1、服务注册:(目录)UDDI允许用户查找服务的基石
2、服务需求者:(传输)SOAP是连接应用和数据的机制
3、服务提供商:(接口)用WSDL定义如何应用服务
服务提供商-发布-服务注册
服务需求者-发现-服务注册
服务提供者-绑定-服务提供商
This tutorial shows you how to write contract-first Web services , that is, developing web services that start with the XML Schema/WSDL contract first followed by the Java code second. Spring-WS focuses on this development style, and this tutorial will help you get started. Note that the first part of this tutorial contains almost no Spring-WS specific information: it is mostly about XML, XSD, and WSDL. The second part focusses on implementing this contract using Spring-WS .
The most important thing when doing contract-first Web service development is to try and think in terms of XML. This means that Java-language concepts are of lesser importance. It is the XML that is sent across the wire, and you should focus on that. The fact that Java is used to implement the Web service is an implementation detail. An important detail, but a detail nonetheless.
In this tutorial, we will define a Web service that is created by a Human Resources department. Clients can send holiday request forms to this service to book a holiday.
In this section, we will focus on the actual XML messages that are sent to and from the Web service. We will start out by determining what these messages look like.
In the scenario, we have to deal with holiday requests, so it makes sense to determine what a holiday looks like in XML:
<Holiday xmlns="http://mycompany.com/hr/schemas"> <StartDate>2006-07-03</StartDate> <EndDate>2006-07-07</EndDate> </Holiday>
A holiday consists of a start date and an end date. We have also decided to use the standard ISO 8601 date format for the dates, because that will save a lot of parsing hassle. We have also added a namespace to the element, to make sure our elements can used within other XML documents.
There is also the notion of an employee in the scenario. Here is what it looks like in XML:
<Employee xmlns="http://mycompany.com/hr/schemas"> <Number>42</Number> <FirstName>Arjen</FirstName> <LastName>Poutsma</LastName> </Employee>
We have used the same namespace as before. If this <Employee/>
element could be used in other scenarios, it might make sense to use a different namespace, such as http://mycompany.com/employees/schemas
.
Both the holiday and employee element can be put in a <HolidayRequest/>
:
<HolidayRequest xmlns="http://mycompany.com/hr/schemas"> <Holiday> <StartDate>2006-07-03</StartDate> <EndDate>2006-07-07</EndDate> </Holiday> <Employee> <Number>42</Number> <FirstName>Arjen</FirstName> <LastName>Poutsma</LastName> </Employee> </HolidayRequest>
The order of the two elements does not matter: <Employee/>
could have been the first element just as well. What is important is that all of the data is there. In fact, the data is the only thing that is important: we are taking a data-driven approach.
Now that we have seen some examples of the XML data that we will use, it makes sense to formalize this into a schema. This data contract defines the message format we accept. There are four different ways of defining such a contract for XML:
DTDs have limited namespace support, so they are not suitable for Web services. Relax NG and Schematron certainly are easier than XML Schema. Unfortunately, they are not so widely supported across platforms. We will use XML Schema.
By far the easiest way to create an XSD is to infer it from sample documents. Any good XML editor or Java IDE offers this functionality. Basically, these tools use some sample XML documents, and generate a schema from it that validates them all. The end result certainly needs to be polished up, but it's a great starting point.
Using the sample described above, we end up with the following generated schema:
<xs:schema xmlns:xs="http://www.w3.org/2001/XMLSchema" elementFormDefault="qualified" targetNamespace="http://mycompany.com/hr/schemas" xmlns:hr="http://mycompany.com/hr/schemas"> <xs:element name="HolidayRequest"> <xs:complexType> <xs:sequence> <xs:element ref="hr:Holiday"/> <xs:element ref="hr:Employee"/> </xs:sequence> </xs:complexType> </xs:element> <xs:element name="Holiday"> <xs:complexType> <xs:sequence> <xs:element ref="hr:StartDate"/> <xs:element ref="hr:EndDate"/> </xs:sequence> </xs:complexType> </xs:element> <xs:element name="StartDate" type="xs:NMTOKEN"/> <xs:element name="EndDate" type="xs:NMTOKEN"/> <xs:element name="Employee"> <xs:complexType> <xs:sequence> <xs:element ref="hr:Number"/> <xs:element ref="hr:FirstName"/> <xs:element ref="hr:LastName"/> </xs:sequence> </xs:complexType> </xs:element> <xs:element name="Number" type="xs:integer"/> <xs:element name="FirstName" type="xs:NCName"/> <xs:element name="LastName" type="xs:NCName"/> </xs:schema>
This generated schema obviously can be improved. The first thing to notice is that every type has a root-level element declaration. This means that the Web service should be able to accept all of these elements as data. This is not desirable: we only want to accept a <HolidayRequest/>
. By removing the wrapping element tags (thus keeping the types), and inlining the results, we can accomplish this.
<xs:schema xmlns:xs="http://www.w3.org/2001/XMLSchema" xmlns:hr="http://mycompany.com/hr/schemas" elementFormDefault="qualified" targetNamespace="http://mycompany.com/hr/schemas"> <xs:element name="HolidayRequest"> <xs:complexType> <xs:sequence> <xs:element name="Holiday" type="hr:HolidayType"/> <xs:element name="Employee" type="hr:EmployeeType"/> </xs:sequence> </xs:complexType> </xs:element> <xs:complexType name="HolidayType"> <xs:sequence> <xs:element name="StartDate" type="xs:NMTOKEN"/> <xs:element name="EndDate" type="xs:NMTOKEN"/> </xs:sequence> </xs:complexType> <xs:complexType name="EmployeeType"> <xs:sequence> <xs:element name="Number" type="xs:integer"/> <xs:element name="FirstName" type="xs:NCName"/> <xs:element name="LastName" type="xs:NCName"/> </xs:sequence> </xs:complexType> </xs:schema>
The schema still has one problem: with a schema like this, you can expect the following messages to validate:
<HolidayRequest xmlns="http://mycompany.com/hr/schemas">
<Holiday>
<StartDate>this is not a date</StartDate>
<EndDate>neither is this</EndDate>
</Holiday>
<!-- ... -->
</HolidayRequest>
Clearly, we must make sure that the start and end date are really dates. XML Schema has an excellent built-in date
type which we can use. We also change the NCName
s to string
s. Finally, we change the sequence
in <HolidayRequest/>
to all
. This tells the XML parser that the order of <Holiday/>
and <Employee/>
is not significant. Our final XSD now looks like this:
<xs:schema xmlns:xs="http://www.w3.org/2001/XMLSchema" xmlns:hr="http://mycompany.com/hr/schemas" elementFormDefault="qualified" targetNamespace="http://mycompany.com/hr/schemas"> <xs:element name="HolidayRequest"> <xs:complexType> <xs:all> <xs:element name="Holiday" type="hr:HolidayType"/> <xs:element name="Employee" type="hr:EmployeeType"/> </xs:all> </xs:complexType> </xs:element> <xs:complexType name="HolidayType"> <xs:sequence> <xs:element name="StartDate" type="xs:date"/> <xs:element name="EndDate" type="xs:date"/> </xs:sequence> </xs:complexType> <xs:complexType name="EmployeeType"> <xs:sequence> <xs:element name="Number" type="xs:integer"/> <xs:element name="FirstName" type="xs:string"/> <xs:element name="LastName" type="xs:string"/> </xs:sequence> </xs:complexType> </xs:schema>
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We store this file as hr.xsd
.
A service contract is generally expressed as a WSDL file. Note that in Spring-WS, writing the WSDL by hand is not required . Based on the XSD and some conventions, Spring-WS can create the WSDL for you, as explained in the section entitled Section 3.6, “Implementing the Endpoint” . You can skip to the next section if you want to; the remainder of this section will show you how to write your own WSDL by hand.
We start our WSDL with the standard preamble, and by importing our existing XSD. To separate the schema from the definition, we will use a separate namespace for the WSDL definitions: http://mycompany.com/hr/definitions
.
<wsdl:definitions xmlns:wsdl="http://schemas.xmlsoap.org/wsdl/" xmlns:soap="http://schemas.xmlsoap.org/wsdl/soap/" xmlns:schema="http://mycompany.com/hr/schemas" xmlns:tns="http://mycompany.com/hr/definitions" targetNamespace="http://mycompany.com/hr/definitions"> <wsdl:types> <xsd:schema xmlns:xsd="http://www.w3.org/2001/XMLSchema"> <xsd:import namespace="http://mycompany.com/hr/schemas" schemaLocation="hr.xsd"/> </xsd:schema> </wsdl:types>
Next, we add our messages based on the written schema types. We only have one message: one with the <HolidayRequest/>
we put in the schema:
<wsdl:message name="HolidayRequest"> <wsdl:part element="schema:HolidayRequest" name="HolidayRequest"/> </wsdl:message>
We add the message to a port type as an operation:
<wsdl:portType name="HumanResource"> <wsdl:operation name="Holiday"> <wsdl:input message="tns:HolidayRequest" name="HolidayRequest"/> </wsdl:operation> </wsdl:portType>
That finished the abstract part of the WSDL (the interface, as it were), and leaves the concrete part. The concrete part consists of a binding
, which tells the client how to invoke the operations you've just defined; and a service
, which tells it where to invoke it.
Adding a concrete part is pretty standard: just refer to the abstract part you defined previously, make sure you use document/literal for the soap:binding
elements (rpc/encoded
is deprecated), pick a soapAction
for the operation (in this case http://mycompany.com/RequestHoliday
, but any URI will do), and determine the location
URL where you want request to come in (in this case http://mycompany.com/humanresources
):
<wsdl:definitions xmlns:wsdl="http://schemas.xmlsoap.org/wsdl/" xmlns:soap="http://schemas.xmlsoap.org/wsdl/soap/" xmlns:schema="http://mycompany.com/hr/schemas" xmlns:tns="http://mycompany.com/hr/definitions" targetNamespace="http://mycompany.com/hr/definitions"> <wsdl:types> <xsd:schema xmlns:xsd="http://www.w3.org/2001/XMLSchema"> <xsd:import namespace="http://mycompany.com/hr/schemas" schemaLocation="hr.xsd"/> </xsd:schema> </wsdl:types> <wsdl:message name="HolidayRequest"> <wsdl:part element="schema:HolidayRequest" name="HolidayRequest"/> </wsdl:message> <wsdl:portType name="HumanResource"> <wsdl:operation name="Holiday"> <wsdl:input message="tns:HolidayRequest" name="HolidayRequest"/> </wsdl:operation> </wsdl:portType> <wsdl:binding name="HumanResourceBinding" type="tns:HumanResource"> <soap:binding style="document" transport="http://schemas.xmlsoap.org/soap/http"/> <wsdl:operation name="Holiday"> <soap:operation soapAction="http://mycompany.com/RequestHoliday"/> <wsdl:input name="HolidayRequest"> <soap:body use="literal"/> </wsdl:input> </wsdl:operation> </wsdl:binding> <wsdl:service name="HumanResourceService"> <wsdl:port binding="tns:HumanResourceBinding" name="HumanResourcePort"> <soap:address location="http://localhost:8080/holidayService/"/> </wsdl:port> </wsdl:service> </wsdl:definitions>
We import the schema defined in Section 3.3, “Data Contract” . |
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This is the final WSDL. We will describe how to implement the resulting schema and WSDL in the next section.
In this section, we will be using Maven2 to create the initial project structure for us. Doing so is not required, but greatly reduces the amount of code we have to write to setup our HolidayService.
The following command creates a Maven2 web application project for us, using the Spring-WS archetype (that is, project template)
mvn archetype:create -DarchetypeGroupId=org.springframework.ws \ -DarchetypeArtifactId=spring-ws-archetype \ -DarchetypeVersion=1.5.9 \ -DgroupId=com.mycompany.hr \ -DartifactId=holidayService
This command will create a new directory called holidayService
. In this directory, there is a 'src/main/webapp'
directory, which will contain the root of the WAR file. You will find the standard web application deployment descriptor 'WEB-INF/web.xml'
here, which defines a Spring-WS MessageDispatcherServlet
and maps all incoming requests to this servlet:
<web-app xmlns="http://java.sun.com/xml/ns/j2ee" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xsi:schemaLocation="http://java.sun.com/xml/ns/j2ee http://java.sun.com/xml/ns/j2ee/web-app_2_4.xsd" version="2.4"> <display-name>MyCompany HR Holiday Service</display-name> <!-- take especial notice of the name of this servlet --> <servlet> <servlet-name>spring-ws </servlet-name> <servlet-class>org.springframework.ws.transport.http.MessageDispatcherServlet</servlet-class> </servlet> <servlet-mapping> <servlet-name>spring-ws</servlet-name> <url-pattern>/*</url-pattern> </servlet-mapping> </web-app>
In addition to the above 'WEB-INF/web.xml'
file, you will also need another, Spring-WS-specific configuration file, named 'WEB-INF/spring-ws-servlet.xml'
. This file contains all of the Spring-WS-specific beans such as EndPoints
, WebServiceMessageReceivers
, and suchlike, and is used to create a new Spring container. The name of this file is derived from the name of the attendant servlet (in this case 'spring-ws'
) with '-servlet.xml'
appended to it. So if you defined a MessageDispatcherServlet
with the name 'dynamite'
, the name of the Spring-WS-specific configuration file would be 'WEB-INF/dynamite-servlet.xml'
.
(You can see the contents of the 'WEB-INF/spring-ws-servlet.xml'
file for this example in ??? .)
In Spring-WS, you will implement Endpoints to handle incoming XML messages. There are two flavors of endpoints: message endpoints and payload endpoints . Message endpoints give access to the entire XML message, including SOAP headers. Typically, the endpoint will only be interested in the payload of the message, that is the contents of the SOAP body. In that case, creating a payload endpoint makes more sense.
In this sample application, we are going to use JDom to handle the XML message. We are also using XPath , because it allows us to select particular parts of the XML JDOM tree, without requiring strict schema conformance. We extend our endpoint from AbstractJDomPayloadEndpoint
, because that will give us a JDOM element to execute the XPath queries on.
package com.mycompany.hr.ws; import java.text.SimpleDateFormat; import java.util.Date; import com.mycompany.hr.service.HumanResourceService; import org.jdom.Element; import org.jdom.JDOMException; import org.jdom.Namespace; import org.jdom.xpath.XPath; import org.springframework.ws.server.endpoint.AbstractJDomPayloadEndpoint; public class HolidayEndpoint extends AbstractJDomPayloadEndpoint { private XPath startDateExpression; private XPath endDateExpression; private XPath nameExpression; private final HumanResourceService humanResourceService; public HolidayEndpoint(HumanResourceService humanResourceService) throws JDOMExceptio n { this.humanResourceService = humanResourceService; Namespace namespace = Namespace.getNamespace("hr", "http://mycompany.com/hr/schemas"); startDateExpression = XPath.newInstance("//hr:StartDate"); startDateExpression.addNamespace(namespace); endDateExpression = XPath.newInstance("//hr:EndDate"); endDateExpression.addNamespace(namespace); nameExpression = XPath.newInstance("concat(//hr:FirstName,' ',//hr:LastName)"); nameExpression.addNamespace(namespace); } protected Element invokeInternal(Element holidayRequest) throws Exception { SimpleDateFormat dateFormat = new SimpleDateFormat("yyyy-MM-dd"); Date startDate = dateFormat.parse(startDateExpression.valueOf(holidayRequest)); Date endDate = dateFormat.parse(endDateExpression.valueOf(holidayRequest)); String name = nameExpression.valueOf(holidayRequest); humanResourceService.bookHoliday(startDate, endDate, name); return null; } }
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Using JDOM is just one of the options to handle the XML: other options include DOM, dom4j, XOM, SAX, and StAX, but also marshalling techniques like JAXB, Castor, XMLBeans, JiBX, and XStream. We chose JDOM because it gives us access to the raw XML, and because it is based on classes (not interfaces and factory methods as with W3C DOM and dom4j), which makes the code less verbose. We use XPath because it is less fragile than marshalling technologies: we don't care for strict schema conformance, as long as we can find the dates and the name.
Because we use JDOM, we must add some dependencies to the Maven pom.xml
, which is in the root of our project directory. Here is the relevant section of the POM:
<dependencies> <dependency> <groupId>org.springframework.ws</groupId> <artifactId>spring-ws-core</artifactId> <version>1.5.9</version> </dependency> <dependency> <groupId>jdom</groupId> <artifactId>jdom</artifactId> <version>1.0</version> </dependency> <dependency> <groupId>jaxen</groupId> <artifactId>jaxen</artifactId> <version>1.1</version> </dependency> <dependency> <groupId>javax.xml.soap</groupId> <artifactId>saaj-api</artifactId> <version>1.3</version> <scope>runtime</scope> </dependency> <dependency> <groupId>com.sun.xml.messaging.saaj</groupId> <artifactId>saaj-impl</artifactId> <version>1.3</version> <scope>runtime</scope> </dependency> </dependencies>
Here is how we would configure these classes in our spring-ws-servlet.xml
Spring XML configuration file:
<beans xmlns="http://www.springframework.org/schema/beans"> <bean id="holidayEndpoint" class="com.mycompany.hr.ws.HolidayEndpoint"> <constructor-arg ref="hrService"/> </bean> <bean id="hrService" class="com.mycompany.hr.service.StubHumanResourceService"/> </beans>
Now that we have written an endpoint that handles the message, we must define how incoming messages are routed to that endpoint. In Spring-WS, this is the responsibility of an EndpointMapping
. In this tutorial, we will route messages based on their content, by using a PayloadRootQNameEndpointMapping
. Here is how we configure a PayloadRootQNameEndpointMapping
in spring-ws-servlet.xml
:
<bean class="org.springframework.ws.server.endpoint.mapping.PayloadRootQNameEndpointMapping"> <property name="mappings"> <props> <prop key="{http://mycompany.com/hr/schemas}HolidayRequest">holidayEndpoint</prop> </props> </property> <property name="interceptors"> <bean class="org.springframework.ws.server.endpoint.interceptor.PayloadLoggingInterceptor"/> </property> </bean>
This means that whenever an XML message is received with the namespace http://mycompany.com/hr/schemas
and the HolidayRequest
local name, it will be routed to the holidayEndpoint
. (It also adds a PayloadLoggingInterceptor
, that dumps incoming and outgoing messages to the log.)
Finally, we need to publish the WSDL. As stated in Section 3.4, “Service contract” , we don't need to write a WSDL ourselves; Spring-WS can generate one for us based on some conventions. Here is how we define the generation:
<bean id="holiday" class="org.springframework.ws.wsdl.wsdl11.DefaultWsdl11Definition"> <property name="schema" ref="schema"/> <property name="portTypeName" value="HumanResource"/> <property name="locationUri" value="/holidayService/"/> <property name="targetNamespace" value="http://mycompany.com/hr/definitions"/> </bean> <bean id="schema" class="org.springframework.xml.xsd.SimpleXsdSchema"> <property name="xsd" value="/WEB-INF/hr.xsd"/> </bean>
The bean id determines the URL where the WSDL can be retrieved. In this case, the bean id is |
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Next, we define the WSDL port type to be |
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We set the location where the service can be reached: |
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Finally, we define the target namespace for the WSDL definition itself. Setting these is not required. If not set, we give the WSDL the same namespace as the schema. |
You can create a WAR file using mvn install . If you deploy the application (to Tomcat, Jetty, etc.), and point your browser at this location , you will see the generated WSDL. This WSDL is ready to be used by clients, such as soapUI , or other SOAP frameworks.
That concludes this tutorial. The tutorial code can be found in the full distribution of Spring-WS. The next step would be to look at the echo sample application that is part of the distribution. After that, look at the airline sample, which is a bit more complicated, because it uses JAXB, WS-Security, Hibernate, and a transactional service layer. Finally, you can read the rest of the reference documentation.