
this application context.
Note | |
---|---|
Of course, this example doesn’t show a flexible kind of security infrastructure. For more options as far as security is concerned, have a look at the Spring Security project at http://projects.spring.io/spring-security/. |
As opposed to Burlap and Hessian, which are both lightweight protocols using their own slim serialization mechanisms, Spring HTTP invokers use the standard Java serialization mechanism to expose services through HTTP. This has a huge advantage if your arguments and return types are complex types that cannot be serialized using the serialization mechanisms Hessian and Burlap use (refer to the next section for more considerations when choosing a remoting technology).
Under the hood, Spring uses either the standard facilities provided by the JDK or
Apache HttpComponents
to perform HTTP calls. Use the latter if you need more
advanced and easier-to-use functionality. Refer to
hc.apache.org/httpcomponents-client-ga/
for more information.
Setting up the HTTP invoker infrastructure for a service object resembles closely the
way you would do the same using Hessian or Burlap. Just as Hessian support provides the
HessianServiceExporter
, Spring’s HttpInvoker support provides the
org.springframework.remoting.httpinvoker.HttpInvokerServiceExporter
.
To expose the AccountService
(mentioned above) within a Spring Web MVC
DispatcherServlet
, the following configuration needs to be in place in the
dispatcher’s application context:
<bean name="/AccountService" class="org.springframework.remoting.httpinvoker.HttpInvokerServiceExporter"> <property name="service" ref="accountService"/> <property name="serviceInterface" value="example.AccountService"/> </bean>
Such an exporter definition will be exposed through the DispatcherServlet
's standard
mapping facilities, as explained in the section on Hessian.
Alternatively, create an HttpInvokerServiceExporter
in your root application context
(e.g. in 'WEB-INF/applicationContext.xml'
):
<bean name="accountExporter" class="org.springframework.remoting.httpinvoker.HttpInvokerServiceExporter"> <property name="service" ref="accountService"/> <property name="serviceInterface" value="example.AccountService"/> </bean>
In addition, define a corresponding servlet for this exporter in 'web.xml'
, with the
servlet name matching the bean name of the target exporter:
<servlet> <servlet-name>accountExporter</servlet-name> <servlet-class>org.springframework.web.context.support.HttpRequestHandlerServlet</servlet-class> </servlet> <servlet-mapping> <servlet-name>accountExporter</servlet-name> <url-pattern>/remoting/AccountService</url-pattern> </servlet-mapping>
If you are running outside of a servlet container and are using Oracle’s Java 6, then you
can use the built-in HTTP server implementation. You can configure the
SimpleHttpServerFactoryBean
together with a SimpleHttpInvokerServiceExporter
as is
shown in this example:
<bean name="accountExporter" class="org.springframework.remoting.httpinvoker.SimpleHttpInvokerServiceExporter"> <property name="service" ref="accountService"/> <property name="serviceInterface" value="example.AccountService"/> </bean> <bean id="httpServer" class="org.springframework.remoting.support.SimpleHttpServerFactoryBean"> <property name="contexts"> <util:map> <entry key="/remoting/AccountService" value-ref="accountExporter"/> </util:map> </property> <property name="port" value="8080" /> </bean>
Again, linking in the service from the client much resembles the way you would do it when using Hessian or Burlap. Using a proxy, Spring will be able to translate your calls to HTTP POST requests to the URL pointing to the exported service.
<bean id="httpInvokerProxy" class="org.springframework.remoting.httpinvoker.HttpInvokerProxyFactoryBean"> <property name="serviceUrl" value="http://remotehost:8080/remoting/AccountService"/> <property name="serviceInterface" value="example.AccountService"/> </bean>
As mentioned before, you can choose what HTTP client you want to use. By default, the
HttpInvokerProxy
uses the JDK’s HTTP functionality, but you can also use the Apache
HttpComponents
client by setting the httpInvokerRequestExecutor
property:
<property name="httpInvokerRequestExecutor"> <bean class="org.springframework.remoting.httpinvoker.HttpComponentsHttpInvokerRequestExecutor"/> </property>
Spring provides full support for standard Java web services APIs:
In addition to stock support for JAX-WS in Spring Core, the Spring portfolio also features Spring Web Services, a solution for contract-first, document-driven web services - highly recommended for building modern, future-proof web services.
Spring provides a convenient base class for JAX-WS servlet endpoint implementations -
SpringBeanAutowiringSupport
. To expose our AccountService
we extend Spring’s
SpringBeanAutowiringSupport
class and implement our business logic here, usually
delegating the call to the business layer. We’ll simply use Spring’s @Autowired
annotation for expressing such dependencies on Spring-managed beans.
/** * JAX-WS compliant AccountService implementation that simply delegates * to the AccountService implementation in the root web application context. * * This wrapper class is necessary because JAX-WS requires working with dedicated * endpoint classes. If an existing service needs to be exported, a wrapper that * extends SpringBeanAutowiringSupport for simple Spring bean autowiring (through * the @Autowired annotation) is the simplest JAX-WS compliant way. * * This is the class registered with the server-side JAX-WS implementation. * In the case of a Java EE 5 server, this would simply be defined as a servlet * in web.xml, with the server detecting that this is a JAX-WS endpoint and reacting * accordingly. The servlet name usually needs to match the specified WS service name. * * The web service engine manages the lifecycle of instances of this class. * Spring bean references will just be wired in here. */ import org.springframework.web.context.support.SpringBeanAutowiringSupport; @WebService(serviceName="AccountService") public class AccountServiceEndpoint extends SpringBeanAutowiringSupport { @Autowired private AccountService biz; @WebMethod public void insertAccount(Account acc) { biz.insertAccount(acc); } @WebMethod public Account[] getAccounts(String name) { return biz.getAccounts(name); } }
Our AccountServletEndpoint
needs to run in the same web application as the Spring
context to allow for access to Spring’s facilities. This is the case by default in Java
EE 5 environments, using the standard contract for JAX-WS servlet endpoint deployment.
See Java EE 5 web service tutorials for details.
The built-in JAX-WS provider that comes with Oracle’s JDK 1.6 supports exposure of web
services using the built-in HTTP server that’s included in JDK 1.6 as well. Spring’s
SimpleJaxWsServiceExporter
detects all @WebService
annotated beans in the Spring
application context, exporting them through the default JAX-WS server (the JDK 1.6 HTTP
server).
In this scenario, the endpoint instances are defined and managed as Spring beans
themselves; they will be registered with the JAX-WS engine but their lifecycle will be
up to the Spring application context. This means that Spring functionality like explicit
dependency injection may be applied to the endpoint instances. Of course,
annotation-driven injection through @Autowired
will work as well.
<bean class="org.springframework.remoting.jaxws.SimpleJaxWsServiceExporter"> <property name="baseAddress" value="http://localhost:8080/"/> </bean> <bean id="accountServiceEndpoint" class="example.AccountServiceEndpoint"> ... </bean> ...
The AccountServiceEndpoint
may derive from Spring’s SpringBeanAutowiringSupport
but
doesn’t have to since the endpoint is a fully Spring-managed bean here. This means that
the endpoint implementation may look like as follows, without any superclass declared -
and Spring’s @Autowired
configuration annotation still being honored:
@WebService(serviceName="AccountService") public class AccountServiceEndpoint { @Autowired private AccountService biz; @WebMethod public void insertAccount(Account acc) { biz.insertAccount(acc); } @WebMethod public List<Account> getAccounts(String name) { return biz.getAccounts(name); } }
Oracle’s JAX-WS RI, developed as part of the GlassFish project, ships Spring support as part of its JAX-WS Commons project. This allows for defining JAX-WS endpoints as Spring-managed beans, similar to the standalone mode discussed in the previous section - but this time in a Servlet environment. Note that this is not portable in a Java EE 5 environment; it is mainly intended for non-EE environments such as Tomcat, embedding the JAX-WS RI as part of the web application.
The difference to the standard style of exporting servlet-based endpoints is that the
lifecycle of the endpoint instances themselves will be managed by Spring here, and that
there will be only one JAX-WS servlet defined in web.xml
. With the standard Java EE 5
style (as illustrated above), you’ll have one servlet definition per service endpoint,
with each endpoint typically delegating to Spring beans (through the use of
@Autowired
, as shown above).
Check out https://jax-ws-commons.java.net/spring/ for details on setup and usage style.
Spring provides two factory beans to create JAX-WS web service proxies, namely
LocalJaxWsServiceFactoryBean
and JaxWsPortProxyFactoryBean
. The former can only
return a JAX-WS service class for us to work with. The latter is the full-fledged
version that can return a proxy that implements our business service interface. In this
example we use the latter to create a proxy for the AccountService
endpoint (again):
<bean id="accountWebService" class="org.springframework.remoting.jaxws.JaxWsPortProxyFactoryBean"> <property name="serviceInterface" value="example.AccountService"/> <property name="wsdlDocumentUrl" value="http://localhost:8888/AccountServiceEndpoint?WSDL"/> <property name="namespaceUri" value="http://example/"/> <property name="serviceName" value="AccountService"/> <property name="portName" value="AccountServiceEndpointPort"/> </bean>
Where serviceInterface
is our business interface the clients will use.
wsdlDocumentUrl
is the URL for the WSDL file. Spring needs this a startup time to
create the JAX-WS Service. namespaceUri
corresponds to the targetNamespace in the
.wsdl file. serviceName
corresponds to the service name in the .wsdl file. portName
corresponds to the port name in the .wsdl file.
Accessing the web service is now very easy as we have a bean factory for it that will
expose it as AccountService
interface. We can wire this up in Spring:
<bean id="client" class="example.AccountClientImpl"> ... <property name="service" ref="accountWebService"/> </bean>
From the client code we can access the web service just as if it was a normal class:
public class AccountClientImpl { private AccountService service; public void setService(AccountService service) { this.service = service; } public void foo() { service.insertAccount(...); } }
Note | |
---|---|
The above is slightly simplified in that JAX-WS requires endpoint interfaces
and implementation classes to be annotated with |
It is also possible to expose services transparently using JMS as the underlying
communication protocol. The JMS remoting support in the Spring Framework is pretty basic
- it sends and receives on the same thread
and in the same non-transactional
Session
, and as such throughput will be very implementation dependent. Note that these
single-threaded and non-transactional constraints apply only to Spring’s JMS
remoting support. See Chapter 23, JMS (Java Message Service) for information on Spring’s rich support for JMS-based
messaging.
The following interface is used on both the server and the client side.
package com.foo; public interface CheckingAccountService { public void cancelAccount(Long accountId); }
The following simple implementation of the above interface is used on the server-side.
package com.foo; public class SimpleCheckingAccountService implements CheckingAccountService { public void cancelAccount(Long accountId) { System.out.println("Cancelling account [" + accountId + "]"); } }
This configuration file contains the JMS-infrastructure beans that are shared on both the client and server.
<?xml version="1.0" encoding="UTF-8"?> <beans xmlns="http://www.springframework.org/schema/beans" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xsi:schemaLocation="http://www.springframework.org/schema/beans http://www.springframework.org/schema/beans/spring-beans.xsd"> <bean id="connectionFactory" class="org.apache.activemq.ActiveMQConnectionFactory"> <property name="brokerURL" value="tcp://ep-t43:61616"/> </bean> <bean id="queue" class="org.apache.activemq.command.ActiveMQQueue"> <constructor-arg value="mmm"/> </bean> </beans>
On the server, you just need to expose the service object using the
JmsInvokerServiceExporter
.
<?xml version="1.0" encoding="UTF-8"?> <beans xmlns="http://www.springframework.org/schema/beans" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xsi:schemaLocation="http://www.springframework.org/schema/beans http://www.springframework.org/schema/beans/spring-beans.xsd"> <bean id="checkingAccountService" class="org.springframework.jms.remoting.JmsInvokerServiceExporter"> <property name="serviceInterface" value="com.foo.CheckingAccountService"/> <property name="service"> <bean class="com.foo.SimpleCheckingAccountService"/> </property> </bean> <bean class="org.springframework.jms.listener.SimpleMessageListenerContainer"> <property name="connectionFactory" ref="connectionFactory"/> <property name="destination" ref="queue"/> <property name="concurrentConsumers" value="3"/> <property name="messageListener" ref="checkingAccountService"/> </bean> </beans>
package com.foo; import org.springframework.context.support.ClassPathXmlApplicationContext; public class Server { public static void main(String[] args) throws Exception { new ClassPathXmlApplicationContext(new String[]{"com/foo/server.xml", "com/foo/jms.xml"}); } }
The client merely needs to create a client-side proxy that will implement the agreed
upon interface ( CheckingAccountService
). The resulting object created off the back of
the following bean definition can be injected into other client side objects, and the
proxy will take care of forwarding the call to the server-side object via JMS.
<?xml version="1.0" encoding="UTF-8"?> <beans xmlns="http://www.springframework.org/schema/beans" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xsi:schemaLocation="http://www.springframework.org/schema/beans http://www.springframework.org/schema/beans/spring-beans.xsd"> <bean id="checkingAccountService" class="org.springframework.jms.remoting.JmsInvokerProxyFactoryBean"> <property name="serviceInterface" value="com.foo.CheckingAccountService"/> <property name="connectionFactory" ref="connectionFactory"/> <property name="queue" ref="queue"/> </bean> </beans>
package com.foo; import org.springframework.context.ApplicationContext; import org.springframework.context.support.ClassPathXmlApplicationContext; public class Client { public static void main(String[] args) throws Exception { ApplicationContext ctx = new ClassPathXmlApplicationContext( new String[] {"com/foo/client.xml", "com/foo/jms.xml"}); CheckingAccountService service = (CheckingAccountService) ctx.getBean("checkingAccountService"); service.cancelAccount(new Long(10)); } }
You may also wish to investigate the support provided by the Lingo project, which (to quote the homepage blurb) "… is a lightweight POJO based remoting and messaging library based on the Spring Framework’s remoting libraries which extends it to support JMS."
Refer to the Spring AMQP Reference Document Spring Remoting with AMQP section for more information.
The main reason why auto-detection of implemented interfaces does not occur for remote
interfaces is to avoid opening too many doors to remote callers. The target object might
implement internal callback interfaces like InitializingBean
or DisposableBean
which
one would not want to expose to callers.
Offering a proxy with all interfaces implemented by the target usually does not matter in the local case. But when exporting a remote service, you should expose a specific service interface, with specific operations intended for remote usage. Besides internal callback interfaces, the target might implement multiple business interfaces, with just one of them intended for remote exposure. For these reasons, we require such a service interface to be specified.
This is a trade-off between configuration convenience and the risk of accidental exposure of internal methods. Always specifying a service interface is not too much effort, and puts you on the safe side regarding controlled exposure of specific methods.
Each and every technology presented here has its drawbacks. You should carefully consider your needs, the services you are exposing and the objects you’ll be sending over the wire when choosing a technology.
When using RMI, it’s not possible to access the objects through the HTTP protocol, unless you’re tunneling the RMI traffic. RMI is a fairly heavy-weight protocol in that it supports full-object serialization which is important when using a complex data model that needs serialization over the wire. However, RMI-JRMP is tied to Java clients: It is a Java-to-Java remoting solution.
Spring’s HTTP invoker is a good choice if you need HTTP-based remoting but also rely on Java serialization. It shares the basic infrastructure with RMI invokers, just using HTTP as transport. Note that HTTP invokers are not only limited to Java-to-Java remoting but also to Spring on both the client and server side. (The latter also applies to Spring’s RMI invoker for non-RMI interfaces.)
Hessian and/or Burlap might provide significant value when operating in a heterogeneous environment, because they explicitly allow for non-Java clients. However, non-Java support is still limited. Known issues include the serialization of Hibernate objects in combination with lazily-initialized collections. If you have such a data model, consider using RMI or HTTP invokers instead of Hessian.
JMS can be useful for providing clusters of services and allowing the JMS broker to take care of load balancing, discovery and auto-failover. By default: Java serialization is used when using JMS remoting but the JMS provider could use a different mechanism for the wire formatting, such as XStream to allow servers to be implemented in other technologies.
Last but not least, EJB has an advantage over RMI in that it supports standard role-based authentication and authorization and remote transaction propagation. It is possible to get RMI invokers or HTTP invokers to support security context propagation as well, although this is not provided by core Spring: There are just appropriate hooks for plugging in third-party or custom solutions here.
The RestTemplate
is the core class for client-side access to RESTful services. It is
conceptually similar to other template classes in Spring, such as JdbcTemplate
and
JmsTemplate
and other template classes found in other Spring portfolio projects.
RestTemplate
's behavior is customized by providing callback methods and configuring
the HttpMessageConverter
used to marshal objects into the HTTP request body and to
unmarshal any response back into an object. As it is common to use XML as a message
format, Spring provides a MarshallingHttpMessageConverter
that uses the Object-to-XML
framework that is part of the org.springframework.oxm
package. This gives you a wide
range of choices of XML to Object mapping technologies to choose from.
This section describes how to use the RestTemplate
and its associated
HttpMessageConverters
.
Invoking RESTful services in Java is typically done using a helper class such as Apache
HttpComponents HttpClient
. For common REST operations this approach is too low level as
shown below.
String uri = "http://example.com/hotels/1/bookings"; PostMethod post = new PostMethod(uri); String request = // create booking request content post.setRequestEntity(new StringRequestEntity(request)); httpClient.executeMethod(post); if (HttpStatus.SC_CREATED == post.getStatusCode()) { Header location = post.getRequestHeader("Location"); if (location != null) { System.out.println("Created new booking at :" + location.getValue()); } }
RestTemplate provides higher level methods that correspond to each of the six main HTTP methods that make invoking many RESTful services a one-liner and enforce REST best practices.
Note | |
---|---|
RestTemplate has an asynchronous counter-part: see Section 21.10.3, “Async RestTemplate”. |
Table 21.1. Overview of RestTemplate methods
HTTP Method | RestTemplate Method |
---|---|
DELETE | |
GET | |
HEAD | |
OPTIONS | |
POST | postForLocation(String url, Object request, String… urlVariables) postForObject(String url, Object request, Class<T> responseType, String… uriVariables) |
PUT | |
PATCH and others |
The names of RestTemplate
methods follow a naming convention, the first part indicates
what HTTP method is being invoked and the second part indicates what is returned. For
example, the method getForObject()
will perform a GET, convert the HTTP response into
an object type of your choice and return that object. The method postForLocation()
will do a POST, converting the given object into a HTTP request and return the response
HTTP Location header where the newly created object can be found. In case of an
exception processing the HTTP request, an exception of the type RestClientException
will be thrown; this behavior can be changed by plugging in another
ResponseErrorHandler
implementation into the RestTemplate
.
The exchange
and execute
methods are generalized versions of the more
specific methods listed above them and can support additional combinations and methods,
like HTTP PATCH. However, note that the underlying HTTP library must also support the
desired combination. The JDK HttpURLConnection
does not support the PATCH
method, but
Apache HttpComponents HttpClient version 4.2 or later does. They also enable
RestTemplate
to read an HTTP response to a generic type (e.g. List<Account>
), using a
ParameterizedTypeReference
, a new class that enables capturing and passing generic
type info.
Objects passed to and returned from these methods are converted to and from HTTP
messages by HttpMessageConverter
instances. Converters for the main mime types are
registered by default, but you can also write your own converter and register it via the
messageConverters()
bean property. The default converter instances registered with the
template are ByteArrayHttpMessageConverter
, StringHttpMessageConverter
,
FormHttpMessageConverter
and SourceHttpMessageConverter
. You can override these
defaults using the messageConverters()
bean property as would be required if using the
MarshallingHttpMessageConverter
or MappingJackson2HttpMessageConverter
.
Each method takes URI template arguments in two forms, either as a String
variable
length argument or a Map<String,String>
. For example,
String result = restTemplate.getForObject( "http://example.com/hotels/{hotel}/bookings/{booking}", String.class,"42", "21");
using variable length arguments and
Map<String, String> vars = Collections.singletonMap("hotel", "42"); String result = restTemplate.getForObject( "http://example.com/hotels/{hotel}/rooms/{hotel}", String.class, vars);
using a Map<String,String>
.
To create an instance of RestTemplate
you can simply call the default no-arg
constructor. This will use standard Java classes from the java.net
package as the
underlying implementation to create HTTP requests. This can be overridden by specifying
an implementation of ClientHttpRequestFactory
. Spring provides the implementation
HttpComponentsClientHttpRequestFactory
that uses the Apache HttpComponents
HttpClient
to create requests. HttpComponentsClientHttpRequestFactory
is configured
using an instance of org.apache.http.client.HttpClient
which can in turn be configured
with credentials information or connection pooling functionality.
Tip | |
---|---|
Note that the |
The previous example using Apache HttpComponents HttpClient
directly rewritten to use
the RestTemplate
is shown below
uri = "http://example.com/hotels/{id}/bookings"; RestTemplate template = new RestTemplate(); Booking booking = // create booking object URI location = template.postForLocation(uri, booking, "1");
To use Apache HttpComponents instead of the native java.net
functionality, construct
the RestTemplate
as follows:
RestTemplate template = new RestTemplate(new HttpComponentsClientHttpRequestFactory());
Tip | |
---|---|
Apache HttpClient supports gzip encoding. To use it,
construct a HttpClient httpClient = HttpClientBuilder.create().build(); ClientHttpRequestFactory requestFactory = new HttpComponentsClientHttpRequestFactory(httpClient); RestTemplate restTemplate = new RestTemplate(requestFactory); |
The general callback interface is RequestCallback
and is called when the execute
method is invoked.
public <T> T execute(String url, HttpMethod method, RequestCallback requestCallback, ResponseExtractor<T> responseExtractor, String... urlVariables) // also has an overload with urlVariables as a Map<String, String>.
The RequestCallback
interface is defined as
public interface RequestCallback { void doWithRequest(ClientHttpRequest request) throws IOException; }
and allows you to manipulate the request headers and write to the request body. When using the execute method you do not have to worry about any resource management, the template will always close the request and handle any errors. Refer to the API documentation for more information on using the execute method and the meaning of its other method arguments.
For each of the main HTTP methods, the RestTemplate
provides variants that either take
a String URI or java.net.URI
as the first argument.
The String URI variants accept template arguments as a String variable length argument
or as a Map<String,String>
. They also assume the URL String is not encoded and needs
to be encoded. For example the following:
restTemplate.getForObject("http://example.com/hotel list", String.class);
will perform a GET on http://example.com/hotel%20list
. That means if the input URL
String is already encoded, it will be encoded twice — i.e.
http://example.com/hotel%20list
will become http://example.com/hotel%2520list
. If
this is not the intended effect, use the java.net.URI
method variant, which assumes
the URL is already encoded is also generally useful if you want to reuse a single (fully
expanded) URI
multiple times.
The UriComponentsBuilder
class can be used to build and encode the URI
including
support for URI templates. For example you can start with a URL String:
UriComponents uriComponents = UriComponentsBuilder.fromUriString( "http://example.com/hotels/{hotel}/bookings/{booking}").build() .expand("42", "21") .encode(); URI uri = uriComponents.toUri();
Or specify each URI component individually:
UriComponents uriComponents = UriComponentsBuilder.newInstance() .scheme("http").host("example.com").path("/hotels/{hotel}/bookings/{booking}").build() .expand("42", "21") .encode(); URI uri = uriComponents.toUri();
Besides the methods described above, the RestTemplate
also has the exchange()
method, which can be used for arbitrary HTTP method execution based on the HttpEntity
class.
Perhaps most importantly, the exchange()
method can be used to add request headers and
read response headers. For example:
HttpHeaders requestHeaders = new HttpHeaders(); requestHeaders.set("MyRequestHeader", "MyValue"); HttpEntity<?> requestEntity = new HttpEntity(requestHeaders); HttpEntity<String> response = template.exchange( "http://example.com/hotels/{hotel}", HttpMethod.GET, requestEntity, String.class, "42"); String responseHeader = response.getHeaders().getFirst("MyResponseHeader"); String body = response.getBody();
In the above example, we first prepare a request entity that contains the
MyRequestHeader
header. We then retrieve the response, and read the MyResponseHeader
and body.
It is possible to specify a Jackson JSON View to serialize only a subset of the object properties. For example:
JacksonSerializationValue jsv = new JacksonSerializationValue(new User("eric", "7!jd#h23"), User.WithoutPasswordView.class); HttpEntity<JacksonSerializationValue> entity = new HttpEntity<JacksonSerializationValue>(jsv); String s = template.postForObject("http://example.com/user", entity, String.class);
Objects passed to and returned from the methods getForObject()
, postForLocation()
,
and put()
are converted to HTTP requests and from HTTP responses by
HttpMessageConverters
. The HttpMessageConverter
interface is shown below to give you
a better feel for its functionality
public interface HttpMessageConverter<T> { // Indicate whether the given class and media type can be read by this converter. boolean canRead(Class<?> clazz, MediaType mediaType); // Indicate whether the given class and media type can be written by this converter. boolean canWrite(Class<?> clazz, MediaType mediaType); // Return the list of MediaType objects supported by this converter. List<MediaType> getSupportedMediaTypes(); // Read an object of the given type from the given input message, and returns it. T read(Class<T> clazz, HttpInputMessage inputMessage) throws IOException, HttpMessageNotReadableException; // Write an given object to the given output message. void write(T t, HttpOutputMessage outputMessage) throws IOException, HttpMessageNotWritableException; }
Concrete implementations for the main media (mime) types are provided in the framework
and are registered by default with the RestTemplate
on the client-side and with
AnnotationMethodHandlerAdapter
on the server-side.
The implementations of HttpMessageConverter
s are described in the following sections.
For all converters a default media type is used but can be overridden by setting the
supportedMediaTypes
bean property
An HttpMessageConverter
implementation that can read and write Strings from the HTTP
request and response. By default, this converter supports all text media types (
text/*
), and writes with a Content-Type
of text/plain
.
An HttpMessageConverter
implementation that can read and write form data from the HTTP
request and response. By default, this converter reads and writes the media type
application/x-www-form-urlencoded
. Form data is read from and written into a
MultiValueMap<String, String>
.
An HttpMessageConverter
implementation that can read and write byte arrays from the
HTTP request and response. By default, this converter supports all media types ( */*
),
and writes with a Content-Type
of application/octet-stream
. This can be overridden
by setting the supportedMediaTypes
property, and overriding getContentType(byte[])
.
An HttpMessageConverter
implementation that can read and write XML using Spring’s
Marshaller
and Unmarshaller
abstractions from the org.springframework.oxm
package.
This converter requires a Marshaller
and Unmarshaller
before it can be used. These
can be injected via constructor or bean properties. By default this converter supports (
text/xml
) and ( application/xml
).
An HttpMessageConverter
implementation that can read and write JSON using Jackson’s
ObjectMapper
. JSON mapping can be customized as needed through the use of Jackson’s
provided annotations. When further control is needed, a custom ObjectMapper
can be
injected through the ObjectMapper
property for cases where custom JSON
serializers/deserializers need to be provided for specific types. By default this
converter supports ( application/json
).
An HttpMessageConverter
implementation that can read and write XML using
Jackson XML extension’s
XmlMapper
. XML mapping can be customized as needed through the use of JAXB
or Jackson’s provided annotations. When further control is needed, a custom XmlMapper
can be injected through the ObjectMapper
property for cases where custom XML
serializers/deserializers need to be provided for specific types. By default this
converter supports ( application/xml
).
An HttpMessageConverter
implementation that can read and write
javax.xml.transform.Source
from the HTTP request and response. Only DOMSource
,
SAXSource
, and StreamSource
are supported. By default, this converter supports (
text/xml
) and ( application/xml
).
Web applications often need to query external REST services those days. The very nature of HTTP and synchronous calls can lead up to challenges when scaling applications for those needs: multiple threads may be blocked, waiting for remote HTTP responses.
AsyncRestTemplate
and Section 21.10.1, “RestTemplate”'s APIs are very similar; see
Table 21.1, “Overview of RestTemplate methods”. The main difference between those APIs is
that AsyncRestTemplate
returns
ListenableFuture
wrappers as opposed to concrete results.
The previous RestTemplate
example translates to:
// async call Future<ResponseEntity<String>> futureEntity = template.getForEntity( "http://example.com/hotels/{hotel}/bookings/{booking}", String.class, "42", "21"); // get the concrete result - synchronous call ResponseEntity<String> entity = futureEntity.get();
ListenableFuture
accepts completion callbacks:
ListenableFuture<ResponseEntity<String>> futureEntity = template.getForEntity( "http://example.com/hotels/{hotel}/bookings/{booking}", String.class, "42", "21"); // register a callback futureEntity.addCallback(new ListenableFutureCallback<ResponseEntity<String>>() { @Override public void onSuccess(ResponseEntity<String> entity) { //... } @Override public void onFailure(Throwable t) { //... } });
Note | |
---|---|
The default |
See the
ListenableFuture
javadocs
and
AsyncRestTemplate
javadocs
for more details.