Version 1.0.0.RC1
April 2009
Table of Contents
Spring has always aimed to be agnostic to the client technologies being used to access its core services, intentionally leaving options open and letting the community drive the demand for any new first-class integration solutions to be added to the Spring project portfolio. Spring BlazeDS Integration is an answer to the commmunity demand for a top-level solution for building Spring-powered Rich Internet Applications using Adobe Flex for the client-side technology.
BlazeDS is an open source project from Adobe that provides the remoting and messaging foundation for connecting a Flex-based front-end to Java back-end services. Though it has previously been possible to use BlazeDS to connect to Spring-managed services, it has not been in a way that feels "natural" to a Spring developer, requiring the extra burden of having to maintain a separate BlazeDS xml configuration. Spring BlazeDS Integration turns the tables by making the BlazeDS MessageBroker a Spring-managed object, opening up the pathways to a more extensive integration that follows "the Spring way".
Java 5 or higher
Spring 2.5 or higher
Adobe BlazeDS 3.2 or higher
Professional from-the-source support on Spring BlazeDS Integration is available from SpringSource, the company behind Spring.
The central component that must be configured to use Spring BlazeDS Integration is the MessageBroker. HTTP messages from the Flex client
will be routed through the Spring DispatcherServlet to the Spring-managed MessageBroker. There is no need to configure the
BlazeDS MessageBrokerServlet when using the Spring-managed MessageBroker.
The DispatcherServlet must be configured as normal in web.xml to bootstrap a Spring WebApplicationContext. For example:
<!-- The front controller of this Spring Web application, responsible for handling all application requests --> <servlet> <servlet-name>Spring MVC Dispatcher Servlet</servlet-name> <servlet-class>org.springframework.web.servlet.DispatcherServlet</servlet-class> <init-param> <param-name>contextConfigLocation</param-name> <param-value>/WEB-INF/config/web-application-config.xml</param-value> </init-param> <load-on-startup>1</load-on-startup> </servlet>
A simplified Spring XML config namespace is provided for configuring the MessageBroker in your WebApplicationContext. To use the namespace support you must add the schema location in your Spring XML config files. A typical config will look something like the following:
<?xml version="1.0" encoding="UTF-8"?> <beans xmlns="http://www.springframework.org/schema/beans" xmlns:flex="http://www.springframework.org/schema/flex" 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-2.5.xsd http://www.springframework.org/schema/flex http://www.springframework.org/schema/flex/spring-flex-1.0.xsd"> ... </beans>
This makes the Spring BlazeDS Integration configuration tags available under the flex namespace in your configuration files. The above setup will
be assumed for the rest of the configuration examples to follow. For the full detail of every attribute and tag available in the config namespace, be sure
to refer to the spring-flex-1.0.xsd as every element and attribute is fully documented there. Using an XSD-aware XML editor such as the one in Eclipse
should bring up the documentation automatically as you type. (Note that until the final xsd is published to the above web address, you would need to manually
add the XSD to your XML catalog in Eclipse for auto-completion to work correctly.)
At a minimum, the MessageBrokerFactoryBean must be configured as a bean in your Spring WebApplicationContext in order to bootstrap the MessageBroker,
along with a MessageBrokerHandlerAdapter and an appropriate HandlerMapping (usually a SimpleUrlHandlerMapping) to route incoming
requests to the Spring-managed MessageBroker.
These beans will be registered automatically by using the provided message-broker tag in your bean
definition file. For example, in its simplest form:
<flex:message-broker/>
This will set up the MessageBroker and necessary supporting infrastructure using sensible defaults. The defaults can be
overriden using the provided attributes of the message-broker tag and its associated child elements. For example, the
default location of the BlazeDS XML configuration file (/WEB-INF/flex/services-config.xml) can be overridden using the
services-config-path attribute. The MessageBrokerFactoryBean uses Spring's ResourceLoader abstraction,
so that typical Spring resource paths may be used. For example, to load the configuration from the application's classpath:
<flex:message-broker services-config-path="classpath*:services-config.xml"
The equivalent MessageBrokerFactoryBean definition using vanilla Spring configuration would be:
<!-- Bootstraps and exposes the BlazeDS MessageBroker --> <bean id="_messageBroker" class="org.springframework.flex.messaging.MessageBrokerFactoryBean" > <property name="servicesConfigPath" value="classpath*:services-config.xml" /> </bean>
Note especially that with the message-broker tag, it is not necessary to assign a custom id to the MessageBroker, and it
is in fact discouraged so that you won't have to continually reference it later. The only reason you would ever need to provide a custom
id is if you were bootstrapping more than one MessageBroker in the same WebApplicationContext.
To properly route incoming requests to the Spring-managed MessageBroker, request mapping must be configured in three places:
DispatcherServlet mapping in web.xml
HandlerMapping in the Spring WebApplicationContext
Channel definitions in the BlazeDS services-config.xml
The simplest request mapping scenario is when the Flex front-end is the only client type for the application. In this case you can just map /messagebroker as the top-level path for requests. The mapping in web.xml would be:
<!-- Map all /messagbroker requests to the DispatcherServlet for handling --> <servlet-mapping> <servlet-name>Spring MVC Dispatcher Servlet</servlet-name> <url-pattern>/messagebroker/*</url-pattern> </servlet-mapping>
When using the message-broker config tag, a SimpleUrlHandlerMapping is installed that by default maps all
incoming DispatcherServlet requests to the Spring-manager MessageBroker using a /*path pattern.
The default mapping can be overridden by providing one or more mapping child elements. If you want to provide your own
HandlerMapping bean configuration, you can disable the default using the disable-default-mapping attribute
of the message-broker tag. The order of the installed SimpleUrlHandlerMapping can be set (for complex
scenarios where multiple handler mapping types are installed in the same context) using the mapping-order attribute.
Then the SimpleUrlHandlerMapping in the Spring WebApplicationContext maps all requests to the Spring-managed MessageBroker via
the MessageBrokerHandlerAdapter. The default setup installed by the message-broker config tag is equivalent to the
following bean definitions:
<!-- Maps request paths at /* to the BlazeDS MessageBroker --> <bean class="org.springframework.web.servlet.handler.SimpleUrlHandlerMapping"> <property name="mappings"> <value> /*=_messageBroker </value> </property> </bean> <!-- Dispatches requests mapped to a MessageBroker --> <bean class="org.springframework.flex.messaging.servlet.MessageBrokerHandlerAdapter"/>
Channel definitions in the BlazeDS services-config.xml must correspond to the chosen mapping. For example, to set up a typical AMF channel in BlazeDS that matches the above mapping strategy:
<channel-definition id="my-amf" class="mx.messaging.channels.AMFChannel"> <endpoint url="http://{server.name}:{server.port}/{context.root}/messagebroker/amf" class="flex.messaging.endpoints.AMFEndpoint"/> <properties> <polling-enabled>false</polling-enabled> </properties> </channel-definition>
See the BlazeDS documentation for more information on configuring communication channels in services-config.xml.
It could often be the case that your application needs to serve more than just Flex-based clients. For example, you may be constructing a RESTful architecture
that is meant to serve multiple client-types. You could potentially even be consuming RESTful endpoints using the Flex HTTPService component. In this case,
you will want to choose a more flexible mapping strategy, such as mapping /spring/* to the DispatcherServlet, mapping /messagebroker/*
to the Spring-managed MessageBroker, and modifying any BlazeDS channel definitions accordingly. You would override the default mapping strategy
of the message-broker tag as follows:
<flex:message-broker> <flex:mapping pattern="/messagebroker/*" /> </flex:message-broker>
and you would have to account for the /spring/* mapping in your BlazeDS channel definitions. For example:
<channel-definition id="my-amf" class="mx.messaging.channels.AMFChannel"> <endpoint url="http://{server.name}:{server.port}/{context.root}/spring/messagebroker/amf" class="flex.messaging.endpoints.AMFEndpoint"/> <properties> <polling-enabled>false</polling-enabled> </properties> </channel-definition>
Explicit channel definition is a requirement when using dynamic destinations (meaning any destination that is added programmatically and not defined in the BlazeDS
services-config.xml, i.e. the destinations created by the remoting-destination tag and the various *-message-destination tags). See
Adobe's documentation here for more detail: http://livedocs.adobe.com/blazeds/1/blazeds_devguide/runtimeconfig_5.html#194376
The only way you don't have to explicitly define the ChannelSet on the client is if
you are using explicitly defined destinations in services-config.xml (i.e, not dynamic destinations) AND you compile your flex client against that file
your destination is using the application-wide default channel AND you compile your flex client against that file
Even if you weren't using dynamically created destinations it is debatable whether it is a good idea to ever compile your client against services-config.xml, thus coupling your client to your server configuration. It is often desirable to keep your flex client and your server side code as two distinct modules, but compiling against services-config.xml blurs the lines between those modules.
Our recommendation is that it is generally cleaner to keep the client-side configuration of ChannelSets explicitly contained within the client module. An excellent way to do this without having to hard-code the URLs in your client code is to use an ActionScript DI framework such as Spring ActionScript (a Spring Extensions project, formerly known as Prana).
If you choose to go the route of compiling your client against services-config.xml, note that you can at least keep the URL information out of the client code by using ServerConfig.getChannel as described in the referenced BlazeDS documentation.
The initialization of the MessageBroker by the MessageBrokerFactoryBean logically consists of two phases:
Parsing the BlazeDS XML configuration files and applying their settings to a newly created MessageBroker
Starting the MessageBroker and its services
A special MessageBrokerConfigProcessor callback interface is provided that allows custom processing to be done on the
newly created MessageBroker after each phase, before it is made available for request processing. This interface is used internally
by Spring BlazeDS Integration, but is also available for general use in advanced programmatic introspection and customization of the
MessageBroker. A custom MessageBrokerConfigProcessor can be configured as a Spring bean and then registered with the
MessageBrokerFactoryBean via the config-processor tag. For example, given a trivial implementation
to log some additional info about the MessageBroker:
package com.example; import org.springframework.flex.messaging.config.MessageBrokerConfigProcessor; import flex.messaging.MessageBroker; import flex.messaging.services.RemotingService; public class MyDestinationCountingConfigProcessor implements MessageBrokerConfigProcessor { public MessageBroker processAfterStartup(MessageBroker broker) { RemotingService remotingService = (RemotingService) broker.getServiceByType(RemotingService.class.getName()); if (remotingService.isStarted()) { System.out.println("The Remoting Service has been started with " +remotingService.getDestinations().size()+" Destinations."); } return broker; } public MessageBroker processBeforeStartup(MessageBroker broker) { return broker; } }
This class could be configured and registered with the MessageBroker as follows:
<flex:message-broker> <flex:config-processor ref="myConfigProcessor" /> </flex:message-broker> <bean id="myConfigProcessor" class="com.example.MyDestinationCountingConfigProcessor" />
In order to propagate useful information back to the Flex client when an exception occurs on the server,
the original exception must be translated into an instance of flex.messaging.MessageException.
If special translation logic is not applied, a generic "Server.Processing" error will propagate to the client that
doesn't give the client the chance to reason on the real cause of the error to take appropriate action. Special
exception translators are configured by default for transforming Spring Security exceptions into an appropriate
MessageException, but it could also be useful to provide custom translation for your own application-level exceptions.
Custom exception translation logic can be provided through implementations of the org.springframework.flex.core.ExceptionTranslator
interface. These implementations must be configured as Spring beans and then registered through the XML configuration namespace as follows:
<!-- Custom exception translator configured as a Spring bean --> <bean id="myExceptionTranslator" class="com.foo.app.MyBusinessExceptionTranslator"/> <flex:message-broker> <flex:exception-translator ref="myExceptionTranslator"/> </flex:message-broker>
Custom message interceptors may be used to apply special processing logic to incoming and outgoing AMF messages in their de-serialized Java form. For example, an interceptor can be used to inspect the contents of the incoming message, or to add extra information to the outgoing message.
Custom message processing logic is provided through implementations of the org.springframework.flex.core.MessageInterceptor
interface. These implementations must be configured as Spring beans and then registered through the XML configuration namespace as follows:
<!-- Custom message interceptor configured as a Spring bean --> <bean id="myMessageInterceptor" class="com.foo.app.MyMessageInterceptor"/> <flex:message-broker> <flex:message-interceptor ref="myMessageInterceptor"/> </flex:message-broker>
Using the XML config namespace automatically installs the needed implementations of flex.messaging.services.ServiceAdapter
for use with the Remoting and Message services. Third-party adapters (such as those provided by the dpHibernate or Gilead projects) can
be configured using the org.springframework.flex.core.ManageableComponentFactoryBean. This factory bean implementation is
able to process arbitrarily complex configuration metadata supplied in JSON format (instead of arbitrarily complex XML as in the native
BlazeDS configuration) and honors the lifecycle semantics (such as proper invocation of the initialize method) of the
ManageableComponent. These custom adapters may be used by Spring-managed Remoting and Message destinations by either setting its id as the
default for the Remoting or Message service, or by setting the service-adapter attribute for a specific destination (see the
Remoting and Messaging chapters for further detail).
For example, to use the special adapter provided by dpHibernate as the default adapter with the Remoting service, the configuration would be similar to the following:
<bean id="hibernate-object" class="org.springframework.flex.core.ManageableComponentFactoryBean"> <constructor-arg value="net.digitalprimates.persistence.hibernate.HibernateAdapter"/> <property name="properties"> <value> {"hibernate" : {"sessionFactory" : { "class" : "net.digitalprimates.persistence.hibernate.utils.HibernateUtil", "getCurrentSessionMethod" : "getCurrentSession" } } } </value> </property> </bean> <flex:message-broker> <flex:remoting-service default-adapter-id="hibernate-object" /> </flex:message-broker>
Using a Spring-managed MessageBroker enables Spring beans to be easily exported for direct remoting calls from a Flex client. This approach
is quite similar to that taken with other remoting technologies in the core Spring Framework. Remoting is applied to existing Spring-managed beans
as an external configuration concern. The MessageBroker transparently handles the process of serialization and deserialization between
the Flex AMF data format and Java.
The BlazeDS RemotingService has traditionally been configured by the inclusion of a remoting-config.xml file in the BlazeDS XML configuration. When
using only Spring-managed remoting destinations, this config file can be left out completely as the inclusion of the message-broker tag
in your Spring configuration will cause the RemotingService to be configured with sensible defaults if none already exists at startup
time. The end result is essentially equivalent to including the following minimal remoting-config.xml in your BlazeDS configuration:
<?xml version="1.0" encoding="UTF-8"?> <service id="remoting-service" class="flex.messaging.services.RemotingService"> <adapters> <adapter-definition id="java-object" class="flex.messaging.services.remoting.adapters.JavaAdapter" default="true"/> </adapters> <default-channels> <channel ref="my-amf"/> </default-channels> </service>
Note that this assumes that there is already an equivalent application-wide default-channels configuration. It is recommended that
you set the desired service-specific channels (see example below) if not relying on an application-wide default setup. If no application-wide
defaults exist, a best guess will be made by configuring the first available channel from the MessageBroker that uses an
AMFEndpoint as the default for the RemotingService.
If you wish to have more explicit control over the defaults that will be set on the RemotingService, you can customize them
via the remoting-service child element of the message-broker tag. For example:
<flex:message-broker> <flex:remoting-service default-adapter-id="my-default-remoting-adapter" default-channels="my-amf, my-secure-amf" /> </flex:message-broker>
If you have an existing remoting-config.xml for a legacy BlazeDS application, the RemotingDestinationExporter will be able to work transparently with it,
allowing you to gradually migrate to all Spring-managed remoting destinations.
The remoting-destination configuration tag can be used to export existing Spring-managed services for direct remoting from a Flex client.
Given the following Spring bean definition for a productService bean:
<bean id="productService" class="flex.samples.product.ProductServiceImpl" />
and assuming the existance of a Spring-managed MessageBroker configured via the message-broker tag, the following
top-level remoting-destination tag will expose the service for remoting to the Flex client as a remote service destination named productService:
<!-- Expose the productService bean for BlazeDS remoting --> <flex:remoting-destination ref="productService" />
By default, the remote service destination exposed to the Flex client will use bean name of the bean being exported as the service id of the
destination, but this may be overridden using the service-id attribute on the remoting-destination tag.
An alternate way of using the remoting-destination tag is as a child element of an top-level bean definition. This is even more concise
and works well if you don't have a need to keep your domain-layer bean definitions separate from infrastructure concerns such as Flex remoting.
(Keep in mind that keeping them separate can lead to easier testability of the core domain layer.) The following achieves the equivalent result
to the previous example:
<bean id="productService" class="flex.samples.product.ProductServiceImpl" > <flex:remoting-destination /> </bean>
The methods that are exposed to be called by the Flex client can be more tightly controlled through use of the include-methods and exclude-methods
attributes of the remoting-destination tag. The BlazeDS channels over which the destination is exposed can also be controlled using the channels
attribute. (These attributes are available whether using the top-level or the nested version.) A more extensively customized example would look something like:
<flex:remoting-destination ref="productService" include-methods="read, update" exclude-methods="create, delete" channels="my-amf, my-secure-amf" />
The remoting-destination tag is transparently configuring a RemotingDestinationExporter bean instance for each bean being exported.
The equivalent full bean syntax without the namespace support would be:
<!-- Expose the productService bean for BlazeDS remoting --> <bean id="product" class="org.springframework.flex.remoting.RemotingDestinationExporter"> <property name="messageBroker" ref="_messageBroker"/> <property name="service" ref="productService"/> <property name="serviceId" value="productService"/> <property name="includeMethods" value="read, update"/> <property name="excludeMethods" value="create, delete"/> <property name="channels" value="my-amf, my-secure-amf"/> </bean>
The @RemotingDestination annotation may be used as an alternative to the XML remoting-destination tag when using annotation-based
Spring configuration. @RemotingDestination is used at the type level to indicate the class being exported. @RemotingInclude and
@RemotingExclude are used at the method level to mark the methods that should be included and excluded for remoting.
The following example illustrates the productService bean configured exclusively through annotations:
package flex.samples.product; import org.springframework.flex.remoting.RemotingDestination; import org.springframework.flex.remoting.RemotingExclude; import org.springframework.flex.remoting.RemotingInclude; import org.springframework.stereotype.Service; @Service("productService") @RemotingDestination(channels={"my-amf","my-secure-amf"}) public class ProductServiceImpl implements ProductService { @RemotingInclude public Product read(String id) { ... } @RemotingExclude public Product create(Product product){ ... } @RemotingInclude public Product update(Product product){ ... } @RemotingExclude public void delete(Product product) { ... } }
Spring Security provides an extremely flexible alternative to the container-based security support provided out-of-the-box with BlazeDS. Spring BlazeDS Integration provides explicit integration support for incorporating Spring Security smoothly into your Flex/BlazeDS application. Spring Security provides a wealth of different configuration options, but rather than go into the many different combinations here, we'll leave most of that to the Spring Security documentation.
Here is a typical simple Spring Security starting configuration for use in conjunction with the explicit integration features provided by Spring BlazeDS integration:
<beans:beans xmlns="http://www.springframework.org/schema/security" xmlns:beans="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-2.0.xsd http://www.springframework.org/schema/security http://www.springframework.org/schema/security/spring-security-2.0.4.xsd"> <http entry-point-ref="preAuthenticatedEntryPoint" /> <beans:bean id="preAuthenticatedEntryPoint" class="org.springframework.security.ui.preauth.PreAuthenticatedProcessingFilterEntryPoint" /> <authentication-provider> <user-service> <user name="jeremy" password="atlanta" authorities="ROLE_USER, ROLE_ADMIN" /> <user name="keith" password="melbourne" authorities="ROLE_USER" /> </user-service> </authentication-provider> </beans:beans>
We will assume the above configuration is in place for the remainder of the examples in this chapter.
Spring Security integration is enabled through the secured child element of the message-broker tag. The
simplest possible configuration would be:
<flex:message-broker> <flex:secured /> </flex:message-broker>
This enables the basic security features. A special BlazeDS LoginCommand implementation is automatically installed that
enables ChannelSet.login and ChannelSet.logout requests to integrate with Spring Security's Authorization mechanisms. Additionally,
the special LoginCommand enables Spring Security granted authorities to be referenced in BlazeDS XML security constraints.
For example, if we were using a traditional BlazeDS remoting destination defined in remoting-config.xml, we could have something like
the following:
<destination id="productService"> ... <security> <security-constraint> <auth-method>Custom</auth-method> <roles> <role>ROLE_USER</role> </roles> </security-constraint> </security> </destination>
As you can see, we are referencing the "ROLE_USER" authority from our simple Spring Security setup. The invocation of this remote
destination would cause the provided LoginCommand to be invoked to both verify that the user is logged in and to check
that they have the appropriate role. Violation of either will result in an exception being thrown by Spring Security.
When using the ChannelSet.login API call from the Flex client with Spring Security integration enabled, the resulting ResponseEvent fired client-side upon successful completion will contain additional information that can be inspected about the current user. The name and authorities will be extracted from the Authentication object and added to the body of the response message. This information, for example, can then be used to conditionally display different portions of the UI based on the user's identity and granted roles:
var token:AsyncToken = myChannelSet.login("jeremy","atlanta"); token.addResponder( new AsyncResponder( function(event:ResultEvent, token:Object = null):void { if (event.result.authorities.indexOf("ROLE_ADMIN") >= 0) { displayAdminPanel(event.result.name); } else { displayUserPanel(event.result.name); } }, function(event:FaultEvent, token:Object = null):void { displayErrorMessage("Login Failed: "+event.fault.faultString); } ) );
Another feature that is automatically installed when the secured tag is used is automatic exception translation from
any thrown SpringSecurityException to the proper BlazeDS SecurityException. The exceptions are caught and translated at the proper
point in the execution chain such that it will result in the proper AMF error message being serialized and sent back to the client.
This is alternative to the normal Spring Security behavior where a filter in the chain catches the exception and sends back a
corresponding HTTP status code. The problem with sending back HTTP status codes other than 200 is that this causes the Flex client
to throw a generic and rather unhelpful exception, and often the status code can't be determined from the Flex client. Sending back
specific AMF error messages instead causes a FaultEvent to be thrown client-side that contains the proper
security fault code that can then be reasoned on and appropriate action can be taken. This behavior is equivalent to that of the
out-of-the-box container-based security mechanisms provided with BlazeDS, so the programming model client-side remains the same.
The secured tag has several additional attributes that allow further customization.
If you are not using Spring Security's
default bean ids for the AuthenticationManager or AccessDecisionManager, you can specify your custom bean references
using the corresponding authentication-manager and access-decision-manager attributes respectively on the secured
tag.
The configuration of the provided LoginCommand can be further controlled via the secured tag. The invalidate-flex-session
attribute controls whether the current Flex session is invalidated when the logout() method is called on the LoginCommand, and
defaults to "true" if not specified. The per-client-authentication attribute turns BlazeDS's per-client authentication mode on when true, and
defaults to "false" if not specified. Enabling per-client authentication will cause the Security context to no longer be stored in the session between
requests and thus will prevent the use of any Spring Security filters that rely on the Security Context being available in the session, but the authentication
and authorization integration will otherwise work as expected. (See the BlazeDS docs for further information on the difference between per-session and per-client
authentication.)
The Spring Security integration allows flexible control over how you secure your application. You can secure BlazeDS endpoints in a manner similar to Spring Security's traditional URL security, and you can secure your Spring services using the many existing object security mechanisms of Spring Security just as if you were writing a traditional web application.
You can set security constraints on specific BlazeDS channels using the secured-channel child element of the secured
tag. For example:
<flex:message-broker> <flex:secured> <flex:secured-channel channel="my-amf" access="ROLE_USER" /> </flex:secured> </flex:message-broker>
This results in any request being routed to the "my-amf" channel to require the user to be logged in and to have the "ROLE_USER"
authority. If either of those is violated, a FaultEvent will be signaled on the client.
You can set security constraints on multiple BlazeDS channels at once using the secured-endpoint-path child element
of the secured tag. In this case you specify a URL pattern to be secured instead of a specific channel id. For
example:
<flex:message-broker> <flex:secured> <flex:secured-endpoint-path pattern="**/messagebroker/**" access="ROLE_USER" /> </flex:secured> </flex:message-broker>
This results in any request being routed to any channel whose endpoint URL contains "/messagebroker/" in the path to require the
user to be logged in and to have the "ROLE_USER" authority. If either of those is violated, a FaultEvent will be
signaled on the client.
Earlier in this chapter you saw an example of using the BlazeDS XML configuration to secure a BlazeDS-managed destination. Since
most of the time you will instead be defining destinations by exporting Spring beans using the remoting-destinationtag, an
alternate approach to securing destinations is needed. This is where Spring Security comes in, as all of its existing authorization
mechanisms should "just work" when security integration is enabled using the secured tag.
One of the major strengths of Spring Security is the multiple levels of granularity it provides you when securing your Spring services. You can go from securing your entire service layer in one concise statement:
<global-method-security> <protect-pointcut expression="execution(* com.mycompany.*Service.*(..))" access="ROLE_USER"/> </global-method-security>
to controlling access in a more fine-grained manner at the method layer using XML:
<bean id="myService" class="com.mycompany.myapp.MyService"> <flex:remoting-destination/> <security:intercept-methods> <security:protect method="set*" access="ROLE_ADMIN" /> <security:protect method="get*" access="ROLE_ADMIN,ROLE_USER" /> <security:protect method="doSomething" access="ROLE_USER" /> </security:intercept-methods> </bean>
to using a combination of XML and annotations:
<security:global-method-security secured-annotations="enabled" jsr250-annotations="enabled"/> ... <flex:remoting-destination ref="myBankServiceImpl" />
public interface BankService { @Secured("IS_AUTHENTICATED_ANONYMOUSLY") public Account readAccount(Long id); @Secured("IS_AUTHENTICATED_ANONYMOUSLY") public Account[] findAccounts(); @Secured("ROLE_TELLER") public Account post(Account account, double amount); }
to even more fine-grained ACL-based domain object permissions. For more details on the options available, see the Spring Security documentation.
The BlazeDS MessageService provides a common abstraction for asynchronous messaging style communication
that is ultimately agnostic to the messaging protocol being used on the server side. Messages can be passed
exclusively between Flex clients, from Java POJOs to subscribed Flex clients, from Flex clients to POJO message
handlers, or between just about any combination thereof. Using the Spring-managed MessageBroker enables support for using
BlazeDS-native AMF messaging, JMS messaging based on Spring's proven and simple JMS abstractions,
or messaging using Spring Integration's MessageChannel abstraction, all from a common programming model.
The same Consumer and Producer APIs are used to interact with message destinations from the Flex client, regardless
of which underlying messaging protocol is being used on the server. As such, this chapter will focus mainly on setting up and using the various
message destination types on the server side. For more details on how to use the Consumer and Producer APIs in the client,
see the BlazeDS documentation.
The BlazeDS MessageService has traditionally been configured by the inclusion of a messaging-config.xml file in the BlazeDS XML configuration.
When using only Spring-managed message destinations, this config file can be left out completely as the inclusion of the message-broker tag
in your Spring configuration will cause the MessageService to be configured with sensible defaults if none already exists at startup
time. The end result is essentially equivalent to including the following minimal messaging-config.xml in your BlazeDS configuration:
<?xml version="1.0" encoding="UTF-8"?> <service id="remoting-service" class="flex.messaging.services.MessageService"> <adapters> <adapter-definition id="actionscript" class="flex.messaging.services.messaging.adapters.ActionScriptAdapter" default="true"/> </adapters> <default-channels> <channel ref="my-polling-amf"/> </default-channels> </service>
Note that this assumes that there is already an equivalent application-wide default-channels configuration. It is recommended that
you set the desired service-specific channels (see example below) if not relying on an application-wide default setup. If no application-wide
defaults exist, a best guess will be made by configuring the first available channel from the MessageBroker that uses an
AMFEndpoint with polling enabled as the default for the MessageService.
If you wish to have more explicit control over the defaults that will be set on the MessageService, you can customize them
via the message-service child element of the message-broker tag. For example:
<flex:message-broker> <flex:message-service default-adapter-id="my-default-messaging-adapter" default-channels="my-polling-amf" /> </flex:message-broker>
If you have an existing messaging-config.xml for a legacy BlazeDS application, the MessageDestinationFactory will be able to work transparently
with it, allowing you to gradually migrate to all Spring-managed messaging destinations.
For simple messaging needs where there are no requirements for message durability, transaction support, or advanced routing logic, the BlazeDS-native
AMF-based message destination is the ideal choice. These destinations can be fully configured in a Spring application context using the
message-destination XML namespace tag. For example, assuming a Spring-managed MessageBroker has been configured, all that is
needed to set up a basic destination named "event-bus" with default settings is the following:
<flex:message-destination id="event-bus" />
This sets up a destination to use the BlazeDS ActionScriptAdapter to handle incoming messages. The settings of the destination can be
further customized through the various attributes of the message-destination tag. Here is an example of the "event-bus" destination configured
with most of the available attributes:
<flex:message-destination id="event-bus" message-broker="messageServiceBroker" channels="my-polling-amf, my-secure-amf" allow-subtopics="true" cluster-message-routing="broadcast" message-time-to-live="1" send-security-constraint="fooConstraint" subscribe-security-constraint="barConstraint" subscription-timeout-minutes="1" subtopic-separator="/" throttle-inbound-max-frequency="500" throttle-inbound-policy="ERROR" throttle-outbound-max-frequency="500" throttle-outbound-policy="IGNORE" />
The message-broker attribute is a reference to the id of a Spring-managed MessageBroker. The channels attribute allows
you to specify a comma-delimited list of the BlazeDS channels to be used (in order of preference) for this destination. The remaining attributes correspond
to the options available via the network and server settings when configuring a message destination in the BlazeDS-specific XML.
Each of these additional attributes is documented in the XSD to provide live code-completion assistance. For additional details on their usage, see
the BlazeDS documentation. The message-destination tag serves as a base for the jms-message-destination and
integration-message-destination tags so that the same configuration options are available no matter the type of the underlying
MessagingAdapter.
The only attribute available on the message-destination tag that is not available in the JMS and Spring Integration implementations is the
service-adapter attribute, which can be used to provide a custom ServiceAdapter via a reference to a
ManageableComponentFactoryBean. This can be used to provide integration with additional messaging protocols not directly supported by
Spring BlazeDS Integration. See Providing Custom Service Adapters for additional information on using the
ManageableComponentFactoryBean.
For integration with JMS, a special JmsAdapter is provided that internally makes use of Spring's JmsTemplate, DestinationResolver,
DefaultMessageListenerContainer and other such JMS abstractions for simplified interaction with JMS resources. The jms-message-destination XML namespace
tag is used to expose JMS destinations as BlazeDS message destinations. The minimal attributes that must be specified are the destination id
and exactly one of jms-destination, queue-name, or topic-name. A JMS ConnectionFactory reference is also
required, but does not have to be explicitly specified if there is already one configured in the current application context with an id of "connectionFactory".
For example, to configure a BlazeDS message destination named "chatIn" that uses a Spring-managed ActiveMQ JMS queue with a local ActiveMQ installation:
<bean id="connectionFactory" class="org.apache.activemq.ActiveMQConnectionFactory"> <property name="brokerURL" value="tcp://localhost:61616"/> </bean> <bean id="chatInQueue" class="org.apache.activemq.command.ActiveMQQueue"> <constructor-arg value="queue.flex.chat.in"/> </bean> <flex:jms-message-destination id="chatIn" jms-destination="chatInQueue" />
Using queue-name or topic-name will cause the destination to be resolved using a Spring DestinationResolver.
The destination-resolver, message-converter, and transaction-manager attributes may be used to set custom references
to a Spring-managed DestinationResolver, MessageConverter, or TransactionManager respectively.
For routing messages with Spring Integration, a special IntegrationAdapter is provided that is able to send/receive messages via a
MessageChannel. This is especially useful when you have more complex routing needs for your messages, such as connecting to email or FTP
endpoints. The integration-message-destination XML namespace tag is used to expose a Spring Integration MessageChannel as a
BlazeDS message destination. For example, to configure a BlazeDS message destination named "chatOut" that uses a Spring Integration
PublishSubscribeChannel:
<integration:publish-subscribe-channel id="chatOutPubSubChannel" /> <flex:integration-message-destination id="chatOut" message-channel="chatOutPubSubChannel" />
A convenient MessageTemplate helper class is provided that allows you to push messages to any BlazeDS MessageDestination from a simple
POJO. This provides a nice abstraction over push style messaging that hides away the details of the underlying messaging protocol. Whether using a simple
AMF based destination or full-blown JMS, etc., the use of the MessageTemplate stays the same. The only thing the MessageTemplate requires
is a reference to a Spring-managed MessageBroker. If the MessageTemplate is configured as a Spring bean, it will try and auto-detect
the MessageBroker from its application context.
As an example of how the MessageTemplate could be used, suppose we have a RESTful travel application that has a Flex-based admin console but also
exposes an API over HTTP. To give the admin console a "live" view of the data, we want to push updates to it anytime a new hotel booking is created. Given the
following setup in our application context:
<flex:message-broker /> <bean id="defaultMessageTemplate" class="org.springframework.flex.messaging.MessageTemplate" /> <flex:message-destination id="chatOut" message-channel="bookingUpdates" />
and assuming the Flex client is subscribed to the "bookingUpdates" destination, this could be achieved with the following controller code:
@Controller public class BookingController { private MessageTemplate template; private BookingService bookingService; @RequestMapping(value="/bookings", method=RequestMethod.POST) public String createBooking(Booking booking){ booking = bookingService.saveBooking(booking); template.send("bookingUpdates", booking); return "redirect:/bookings/"+booking.getId(); } @Autowired public void setTemplate(MessageTemplate template) { this.template = template; } @Autowired public void setBookingService(BookingService bookingService) { this.bookingService = bookingService; } }