JAX-WS, like JAX-RS, uses annotations, and machine-generated JAX-WS code is awash with these. The first example is stingy in its use of annotations in order to underscore exactly what is required for a SOAP-based service. Later examples introduce additional annotations.:
The RandService class (see Example 4-1) defines a SOAP-based service with two operations, each an annotated Java method:
- Operation next1 takes no arguments and returns one randomly generated integer.
- Operation nextN takes one argument, the number of randomly generated integers desired, and returns a list (in this implementation, an array) of integers.
Example 4-1. A SOAP-based service with two operations
packagerand;importjavax.jws.WebService;importjavax.jws.WebMethod;importjava.util.Random;@WebService
publicclassRandService{privatestaticfinalintmaxRands=16;@WebMethod// optional but helpful annotation
publicintnext1(){returnnewRandom().nextInt();}@WebMethod// optional but helpful annotation
publicint[]nextN(finalintn){finalintk=(n>maxRands)?maxRands:Math.abs(n);int[]rands=newint[k];Randomr=newRandom();for(inti=0;i<k;i++)rands[i]=r.nextInt();returnrands;}}
The @WebService annotation (line 1) marks the RandService POJO class as a web service, and the
@WebMethod annotation (lines 2 and 3) specifies which of the encapsulated methods
is a service operation. In this example, the RandService class has only two
methods and each of these is annotated as @WebMethod. The @WebMethod annotation is optional but
recommended. In a class annotated as a @WebService, a public instance
method is thereby a service operation even if the method is
not annotated.
This SOAP service code is compiled in the
usual way, assuming JDK 1.6 or greater.
Recall that core Java 6 or greater includes the Endpoint class for publishing web services,
SOAP-based (@WebService) and REST-style (@WebServiceProvider) alike.
The class RandPublisher (see Example 4-2) is the
Endpoint publisher for the RandService.
The publish method used here (line 2) takes two arguments: a URL that specifies the
service endpoint (line 1) and an instance of the service implementation class, in this
case the RandService class (line 2).
In the URL, the port number 8888 and the URI /rs are arbitrary, although a port number greater than
1023 is recommended because modern operating systems typically reserve port numbers below 1024
for particular applications (e.g., port 80 is typically reserved for HTTP requests to a
web server).
The RandPublisher as coded here runs indefinitely, but there are various
way to control an Endpoint publisher’s life span.
The web service publisher can be executed in the usual way:
%javarand.RandPublisher
The output should be similar to this:
PublishingRandServiceatendpointhttp://localhost:8888/rscom.sun.xml.internal.ws.model.RuntimeModelergetRequestWrapperClassINFO:DynamicallycreatingrequestwrapperClassrand.jaxws.Next1com.sun.xml.internal.ws.model.RuntimeModelergetResponseWrapperClassDynamicallycreatingresponsewrapperbeanClassrand.jaxws.Next1Responsecom.sun.xml.internal.ws.model.RuntimeModelergetRequestWrapperClassINFO:DynamicallycreatingrequestwrapperClassrand.jaxws.NextNcom.sun.xml.internal.ws.model.RuntimeModelergetResponseWrapperClassINFO:DynamicallycreatingresponsewrapperbeanClassrand.jaxws.NextNResponse
The first line of output is from the RandPublisher but the others are from the Java
run-time. The dynamically created wrapper classes such as Next1 and
Next1Response are JAX-B artifacts that represent the
incoming SOAP request (Next1) and the outgoing SOAP response (Next1Response).
Once the service is published, a utility such as curl can be used to confirm that the service is indeed up and running:
%curlhttp://localhost:8888/rs?xsd=1
This curl request contains the query string entry xsd=1 that asks for the XML Schema associated with this
service; the schema, like the JAX-B artifacts, is generated dynamically (see Example 4-3).
Example 4-3. The XML Schema generated dynamically for the RandService
<?xmlversion="1.0"encoding="UTF-8"?><xs:schemaxmlns:tns="http://rand/"xmlns:xs="http://www.w3.org/2001/XMLSchema"version="1.0"targetNamespace="http://rand/"><xs:elementname="next1"type="tns:next1"></xs:element><xs:elementname="next1Response"type="tns:next1Response"></xs:element><xs:elementname="nextN"type="tns:nextN"></xs:element><xs:elementname="nextNResponse"type="tns:nextNResponse"></xs:element><xs:complexTypename="next1"><xs:sequence></xs:sequence></xs:complexType><xs:complexTypename="next1Response"><xs:sequence><xs:elementname="return"type="xs:int"></xs:element></xs:sequence></xs:complexType><xs:complexTypename="nextN"><xs:sequence><xs:elementname="arg0"type="xs:int"></xs:element></xs:sequence></xs:complexType><xs:complexTypename="nextNResponse"><xs:sequence><xs:elementname="return"type="xs:int"minOccurs="0"maxOccurs="unbounded"></xs:element></xs:sequence></xs:complexType></xs:schema>
The schema will be studied carefully later. For now, the point of interest is that
the schema provides a data type for each SOAP message that travels, in either direction,
between the
service and the client. Each message is of an XML Schema complexType as opposed to an
simple type such as xsd:date, xsd:string, or xsd:integer.
In the RandService there are two SOAP messages (for instance, the messages Next1 and
Next1Response) per web service operation (in this case, the next1 operation) because each operation
implements the familiar request/response pattern: a client issues a request, delivered to the
service as a
Next1 SOAP message, and gets a response, in this case a Next1Response message, in return.
Accordingly, the schema contains four typed SOAP messages because the RandService has two
operations in the request/response pattern, which means two messages per operation. The number
of complexType occurrences in the XML Schema may exceed the total number of messages needed
to implement the service’s operations because special error messages, SOAP faults, also may
be defined in the XML Schema. SOAP faults are covered in the next chapter.
The XML Schema types such as Next1 and Next1Response are the XML counterparts to
the JAX-B artifacts, noted earlier, with the same names. The schema types and the
JAX-B types together allow the SOAP libraries to transform Java objects into XML documents (in particular, SOAP Envelope
instances)
and SOAP Envelope instances into Java objects. The Endpoint publisher’s underlying SOAP libraries
handle the generation of the JAX-B artifacts and the generation of the XML Schema.
Publishing a SOAP-Based Service with a Standalone Web Server
Publishing a @WebService with Tomcat or Jetty is almost the same as publishing a @WebServiceProvider (see
A RESTful Service as a @WebServiceProvider) with
these web servers. Here, for quick review, are the details.
Two configuration files are needed:
the usual file web.xml and the additional file sun-jaxws.xml. Here is the web.xml, which would work for
any implementation annotated as @WebService or @WebServiceProvider:
<?xmlversion="1.0"encoding="UTF-8"?><web-app><listener><listener-class>com.sun.xml.ws.transport.http.servlet.WSServletContextListener</listener-class></listener><servlet><servlet-name>jaxws</servlet-name><servlet-class>com.sun.xml.ws.transport.http.servlet.WSServlet</servlet-class><load-on-startup>1</load-on-startup></servlet><servlet-mapping><servlet-name>jaxws</servlet-name><url-pattern>/*</url-pattern></servlet-mapping></web-app>
The Metro classes WSServletContextListener and WSServlet are in the JAR file
currently named webservices-rt.jar, which can be downloaded with the rest of Metro
JARs. A second Metro library file webservices-api.jar is also
required.
The JAR files in question should be in the src directory so that
the Ant script can package them in the deployed WAR file. In any case, the
WSServletContextListener parses the sun-jaxws.xml file.
The WSServlet acts as the interceptor: the servlet receives incoming requests and
dispatches these to the RandService.
The second configuration file, sun-jaxws.xml, is:
<?xmlversion="1.0"encoding="UTF-8"?><endpointsversion="2.0"xmlns="http://java.sun.com/xml/ns/jax-ws/ri/runtime"><endpointimplementation="rand.RandService"name="RandService"url-pattern="/*"/></endpoints>
This file completes the routing by notifying the WSServletContextListener that
the WSServlet should dispatch requests to a RandService instance (line 1).
With the two configuration files and the Metro library JARs in the src
directory, the RandService can be deployed to Tomcat in the usual way:
%ant-Dwar.name=randdeploy
Once the @WebService has been deployed, a curl call or a browser can be used to
verify that the service is up and running:
%curlhttp://localhost:8080/myWarFileName?xsd=1
If successful, this command returns the XML Schema associated with the service.
Even this first and rather simple example underscores a major appeal of SOAP-based services: underlying SOAP libraries handle the conversions between native language types (in this case, Java types) and XML Schema types. Figure 4-1 depicts the architecture.
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