Service Component Architecture SCA-J Common Annotations and APIs Specification Version 1.1
Committee Specification Draft 05
8 November 2010
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Technical Committee:
OASIS Service Component Architecture / J (SCA-J) TC
Chair(s):
David Booz, IBM
Anish Karmarkar, Oracle Corporation
Editor(s):
David Booz, IBM
Mike Edwards, IBM
Anish Karmarkar, Oracle Corporation
Related work:
This specification replaces or supersedes:
This specification is related to:
http://docs.oasis-open.org/opencsa/sca-j/sca-caa-apis-1.1-csd05.jar
http://docs.oasis-open.org/opencsa/sca-j/sca-j-caa-javadoc-1.1-csd05.zip
http://docs.oasis-open.org/opencsa/sca-j/javadoc/index.html
Declared XML Namespace(s):
http://docs.oasis-open.org/ns/opencsa/sca/200912
Java Artifacts:
http://docs.oasis-open.org/opencsa/sca-j/sca-j-common-annotations-and-apis-1.1-csd05.zip
Abstract:
The SCA-J Common Annotations and APIs specification defines a Java syntax for programming concepts defined in the SCA Assembly Model Specification. It specifies a set of APIs and annotations that can be used by Java-based artifacts described by other SCA specifications such as the POJO Component Implementation Specification [JAVA_CI].
Specifically, this specification covers:
1. Implementation metadata for specifying component services, references, and properties
2. A client and component API
3. Metadata for asynchronous services
4. Metadata for callbacks
5. Definitions of standard component implementation scopes
6. Java to WSDL and WSDL to Java mappings
7. Security policy annotations
Note that other Java-based SCA specifications can choose to implement their own mappings of assembly model concepts using native APIs and idioms when appropriate.
Status:
This document was last revised or approved by the OASIS Service Component Architecture / J (SCA-J) TC on the above date. The level of approval is also listed above. Check the “Latest Version” or “Latest Approved Version” location noted above for possible later revisions of this document.
Technical Committee members should send comments on this specification to the Technical Committee’s email list. Others should send comments to the Technical Committee by using the “Send A Comment” button on the Technical Committee’s web page at http://www.oasis-open.org/committees/sca-j/.
For information on whether any patents have been disclosed that might be essential to implementing this specification, and any offers of patent licensing terms, please refer to the Intellectual Property Rights section of the Technical Committee web page (http://www.oasis-open.org/committees/sca-j/ipr.php.
Citation Format:
When referencing this specification the following citation format should be used:
sca-javacaa-v1.1 OASIS Committee Specification Draft 05, Service Component Architecture SCA-J Common Annotations and APIs Specification Version 1.1, November 2010. http://docs.oasis-open.org/opencsa/sca-j/sca-javacaa-1.1-spec-csd05.pdf
Notices
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Table of Contents
2.1.2 Java Semantics of a Remotable Service
2.1.3 Java Semantics of a Local Service
2.2 Implementation Scopes: @Scope, @Init, @Destroy
2.3.1 Marking Services as “allows pass by reference”
2.3.2 Marking References as “allows pass by reference”
2.3.3 Applying “allows pass by reference” to Service Proxies
2.3.4 Using “allows pass by reference” to Optimize Remotable Calls
3.1 Java Interface Element – <interface.java>
3.5 SCA Java Annotations for Interface Classes
3.6 Compatibility of Java Interfaces
4 SCA Component Implementation Lifecycle
4.1 Overview of SCA Component Implementation Lifecycle
4.2 SCA Component Implementation Lifecycle State Diagram
5.1 Accessing Services from an SCA Component
5.1.1 Using the Component Context API
5.2 Accessing Services from non-SCA Component Implementations
5.2.1 SCAClientFactory Interface and Related Classes
7.2.2 Callback Instance Management
7.2.4 Implementing Multiple Bidirectional Interfaces
7.3 Asynchronous handling of Long Running Service Operations
7.4 SCA Asynchronous Service Interface
8.1 General Intent Annotations
8.2 Specific Intent Annotations
8.2.1 How to Create Specific Intent Annotations
8.3 Application of Intent Annotations
8.3.1 Intent Annotation Examples
8.3.2 Inheritance and Annotation
8.4 Relationship of Declarative and Annotated Intents
8.6 Security Policy Annotations
8.7 Transaction Policy Annotations
9.3 ServiceReference Interface
9.4 ResponseDispatch interface
9.6 ServiceUnavailableException
9.10 SCAClientFactoryFinder Interface
9.11 SCAClientFactoryFinderImpl Class
10.16 @ManagedSharedTransaction
11 WSDL to Java and Java to WSDL
11.1 JAX-WS Annotations and SCA Interfaces
11.2 JAX-WS Client Asynchronous API for a Synchronous Service
11.3 Treatment of SCA Asynchronous Service API
A. XML Schema: sca-interface-java-1.1.xsd
B. Java Classes and Interfaces
B.1 SCAClient Classes and Interfaces
B.1.2 SCAClientFactoryFinder interface
B.1.3 SCAClientFactoryFinderImpl class
B.1.4 SCAClient Classes and Interfaces - what does a vendor need to do?
The SCA-J Common Annotations and APIs specification defines a Java syntax for programming concepts defined in the SCA Assembly Model Specification [ASSEMBLY]. It specifies a set of APIs and annotations that can be used by SCA Java-based specifications.
Specifically, this specification covers:
1. Implementation metadata for specifying component services, references, and properties
2. A client and component API
3. Metadata for asynchronous services
4. Metadata for callbacks
5. Definitions of standard component implementation scopes
6. Java to WSDL and WSDL to Java mappings
7. Security policy annotations
The goal of defining the annotations and APIs in this specification is to promote consistency and reduce duplication across the various SCA Java-based specifications. The annotations and APIs defined in this specification are designed to be used by other SCA Java-based specifications in either a partial or complete fashion.
The key words “MUST”, “MUST NOT”, “REQUIRED”, “SHALL”, “SHALL NOT”, “SHOULD”, “SHOULD NOT”, “RECOMMENDED”, “MAY”, and “OPTIONAL” in this document are to be interpreted as described in [RFC2119].
[RFC2119] S. Bradner, Key words for use in RFCs to Indicate Requirement Levels, http://www.ietf.org/rfc/rfc2119.txt, IETF RFC 2119, March 1997.
[ASSEMBLY] OASIS Committee Draft
06, SCA Assembly Model Specification Version 1.1, August 2010.
http://docs.oasis-open.org/opencsa/sca-assembly/sca-assembly-1.1-spec-cd06.pdf
[SDO] OASIS Committee Draft 02, Service Data Objects
Specification Version 3.0, November 2009.
http://www.oasis-open.org/committees/download.php/35313/sdo-3.0-cd02.zip
[JAX-B] JAXB 2.1 Specification, http://www.jcp.org/en/jsr/detail?id=222
[WSDL] WSDL Specification, WSDL 1.1: http://www.w3.org/TR/wsdl,
[POLICY] OASIS Committee
Draft 04, SCA Policy Framework Version 1.1, September 2010.
http://docs.oasis-open.org/opencsa/sca-policy/sca-policy-1.1-spec-cd04.pdf
[JSR-250] Common Annotations for the Java Platform specification (JSR-250), http://www.jcp.org/en/jsr/detail?id=250
[JAX-WS] JAX-WS 2.1 Specification (JSR-224), http://www.jcp.org/en/jsr/detail?id=224
[JAVABEANS] JavaBeans 1.01
Specification,
http://java.sun.com/javase/technologies/desktop/javabeans/api/
[JAAS] Java Authentication and Authorization Service Reference Guide
http://java.sun.com/javase/6/docs/technotes/guides/security/jaas/JAASRefGuide.html
[EBNF-Syntax] Extended BNF syntax format used for formal
grammar of constructs
http://www.w3.org/TR/2004/REC-xml-20040204/#sec-notation
[JAVA_CI] OASIS Committee Specification Draft 03, SCA POJO Component Implementation Specification Version 1.1, November 2010.
http://docs.oasis-open.org/opencsa/sca-j/sca-javaci-1.1-spec-csd03.pdf
This section describes SCA Java-based metadata, which applies to Java-based implementation types.
The @Service annotation is used on a Java class to specify the interfaces of the services provided by the implementation. Service interfaces are defined in one of the following ways:
· As a Java interface
· As a Java class
· As a Java interface generated from a Web Services Description Language [WSDL] (WSDL) portType (Java interfaces generated from WSDL portTypes are always remotable)
A remotable service is defined using the @Remotable annotation on the Java interface or Java class that defines the service, or on a service reference. Remotable services are intended to be used for coarse grained services, and the parameters are passed by-value. Remotable Services MUST NOT make use of method overloading. [JCA20001]
Snippet 2‑1 shows an example of a Java interface for a remotable service:
package services.hello;
@Remotable
public interface HelloService {
String hello(String message);
}
Snippet 2‑1: Remotable Java Interface
A local service can only be called by clients that are deployed within the same address space as the component implementing the local service.
A local interface is defined by a Java interface or a Java class with no @Remotable annotation.
Snippet 2‑2 shows an example of a Java interface for a local service:
package services.hello;
public interface HelloService {
String hello(String message);
}
Snippet 2‑2: Local Java Interface
The style of local interfaces is typically fine grained and is intended for tightly coupled interactions.
The data exchange semantic for calls to local services is by-reference. This means that implementation code which uses a local interface needs to be written with the knowledge that changes made to parameters (other than simple types) by either the client or the provider of the service are visible to the other.
Accessing a service using reference injection is done by defining a field, a setter method, or a constructor parameter typed by the service interface and annotated with a @Reference annotation.
Implementations can be configured with data values through the use of properties, as defined in the SCA Assembly Model specification [ASSEMBLY]. The @Property annotation is used to define an SCA property.
Component implementations can either manage their own state or allow the SCA runtime to do so. In the latter case, SCA defines the concept of implementation scope, which specifies a visibility and lifecycle contract an implementation has with the SCA runtime. Invocations on a service offered by a component will be dispatched by the SCA runtime to an implementation instance according to the semantics of its implementation scope.
Scopes are specified using the @Scope annotation on the implementation class.
This specification defines two scopes:
· STATELESS
· COMPOSITE
Java-based implementation types can choose to support any of these scopes, and they can define new scopes specific to their type.
An implementation type can allow component implementations to declare lifecycle methods that are called when an implementation is instantiated or the scope is expired.
@Init denotes a method called upon first use of an instance during the lifetime of the scope (except for composite scoped implementation marked to eagerly initialize, see section Composite Scope).
@Destroy specifies a method called when the scope ends.
Note that only no-argument methods with a void return type can be annotated as lifecycle methods.
Snippet 2‑3 is an example showing a fragment of a service implementation annotated with lifecycle methods:
@Init
public void start() {
...
}
@Destroy
public void stop() {
...
}
Snippet 2‑3: Java Component Implementation with Lifecycle Methods
The following sections specify the two standard scopes which a Java-based implementation type can support.
For stateless scope components, there is no implied correlation between implementation instances used to dispatch service requests.
The concurrency model for the stateless scope is single threaded. This means that the SCA runtime MUST ensure that a stateless scoped implementation instance object is only ever dispatched on one thread at any one time. [JCA20002] In addition, within the SCA lifecycle of a stateless scoped implementation instance, the SCA runtime MUST only make a single invocation of one business method. [JCA20003] Note that the SCA lifecycle might not correspond to the Java object lifecycle due to runtime techniques such as pooling.
The meaning of "composite scope" is defined in relation to the composite containing the component.
It is important to distinguish between different uses of a composite, where these uses affect the numbers of instances of components within the composite. There are 2 cases:
a) Where the composite containing the component using the Java implementation is the SCA Domain (i.e. a deployment composite declares the component using the implementation)
b) Where the composite containing the component using the Java implementation is itself used as the implementation of a higher level component (any level of nesting is possible, but the component is NOT at the Domain level)
Where an implementation is used by a "domain level component", and the implementation is marked "Composite" scope, the SCA runtime MUST ensure that all consumers of the component appear to be interacting with a single runtime instance of the implementation. [JCA20004]
Where an implementation is marked "Composite" scope and it is used by a component that is nested inside a composite that is used as the implementation of a higher level component, the SCA runtime MUST ensure that all consumers of the component appear to be interacting with a single runtime instance of the implementation. There can be multiple instances of the higher level component, each running on different nodes in a distributed SCA runtime. [JCA20008]
The SCA runtime can exploit shared state technology in combination with other well known high availability techniques to provide the appearance of a single runtime instance for consumers of composite scoped components.
The lifetime of the containing composite is defined as the time it becomes active in the runtime to the time it is deactivated, either normally or abnormally.
When the implementation class is marked for eager initialization, the SCA runtime MUST create a composite scoped instance when its containing component is started. [JCA20005] If a method of an implementation class is marked with the @Init annotation, the SCA runtime MUST call that method when the implementation instance is created. [JCA20006]
The concurrency model for the composite scope is multi-threaded. This means that the SCA runtime MAY run multiple threads in a single composite scoped implementation instance object and the SCA runtime MUST NOT perform any synchronization. [JCA20007]
Calls to remotable services (see section "Java Semantics of a Remotable Service") have by-value semantics. This means that input parameters passed to the service can be modified by the service without these modifications being visible to the client. Similarly, the return value or exception from the service can be modified by the client without these modifications being visible to the service implementation. For remote calls (either cross-machine or cross-process), these semantics are a consequence of marshalling input parameters, return values and exceptions “on the wire” and unmarshalling them “off the wire” which results in physical copies being made. For local method calls within the same JVM, Java language calling semantics are by-reference and therefore do not provide the correct by-value semantics for SCA remotable interfaces. To compensate for this, the SCA runtime can intervene in these calls to provide by-value semantics by making copies of any mutable objects passed.
The cost of such copying can be very high relative to the cost of making a local call, especially if the data being passed is large. Also, in many cases this copying is not needed if the implementation observes certain conventions for how input parameters, return values and exceptions are used. The @AllowsPassByReference annotation allows service method implementations and client references to be marked as “allows pass by reference” to indicate that they use input parameters, return values and exceptions in a manner that allows the SCA runtime to avoid the cost of copying mutable objects when a remotable service is called locally within the same JVM.
Marking a service method implementation as “allows pass by reference” asserts that the method implementation observes the following restrictions:
· Method execution will not modify any input parameter before the method returns.
· The service implementation will not retain a reference to any mutable input parameter, mutable return value or mutable exception after the method returns.
· The method will observe “allows pass by reference” client semantics (see section 2.3.2) for any callbacks that it makes.
See section "@AllowsPassByReference" for details of how the @AllowsPassByReference annotation is used to mark a service method implementation as “allows pass by reference”.
Marking a client reference as “allows pass by reference” asserts that method calls through the reference observe the following restrictions:
· The client implementation will not modify any of the method’s input parameters before the method returns. Such modifications might occur in callbacks or separate client threads.
· If the method is one-way, the client implementation will not modify any of the method’s input parameters at any time after calling the method. This is because one-way method calls return immediately without waiting for the service method to complete.
See section "Applying “allows pass by reference” to Service Proxies" for details of how the @AllowsPassByReference annotation is used to mark a client reference as “allows pass by reference”.
Service method calls are made by clients using service proxies, which can be obtained by injection into client references or by making API calls. A service proxy is marked as “allows pass by reference” if and only if any of the following applies:
· It is injected into a reference or callback reference that is marked “allows pass by reference”.
· It is obtained by calling ComponentContext.getService() or ComponentContext.getServices() with the name of a reference that is marked “allows pass by reference”.
· It is obtained by calling RequestContext.getCallback() from a service implementation that is marked “allows pass by reference”.
· It is obtained by calling ServiceReference.getService() on a service reference that is marked “allows pass by reference”.
A service reference for a remotable service call is marked “allows pass by reference” if and only if any of the following applies:
· It is injected into a reference or callback reference that is marked “allows pass by reference”.
· It is obtained by calling ComponentContext.getServiceReference() or ComponentContext.getServiceReferences() with the name of a reference that is marked “allows pass by reference”.
· It is obtained by calling RequestContext.getCallbackReference() from a service implementation that is marked “allows pass by reference”.
· It is obtained by calling ComponentContext.cast() on a proxy that is marked “allows pass by reference”.
The SCA runtime MAY use by-reference semantics when passing input parameters, return values or exceptions on calls to remotable services within the same JVM if both the service method implementation and the service proxy used by the client are marked “allows pass by reference”. [JCA20009]
The SCA runtime MUST use by-value semantics when passing input parameters, return values and exceptions on calls to remotable services within the same JVM if the service method implementation is not marked “allows pass by reference” or the service proxy used by the client is not marked “allows pass by reference”. [JCA20010]
This section describes the SCA Java interface element and the SCA metadata for Java interfaces.
The Java interface element is used in SCA Documents in places where an interface is declared in terms of a Java interface class. The Java interface element identifies the Java interface class and can also identify a callback interface, where the first Java interface represents the forward (service) call interface and the second interface represents the interface used to call back from the service to the client.
It is possible that the Java interface class referenced by the <interface.java/> element contains one or more annotations defined by the JAX-WS specification [JAX-WS]. These annotations can affect the interpretation of the <interface.java/> element. In the most extreme case, the annotations cause the replacement of the <interface.java/> element with an <interface.wsdl/> element. The relevant JAX-WS annotations and their effects on the <interface.java/> element are described in the section "JAX-WS Annotations and SCA Interfaces".
The interface.java element MUST conform to the schema defined in the sca-interface-java.xsd schema. [JCA30004]
Snippet 3‑1 is the pseudo-schema for the interface.java element
<interface.java interface="NCName"
callbackInterface="NCName"?
requires="list of xs:QName"?
policySets="list of xs:QName"?
remotable="boolean"?/>
Snippet 3‑1: interface.java Pseudo-Schema
The interface.java element has the attributes:
· interface : NCName (1..1) – the Java interface class to use for the service interface. The value of the @interface attribute MUST be the fully qualified name of the Java interface class [JCA30001]
If the identified class is annotated with either the JAX-WS @WebService or @WebServiceProvider annotations and the annotation has a non-empty wsdlLocation property, then the SCA Runtime MUST act as if an <interface.wsdl/> element is present instead of the <interface.java/> element, with an @interface attribute identifying the portType mapped from the Java interface class and containing @requires and @policySets attribute values equal to the @requires and @policySets attribute values of the <interface.java/> element. [JCA30010]
· callbackInterface : NCName (0..1) – the Java interface class to use for the callback interface. The value of the @callbackInterface attribute MUST be the fully qualified name of a Java interface used for callbacks [JCA30002]
· requires : QName (0..1) – a list of policy intents. See the Policy Framework specification [POLICY] for a description of this attribute
· policySets : QName (0..1) – a list of policy sets. See the Policy Framework specification [POLICY] for a description of this attribute.
· remotable : boolean (0..1) – indicates whether or not the interface is remotable. A value of “true” means the interface is remotable and a value of “false” means it is not. This attribute does not have a default value. If it is not specified then the remotability is determined by the presence or absence of the @Remotable annotation on the interface class. The @remotable attribute applies to both the interface and any optional callbackInterface. The @remotable attribute is intended as an alternative to using the @Remotable annotation on the interface class. The value of the @remotable attribute on the <interface.java/> element does not override the presence of a @Remotable annotation on the interface class and so if the interface class contains a @Remotable annotation and the @remotable attribute has a value of "false", then the SCA Runtime MUST raise an error and MUST NOT run the component concerned. [JCA30005]
Snippet 3‑2 shows an example of the Java interface element:
<interface.java interface="services.stockquote.StockQuoteService"
callbackInterface="services.stockquote.StockQuoteServiceCallback"/>
Snippet 3‑2 Example interface.java Element
Here, the Java interface is defined in the Java class file ./services/stockquote/StockQuoteService.class, where the root directory is defined by the contribution in which the interface exists. Similarly, the callback interface is defined in the Java class file ./services/stockquote/StockQuoteServiceCallback.class.
Note that the Java interface class identified by the @interface attribute can contain a Java @Callback annotation which identifies a callback interface. If this is the case, then it is not necessary to provide the @callbackInterface attribute. However, if the Java interface class identified by the @interface attribute does contain a Java @Callback annotation, then the Java interface class identified by the @callbackInterface attribute MUST be the same interface class. [JCA30003]
For the Java interface type system, parameters and return types of the service methods are described using Java classes or simple Java types. It is recommended that the Java Classes used conform to the requirements of either JAXB [JAX-B] or of Service Data Objects [SDO] because of their integration with XML technologies.
The @Remotable annotation on a Java interface, a service implementation class, or a service reference denotes an interface or class that is designed to be used for remote communication. Remotable interfaces are intended to be used for coarse grained services. Operations' parameters, return values and exceptions are passed by-value. Remotable Services are not allowed to make use of method overloading.
A callback interface is declared by using a @Callback annotation on a Java service interface, with the Java Class object of the callback interface as a parameter. There is another form of the @Callback annotation, without any parameters, that specifies callback injection for a setter method or a field of an implementation.
An interface can be annotated with @AsyncInvocation or with the equivalent @Requires("sca:asyncInvocation") annotation to indicate that request/response operations of that interface are long running and that response messages are likely to be sent an arbitrary length of time after the initial request message is sent to the target service. This is described in the SCA Assembly Specification [ASSEMBLY].
For a service client, it is strongly recommended that the client uses the asynchronous form of the client interface when using a reference to a service with an interface annotated with @AsyncInvocation, using either polling or callbacks to receive the response message. See the sections "Asynchronous Programming" and the section "JAX-WS Client Asynchronous API for a Synchronous Service" for more details about the asynchronous client API.
For a service implementation, SCA provides an asynchronous service mapping of the WSDL request/response interface which enables the service implementation to send the response message at an arbitrary time after the original service operation is invoked. This is described in the section "Asynchronous handling of Long Running Service Operations".
A Java interface referenced by the @interface attribute of an <interface.java/> element MUST NOT contain any of the following SCA Java annotations:
@AllowsPassByReference, @ComponentName, @Constructor, @Context, @Destroy, @EagerInit, @Init, @Intent, @Property, @Qualifier, @Reference, @Scope, @Service. [JCA30006]
A Java interface referenced by the @callbackInterface attribute of an <interface.java/> element MUST NOT contain any of the following SCA Java annotations:
@AllowsPassByReference, @Callback, @ComponentName, @Constructor, @Context, @Destroy, @EagerInit, @Init, @Intent, @Property, @Qualifier, @Reference, @Scope, @Service. [JCA30007]
The SCA Assembly Model specification [ASSEMBLY] defines a number of criteria that need to be satisfied in order for two interfaces to be compatible or have a compatible superset or subset relationship. If these interfaces are both Java interfaces, compatibility also means that every method that is present in both interfaces is defined consistently in both interfaces with respect to the @OneWay annotation, that is, the annotation is either present in both interfaces or absent in both interfaces. [JCA30009]
This section describes the lifecycle of an SCA component implementation.
At a high level, there are 3 main phases through which an SCA component implementation will transition when it is used by an SCA Runtime:
· The Initialization phase. This involves constructing an instance of the component implementation class and injecting any properties and references. Once injection is complete, the method annotated with @Init is called, if present, which provides the component implementation an opportunity to perform any internal initialization it requires.
· The Running phase. This is where the component implementation has been initialized and the SCA Runtime can dispatch service requests to it over its Service interfaces.
· The Destroying phase. This is where the component implementation’s scope has ended and the SCA Runtime destroys the component implementation instance. The SCA Runtime calls the method annotated with @Destroy, if present, which provides the component implementation an opportunity to perform any internal clean up that is required.
The state diagram in Figure 4‑1 shows the lifecycle of an SCA component implementation. The sections that follow it describe each of the states that it contains.
It should be noted that some component implementation specifications might not implement all states of the lifecycle. In this case, that state of the lifecycle is skipped over.
Figure 4‑1: SCA - Component Implementation Lifecycle
The SCA Runtime MUST call a constructor of the component implementation at the start of the Constructing state. [JCA40001] The SCA Runtime MUST perform any constructor reference or property injection when it calls the constructor of a component implementation. [JCA40002]
The result of invoking operations on any injected references when the component implementation is in the Constructing state is undefined.
When the constructor completes successfully, the SCA Runtime MUST transition the component implementation to the Injecting state. [JCA40003] If an exception is thrown whilst in the Constructing state, the SCA Runtime MUST transition the component implementation to the Terminated state. [JCA40004]
When a component implementation instance is in the Injecting state, the SCA Runtime MUST first inject all field and setter properties that are present into the component implementation. [JCA40005] The order in which the properties are injected is unspecified.
When a component implementation instance is in the Injecting state, the SCA Runtime MUST inject all field and setter references that are present into the component implementation, after all the properties have been injected. [JCA40006] The order in which the references are injected is unspecified.
The SCA Runtime MUST ensure that the correct synchronization model is used so that all injected properties and references are made visible to the component implementation without requiring the component implementation developer to do any specific synchronization. [JCA40007]
The SCA Runtime MUST NOT invoke Service methods on the component implementation when the component implementation is in the Injecting state. [JCA40008]
The result of invoking operations on any injected references when the component implementation is in the Injecting state is undefined.
When the injection of properties and references completes successfully, the SCA Runtime MUST transition the component implementation to the Initializing state. [JCA40009] If an exception is thrown whilst injecting properties or references, the SCA Runtime MUST transition the component implementation to the Destroying state. [JCA40010] If a property or reference is unable to be injected, the SCA Runtime MUST transition the component implementation to the Destroying state. [JCA40024]
When the component implementation enters the Initializing State, the SCA Runtime MUST call the method annotated with @Init on the component implementation, if present. [JCA40011]
The component implementation can invoke operations on any injected references when it is in the Initializing state. However, depending on the order in which the component implementations are initialized, the target of the injected reference might not be available since it has not yet been initialized. If a component implementation invokes an operation on an injected reference that refers to a target that has not yet been initialized, the SCA Runtime MUST throw a ServiceUnavailableException. [JCA40012]
The SCA Runtime MUST NOT invoke Service methods on the component implementation when the component implementation instance is in the Initializing state. [JCA40013]
Once the method annotated with @Init completes successfully, the SCA Runtime MUST transition the component implementation to the Running state. [JCA40014] If an exception is thrown whilst initializing, the SCA Runtime MUST transition the component implementation to the Destroying state. [JCA40015]
The SCA Runtime MUST invoke Service methods on a component implementation instance when the component implementation is in the Running state and a client invokes operations on a service offered by the component. [JCA40016]
The component implementation can invoke operations on any injected references when the component implementation instance is in the Running state.
When the component implementation scope ends, the SCA Runtime MUST transition the component implementation to the Destroying state. [JCA40017]
When a component implementation enters the Destroying state, the SCA Runtime MUST call the method annotated with @Destroy on the component implementation, if present. [JCA40018]
The component implementation can invoke operations on any injected references when it is in the Destroying state. However, depending on the order in which the component implementations are destroyed, the target of the injected reference might no longer be available since it has been destroyed. If a component implementation invokes an operation on an injected reference that refers to a target that has been destroyed, the SCA Runtime MUST throw an InvalidServiceException. [JCA40019]
The SCA Runtime MUST NOT invoke Service methods on the component implementation when the component implementation instance is in the Destroying state. [JCA40020]
Once the method annotated with @Destroy completes successfully, the SCA Runtime MUST transition the component implementation to the Terminated state. [JCA40021] If an exception is thrown whilst destroying, the SCA Runtime MUST transition the component implementation to the Terminated state. [JCA40022]
The lifecycle of the SCA Component has ended.
The SCA Runtime MUST NOT invoke Service methods on the component implementation when the component implementation instance is in the Terminated state. [JCA40023]
This section describes how SCA services can be programmatically accessed from components and also from non-managed code, that is, code not running as an SCA component.
An SCA component can obtain a service reference either through injection or programmatically through the ComponentContext API. Using reference injection is the recommended way to access a service, since it results in code with minimal use of middleware APIs. The ComponentContext API is provided for use in cases where reference injection is not possible.
When a component implementation needs access to a service where the reference to the service is not known at compile time, the reference can be located using the component’s ComponentContext.
This section describes how Java code not running as an SCA component that is part of an SCA composite accesses SCA services via references.
Client code can use the SCAClientFactory class
to obtain proxy reference objects for a service which is in an SCA Domain. The
URI of the domain, the relative URI of the service and the business interface
of the service must all be known in order to use the SCAClientFactory class.
Objects which implement the SCAClientFactory are obtained using the newInstance()
methods of the SCAClientFactory class.
Snippet 5‑1 is a sample of the code that a client would use:
package org.oasisopen.sca.client.example;
import java.net.URI;
import org.oasisopen.sca.client.SCAClientFactory;
import org.oasisopen.sca.client.example.HelloService;
/**
* Example of use of Client API for a client application to obtain
* an SCA reference proxy for a service in an SCA Domain.
*/
public class Client1 {
public void someMethod() {
try {
String serviceURI = "SomeHelloServiceURI";
URI domainURI = new URI("SomeDomainURI");
SCAClientFactory scaClient =
SCAClientFactory.newInstance( domainURI );
HelloService helloService =
scaClient.getService(HelloService.class,
serviceURI);
String reply = helloService.sayHello("Mark");
} catch (Exception e) {
System.out.println("Received exception");
}
}
}
Snippet 5‑1: Using the SCAClientFactory Interface
For details about the SCAClientFactory interface and its related classes see the section "SCAClientFactory Class".
Clients calling service methods can experience business exceptions and SCA runtime exceptions.
Business exceptions are thrown by the implementation of the called service method, and are defined as checked exceptions on the interface that types the service.
SCA runtime exceptions are raised by the SCA runtime and signal problems in management of component execution or problems interacting with remote services. The SCA runtime exceptions are defined in the Java API section.
Asynchronous programming of a service is where a client invokes a service and carries on executing without waiting for the service to execute. Typically, the invoked service executes at some later time. Output from the invoked service, if any, is fed back to the client through a separate mechanism, since no output is available at the point where the service is invoked. This is in contrast to the call-and-return style of synchronous programming, where the invoked service executes and returns any output to the client before the client continues. The SCA asynchronous programming model consists of:
· support for non-blocking method calls
· callbacks
Each of these topics is discussed in the following sections.
Non-blocking calls represent the simplest form of asynchronous programming, where the client of the service invokes the service and continues processing immediately, without waiting for the service to execute.
A method with a void return type and which has no declared exceptions can be marked with a @OneWay annotation. This means that the method is non-blocking and communication with the service provider can use a binding that buffers the request and sends it at some later time.
For a Java client to make a non-blocking call to methods that either return values or throw exceptions, a Java client can use the JAX-WS asynchronous client API model that is described in the section "JAX-WS Client Asynchronous API for a Synchronous Service". It is considered to be a best practice that service designers define one-way methods as often as possible, in order to give the greatest degree of binding flexibility to deployers.
A callback service is a service that is used for asynchronous communication from a service provider back to its client, in contrast to the communication through return values from synchronous operations. Callbacks are used by bidirectional services, which are services that have two interfaces:
· an interface for the provided service
· a callback interface that is provided by the client
Callbacks can be used for both remotable and local services. Either both interfaces of a bidirectional service are remotable, or both are local. It is illegal to mix the two, as defined in the SCA Assembly Model specification [ASSEMBLY].
A callback interface is declared by using a @Callback annotation on a service interface, with the Java Class object of the interface as a parameter. The annotation can also be applied to a method or to a field of an implementation, which is used in order to have a callback injected, as explained in the next section.
Bidirectional interfaces and callbacks are used when a simple request/response pattern isn’t sufficient to capture the business semantics of a service interaction. Callbacks are well suited for cases when a service request can result in multiple responses or new requests from the service back to the client, or where the service might respond to the client some time after the original request has completed.
Snippet 7‑1 shows a scenario in which bidirectional interfaces and callbacks could be used. A client requests a quotation from a supplier. To process the enquiry and return the quotation, some suppliers might need additional information from the client. The client does not know which additional items of information will be needed by different suppliers. This interaction can be modeled as a bidirectional interface with callback requests to obtain the additional information.
package somepackage;
import org.oasisopen.sca.annotation.Callback;
import org.oasisopen.sca.annotation.Remotable;
@Remotable
@Callback(QuotationCallback.class)
public interface Quotation {h
double requestQuotation(String productCode, int quantity);
}
@Remotable
public interface QuotationCallback {
String getState();
String getZipCode();
String getCreditRating();
}
Snippet 7‑1: Using a Bidirectional Interface
In Snippet 7‑1, the requestQuotation operation requests a quotation to supply a given quantity of a specified product. The QuotationCallBack interface provides a number of operations that the supplier can use to obtain additional information about the client making the request. For example, some suppliers might quote different prices based on the state or the ZIP code to which the order will be shipped, and some suppliers might quote a lower price if the ordering company has a good credit rating. Other suppliers might quote a standard price without requesting any additional information from the client.
Snippet 7‑2 illustrates a possible implementation of the example service, using the @Callback annotation to request that a callback proxy be injected.
@Callback
protected QuotationCallback callback;
public double requestQuotation(String productCode, int quantity) {
double price = getPrice(productQuote, quantity);
double discount = 0;
if (quantity > 1000 && callback.getState().equals("FL")) {
discount = 0.05;
}
if (quantity > 10000 && callback.getCreditRating().charAt(0) == 'A') {
discount += 0.05;
}
return price * (1-discount);
}
Snippet 7‑2: Example Implementation of a Service with a Bidirectional Interface
Snippet 7‑3 is taken from the client of this example service. The client’s service implementation class implements the methods of the QuotationCallback interface as well as those of its own service interface ClientService.
public class ClientImpl implements ClientService, QuotationCallback {
private QuotationService myService;
@Reference
public void setMyService(QuotationService service) {
myService = service;
}
public void aClientMethod() {
...
double quote = myService.requestQuotation("AB123", 2000);
...
}
public String getState() {
return "TX";
}
public String getZipCode() {
return "78746";
}
public String getCreditRating() {
return "AA";
}
}
Snippet 7‑3: Example Client Using a Biderictional Interface
Snippet 7‑3 the callback is stateless, i.e., the callback requests do not need any information relating to the original service request. For a callback that needs information relating to the original service request (a stateful callback), this information can be passed to the client by the service provider as parameters on the callback request.
Instance management for callback requests received by the client of the bidirectional service is handled in the same way as instance management for regular service requests. If the client implementation has STATELESS scope, the callback is dispatched using a newly initialized instance. If the client implementation has COMPOSITE scope, the callback is dispatched using the same shared instance that is used to dispatch regular service requests.
As described in the section "Using Callbacks", a stateful callback can obtain information relating to the original service request from parameters on the callback request. Alternatively, a composite-scoped client could store information relating to the original request as instance data and retrieve it when the callback request is received. These approaches could be combined by using a key passed on the callback request (e.g., an order ID) to retrieve information that was stored in a composite-scoped instance by the client code that made the original request.
When a bidirectional service is invoked, the SCA runtime MUST inject a callback reference for the invoking service into all fields and setter methods of the service implementation class that are marked with a @Callback annotation and typed by the callback interface of the bidirectional service, and the SCA runtime MUST inject null into all other fields and setter methods of the service implementation class that are marked with a @Callback annotation. [JCA60001] When a non-bidirectional service is invoked, the SCA runtime MUST inject null into all fields and setter methods of the service implementation class that are marked with a @Callback annotation. [JCA60002]
Since it is possible for a single implementation class to implement multiple services, it is also possible for callbacks to be defined for each of the services that it implements. The service implementation can include an injected field for each of its callbacks. The runtime injects the callback onto the appropriate field based on the type of the callback. Snippet 7‑4 shows the declaration of two fields, each of which corresponds to a particular service offered by the implementation.
@Callback
protected MyService1Callback callback1;
@Callback
protected MyService2Callback callback2;
Snippet 7‑4: Multiple Bidirectional Interfaces in an Implementation
If a single callback has a type that is compatible with multiple declared callback fields, then all of them will be set.
In addition to injecting a reference to a callback service, it is also possible to obtain a reference to a Callback instance by annotating a field or method of type ServiceReference with the @Callback annotation.
A reference implementing the callback service interface can be obtained using ServiceReference.getService().
Snippet 7‑5 comes from a service implementation that uses the callback API:
@Callback
protected ServiceReference<MyCallback> callback;
public void someMethod() {
MyCallback myCallback = callback.getService(); …
myCallback.receiveResult(theResult);
}
Snippet 7‑5: Using the Callback API
Because ServiceReference objects are serializable, they can be stored persistently and retrieved at a later time to make a callback invocation after the associated service request has completed. ServiceReference objects can also be passed as parameters on service invocations, enabling the responsibility for making the callback to be delegated to another service.
Alternatively, a callback can be retrieved programmatically using the RequestContext API. Snippet 7‑6 shows how to retrieve a callback in a method programmatically:
@Context
ComponentContext context;
public void someMethod() {
MyCallback myCallback = context.getRequestContext().getCallback();
…
myCallback.receiveResult(theResult);
}
Snippet 7‑6: Using RequestContext to get a Callback
This is necessary if the service implementation has COMPOSITE scope, because callback injection is not performed for composite-scoped implementations.
Long-running request-response operations are described in the SCA Assembly Specification [ASSEMBLY]. These operations are characterized by following the WSDL request-response message exchange pattern, but where the timing of the sending of the response message is arbitrarily later than the receipt of the request message, with an impact on the client component, on the service component and also on the transport binding used to communicate between them.
In SCA, such operations are marked with an intent "asyncInvocation" and is expected that the client component, the service component and the binding are all affected by the presence of this intent. This specification does not describe the effects of the intent on the binding, other than to note that in general, there is an implication that the sending of the response message is typically separate from the sending of the request message, typically requiring a separate response endpoint on the client to which the response can be sent.
For components that are clients of a long-running request-response operation, it is strongly recommended that the client makes use of the JAX-WS Client Asynchronous API, either using the polling interface or the callback mechanism described in the section "JAX-WS Client Asynchronous API for a Synchronous Service". The principle is that the client should not synchronously wait for a response from the long running operation since this could take a long time and it is preferable not to tie up resources while waiting.
For the service implementation component, the JAX-WS client asynchronous API is not suitable, so the SCA Java Common Annotations and APIs specification defines the SCA Asynchronous Service interface, which, like the JAX-WS client asynchronous API, is an alternative mapping of a WSDL request-response operation into a Java interface.
The SCA Asynchronous Service interface follows some of the patterns defined by the JAX-WS client asynchronous API, but it is a simpler interface aligned with the needs of a service implementation class.
As an example, for a WSDL portType with a single operation "getPrice" with a String request parameter and a float response, the synchronous Java interface mapping appears in Snippet 7‑7.
// synchronous mapping
public interface StockQuote {
float getPrice(String ticker);
}
Snippet 7‑7: Example Synchronous Java Interface Mapping
The JAX-WS client asynchronous API for the same portType adds two asynchronous forms for each synchronous method, as shown in Snippet 7‑8.
// asynchronous mapping
public interface StockQuote {
float getPrice(String ticker);
Response<Float> getPriceAsync(String ticker);
Future<?> getPriceAsync(String ticker, AsyncHandler<Float> handler);
}
Snippet 7‑8: Example JAX-WS Client Asynchronous Java interface Mapping
The SCA Asynchronous Service interface has a single method similar to the final one in the asynchronous client interface, as shown in Snippet 7‑8.
// asynchronous mapping
@Requires("sca:asyncInvocation")
public interface StockQuote {
void getPriceAsync(String ticker, ResponseDispatch<Float> dispatch);
}
Snippet 7‑9: Example SCA Asynchronous Service Java interface Mapping
The main characteristics of the SCA asynchronous mapping are:
· there is a single method, with a name with the string "Async" appended to the operation name
· it has a void return type
· it has two input parameters, the first is the request message of the operation and the second is a ResponseDispatch object typed by the response message of the operation (following the rules expressed in the JAX-WS specification for the typing of the AsyncHandler object in the client asynchronous API)
· it is annotated with the asyncInvocation intent
· if the synchronous method has any business faults/exceptions, it is annotated with @AsyncFault, containing a list of the exception classes
Unlike the JAX-WS asynchronous client interface, there is only a single operation for the service implementation to provide (it would be inconvenient for the service implementation to be required to implement multiple methods for each operation in the WSDL interface).
The ResponseDispatch parameter is the mechanism by which the service implementation sends back the response message resulting from the invocation of the service method. The ResponseDispatch is serializable and it can be invoked once at any time after the invocation of the service method, either before or after the service method returns. This enables the service implementation to store the ResponseDispatch in serialized form and release resources while waiting for the completion of whatever activities result from the processing of the initial invocation.
The ResponseDispatch object is allocated by the SCA runtime/binding implementation and it is expected to contain whatever metadata is required to deliver the response message back to the client that invoked the service operation.
The SCA asynchronous service Java interface mapping of a WSDL request-response operation MUST appear as follows:
The interface is annotated with the "asyncInvocation" intent.
– For each service operation in the WSDL, the Java interface contains an operation with
– a name which is the JAX-WS mapping of the WSDL operation name, with the suffix "Async" added
– a void return type
– a set of input parameter(s) which match the JAX-WS mapping of the input parameter(s) of the WSDL operation plus an additional last parameter which is a ResponseDispatch object typed by the JAX-WS Response Bean mapping of the output parameter(s) of the WSDL operation, where ResponseDispatch is the type defined in the SCA Java Common Annotations and APIs specification. [JCA60003]
An SCA Runtime MUST support the use of the SCA asynchronous service interface for the interface of an SCA service. [JCA60004]
The ResponseDispatch object passed in as a parameter to a method of a service implementation using the SCA asynchronous service Java interface can be invoked once only through either its sendResponse method or through its sendFault method to return the response resulting from the service method invocation. If the SCA asynchronous service interface ResponseDispatch handleResponse method is invoked more than once through either its sendResponse or its sendFault method, the SCA runtime MUST throw an IllegalStateException. [JCA60005]
For the purposes of matching interfaces (when wiring between a reference and a service, or when using an implementation class by a component), an interface which has one or more methods which follow the SCA asynchronous service pattern MUST be treated as if those methods are mapped as the equivalent synchronous methods, as follows:
Asynchronous service methods are characterized by:
– void return type
– a method name with the suffix "Async"
– a last input parameter with a type of ResponseDispatch<X>
– annotation with the asyncInvocation intent
– possible annotation with the @AsyncFault annotation
The mapping of each such method is as if the method had the return type "X", the method name without the suffix "Async" and all the input parameters except the last parameter of the type ResponseDispatch<X>, plus the list of exceptions contained in the @AsyncFault annotation. [JCA60006]
SCA provides facilities for the attachment of policy-related metadata to SCA assemblies, which influence how implementations, services and references behave at runtime. The policy facilities are described in the SCA Policy Framework specification [POLICY]. In particular, the facilities include Intents and Policy Sets, where intents express abstract, high-level policy requirements and policy sets express low-level detailed concrete policies.
Policy metadata can be added to SCA assemblies through the means of declarative statements placed into Composite documents and into Component Type documents. These annotations are completely independent of implementation code, allowing policy to be applied during the assembly and deployment phases of application development.
However, it can be useful and more natural to attach policy metadata directly to the code of implementations. This is particularly important where the policies concerned are relied on by the code itself. An example of this from the Security domain is where the implementation code expects to run under a specific security Role and where any service operations invoked on the implementation have to be authorized to ensure that the client has the correct rights to use the operations concerned. By annotating the code with appropriate policy metadata, the developer can rest assured that this metadata is not lost or forgotten during the assembly and deployment phases.
This specification has a series of annotations which provide the capability for the developer to attach policy information to Java implementation code. The annotations concerned first provide general facilities for attaching SCA Intents and Policy Sets to Java code. Secondly, there are further specific annotations that deal with particular policy intents for certain policy domains such as Security and Transactions.
This specification supports using the Common Annotations for the Java Platform specification (JSR-250) [JSR-250]. An implication of adopting the common annotation for Java platform specification is that the SCA Java specification supports consistent annotation and Java class inheritance relationships. SCA policy annotation semantics follow the General Guidelines for Inheritance of Annotations in the Common Annotations for the Java Platform specification [JSR-250], except that member-level annotations in a class or interface do not have any effect on how class-level annotations are applied to other members of the class or interface.
SCA provides the annotation @Requires for the attachment of any intent to a Java class, to a Java interface or to elements within classes and interfaces such as methods and fields.
The @Requires annotation can attach one or multiple intents in a single statement.
Each intent is expressed as a string. Intents are XML QNames, which consist of a Namespace URI followed by the name of the Intent. The precise form used follows the string representation used by the javax.xml.namespace.QName class, which is shown in Snippet 8‑1.
"{" + Namespace URI + "}" + intentname
Snippet 8‑1: Intent Format
Intents can be qualified, in which case the string consists of the base intent name, followed by a ".", followed by the name of the qualifier. There can also be multiple levels of qualification.
This representation is quite verbose, so we expect that reusable String constants will be defined for the namespace part of this string, as well as for each intent that is used by Java code. SCA defines constants for intents such as those in Snippet 8‑2.
public static final String SCA_PREFIX =
"{http://docs.oasis-open.org/ns/opencsa/sca/200912}";
public static final String CONFIDENTIALITY =
SCA_PREFIX + "confidentiality";
public static final String CONFIDENTIALITY_MESSAGE =
CONFIDENTIALITY + ".message";
Snippet 8‑2: Example Intent Constants
Notice that, by convention, qualified intents include the qualifier as part of the name of the constant, separated by an underscore. These intent constants are defined in the file that defines an annotation for the intent (annotations for intents, and the formal definition of these constants, are covered in a following section).
Multiple intents (qualified or not) are expressed as separate strings within an array declaration.
An example of the @Requires annotation with 2 qualified intents (from the Security domain) is shown in Snippet 8‑3:
@Requires({CONFIDENTIALITY_MESSAGE, INTEGRITY_MESSAGE})
Snippet 8‑3: Multiple Intnets in One Annotation
The annotation in Snippet 8‑3 attaches the intents "confidentiality.message" and "integrity.message".
Snippet 8‑4 is an example of a reference requiring support for confidentiality:
package com.foo;
import static org.oasisopen.sca.annotation.Confidentiality.*;
import static org.oasisopen.sca.annotation.Reference;
import static org.oasisopen.sca.annotation.Requires;
public class Foo {
@Requires(CONFIDENTIALITY)
@Reference
public void setBar(Bar bar) {
…
}
}
Snippet 8‑4: Annotation a Reference
Users can also choose to only use constants for the namespace part of the QName, so that they can add new intents without having to define new constants. In that case, the definition of Snippet 8‑4 would instead look like Snippet 8‑5.
package com.foo;
import static org.oasisopen.sca.Constants.*;
import static org.oasisopen.sca.annotation.Reference;
import static org.oasisopen.sca.annotation.Requires;
public class Foo {
@Requires(SCA_PREFIX+"confidentiality")
@Reference
public void setBar(Bar bar) {
…
}
}
Snippet 8‑5: Using Intent Constants and strings
The formal syntax [EBNF-Syntax] for the @Requires annotation follows:
'@Requires("' QualifiedIntent '"' (',"' QualifiedIntent '"')* ')'
where
QualifiedIntent ::= QName('.' Qualifier)*
Qualifier ::= NCName
See section @Requires for the formal definition of the @Requires annotation.
In addition to the general intent annotation supplied by the @Requires annotation described in section 8.2, it is also possible to have Java annotations that correspond to specific policy intents. SCA provides a number of these specific intent annotations and it is also possible to create new specific intent annotations for any intent.
The general form of these specific intent annotations is an annotation with a name derived from the name of the intent itself. If the intent is a qualified intent, qualifiers are supplied as an attribute to the annotation in the form of a string or an array of strings.
For example, the SCA confidentiality intent described in the section on General Intent Annotations using the @Requires(CONFIDENTIALITY) annotation can also be specified with the @Confidentiality specific intent annotation. The specific intent annotation for the "integrity" security intent is shown in Snippet 8‑6.
@Integrity
Snippet 8‑6: Example Specific Intent Annotation
An example of a qualified specific intent for the "authentication" intent is shown in Snippet 8‑7.
@Authentication( {"message", "transport"} )
Snippet 8‑7: Example Qualified Specific Intent Annotation
This annotation attaches the pair of qualified intents: "authentication.message" and "authentication.transport" (the sca: namespace is assumed in this both of these cases – "http://docs.oasis-open.org/ns/opencsa/sca/200912").
The general form of specific intent annotations is shown in Snippet 8‑8
'@' Intent ('(' qualifiers ')')?
where Intent is an NCName that denotes a particular type of intent.
Intent ::= NCName
qualifiers ::= '"' qualifier '"' (',"' qualifier '"')*
qualifier ::= NCName ('.' qualifier)?
Snippet 8‑8: Specific Intent Annotation Format
SCA identifies annotations that correspond to intents by providing an @Intent annotation which MUST be used in the definition of a specific intent annotation. [JCA70001]
The @Intent annotation takes a single parameter, which (like the @Requires annotation) is the String form of the QName of the intent. As part of the intent definition, it is good practice (although not required) to also create String constants for the Namespace, for the Intent and for Qualified versions of the Intent (if defined). These String constants are then available for use with the @Requires annotation and it is also possible to use one or more of them as parameters to the specific intent annotation.
Alternatively, the QName of the intent can be specified using separate parameters for the targetNamespace and the localPart, as shown in Snippet 8‑9:
@Intent(targetNamespace=SCA_NS, localPart="confidentiality")
Snippet 8‑9: Defining a Specific Intent Annotation
See section @Intent for the formal definition of the @Intent annotation.
When an intent can be qualified, it is good practice for the first attribute of the annotation to be a string (or an array of strings) which holds one or more qualifiers.
In this case, the attribute’s definition needs to be marked with the @Qualifier annotation. The @Qualifier tells SCA that the value of the attribute is treated as a qualifier for the intent represented by the whole annotation. If more than one qualifier value is specified in an annotation, it means that multiple qualified forms exist. For example the annotation in Snippet 8‑10
@Confidentiality({"message","transport"})
Snippet 8‑10: Multiple Qualifiers in an Annotation'
implies that both of the qualified intents "confidentiality.message" and "confidentiality.transport" are set for the element to which the @Confidentiality annotation is attached.
See section @Qualifier for the formal definition of the @Qualifier annotation.
Examples of the use of the @Intent and the @Qualifier annotations in the definition of specific intent annotations are shown in the section dealing with Security Interaction Policy.
The SCA Intent annotations can be applied to the following Java elements:
· Java class
· Java interface
· Method
· Field
· Constructor parameter
Intent annotations MUST NOT be applied to the following:
· A method of a service implementation class, except for a setter method that is either annotated with @Reference or introspected as an SCA reference according to the rules in the appropriate Component Implementation specification
· A service implementation class field that is not either annotated with @Reference or introspected as an SCA reference according to the rules in the appropriate Component Implementation specification
· A service implementation class constructor parameter that is not annotated with @Reference
Intent annotations can be applied to classes, interfaces, and interface methods. Applying an intent annotation to a field, setter method, or constructor parameter allows intents to be defined at references. Intent annotations can also be applied to reference interfaces and their methods.
Where multiple intent annotations (general or specific) are applied to the same Java element, the SCA runtime MUST compute the combined intents for the Java element by merging the intents from all intent annotations on the Java element according to the SCA Policy Framework [POLICY] rules for merging intents at the same hierarchy level. [JCA70003]
An example of multiple policy annotations being used together is shown in Snippet 8‑11:
@Authentication
@Requires({CONFIDENTIALITY_MESSAGE, INTEGRITY_MESSAGE})
Snippet 8‑11: Multiple Policy Annotations
In this case, the effective intents are "authentication", "confidentiality.message" and "integrity.message".
If intent annotations are specified on both an interface method and the method's declaring interface, the SCA runtime MUST compute the effective intents for the method by merging the combined intents from the method with the combined intents for the interface according to the SCA Policy Framework [POLICY] rules for merging intents within a structural hierarchy, with the method at the lower level and the interface at the higher level. [JCA70004] This merging process does not remove or change any intents that are applied to the interface.
The following examples show how the rules defined in section 8.3 are applied.
Snippet 8‑12 shows how intents on references are merged. In this example, the intents for myRef are "authentication" and "confidentiality.message".
@Authentication
@Requires(CONFIDENTIALITY)
@Confidentiality("message")
@Reference
protected MyService myRef;
Snippet 8‑12: Merging Intents on References
Snippet 8‑13 shows that mutually exclusive intents cannot be applied to the same Java element. In this example, the Java code is in error because of contradictory mutually exclusive intents "managedTransaction" and "noManagedTransaction".
@Requires({SCA_PREFIX+"managedTransaction",
SCA_PREFIX+"noManagedTransaction"})
@Reference
protected MyService myRef;
Snippet 8‑13: Mutually Exclusive Intents
Snippet 8‑14 shows that intents can be applied to Java service interfaces and their methods. In this example, the effective intents for MyService.mymethod() are "authentication" and "confidentiality".
@Authentication
public interface MyService {
@Confidentiality
public void mymethod();
}
@Service(MyService.class)
public class MyServiceImpl {
public void mymethod() {...}
}
Snippet 8‑14: Intents on Java Interfaces, Interface Methods, and Java Classes
Snippet 8‑15 shows that intents can be applied to Java service implementation classes. In this example, the effective intents for MyService.mymethod() are "authentication", "confidentiality", and "managedTransaction".
@Authentication
public interface MyService {
@Confidentiality
public void mymethod();
}
@Service(MyService.class)
@Requires(SCA_PREFIX+"managedTransaction")
public class MyServiceImpl {
public void mymethod() {...}
}
Snippet 8‑15: Intents on Java Service Implementation Classes
Snippet 8‑16 shows that intents can be applied to Java reference interfaces and their methods, and also to Java references. In this example, the effective intents for the method mymethod() of the reference myRef are "authentication", "integrity", and "confidentiality".
@Authentication
public interface MyRefInt {
@Integrity
public void mymethod();
}
@Service(MyService.class)
public class MyServiceImpl {
@Confidentiality
@Reference
protected MyRefInt myRef;
}
Snippet 8‑16: Intents on Java References and their Interfaces and Methods
Snippet 8‑17 shows that intents cannot be applied to methods of Java implementation classes. In this example, the Java code is in error because of the @Authentication intent annotation on the implementation method MyServiceImpl.mymethod().
public interface MyService {
public void mymethod();
}
@Service(MyService.class)
public class MyServiceImpl {
@Authentication
public void mymethod() {...}
}
Snippet 8‑17: Intent on Implementation Method
Snippet 8‑18 shows one effect of applying the SCA Policy Framework rules for merging intents within a structural hierarchy to Java service interfaces and their methods. In this example a qualified intent overrides an unqualified intent, so the effective intent for MyService.mymethod() is "confidentiality.message".
@Confidentiality("message")
public interface MyService {
@Confidentiality
public void mymethod();
}
Snippet 8‑18: Merging Qualified and Unqualified Intents on Java Interfaces and Methods
Snippet 8‑19 shows another effect of applying the SCA Policy Framework rules for merging intents within a structural hierarchy to Java service interfaces and their methods. In this example a lower-level intent causes a mutually exclusive higher-level intent to be ignored, so the effective intent for mymethod1() is "managedTransaction" and the effective intent for mymethod2() is "noManagedTransaction".
@Requires(SCA_PREFIX+"managedTransaction")
public interface MyService {
public void mymethod1();
@Requires(SCA_PREFIX+"noManagedTransaction")
public void mymethod2();
}
Snippet 8‑19: Merging Mutually Exclusive Intents on Java Interfaces and Methods
Snippet 8‑20 shows the inheritance relations of intents on classes, operations, and super classes.
package services.hello;
import org.oasisopen.sca.annotation.Authentication;
import org.oasisopen.sca.annotation.Integrity;
@Integrity("transport")
@Authentication
public class HelloService {
@Integrity
@Authentication("message")
public String hello(String message) {...}
@Integrity
@Authentication("transport")
public String helloThere() {...}
}
package services.hello;
import org.oasisopen.sca.annotation.Authentication;
import org.oasisopen.sca.annotation.Confidentiality;
@Confidentiality("message")
public class HelloChildService extends HelloService {
@Confidentiality("transport")
public String hello(String message) {...}
@Authentication
String helloWorld() {...}
}
Snippet 8‑20: Usage example of Annotated Policy and Inheritance
The effective intent annotation on the helloWorld method of HelloChildService is @Authentication and @Confidentiality("message").
The effective intent annotation on the hello method of HelloChildService is @Confidentiality("transport"),
The effective intent annotation on the helloThere method of HelloChildService is @Integrity and @Authentication("transport"), the same as for this method in the HelloService class.
The effective intent annotation on the hello method of HelloService is @Integrity and @Authentication("message")
Table 8‑1 shows the equivalent declarative security interaction policy of the methods of the HelloService and HelloChildService implementations corresponding to the Java classes shown in Snippet 8‑20.
|
Method |
||
Class |
hello() |
helloThere() |
helloWorld() |
HelloService |
integrity authentication.message |
integrity authentication.transport |
N/A |
HelloChildService |
confidentiality.transport |
integrity authentication.transport |
authentication confidentiality.message |
Table 8‑1: Declarative Intents Equivalent to Annotated Intents in Snippet 8‑20
Annotated intents on a Java class cannot be overridden by declarative intents in a composite document which uses the class as an implementation. This rule follows the general rule for intents that they represent requirements of an implementation in the form of a restriction that cannot be relaxed.
However, a restriction can be made more restrictive so that an unqualified version of an intent expressed through an annotation in the Java class can be qualified by a declarative intent in a using composite document.
The SCA Policy Framework uses Policy Sets to capture
detailed low-level concrete policies. For example, a concrete policy is the
specific encryption algorithm to use when encrypting messages when using a
specific communication protocol to link a reference to a service.
Policy Sets can be applied directly to Java implementations using the @PolicySets
annotation. The @PolicySets annotation either takes the QName of a single
policy set as a string or the name of two or more policy sets as an array of
strings:
'@PolicySets({' policySetQName (',' policySetQName )* '})'
Snippet 8‑21: PolicySet Annotation Format
As for intents, PolicySet names are QNames – in the form of "{Namespace-URI}localPart".
An example of the @PolicySets annotation is shown in Snippet 8‑22:
@Reference(name="helloService", required=true)
@PolicySets({ MY_NS + "WS_Encryption_Policy",
MY_NS + "WS_Authentication_Policy" })
public setHelloService(HelloService service) {
. . .
}
Snippet 8‑22: Use of @PolicySets
In this case, the Policy Sets WS_Encryption_Policy and WS_Authentication_Policy are applied, both using the namespace defined for the constant MY_NS.
PolicySets need to satisfy intents expressed for the implementation when both are present, according to the rules defined in the Policy Framework specification [POLICY].
The SCA Policy Set annotation can be applied to the following Java elements:
· Java class
· Java interface
· Method
· Field
· Constructor parameter
The @PolicySets annotation MUST NOT be applied to the following:
· A method of a service implementation class, except for a setter method that is either annotated with @Reference or introspected as an SCA reference according to the rules in the appropriate Component Implementation specification
· A service implementation class field that is not either annotated with @Reference or introspected as an SCA reference according to the rules in the appropriate Component Implementation specification
· A service implementation class constructor parameter that is not annotated with @Reference
The @PolicySets annotation can be applied to classes, interfaces, and interface methods. Applying a @PolicySets annotation to a field, setter method, or constructor parameter allows policy sets to be defined at references. The @PolicySets annotation can also be applied to reference interfaces and their methods.
If the @PolicySets annotation is specified on both an interface method and the method's declaring interface, the SCA runtime MUST compute the effective policy sets for the method by merging the policy sets from the method with the policy sets from the interface. [JCA70006] This merging process does not remove or change any policy sets that are applied to the interface.
This section introduces annotations for commonly used SCA security intents, as defined in the SCA Policy Framework Specification [POLICY]. Also see the SCA Policy Framework Specification for additional security policy intents that can be used with the @Requires annotation. The following annotations for security policy intents and qualifiers are defined:
· @Authentication
· @Authorization
· @Confidentiality
· @Integrity
· @MutualAuthentication
The @Authentication, @Confidentiality, and @Integrity intents have the same pair of Qualifiers:
· message
· transport
The formal definitions of the security intent annotations are found in the section “Java Annotations”.
Snippet 8‑23 shows an example of applying security intents to the setter method used to inject a reference. Accessing the hello operation of the referenced HelloService requires both "integrity.message" and "authentication.message" intents to be honored.
package services.hello;
// Interface for HelloService
public interface HelloService {
String hello(String helloMsg);
}
package services.client;
// Interface for ClientService
public interface ClientService {
public void clientMethod();
}
// Implementation class for ClientService
package services.client;
import services.hello.HelloService;
import org.oasisopen.sca.annotation.*;
@Service(ClientService.class)
public class ClientServiceImpl implements ClientService {
private HelloService helloService;
@Reference(name="helloService", required=true)
@Integrity("message")
@Authentication("message")
public void setHelloService(HelloService service) {
helloService = service;
}
public void clientMethod() {
String result = helloService.hello("Hello World!");
…
}
}
Snippet 8‑23: Usage of Security Intents on a Reference
This section introduces annotations for commonly used SCA transaction intents, as defined in the SCA Policy Framework specification [POLICY]. Also see the SCA Policy Framework Specification for additional transaction policy intents that can be used with the @Requires annotation. The following annotations for transaction policy intents and qualifiers are defined:
· @ManagedTransaction
· @NoManagedTransaction
· @SharedManagedTransaction
The @ManagedTransaction intent has the following Qualifiers:
· global
· local
The formal definitions of the transaction intent annotations are found in the section “Java Annotations”.
Snippet 8‑24 shows an example of applying a transaction intent to a component implementation, where the component implementation requires a global transaction.
package services.hello;
// Interface for HelloService
public interface HelloService {
String hello(String helloMsg);
}
// Implementation class for HelloService
package services.hello.impl;
import services.hello.HelloService;
import org.oasisopen.sca.annotation.*;
@Service(HelloService.class)
@ManagedTransaction("global")
public class HelloServiceImpl implements HelloService {
public void someMethod() {
…
}
}
Snippet 8‑24: Usage of Transaction Intents in an Implementation
This section provides a reference for the Java API offered by SCA.
Figure 9‑1 defines the ComponentContext interface:
package org.oasisopen.sca;
import java.util.Collection;
public interface ComponentContext {
String getURI();
<B> B getService(Class<B> businessInterface, String referenceName);
<B> ServiceReference<B> getServiceReference( Class<B> businessInterface,
String referenceName);
<B> Collection<B> getServices( Class<B> businessInterface,
String referenceName);
<B> Collection<ServiceReference<B>> getServiceReferences(
Class<B> businessInterface,
String referenceName);
<B> ServiceReference<B> createSelfReference(Class<B> businessInterface);
<B> ServiceReference<B> createSelfReference( Class<B> businessInterface,
String serviceName);
<B> B getProperty(Class<B> type, String propertyName);
RequestContext getRequestContext();
<B> ServiceReference<B> cast(B target) throws IllegalArgumentException;
}
Figure 9‑1: ComponentContext Interface
getURI () method:
Returns the structural URI [ASSEMBLY] of the component within the SCA Domain.
Returns:
·
String which contains the absolute URI of the
component in the SCA Domain
The ComponentContext.getURI method MUST return
the structural URI of the component in the SCA Domain. [JCA80008]
Parameters:
· none
Exceptions:
· none
getService ( Class<B> businessInterface, String referenceName ) method:
Returns a typed service proxy object for a reference defined by the current component, where the reference has multiplicity 0..1 or 1..1.
Returns:
· B which is a proxy object for the reference, which implements the interface B contained in the businessInterface parameter.
The ComponentContext.getService method MUST return the proxy object implementing the interface provided by the businessInterface parameter, for the reference named by the referenceName parameter with the interface defined by the businessInterface parameter when that reference has a target service configured. [JCA80009]
The ComponentContext.getService method MUST return null if the multiplicity of the reference named by the referenceName parameter is 0..1 and the reference has no target service configured. [JCA80010]
Parameters:
· Class<B> businessInterface - the Java interface for the service reference
· String referenceName - the name of the service reference
Exceptions:
· The ComponentContext.getService method MUST throw an IllegalArgumentException if the reference identified by the referenceName parameter has multiplicity of 0..n or 1..n. [JCA80001]
· The ComponentContext.getService method MUST throw an IllegalArgumentException if the component does not have a reference with the name supplied in the referenceName parameter. [JCA80011]
· The ComponentContext.getService method MUST throw an IllegalArgumentException if the service reference with the name supplied in the referenceName does not have an interface compatible with the interface supplied in the businessInterface parameter. [JCA80012]
getServiceReference ( Class<B> businessInterface, String referenceName ) method:
Returns a ServiceReference object for a reference defined by the current component, where the reference has multiplicity 0..1 or 1..1.
Returns:
·
ServiceReference<B> which is a
ServiceReference proxy object for the reference, which implements the interface
contained in the businessInterface parameter.
The ComponentContext.getServiceReference method
MUST return a ServiceReference object typed by the interface provided by the
businessInterface parameter, for the reference named by the referenceName
parameter with the interface defined by the businessInterface parameter when
that reference has a target service configured. [JCA80013]
The ComponentContext.getServiceReference method
MUST return null if the multiplicity of the reference named by the
referenceName parameter is 0..1 and the reference has no target service
configured. [JCA80007]
Parameters:
· Class<B> businessInterface - the Java interface for the service reference
· String referenceName - the name of the service reference
Exceptions:
· The ComponentContext.getServiceReference method MUST throw an IllegalArgumentException if the reference named by the referenceName parameter has multiplicity greater than one. [JCA80004]
· The ComponentContext.getServiceReference method MUST throw an IllegalArgumentException if the reference named by the referenceName parameter does not have an interface of the type defined by the businessInterface parameter. [JCA80005]
· The ComponentContext.getServiceReference method MUST throw an IllegalArgumentException if the component does not have a reference with the name provided in the referenceName parameter. [JCA80006]
getServices(Class<B> businessInterface, String referenceName) method:
Returns a list of typed service proxies for a reference defined by the current component, where the reference has multiplicity 0..n or 1..n.
Returns:
· Collection<B> which is a collection of proxy objects for the reference, one for each target service to which the reference is wired, where each proxy object implements the interface B contained in the businessInterface parameter.
The ComponentContext.getServices method MUST return a collection containing one proxy object implementing the interface provided by the businessInterface parameter for each of the target services configured on the reference identified by the referenceName parameter. [JCA80014]
The ComponentContext.getServices method MUST return an empty collection if the service reference with the name supplied in the referenceName parameter is not wired to any target services. [JCA80015]
Parameters:
· Class<B> businessInterface - the Java interface for the service reference
· String referenceName - the name of the service reference
Exceptions:
· The ComponentContext.getServices method MUST throw an IllegalArgumentException if the reference identified by the referenceName parameter has multiplicity of 0..1 or 1..1. [JCA80016]
· The ComponentContext.getServices method MUST throw an IllegalArgumentException if the component does not have a reference with the name supplied in the referenceName parameter. [JCA80017]
· The ComponentContext.getServices method MUST throw an IllegalArgumentException if the service reference with the name supplied in the referenceName does not have an interface compatible with the interface supplied in the businessInterface parameter.[JCA80018]
getServiceReferences(Class<B> businessInterface, String referenceName) method:
Returns a list of typed ServiceReference objects for a reference defined by the current component, where the reference has multiplicity 0..n or 1..n.
Returns:
· Collection<ServiceReference<B>> which is a collection of ServiceReference objects for the reference, one for each target service to which the reference is wired, where each proxy object implements the interface B contained in the businessInterface parameter. The collection is empty if the reference is not wired to any target services.
The ComponentContext.getServiceReferences method MUST return a collection containing one ServiceReference object typed by the interface provided by the businessInterface parameter for each of the target services configured on the reference identified by the referenceName parameter. [JCA80019]
The ComponentContext.getServiceReferences method MUST return an empty collection if the service reference with the name supplied in the referenceName parameter is not wired to any target services. [JCA80020]
Parameters:
· Class<B> businessInterface - the Java interface for the service reference
· String referenceName - the name of the service reference
Exceptions:
· The ComponentContext.getServiceReferences method MUST throw an IllegalArgumentException if the reference identified by the referenceName parameter has multiplicity of 0..1 or 1..1. [JCA80021]
· The ComponentContext.getServiceReferences method MUST throw an IllegalArgumentException if the component does not have a reference with the name supplied in the referenceName parameter. [JCA80022]
· The ComponentContext.getServiceReferences method MUST throw an IllegalArgumentException if the service reference with the name supplied in the referenceName does not have an interface compatible with the interface supplied in the businessInterface parameter. [JCA80023]
createSelfReference(Class<B> businessInterface) method:
Returns a ServiceReference object that can be used to invoke this component over the designated service.
Returns:
· ServiceReference<B> which is a ServiceReference object for the service of this component which has the supplied business interface. If the component has multiple services with the same business interface the SCA runtime can return a ServiceReference for any one of them.
The ComponentContext.createSelfReference method MUST return a ServiceReference object typed by the interface defined by the businessInterface parameter for one of the services of the invoking component which has the interface defined by the businessInterface parameter. [JCA80024]
Parameters:
· Class<B> businessInterface - the Java interface for the service
Exceptions:
· The ComponentContext.getServiceReferences method MUST throw an IllegalArgumentException if the component does not have a service which implements the interface identified by the businessInterface parameter. [JCA80025]
createSelfReference(Class<B> businessInterface, String serviceName) method:
Returns a ServiceReference that can be used to invoke this component over the designated service. The serviceName parameter explicitly declares the service name to invoke
Returns:
· ServiceReference<B> which is a ServiceReference proxy object for the reference, which implements the interface contained in the businessInterface parameter.
The ComponentContext.createSelfReference method MUST return a ServiceReference object typed by the interface defined by the businessInterface parameter for the service identified by the serviceName of the invoking component and which has the interface defined by the businessInterface parameter. [JCA80026]
Parameters:
· Class<B> businessInterface - the Java interface for the service reference
· String serviceName - the name of the service reference
Exceptions:
· The ComponentContext.createSelfReference method MUST throw an IllegalArgumentException if the component does not have a service with the name identified by the serviceName parameter. [JCA80027]
· The ComponentContext.createSelfReference method MUST throw an IllegalArgumentException if the component service with the name identified by the serviceName parameter does not implement a business interface which is compatible with the supplied businessInterface parameter. [JCA80028]
getProperty (Class<B> type, String propertyName) method:
Returns the value of an SCA property defined by this component.
Returns:
· <B> which is an object of the type identified by the type parameter containing the value specified for the property in the SCA configuration of the component. null if the SCA configuration of the component does not specify any value for the property.
The ComponentContext.getProperty method MUST return an object of the type identified by the type parameter containing the value specified in the component configuration for the property named by the propertyName parameter or null if no value is specified in the configuration. [JCA80029]
Parameters:
· Class<B> type - the Java class of the property (Object mapped type for primitive Java types - e.g. Integer if the type is int)
· String propertyName - the name of the property
Exceptions:
· The ComponentContext.getProperty method MUST throw an IllegalArgumentException if the component does not have a property with the name identified by the propertyName parameter. [JCA80030]
· The ComponentContext.getProperty method MUST throw an IllegalArgumentException if the component property with the name identified by the propertyName parameter does not have a type which is compatible with the supplied type parameter. [JCA80031]
getRequestContext() method:
Returns the RequestContext for the current SCA service request.
Returns:
· RequestContext which is the RequestContext object for the current SCA service invocation. null if there is no current request or if the context is unavailable.
The ComponentContext.getRequestContext method MUST return non-null when invoked during the execution of a Java business method for a service operation or a callback operation, on the same thread that the SCA runtime provided, and MUST return null in all other cases. [JCA80002]
Parameters:
· none
Exceptions:
· none
cast(B target) method:
Casts a type-safe reference to a ServiceReference
Returns:
· ServiceReference<B> which is a ServiceReference object which implements the same business interface B as a reference proxy object
The ComponentContext.cast method MUST return a ServiceReference object which is typed by the same business interface as specified by the reference proxy object supplied in the target parameter. [JCA80032]
Parameters:
· B target - a type safe reference proxy object which implements the business interface B
Exceptions:
· The ComponentContext.cast method MUST throw an IllegalArgumentException if the supplied target parameter is not an SCA reference proxy object. [JCA80033]
A component can access its component context by defining a field or setter method typed by org.oasisopen.sca.ComponentContext and annotated with @Context. To access a target service, the component uses ComponentContext.getService(..).
Snippet 9‑1 shows an example of component context usage in a Java class using the @Context annotation.
private ComponentContext componentContext;
@Context
public void setContext(ComponentContext context) {
componentContext = context;
}
public void doSomething() {
HelloWorld service =
componentContext.getService(HelloWorld.class,"HelloWorldComponent");
service.hello("hello");
}
Snippet 9‑1: ComponentContext Injection Example
Similarly, non-SCA client code can use the ComponentContext API to perform operations against a component in an SCA domain. How the non-SCA client code obtains a reference to a ComponentContext is runtime specific.
Figure 9‑2 shows the RequestContext
interface:
package org.oasisopen.sca;
import javax.security.auth.Subject;
public interface RequestContext {
Subject getSecuritySubject();
String getServiceName();
<CB> ServiceReference<CB> getCallbackReference();
<CB> CB getCallback();
<B> ServiceReference<B> getServiceReference();
}
Figure 9‑2: RequestContext Interface
getSecuritySubject ( ) method:
Returns the JAAS Subject of the current request (see the JAAS Reference Guide [JAAS] for details of JAAS).
Returns:
· javax.security.auth.Subject object which is the JAAS subject for the request.
null if there is no subject for the request.
The RequestContext.getSecuritySubject method MUST return the JAAS subject of the current request, or null if there is no subject or null if the method is invoked from code not processing a service request or callback request. [JCA80034]
Parameters:
· none
Exceptions:
· none
getServiceName ( ) method:
Returns the name of the service on the Java implementation the request came in on.
Returns:
· String containing the name of the service. null if the method is invoked from a thread that is not processing a service operation or a callback operation.
The RequestContext.getServiceName method MUST return the name of the service for which an operation is being processed, or null if invoked from a thread that is not processing a service operation or a callback operation. [JCA80035]
Parameters:
· none
Exceptions:
· none
getCallbackReference ( ) method:
Returns a service reference proxy for the callback for the invoked service operation, as specified by the service client.
Returns:
· ServiceReference<CB> which is a service reference for the callback for the invoked service, as supplied by the service client. It is typed with the callback interface.
null if the invoked service has an interface which is not bidirectional or if the getCallbackReference() method is called during the processing of a callback operation.
null if the method is invoked from a thread that is not processing a service operation.
The RequestContext.getCallbackReference method MUST return a ServiceReference object typed by the interface of the callback supplied by the client of the invoked service, or null if either the invoked service is not bidirectional or if the method is invoked from a thread that is not processing a service operation. [JCA80036]
Parameters:
· none
Exceptions:
· none
getCallback ( ) method:
Returns a proxy for the callback for the invoked service as specified by the service client.
Returns:
· CB proxy object for the callback for the invoked service as supplied by the service client. It is typed with the callback interface.
null if the invoked service has an interface which is not bidirectional or if the getCallback() method is called during the processing of a callback operation.
null if the method is invoked from a thread that is not processing a service operation.
The RequestContext.getCallback method MUST return a reference proxy object typed by the interface of the callback supplied by the client of the invoked service, or null if either the invoked service is not bidirectional or if the method is invoked from a thread that is not processing a service operation. [JCA80037]
Parameters:
· none
Exceptions:
· none
getServiceReference ( ) method:
Returns a ServiceReference object for the service that was invoked.
Returns:
· ServiceReference<B> which is a service reference for the invoked service. It is typed with the interface of the service.
null if the method is invoked from a thread that is not processing a service operation or a callback operation.
When invoked during the execution of a service operation, the RequestContext.getServiceReference method MUST return a ServiceReference that represents the service that was invoked. [JCA80003]
When invoked during the execution of a callback operation, the RequestContext.getServiceReference method MUST return a ServiceReference that represents the callback that was invoked. [JCA80038]
When invoked from a thread not involved in the execution of either a service operation or of a callback operation, the RequestContext.getServiceReference method MUST return null. [JCA80039]
Parameters:
· none
Exceptions:
· none
ServiceReferences can be injected using the @Reference annotation on a field, a setter method, or constructor parameter taking the type ServiceReference. The detailed description of the usage of these methods is described in the section on Asynchronous Programming in this document.
ServiceReferences can be injected using the @Reference annotation on a field, a setter method, or constructor parameter taking the type ServiceReference. The detailed description of the usage of these methods is described in the section on Asynchronous Programming in this document.
Figure 9‑3 defines the ServiceReference interface:
package org.oasisopen.sca;
public interface ServiceReference<B> extends java.io.Serializable {
B getService();
Class<B> getBusinessInterface();
}
Figure 9‑3: ServiceReference Interface
getService ( ) method:
Returns a type-safe reference to the target of this reference. The instance returned is guaranteed to implement the business interface for this reference. The value returned is a proxy to the target that implements the business interface associated with this reference.
Returns:
· <B> which is type-safe reference proxy object to the target of this reference. It is typed with the interface of the target service.
The ServiceReference.getService method MUST return a reference proxy object which can be used to invoke operations on the target service of the reference and which is typed with the business interface of the reference. [JCA80040]
Parameters:
· none
Exceptions:
· none
getBusinessInterface ( ) method:
Returns the Java class for the business interface associated with this ServiceReference.
Returns:
· Class<B> which is a Class object of the business interface associated with the reference.
The ServiceReference.getBusinessInterface method MUST return a Class object representing the business interface of the reference. [JCA80041]
Parameters:
· none
Exceptions:
· none
The ResponseDispatch interface is shown in Figure 9‑4:
package org.oasisopen.sca;
public interface ResponseDispatch<T> {
void sendResponse(T res);
void sendFault(Throwable e);
Map<String, Object> getContext();
}
Figure 9‑4: ResponseDispatch Interface
sendResponse ( T response ) method:
Sends the response message from an asynchronous service method. This method can only be invoked once for a given ResponseDispatch object and cannot be invoked if sendFault has previously been invoked for the same ResponseDispatch object.
Returns:
· void
The ResponseDispatch.sendResponse() method MUST send the response message to the client of an asynchronous service. [JCA50057]
Parameters:
· T - an instance of the response message returned by the service operation
Exceptions:
· The ResponseDispatch.sendResponse() method MUST throw an InvalidStateException if either the sendResponse method or the sendFault method has already been called once. [JCA80058]
sendFault ( Throwable e ) method:
Sends an exception as a fault from an asynchronous service method. This method can only be invoked once for a given ResponseDispatch object and cannot be invoked if sendResponse has previously been invoked for the same ResponseDispatch object.
Returns:
· void
The ResponseDispatch.sendFault() method MUST send the supplied fault to the client of an asynchronous service. [JCA80059]
Parameters:
· e - an instance of an exception returned by the service operation
Exceptions:
· The ResponseDispatch.sendFault() method MUST throw an InvalidStateException if either the sendResponse method or the sendFault method has already been called once. [JCA80060]
getContext () method:
Obtains the context object for the ResponseDispatch method
Returns:
·
Map<String, object> which is the context
object for the ResponseDispatch object.
The invoker can update the context object with appropriate context information,
prior to invoking either the sendResponse method or the sendFault method
Parameters:
· none
Exceptions:
· none
Figure 9‑5 shows the ServiceRuntimeException.
package org.oasisopen.sca;
public class ServiceRuntimeException extends RuntimeException {
…
}
Figure 9‑5: ServiceRuntimeException
This exception signals problems in the management of SCA component execution.
Figure 9‑6 shows the ServiceUnavailableException.
package org.oasisopen.sca;
public class ServiceUnavailableException extends ServiceRuntimeException {
…
}
Figure 9‑6: ServiceUnavailableException
This exception signals problems in the interaction with remote services. These are exceptions that can be transient, so retrying is appropriate. Any exception that is a ServiceRuntimeException that is not a ServiceUnavailableException is unlikely to be resolved by retrying the operation, since it most likely requires human intervention
Figure 9‑7 shows the InvalidServiceException.
package org.oasisopen.sca;
public class InvalidServiceException extends ServiceRuntimeException {
…
}
Figure 9‑7: InvalidServiceException
This exception signals that the ServiceReference is no longer valid. This can happen when the target of the reference is undeployed. This exception is not transient and therefore is unlikely to be resolved by retrying the operation and will most likely require human intervention.
The SCA Constants interface defines a number of constant values that are used in the SCA Java APIs and Annotations. Figure 9‑8 shows the Constants interface:
package org.oasisopen.sca;
public interface Constants {
String SCA_NS = "http://docs.oasis-open.org/ns/opencsa/sca/200912";
String SCA_PREFIX = "{"+SCA_NS+"}";
String SERVERAUTHENTICATION = SCA_PREFIX + "serverAuthentication";
String CLIENTAUTHENTICATION = SCA_PREFIX + "clientAuthentication";
String ATLEASTONCE = SCA_PREFIX + "atLeastOnce";
String ATMOSTONCE = SCA_PREFIX + "atMostOnce";
String EXACTLYONCE = SCA_PREFIX + "exactlyOnce";
String ORDERED = SCA_PREFIX + "ordered";
String TRANSACTEDONEWAY = SCA_PREFIX + "transactedOneWay";
String IMMEDIATEONEWAY = SCA_PREFIX + "immediateOneWay";
String PROPAGATESTRANSACTION = SCA_PREFIX + "propagatesTransaction";
String SUSPENDSTRANSACTION = SCA_PREFIX + "suspendsTransaction";
String ASYNCINVOCATION = SCA_PREFIX + "asyncInvocation";
String SOAP = SCA_PREFIX + "SOAP";
String JMS = SCA_PREFIX + "JMS";
String NOLISTENER = SCA_PREFIX + "noListener";
String EJB = SCA_PREFIX + "EJB";
}
Figure 9‑8: Constants Interface
The SCAClientFactory class provides the means for client code to obtain a proxy reference object for a service within an SCA Domain, through which the client code can invoke operations of that service. This is particularly useful for client code that is running outside the SCA Domain containing the target service, for example where the code is "unmanaged" and is not running under an SCA runtime.
The SCAClientFactory is an abstract class which provides a set of static newInstance(...) methods which the client can invoke in order to obtain a concrete object implementing the SCAClientFactory interface for a particular SCA Domain. The returned SCAClientFactory object provides a getService() method which provides the client with the means to obtain a reference proxy object for a service running in the SCA Domain.
The SCAClientFactory class is shown in Figure 9‑9:
package org.oasisopen.sca.client;
import java.net.URI;
import java.util.Properties;
import org.oasisopen.sca.NoSuchDomainException;
import org.oasisopen.sca.NoSuchServiceException;
import org.oasisopen.sca.client.SCAClientFactoryFinder;
import org.oasisopen.sca.client.impl.SCAClientFactoryFinderImpl;
public abstract class SCAClientFactory {
protected static SCAClientFactoryFinder factoryFinder;
private URI domainURI;
private SCAClientFactory() {
}
protected SCAClientFactory(URI domainURI)
throws NoSuchDomainException {
this.domainURI = domainURI;
}
protected URI getDomainURI() {
return domainURI;
}
public static SCAClientFactory newInstance( URI domainURI )
throws NoSuchDomainException {
return newInstance(null, null, domainURI);
}
public static SCAClientFactory newInstance(Properties properties,
URI domainURI)
throws NoSuchDomainException {
return newInstance(properties, null, domainURI);
}
public static SCAClientFactory newInstance(ClassLoader classLoader,
URI domainURI)
throws NoSuchDomainException {
return newInstance(null, classLoader, domainURI);
}
public static SCAClientFactory newInstance(Properties properties,
ClassLoader classLoader,
URI domainURI)
throws NoSuchDomainException {
final SCAClientFactoryFinder finder =
factoryFinder != null ? factoryFinder :
new SCAClientFactoryFinderImpl();
final SCAClientFactory factory
= finder.find(properties, classLoader, domainURI);
return factory;
}
public abstract <T> T getService(Class<T> interfaze, String serviceURI)
throws NoSuchServiceException, NoSuchDomainException;
}
Figure 9‑9: SCAClientFactory Class
newInstance ( URI domainURI ) method:
Obtains a object implementing the SCAClientFactory class.
Returns:
· object which implements the SCAClientFactory class
The SCAClientFactory.newInstance( URI ) method MUST return an object which implements the SCAClientFactory class for the SCA Domain identified by the domainURI parameter. [JCA80042]
Parameters:
· domainURI - a URI for the SCA Domain which is targeted by the returned SCAClient object
Exceptions:
· The SCAClientFactory.newInstance( URI ) method MUST throw a NoSuchDomainException if the domainURI parameter does not identify a valid SCA Domain. [JCA80043]
newInstance(Properties properties, URI domainURI) method:
Obtains a object implementing the SCAClientFactory class, using a specified set of properties.
Returns:
· object which implements the SCAClientFactory class
The SCAClientFactory.newInstance( Properties, URI ) method MUST return an object which implements the SCAClientFactory class for the SCA Domain identified by the domainURI parameter. [JCA80044]
Parameters:
· properties - a set of Properties that can be used when creating the object which implements the SCAClientFactory class.
· domainURI - a URI for the SCA Domain which is targeted by the returned SCAClient object
Exceptions:
· The SCAClientFactory.newInstance( Properties, URI ) method MUST throw a NoSuchDomainException if the domainURI parameter does not identify a valid SCA Domain. [JCA80045]
newInstance(Classloader classLoader, URI domainURI) method:
Obtains a object implementing the SCAClientFactory class using a specified classloader.
Returns:
· object which implements the SCAClientFactory class
The SCAClientFactory.newInstance( Classloader, URI ) method MUST return an object which implements the SCAClientFactory class for the SCA Domain identified by the domainURI parameter. [JCA80046]
Parameters:
· classLoader - a ClassLoader to use when creating the object which implements the SCAClientFactory class.
· domainURI - a URI for the SCA Domain which is targeted by the returned SCAClient object
Exceptions:
· The SCAClientFactory.newInstance( Classloader, URI ) method MUST throw a NoSuchDomainException if the domainURI parameter does not identify a valid SCA Domain. [JCA80047]
newInstance(Properties properties, Classloader classLoader, URI domainURI) method:
Obtains a object implementing the SCAClientFactory class using a specified set of properties and a specified classloader.
Returns:
· object which implements the SCAClientFactory class
The SCAClientFactory.newInstance( Properties, Classloader, URI ) method MUST return an object which implements the SCAClientFactory class for the SCA Domain identified by the domainURI parameter. [JCA80048]
Parameters:
· properties - a set of Properties that can be used when creating the object which implements the SCAClientFactory class.
· classLoader - a ClassLoader to use when creating the object which implements the SCAClientFactory class.
· domainURI - a URI for the SCA Domain which is targeted by the returned SCAClient object
Exceptions:
· The SCAClientFactory.newInstance( Properties, Classloader, URI ) MUST throw a NoSuchDomainException if the domainURI parameter does not identify a valid SCA Domain. [JCA80049]
getService( Class<T> interfaze, String serviceURI ) method:
Obtains a proxy reference object for a specified target service in a specified SCA Domain.
Returns:
·
<T> a proxy object which implements the
business interface T
Invocations of a business method of the proxy causes the invocation of the
corresponding operation of the target service.
The SCAClientFactory.getService method MUST return a proxy object which implements the business interface defined by the interfaze parameter and which can be used to invoke operations on the service identified by the serviceURI parameter. [JCA80050]
Parameters:
· interfaze - a Java interface class which is the business interface of the target service
· serviceURI - a String containing the relative URI of the target service within its SCA Domain.
Takes the form componentName/serviceName or can also take the extended form componentName/serviceName/bindingName to use a specific binding of the target service
Exceptions:
· The SCAClientFactory.getService method MUST throw a NoSuchServiceException if a service with the relative URI serviceURI and a business interface which matches interfaze cannot be found in the SCA Domain targeted by the SCAClient object. [JCA80051]
· The SCAClientFactory.getService method MUST throw a NoSuchServiceException if the domainURI of the SCAClientFactory does not identify a valid SCA Domain. [JCA80052]
SCAClientFactory ( URI ) method: a single argument constructor that must be available on all concrete subclasses of SCAClientFactory. The URI required is the URI of the Domain targeted by the SCAClientFactory
getDomainURI() method:
Obtains the Domain URI value for this SCAClientFactory
Returns:
· URI of the target SCA Domain for this SCAClientFactory
The SCAClientFactory.getDomainURI method MUST return the SCA Domain URI of the Domain associated with the SCAClientFactory object. [JCA80053]
Parameters:
· none
Exceptions:
· The SCAClientFactory.getDomainURI method MUST throw a NoSuchServiceException if the domainURI of the SCAClientFactory does not identify a valid SCA Domain. [JCA80054]
private SCAClientFactory() method:
This private no-argument constructor prevents instantiation of an SCAClientFactory instance without the use of the constructor with an argument, even by subclasses of the abstract SCAClientFactory class.
factoryFinder protected field:
Provides a means by which a provider of an SCAClientFactory implementation can inject a factory finder implementation into the abstract SCAClientFactory class - once this is done, future invocations of the SCAClientFactory use the injected factory finder to locate and return an instance of a subclass of SCAClientFactory.
The SCAClientFactoryFinder interface is a Service Provider Interface representing a SCAClientFactory finder. SCA provides a default reference implementation of this interface. SCA runtime vendors can create alternative implementations of this interface that use different class loading or lookup mechanisms:
package org.oasisopen.sca.client;
public interface SCAClientFactoryFinder {
SCAClientFactory find(Properties properties,
ClassLoader classLoader,
URI domainURI )
throws NoSuchDomainException ;
}
Figure 9‑10: SCAClientFactoryFinder Interface
find (Properties properties, ClassLoader classloader, URI domainURI) method:
Obtains an implementation of the SCAClientFactory interface.
Returns:
· SCAClientFactory implementation object
The implementation of the SCAClientFactoryFinder.find method MUST return an object which is an implementation of the SCAClientFactory interface, for the SCA Domain represented by the doaminURI parameter, using the supplied properties and classloader. [JCA80055]
Parameters:
· properties - a set of Properties that can be used when creating the object which implements the SCAClientFactory interface.
· classLoader - a ClassLoader to use when creating the object which implements the SCAClientFactory interface.
· domainURI - a URI for the SCA Domain targeted by the SCAClientFactory
Exceptions:
· The implementation of the SCAClientFactoryFinder.find method MUST throw a ServiceRuntimeException if the SCAClientFactory implementation could not be found. [JCA80056]
This class is a default implementation of an SCAClientFactoryFinder, which is used to find an implementation of an SCAClientFactory subclass, as used to obtain an SCAClient object for use by a client. SCA runtime providers can replace this implementation with their own version.
package org.oasisopen.sca.client.impl;
public class SCAClientFactoryFinderImpl implements SCAClientFactoryFinder {
...
public SCAClientFactoryFinderImpl() {...}
public SCAClientFactory find(Properties properties,
ClassLoader classLoader
URI domainURI)
throws NoSuchDomainException, ServiceRuntimeException {...}
...
}
Snippet 9‑2: SCAClientFactoryFinderImpl Class
SCAClientFactoryFinderImpl () method:
Public constructor for the SCAClientFactoryFinderImpl.
Returns:
· SCAClientFactoryFinderImpl which implements the SCAClientFactoryFinder interface
Parameters:
· none
Exceptions:
· none
find (Properties, ClassLoader, URI) method:
Obtains an implementation of the SCAClientFactory interface. It discovers a provider's SCAClientFactory implementation by referring to the following information in this order:
1. The org.oasisopen.sca.client.SCAClientFactory property from the Properties specified on the newInstance() method call if specified
2. The org.oasisopen.sca.client.SCAClientFactory property from the System Properties
3. The META-INF/services/org.oasisopen.sca.client.SCAClientFactory file
Returns:
· SCAClientFactory implementation object
Parameters:
· properties - a set of Properties that can be used when creating the object which implements the SCAClientFactory interface.
· classLoader - a ClassLoader to use when creating the object which implements the SCAClientFactory interface.
· domainURI - a URI for the SCA Domain targeted by the SCAClientFactory
Exceptions:
· ServiceRuntimeException - if the SCAClientFactory implementation could not be found
Figure 9‑11 shows the NoSuchDomainException:
package org.oasisopen.sca;
public class NoSuchDomainException extends Exception {
...
}
Figure 9‑11: NoSuchDomainException Class
This exception indicates that the Domain specified could not be found.
Figure 9‑12 shows the NoSuchServiceException:
package org.oasisopen.sca;
public
class NoSuchServiceException extends Exception {
...
}
Figure 9‑12: NoSuchServiceException Class
This exception indicates that the service specified could not be found.
This section provides definitions of all the Java annotations which apply to SCA.
This specification places constraints on some annotations that are not detectable by a Java compiler. For example, the definition of the @Property and @Reference annotations indicate that they are allowed on parameters, but the sections "@Property" and "@Reference" constrain those definitions to constructor parameters. An SCA runtime MUST verify the proper use of all SCA annotations and if an annotation is improperly used, the SCA runtime MUST NOT run the component which uses the invalid implementation code. [JCA90001]
SCA annotations MUST NOT be used on static methods or on static fields. It is an error to use an SCA annotation on a static method or a static field of an implementation class and the SCA runtime MUST NOT instantiate such an implementation class. [JCA90002]
Figure 10‑1 defines the @AllowsPassByReference annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.FIELD;
import static java.lang.annotation.ElementType.METHOD;
import static java.lang.annotation.ElementType.PARAMETER;
import static java.lang.annotation.ElementType.TYPE;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
@Target({TYPE, METHOD, FIELD, PARAMETER})
@Retention(RUNTIME)
public @interface AllowsPassByReference {
boolean value() default true;
}
Figure 10‑1: AllowsPassByReference Annotation
The @AllowsPassByReference annotation allows service method implementations and client references to be marked as “allows pass by reference” to indicate that they use input parameters, return values and exceptions in a manner that allows the SCA runtime to avoid the cost of copying mutable objects when a remotable service is called locally within the same JVM.
The @AllowsPassByReference annotation has the attribute:
· value – specifies whether the “allows pass by reference” marker applies to the service implementation class, service implementation method, or client reference to which this annotation applies; if not specified, defaults to true.
The @AllowsPassByReference annotation MUST only annotate the following locations:
· a service implementation class
· an individual method of a remotable service implementation
· an individual reference which uses a remotable interface, where the reference is a field, a setter method, or a constructor parameter [JCA90052]
The “allows pass by reference” marking of a method implementation of a remotable service is determined as follows:
1. If the method has an @AllowsPassByReference annotation, the method is marked “allows pass by reference” if and only if the value of the method’s annotation is true.
2. Otheriwse, if the class has an @AllowsPassByReference annotation, the method is marked “allows pass by reference” if and only if the value of the class’s annotation is true.
3. Otherwise, the method is not marked “allows pass by reference”.
The “allows pass by reference” marking of a reference for a remotable service is determined as follows:
1. If the reference has an @AllowsPassByReference annotation, the reference is marked “allows pass by reference” if and only if the value of the reference’s annotation is true.
2. Otherwise, if the service implementation class containing the reference has an @AllowsPassByReference annotation, the reference is marked “allows pass by reference” if and only if the value of the class’s annotation is true.
3. Otherwise, the reference is not marked “allows pass by reference”.
Snippet 10‑1 shows a sample where @AllowsPassByReference is defined for the implementation of a service method on the Java component implementation class.
@AllowsPassByReference
public String hello(String message) {
…
}
Snippet 10‑1: Use of @AllowsPassByReference on a Method
Snippet 10‑2 shows a sample where @AllowsPassByReference is defined for a client reference of a Java component implementation class.
@AllowsPassByReference
@Reference
private StockQuoteService stockQuote;
Snippet 10‑2: Use of @AllowsPassByReference on a Reference
Figure 10‑2 defines the @AsyncFault annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.METHOD;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import java.lang.annotation.Inherited;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
@Inherited
@Target({METHOD})
@Retention(RUNTIME)
public @interface AsyncFault {
Class<?>[] value() default {};
}
Figure 10‑2: AsyncFault Annotation
The @AsyncFault annotation is used to indicate the faults/exceptions which are returned by the asynchronous service method which it annotates.
Figure 10‑3 defines the @AsyncInvocation annotation, which is used to attach the "asyncInvocation" policy intent to an interface or to a method:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.METHOD;
import static java.lang.annotation.ElementType.TYPE;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import static org.oasisopen.sca.Constants.SCA_PREFIX;
import java.lang.annotation.Inherited;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
@Inherited
@Target({TYPE, METHOD})
@Retention(RUNTIME)
@Intent(AsyncInvocation.ASYNCINVOCATION)
public @interface AsyncInvocation {
String ASYNCINVOCATION = SCA_PREFIX + "asyncInvocation";
boolean value() default true;
}
Figure 10‑3: AsyncInvocation Annotation
The @AsyncInvocation annotation is used to indicate that the operations of a Java interface uses the long-running request-response pattern as described in the SCA Assembly specification.
The following Java code defines the @Authentication annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.FIELD;
import static java.lang.annotation.ElementType.METHOD;
import static java.lang.annotation.ElementType.PARAMETER;
import static java.lang.annotation.ElementType.TYPE;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import static org.oasisopen.sca.Constants.SCA_PREFIX;
import java.lang.annotation.Inherited;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
@Inherited
@Target({TYPE, FIELD, METHOD, PARAMETER})
@Retention(RUNTIME)
@Intent(Authentication.AUTHENTICATION)
public @interface Authentication {
String AUTHENTICATION = SCA_PREFIX + "authentication";
String AUTHENTICATION_MESSAGE = AUTHENTICATION + ".message";
String AUTHENTICATION_TRANSPORT = AUTHENTICATION + ".transport";
/**
* List of authentication qualifiers (such as "message"
* or "transport").
*
* @return authentication qualifiers
*/
@Qualifier
String[] value() default "";
}
Figure 10‑4: Authentication Annotation
The @Authentication annotation is used to indicate the need for authentication. See the SCA Policy Framework Specification [POLICY] for details on the meaning of the intent. See the section on Application of Intent Annotations for samples of how intent annotations are used in Java.
Figure 10‑5 defines the @Authorization annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.FIELD;
import static java.lang.annotation.ElementType.METHOD;
import static java.lang.annotation.ElementType.PARAMETER;
import static java.lang.annotation.ElementType.TYPE;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import static org.oasisopen.sca.Constants.SCA_PREFIX;
import java.lang.annotation.Inherited;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
/**
* The @Authorization annotation is used to indicate that
* an authorization policy is required.
*/
@Inherited
@Target({TYPE, FIELD, METHOD, PARAMETER})
@Retention(RUNTIME)
@Intent(Authorization.AUTHORIZATION)
public @interface Authorization {
String AUTHORIZATION = SCA_PREFIX + "authorization";
}
Figure 10‑5: Authorization Annotation
The @Authorization annotation is used to indicate the need for an authorization policy. See the SCA Policy Framework Specification [POLICY] for details on the meaning of the intent. See the section on Application of Intent Annotations for samples of how intent annotations are used in Java.
Figure 10‑6 defines the @Callback annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.FIELD;
import static java.lang.annotation.ElementType.METHOD;
import static java.lang.annotation.ElementType.TYPE;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
@Target({TYPE, METHOD, FIELD})
@Retention(RUNTIME)
public @interface Callback {
Class<?> value() default Void.class;
}
Figure 10‑6: Callback Annotation
The @Callback annotation is used to annotate a service interface or to annotate a Java class (used to define an interface) with a callback interface by specifying the Java class object of the callback interface as an attribute.
The @Callback annotation has the attribute:
· value – the name of a Java class file containing the callback interface
The @Callback annotation can also be used to annotate a method or a field of an SCA implementation class, in order to have a callback object injected. When used to annotate a method or a field of an implementation class for injection of a callback object, the@Callback annotation MUST NOT specify any attributes. [JCA90046] When used to annotate a method or a field of an implementation class for injection of a callback object, the type of the method or field MUST be the callback interface of at least one bidirectional service offered by the implementation class. [JCA90054] When used to annotate a setter method or a field of an implementation class for injection of a callback object, the SCA runtime MUST inject a callback reference proxy into that method or field when the Java class is initialized, if the component is invoked via a service which has a callback interface and where the type of the setter method or field corresponds to the type of the callback interface. [JCA90058]
The @Callback annotation MUST NOT appear on a setter method or a field of a Java implementation class that has COMPOSITE scope. [JCA90057]
Snippet 10‑3 shows an example use of the @Callback annotation to declare a callback interface.
package somepackage;
import org.oasisopen.sca.annotation.Callback;
import org.oasisopen.sca.annotation.Remotable;
@Remotable
@Callback(MyServiceCallback.class)
public interface MyService {
void someMethod(String arg);
}
@Remotable
public interface MyServiceCallback {
void receiveResult(String result);
}
Snippet 10‑3: Use of @Callback
The implied component type is for Snippet 10‑3 is shown in Snippet 10‑4.
<componentType xmlns="http://docs.oasis-open.org/ns/opencsa/sca/200912" >
<service name="MyService">
<interface.java interface="somepackage.MyService"
callbackInterface="somepackage.MyServiceCallback"/>
</service>
</componentType>
Snippet 10‑4: Implied componentType for Snippet 10‑3
Figure 10‑7 defines the @ComponentName annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.FIELD;
import static java.lang.annotation.ElementType.METHOD;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
@Target({METHOD, FIELD})
@Retention(RUNTIME)
public @interface ComponentName {
}
Figure 10‑7: ComponentName Annotation
The @ComponentName annotation is used to denote a Java class field or setter method that is used to inject the component name.
Snippet 10‑5 shows a component name field definition sample.
@ComponentName
private String componentName;
Snippet 10‑5: Use of @ComponentName on a Field
Snippet 10‑6 shows a component name setter method sample.
@ComponentName
public void setComponentName(String name) {
//…
}
Snippet 10‑6: Use of @ComponentName on a Setter
Figure 10‑8 defines the @Confidentiality annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.FIELD;
import static java.lang.annotation.ElementType.METHOD;
import static java.lang.annotation.ElementType.PARAMETER;
import static java.lang.annotation.ElementType.TYPE;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import static org.oasisopen.sca.Constants.SCA_PREFIX;
import java.lang.annotation.Inherited;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
@Inherited
@Target({TYPE, FIELD, METHOD, PARAMETER})
@Retention(RUNTIME)
@Intent(Confidentiality.CONFIDENTIALITY)
public @interface Confidentiality {
String CONFIDENTIALITY = SCA_PREFIX + "confidentiality";
String CONFIDENTIALITY_MESSAGE = CONFIDENTIALITY + ".message";
String CONFIDENTIALITY_TRANSPORT = CONFIDENTIALITY + ".transport";
/**
* List of confidentiality qualifiers such as "message" or
* "transport".
*
* @return confidentiality qualifiers
*/
@Qualifier
String[] value() default "";
}
Figure 10‑8: Confidentiality Annotation
The @Confidentiality annotation is used to indicate the need for confidentiality. See the SCA Policy Framework Specification [POLICY] for details on the meaning of the intent. See the section on Application of Intent Annotations for samples of how intent annotations are used in Java.
Figure 10‑9 defines the @Constructor annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.CONSTRUCTOR;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
@Target(CONSTRUCTOR)
@Retention(RUNTIME)
public @interface Constructor { }
Figure 10‑9: Constructor Annotation
The @Constructor annotation is used to mark a particular constructor to use when instantiating a Java component implementation. If a constructor of an implementation class is annotated with @Constructor and the constructor has parameters, each of these parameters MUST have either a @Property annotation or a @Reference annotation. [JCA90003]
Snippet 10‑7 shows a sample for the @Constructor annotation.
public class HelloServiceImpl implements HelloService {
public
HelloServiceImpl(){
...
}
@Constructor
public HelloServiceImpl(@Property(name="someProperty")
String someProperty ){
...
}
public
String hello(String message) {
...
}
}
Snippet 10‑7: Use of @Constructor
Figure 10‑10 defines the @Context annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.FIELD;
import static java.lang.annotation.ElementType.METHOD;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
@Target({METHOD, FIELD})
@Retention(RUNTIME)
public @interface Context {
}
Figure 10‑10: Context Annotation
The @Context annotation is used to denote a Java class field or a setter method that is used to inject a composite context for the component. The type of context to be injected is defined by the type of the Java class field or type of the setter method input argument; the type is either ComponentContext or RequestContext.
The @Context annotation has no attributes.
Snippet 10‑8 shows a ComponentContext field definition sample.
@Context
protected ComponentContext context;
Snippet 10‑8: Use of @Context for a ComponentContext
Snippet 10‑9 shows a RequestContext field definition sample.
@Context
protected RequestContext context;
Snippet 10‑9: Use of @Context for a RequestContext
Figure 10‑11 defines the @Destroy annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.METHOD;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
@Target(METHOD)
@Retention(RUNTIME)
public @interface Destroy {
}
Figure 10‑11: Destroy Annotation
The @Destroy annotation is used to denote a single Java class method that will be called when the scope defined for the implementation class ends. A method annotated with @Destroy can have any access modifier and MUST have a void return type and no arguments. [JCA90004]
If there is a method annotated with @Destroy that matches the criteria for the annotation, the SCA runtime MUST call the annotated method when the scope defined for the implementation class ends. [JCA90005]
Snippet 10‑10 shows a sample for a destroy method definition.
@Destroy
public void myDestroyMethod() {
…
}
Snippet 10‑10: Use of @Destroy
Figure 10‑12: EagerInit Annotation defines the @EagerInit annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.TYPE;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
@Target(TYPE)
@Retention(RUNTIME)
public @interface EagerInit {
}
Figure 10‑12: EagerInit Annotation
The @EagerInit annotation is used to mark the Java class of a COMPOSITE scoped implementation for eager initialization. When marked for eager initialization with an @EagerInit annotation, the composite scoped instance MUST be created when its containing component is started. [JCA90007]
Figure 10‑13: Init Annotation defines the @Init annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.METHOD;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
@Target(METHOD)
@Retention(RUNTIME)
public @interface Init {
}
Figure 10‑13: Init Annotation
The @Init annotation is used to denote a single Java class method that is called when the scope defined for the implementation class starts. A method marked with the @Init annotation can have any access modifier and MUST have a void return type and no arguments. [JCA90008]
If there is a method annotated with @Init that matches the criteria for the annotation, the SCA runtime MUST call the annotated method after all property and reference injection is complete. [JCA90009]
Snippet 10‑11 shows an example of an init method definition.
@Init
public void myInitMethod() {
…
}
Snippet 10‑11: Use of @Init
Figure 10‑14 defines the @Integrity annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.FIELD;
import static java.lang.annotation.ElementType.METHOD;
import static java.lang.annotation.ElementType.PARAMETER;
import static java.lang.annotation.ElementType.TYPE;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import static org.oasisopen.sca.Constants.SCA_PREFIX;
import java.lang.annotation.Inherited;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
@Inherited
@Target({TYPE, FIELD, METHOD, PARAMETER})
@Retention(RUNTIME)
@Intent(Integrity.INTEGRITY)
public @interface Integrity {
String INTEGRITY = SCA_PREFIX + "integrity";
String INTEGRITY_MESSAGE = INTEGRITY + ".message";
String INTEGRITY_TRANSPORT = INTEGRITY + ".transport";
/**
* List of integrity qualifiers (such as "message" or "transport").
*
* @return integrity qualifiers
*/
@Qualifier
String[] value() default "";
}
Figure 10‑14: Integrity Annotation
The @Integrity annotation is used to indicate that the invocation requires integrity (i.e. no tampering of the messages between client and service). See the SCA Policy Framework Specification [POLICY] for details on the meaning of the intent. See the section on Application of Intent Annotations for samples of how intent annotations are used in Java.
Figure 10‑15 defines the @Intent annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.ANNOTATION_TYPE;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
@Target({ANNOTATION_TYPE})
@Retention(RUNTIME)
public @interface Intent {
/**
* The qualified name of the intent, in the form defined by
* {@link javax.xml.namespace.QName#toString}.
* @return the qualified name of the intent
*/
String value() default "";
/**
* The XML namespace for the intent.
* @return the XML namespace for the intent
*/
String targetNamespace() default "";
/**
* The name of the intent within its namespace.
* @return name of the intent within its namespace
*/
String localPart() default "";
}
Figure 10‑15: Intent Annotation
The @Intent annotation is used for the creation of new annotations for specific intents. It is not expected that the @Intent annotation will be used in application code.
See the section "How to Create Specific Intent Annotations" for details and samples of how to define new intent annotations.
Figure 10‑16 defines the @ManagedSharedTransaction annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.FIELD;
import static java.lang.annotation.ElementType.METHOD;
import static java.lang.annotation.ElementType.PARAMETER;
import static java.lang.annotation.ElementType.TYPE;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import static org.oasisopen.sca.Constants.SCA_PREFIX;
import java.lang.annotation.Inherited;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
/**
* The @ManagedSharedTransaction annotation is used to indicate that
* a distributed ACID transaction is required.
*/
@Inherited
@Target({TYPE, FIELD, METHOD, PARAMETER})
@Retention(RUNTIME)
@Intent(ManagedSharedTransaction.MANAGEDSHAREDTRANSACTION)
public @interface ManagedSharedTransaction {
String MANAGEDSHAREDTRANSACTION = SCA_PREFIX + "managedSharedTransaction";
}
Figure 10‑16: ManagedSharedTransaction Annotation
The @ManagedSharedTransaction annotation is used to indicate the need for a distributed and globally coordinated ACID transaction. See the SCA Policy Framework Specification [POLICY] for details on the meaning of the intent. See the section on Application of Intent Annotations for samples of how intent annotations are used in Java.
Figure 10‑17 defines the @ManagedTransaction annotation:
import static java.lang.annotation.ElementType.FIELD;
import static java.lang.annotation.ElementType.METHOD;
import static java.lang.annotation.ElementType.PARAMETER;
import static java.lang.annotation.ElementType.TYPE;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import static org.oasisopen.sca.Constants.SCA_PREFIX;
import java.lang.annotation.Inherited;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
/**
* The @ManagedTransaction annotation is used to indicate the
* need for an ACID transaction environment.
*/
@Inherited
@Target({TYPE, FIELD, METHOD, PARAMETER})
@Retention(RUNTIME)
@Intent(ManagedTransaction.MANAGEDTRANSACTION)
public @interface ManagedTransaction {
String MANAGEDTRANSACTION = SCA_PREFIX + "managedTransaction";
String MANAGEDTRANSACTION_LOCAL = MANAGEDTRANSACTION + ".local";
String MANAGEDTRANSACTION_GLOBAL = MANAGEDTRANSACTION + ".global";
/**
* List of managedTransaction qualifiers (such as "global" or "local").
*
* @return managedTransaction qualifiers
*/
@Qualifier
String[] value() default "";
}
Figure 10‑17: ManagedTransaction Annotation
The @ManagedTransaction annotation is used to indicate the need for an ACID transaction. See the SCA Policy Framework Specification [POLICY] for details on the meaning of the intent. See the section on Application of Intent Annotations for samples of how intent annotations are used in Java.
Figure 10‑18 defines the @MutualAuthentication annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.FIELD;
import static java.lang.annotation.ElementType.METHOD;
import static java.lang.annotation.ElementType.PARAMETER;
import static java.lang.annotation.ElementType.TYPE;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import static org.oasisopen.sca.Constants.SCA_PREFIX;
import java.lang.annotation.Inherited;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
/**
* The @MutualAuthentication annotation is used to indicate that
* a mutual authentication policy is needed.
*/
@Inherited
@Target({TYPE, FIELD, METHOD, PARAMETER})
@Retention(RUNTIME)
@Intent(MutualAuthentication.MUTUALAUTHENTICATION)
public @interface MutualAuthentication {
String MUTUALAUTHENTICATION = SCA_PREFIX + "mutualAuthentication";
}
Figure 10‑18: MutualAuthentication Annotation
The @MutualAuthentication annotation is used to indicate the need for mutual authentication between a service consumer and a service provider. See the SCA Policy Framework Specification [POLICY] for details on the meaning of the intent. See the section on Application of Intent Annotations for samples of how intent annotations are used in Java.
Figure 10‑19 defines the @NoManagedTransaction annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.FIELD;
import static java.lang.annotation.ElementType.METHOD;
import static java.lang.annotation.ElementType.PARAMETER;
import static java.lang.annotation.ElementType.TYPE;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import static org.oasisopen.sca.Constants.SCA_PREFIX;
import java.lang.annotation.Inherited;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
/**
* The @NoManagedTransaction annotation is used to indicate that
* a non-transactional environment is needed.
*/
@Inherited
@Target({TYPE, FIELD, METHOD, PARAMETER})
@Retention(RUNTIME)
@Intent(NoManagedTransaction.NOMANAGEDTRANSACTION)
public @interface NoManagedTransaction {
String NOMANAGEDTRANSACTION = SCA_PREFIX + "noManagedTransaction";
}
Figure 10‑19: NoManagedTransaction Annotation
The @NoManagedTransaction annotation is used to indicate that the component does not want to run in an ACID transaction. See the SCA Policy Framework Specification [POLICY] for details on the meaning of the intent. See the section on Application of Intent Annotations for samples of how intent annotations are used in Java.
Figure 10‑20 defines the @OneWay annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.METHOD;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
@Target(METHOD)
@Retention(RUNTIME)
public @interface OneWay {
}
Figure 10‑20: OneWay Annotation
A method annotated with @OneWay MUST have a void return type and MUST NOT have declared checked exceptions. [JCA90055]
When a method of a Java interface is annotated with @OneWay, the SCA runtime MUST ensure that all invocations of that method are executed in a non-blocking fashion, as described in the section on Asynchronous Programming. [JCA90056]
The @OneWay annotation has no attributes.
Snippet 10‑12 shows the use of the @OneWay annotation on an interface.
package services.hello;
import org.oasisopen.sca.annotation.OneWay;
public interface HelloService {
@OneWay
void hello(String name);
}
Snippet 10‑12: Use of @OneWay
Figure 10‑21 defines the @PolicySets annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.FIELD;
import static java.lang.annotation.ElementType.METHOD;
import static java.lang.annotation.ElementType.PARAMETER;
import static java.lang.annotation.ElementType.TYPE;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
@Target({TYPE, FIELD, METHOD, PARAMETER})
@Retention(RUNTIME)
public @interface PolicySets {
/**
* Returns the policy sets to be applied.
*
* @return the policy sets to be applied
*/
String[] value() default "";
}
Figure 10‑21: PolicySets Annotation
The @PolicySets annotation is used to attach one or more SCA Policy Sets to a Java implementation class or to one of its subelements.
See the section "Policy Set Annotations" for details and samples.
Figure 10‑22 defines the @Property annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.FIELD;
import static java.lang.annotation.ElementType.METHOD;
import static java.lang.annotation.ElementType.PARAMETER;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
@Target({METHOD, FIELD, PARAMETER})
@Retention(RUNTIME)
public @interface Property {
String name() default "";
boolean required() default true;
}
Figure 10‑22: Property Annotation
The @Property annotation is used to denote a Java class field, a setter method, or a constructor parameter that is used to inject an SCA property value. The type of the property injected, which can be a simple Java type or a complex Java type, is defined by the type of the Java class field or the type of the input parameter of the setter method or constructor.
When the Java type of a field, setter method or constructor parameter with the @Property annotation is a primitive type or a JAXB annotated class, the SCA runtime MUST convert a property value specified by an SCA component definition into an instance of the Java type as defined by the XML to Java mapping in the JAXB specification [JAXB] with XML schema validation enabled. [JCA90061]
When the Java type of a field, setter method or constructor parameter with the @Property annotation is not a JAXB annotated class, the SCA runtime can use any XML to Java mapping when converting property values into instances of the Java type.
The @Property annotation MUST NOT be used on a class field that is declared as final. [JCA90011]
Where there is both a setter method and a field for a property, the setter method is used.
The @Property annotation has the attributes:
· name (0..1) – the name of the property. For a field annotation, the default is the name of the field of the Java class. For a setter method annotation, the default is the JavaBeans property name [JAVABEANS] corresponding to the setter method name. For a @Property annotation applied to a constructor parameter, there is no default value for the name attribute and the name attribute MUST be present. [JCA90013]
· required (0..1) – a boolean value which specifies whether injection of the property value is required or not, where true means injection is required and false means injection is not required. Defaults to true. For a @Property annotation applied to a constructor parameter, the required attribute MUST NOT have the value false. [JCA90014]
}
Snippet 10‑13 shows a property field definition sample.
@Property(name="currency", required=true)
protected String currency;
The following snippet shows a property setter sample
@Property(name="currency", required=true)
public void setCurrency( String theCurrency ) {
....
Snippet 10‑13: Use of @Property on a Field
For a @Property annotation, if the type of the Java class field or the type of the input parameter of the setter method or constructor is defined as an array or as any type that extends or implements java.util.Collection, then the SCA runtime MUST introspect the component type of the implementation with a <property/> element with a @many attribute set to true, otherwise @many MUST be set to false. [JCA90047]
Snippet 10‑14 shows the definition of a configuration property using the @Property annotation for a collection.
...
private List<String> helloConfigurationProperty;
@Property(required=true)
public void setHelloConfigurationProperty(List<String> property) {
helloConfigurationProperty = property;
}
...
Snippet 10‑14: Use of @Property with a Collection
Figure 10‑23 defines the @Qualifier annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.METHOD;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
@Target(METHOD)
@Retention(RUNTIME)
public @interface Qualifier {
}
Figure 10‑23: Qualifier Annotation
The @Qualifier annotation is applied to an attribute of a specific intent annotation definition, defined using the @Intent annotation, to indicate that the attribute provides qualifiers for the intent. The @Qualifier annotation MUST be used in a specific intent annotation definition where the intent has qualifiers. [JCA90015]
See the section "How to Create Specific Intent Annotations" for details and samples of how to define new intent annotations.
Figure 10‑24 defines the @Reference annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.FIELD;
import static java.lang.annotation.ElementType.METHOD;
import static java.lang.annotation.ElementType.PARAMETER;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
@Target({METHOD, FIELD, PARAMETER})
@Retention(RUNTIME)
public @interface Reference {
String name() default "";
boolean required() default true;
}
Figure 10‑24: Reference Annotation
The @Reference annotation type is used to annotate a Java class field, a setter method, or a constructor parameter that is used to inject a service that resolves the reference. The interface of the service injected is defined by the type of the Java class field or the type of the input parameter of the setter method or constructor.
The @Reference annotation MUST NOT be used on a class field that is declared as final. [JCA90016]
Where there is both a setter method and a field for a reference, the setter method is used.
The @Reference annotation has the attributes:
· name : String (0..1) – the name of the reference. For a field annotation, the default is the name of the field of the Java class. For a setter method annotation, the default is the JavaBeans property name corresponding to the setter method name. For a @Reference annotation applied to a constructor parameter, there is no default for the name attribute and the name attribute MUST be present. [JCA90018]
· required (0..1) – a boolean value which specifies whether injection of the service reference is required or not, where true means injection is required and false means injection is not required. Defaults to true. For a @Reference annotation applied to a constructor parameter, the required attribute MUST have the value true. [JCA90019]
Snippet 10‑15 shows a reference field definition sample.
@Reference(name="stockQuote", required=true)
protected StockQuoteService stockQuote;
Snippet 10‑15: Use of @Reference on a Field
Snippet 10‑16 shows a reference setter sample
@Reference(name="stockQuote", required=true)
public void setStockQuote( StockQuoteService theSQService ) {
...
}
Snippet 10‑16: Use of @Reference on a Setter
Snippet 10‑17 shows a sample of a service reference using the @Reference annotation. The name of the reference is “helloService” and its type is HelloService. The clientMethod() calls the “hello” operation of the service referenced by the helloService reference.
package services.hello;
private HelloService helloService;
@Reference(name="helloService", required=true)
public setHelloService(HelloService service) {
helloService = service;
}
public void clientMethod() {
String result = helloService.hello("Hello World!");
…
}
Snippet 10‑17: Use of @Reference and a ServiceReference
The presence of a @Reference annotation is reflected in the componentType information that the runtime generates through reflection on the implementation class. Snippet 10‑18 shows the component type for the component implementation fragment in Snippet 10‑17.
<?xml version="1.0" encoding="ASCII"?>
<componentType xmlns="http://docs.oasis-open.org/ns/opencsa/sca/200912">
<!-- Any services offered by the component would be listed here -->
<reference name="helloService" multiplicity="1..1">
<interface.java interface="services.hello.HelloService"/>
</reference>
</componentType>
Snippet 10‑18: Implied componentType for Implementation in Snippet 10‑17
If the type of a reference is not an array or any type that extends or implements java.util.Collection, then the SCA runtime MUST introspect the component type of the implementation with a <reference/> element with @multiplicity= 0..1 if the @Reference annotation required attribute is false and with @multiplicity=1..1 if the @Reference annotation required attribute is true. [JCA90020]
If the type of a reference is defined as an array or as any type that extends or implements java.util.Collection, then the SCA runtime MUST introspect the component type of the implementation with a <reference/> element with @multiplicity=0..n if the @Reference annotation required attribute is false and with @multiplicity=1..n if the @Reference annotation required attribute is true. [JCA90021]
Snippet 10‑19 shows a sample of a service reference definition using the @Reference annotation on a java.util.List. The name of the reference is “helloServices” and its type is HelloService. The clientMethod() calls the “hello” operation of all the services referenced by the helloServices reference. In this case, at least one HelloService needs to be present, so required is true.
@Reference(name="helloServices", required=true)
protected List<HelloService> helloServices;
public void clientMethod() {
…
for (int index = 0; index < helloServices.size(); index++) {
HelloService helloService =
(HelloService)helloServices.get(index);
String result = helloService.hello("Hello World!");
}
…
}
Snippet 10‑19: Use of @Reference with a List of ServiceReferences
Snippet 10‑20 shows the XML representation of the component type reflected from for the former component implementation fragment. There is no need to author this component type in this case since it can be reflected from the Java class.
<?xml version="1.0" encoding="ASCII"?>
<componentType xmlns="http://docs.oasis-open.org/ns/opencsa/sca/200912">
<!-- Any services offered by the component would be listed here -->
<reference name="helloServices" multiplicity="1..n">
<interface.java interface="services.hello.HelloService"/>
</reference>
</componentType>
Snippet 10‑20: Implied componentType for Implementation in Snippet 10‑19
An unwired reference with a multiplicity of 0..1 MUST be presented to the implementation code by the SCA runtime as null [JCA90022] An unwired reference with a multiplicity of 0..n MUST be presented to the implementation code by the SCA runtime as an empty array or empty collection [JCA90023]
References MAY be reinjected by an SCA runtime after the initial creation of a component if the reference target changes due to a change in wiring that has occurred since the component was initialized. [JCA90024]
In order for reinjection to occur, the following MUST be true:
1. The component MUST NOT be STATELESS scoped.
2. The reference MUST use either field-based injection or setter injection. References that are injected through constructor injection MUST NOT be changed.
Setter injection allows for code in the setter method to perform processing in reaction to a change.
If a reference target changes and the reference is not reinjected, the reference MUST continue to work as if the reference target was not changed. [JCA90026]
If an operation is called on a reference where the target of that reference has been undeployed, the SCA runtime SHOULD throw an InvalidServiceException. [JCA90027] If an operation is called on a reference where the target of the reference has become unavailable for some reason, the SCA runtime SHOULD throw a ServiceUnavailableException. [JCA90028] If the target service of the reference is changed, the reference MUST either continue to work or throw an InvalidServiceException when it is invoked. [JCA90029] If it doesn't work, the exception thrown will depend on the runtime and the cause of the failure.
A ServiceReference that has been obtained from a reference by ComponentContext.cast() corresponds to the reference that is passed as a parameter to cast(). If the reference is subsequently reinjected, the ServiceReference obtained from the original reference MUST continue to work as if the reference target was not changed. [JCA90030] If the target of a ServiceReference has been undeployed, the SCA runtime SHOULD throw a InvalidServiceException when an operation is invoked on the ServiceReference. [JCA90031] If the target of a ServiceReference has become unavailable, the SCA runtime SHOULD throw a ServiceUnavailableException when an operation is invoked on the ServiceReference. [JCA90032] If the target service of a ServiceReference is changed, the reference MUST either continue to work or throw an InvalidServiceException when it is invoked. [JCA90033] If it doesn't work, the exception thrown will depend on the runtime and the cause of the failure.
A reference or ServiceReference accessed through the component context by calling getService() or getServiceReference() MUST correspond to the current configuration of the domain. This applies whether or not reinjection has taken place. [JCA90034] If the target of a reference or ServiceReference accessed through the component context by calling getService() or getServiceReference() has been undeployed or has become unavailable, the result SHOULD be a reference to the undeployed or unavailable service, and attempts to call business methods SHOULD throw an InvalidServiceException or a ServiceUnavailableException. [JCA90035] If the target service of a reference or ServiceReference accessed through the component context by calling getService() or getServiceReference() has changed, the returned value SHOULD be a reference to the changed service. [JCA90036]
The rules for reference reinjection also apply to references with a multiplicity of 0..n or 1..n. This means that in the cases where reference reinjection is not allowed, the array or Collection for a reference of multiplicity 0..n or multiplicity 1..n MUST NOT change its contents when changes occur to the reference wiring or to the targets of the wiring. [JCA90037] In cases where the contents of a reference array or collection change when the wiring changes or the targets change, then for references that use setter injection, the setter method MUST be called by the SCA runtime for any change to the contents. [JCA90038] A reinjected array or Collection for a reference MUST NOT be the same array or Collection object previously injected to the component. [JCA90039]
|
Effect on |
||
Change event |
Injected Reference or ServiceReference |
Existing ServiceReference Object** |
Subsequent invocations of ComponentContext.getServiceReference() or getService() |
Change to the target of the reference |
can be reinjected (if other conditions* apply). If not reinjected, then it continues to work as if the reference target was not changed. |
continue to work as if the reference target was not changed. |
Result corresponds to the current configuration of the domain. |
Target service undeployed |
Business methods throw InvalidServiceException. |
Business methods throw InvalidServiceException. |
Result is a reference to the undeployed service. Business methods throw InvalidServiceException. |
Target service becomes unavailable |
Business methods throw ServiceUnavailableException |
Business methods throw ServiceUnavailableException |
Result is be a reference to the unavailable service. Business methods throw ServiceUnavailableException. |
Target service changed |
might continue to work, depending on the runtime and the type of change that was made. If it doesn't work, the exception thrown will depend on the runtime and the cause of the failure. |
might continue to work, depending on the runtime and the type of change that was made. If it doesn't work, the exception thrown will depend on the runtime and the cause of the failure. |
Result is a reference to the changed service. |
* Other conditions: The component cannot be STATELESS scoped. The reference has to use either field-based injection or setter injection. References that are injected through constructor injection cannot be changed. ** Result of invoking ComponentContext.cast() corresponds to the reference that is passed as a parameter to cast(). |
Table 10‑1Reinjection Effects
Figure 10‑25 defines the @Remotable annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.TYPE;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
@Target(TYPE,METHOD,FIELD,PARAMETER)
@Retention(RUNTIME)
public @interface Remotable {
}
Figure 10‑25: Remotable Annotation
The @Remotable annotation is used to indicate that an SCA service interface is remotable. The @Remotable annotation is valid only on a Java interface, a Java class, a field, a setter method, or a constructor parameter. It MUST NOT appear anywhere else. [JCA90053] A remotable service can be published externally as a service and MUST be translatable into a WSDL portType. [JCA90040]
The @Remotable annotation has no attributes. When placed on a Java service interface, it indicates that the interface is remotable. When placed on a Java service implementation class, it indicates that all SCA service interfaces provided by the class (including the class itself, if the class defines an SCA service interface) are remotable. When placed on a service reference, it indicates that the interface for the reference is remotable.
Snippet 10‑21 shows the Java interface for a remotable service with its @Remotable annotation.
package services.hello;
import org.oasisopen.sca.annotation.*;
@Remotable
public interface HelloService {
String hello(String message);
}
Snippet 10‑21: Use of @Remotable on an Interface
The style of remotable interfaces is typically coarse grained and intended for loosely coupled interactions. Remotable service interfaces are not allowed to make use of method overloading.
Complex data types exchanged via remotable service interfaces need to be compatible with the marshalling technology used by the service binding. For example, if the service is going to be exposed using the standard Web Service binding, then the parameters can be JAXB [JAX-B] types or they can be Service Data Objects (SDOs) [SDO].
Independent of whether the remotable service is called from outside of the composite that contains it or from another component in the same composite, the data exchange semantics are by-value.
Implementations of remotable services can modify input data during or after an invocation and can modify return data after the invocation. If a remotable service is called locally or remotely, the SCA container is responsible for making sure that no modification of input data or post-invocation modifications to return data are seen by the caller.
Snippet 10‑22 shows how a Java service implementation class can use the @Remotable annotation to define a remotable SCA service interface using a Java service interface that is not marked as remotable.
package services.hello;
import org.oasisopen.sca.annotation.*;
public interface HelloService {
String hello(String message);
}
package services.hello;
import org.oasisopen.sca.annotation.*;
@Remotable
@Service(HelloService.class)
public class HelloServiceImpl implements HelloService {
public String hello(String message) {
...
}
}
Snippet 10‑22: Use of @Remotable on a Class
Snippet 10‑23 shows how a reference can use the @Remotable annotation to define a remotable SCA service interface using a Java service interface that is not marked as remotable.
package services.hello;
import org.oasisopen.sca.annotation.*;
public interface HelloService {
String hello(String message);
}
package services.hello;
import org.oasisopen.sca.annotation.*;
public class HelloClient {
@Remotable
@Reference
protected HelloService myHello;
public String greeting(String message) {
return myHello.hello(message);
}
}
Snippet 10‑23: Use of @Remotable on a Reference
Figure 10‑26 defines the @Requires annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.FIELD;
import static java.lang.annotation.ElementType.METHOD;
import static java.lang.annotation.ElementType.PARAMETER;
import static java.lang.annotation.ElementType.TYPE;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import java.lang.annotation.Inherited;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
@Inherited
@Retention(RUNTIME)
@Target({TYPE, METHOD, FIELD, PARAMETER})
public @interface Requires {
/**
* Returns the attached intents.
*
* @return the attached intents
*/
String[] value() default "";
}
Figure 10‑26: Requires Annotation
The @Requires annotation supports general purpose intents specified as strings. Users can also define specific intent annotations using the @Intent annotation.
See the section "General Intent Annotations" for details and samples.
Figure 10‑27 defines the @Scope annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.TYPE;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
@Target(TYPE)
@Retention(RUNTIME)
public @interface Scope {
String value() default "STATELESS";
}
Figure 10‑27: Scope Annotation
The @Scope annotation MUST only be used on a service's implementation class. It is an error to use this annotation on an interface. [JCA90041]
The @Scope annotation has the attribute:
· value – the name of the scope.
SCA defines the following scope names, but others can be defined by particular Java-based implementation types
STATELESS
COMPOSITE
The default value is STATELESS.
Snippet 10‑24 shows a sample for a COMPOSITE scoped service implementation:
package services.hello;
import org.oasisopen.sca.annotation.*;
@Service(HelloService.class)
@Scope("COMPOSITE")
public class HelloServiceImpl implements HelloService {
public String hello(String message) {
...
}
}
Snippet 10‑24: Use of @Scope
Figure 10‑28 defines the @Service annotation:
package org.oasisopen.sca.annotation;
import static java.lang.annotation.ElementType.TYPE;
import static java.lang.annotation.RetentionPolicy.RUNTIME;
import java.lang.annotation.Retention;
import java.lang.annotation.Target;
@Target(TYPE)
@Retention(RUNTIME)
public @interface Service {
Class<?>[] value();
String[] names() default {};
}
Figure 10‑28: Service Annotation
The @Service annotation is used on a component implementation class to specify the SCA services offered by the implementation. An implementation class need not be declared as implementing all of the interfaces implied by the services declared in its @Service annotation, but all methods of all the declared service interfaces MUST be present. [JCA90042] A class used as the implementation of a service is not required to have a @Service annotation. If a class has no @Service annotation, then the rules determining which services are offered and what interfaces those services have are determined by the specific implementation type.
The @Service annotation has the attributes:
· value (1..1) – An array of interface or class objects that are exposed as services by this implementation. If the array is empty, no services are exposed.
· names (0..1) - An array of Strings which are used as the service names for each of the interfaces declared in the value array. The number of Strings in the names attribute array of the @Service annotation MUST match the number of elements in the value attribute array. [JCA90050] The value of each element in the @Service names array MUST be unique amongst all the other element values in the array. [JCA90060]
The service name of an exposed service defaults to the name of its interface or class, without the package name. If the names attribute is specified, the service name for each interface or class in the value attribute array is the String declared in the corresponding position in the names attribute array.
If a component implementation has two services with the same Java simple name, the names attribute of the @Service annotation MUST be specified. [JCA90045] If a Java implementation needs to realize two services with the same Java simple name then this can be achieved through subclassing of the interface.
Snippet 10‑25 shows an implementation of the HelloService marked with the @Service annotation.
package services.hello;
import org.oasisopen.sca.annotation.Service;
@Service(HelloService.class)
public class HelloServiceImpl implements HelloService {
public void hello(String name) {
System.out.println("Hello " + name);
}
}
Snippet 10‑25: Use of @Service
This specification applies the WSDL to Java and Java to WSDL mapping rules as defined by the JAX-WS 2.1 specification [JAX-WS] for generating remotable Java interfaces from WSDL portTypes and vice versa.
SCA runtimes MUST support the JAX-WS 2.1 mappings from WSDL to Java and from Java to WSDL. [JCA100022] For the purposes of the Java-to-WSDL mapping algorithm, the SCA runtime MUST treat a Java interface as if it had a @WebService annotation on the class, even if it doesn't. [JCA100001] The SCA runtime MUST treat an @org.oasisopen.sca.annotation.OneWay annotation as a synonym for the @javax.jws.OneWay annotation. [JCA100002] For the WSDL-to-Java mapping, the SCA runtime MUST take the generated @WebService annotation to imply that the Java interface is @Remotable. [JCA100003]
For the mapping from Java types to XML schema types, SCA permits both the JAXB 2.1 [JAX-B] mapping and the SDO 2.1 [SDO] mapping. SCA runtimes MUST support the JAXB 2.1 mapping from XML Schema to Java and from Java to XML Schema. [JCA100004] SCA runtimes MAY support the SDO 2.1 mapping from XML schema types to Java and from Java to XML Schema. [JCA100005] Having a choice of binding technologies is allowed, as noted in the first paragraph of section 5 of the JSR 181 (version 2) specification, which is referenced by the JAX-WS specification.
A Java class or interface used to define an SCA interface can contain JAX-WS annotations. In addition to affecting the Java to WSDL mapping defined by the JAX-WS specification [JAX-WS] these annotations can impact the SCA interface. An SCA runtime MUST apply the JAX-WS annotations as described in Table 11‑1 and Table 11‑2 when introspecting a Java class or interface class. [JCA100011] This could mean that the interface of a Java implementation is defined by a WSDL interface declaration. If the services provided by an implementation class are explicitly identified by an @Service annotation, only the identified classes define services of the implementation even if implemented interfaces that are not listed in the @Service annotation contain @JAX-WS annotations.
Annotation |
Property |
Impact to SCA Interface |
@WebService |
|
A Java interface or class annotated with @WebService MUST be treated as if annotated with the SCA @Remotable annotation [JCA100012] |
name |
The value of the name attribute of the @WebService annotation, if present, MUST be used to define the name of an SCA service when there is no @Service annotation present in the SCA component implementation. [JCA100023] The value of the name attribute of the @WebService annotation, if present, MUST be used to define the name of an SCA service when the @Service annotation is present without the names attribute and indicates that the Java interface or class annotated with the @WebService annotation defines an SCA service interface. [JCA100028] |
|
targetNamespace |
None |
|
serviceName |
None |
|
wsdlLocation |
A Java class annotated with the @WebService annotation with its wsdlLocation attribute set MUST have its interface defined by the referenced WSDL definition instead of the annotated Java class. [JCA100013] |
|
endpointInterface |
A Java class annotated with the @WebService annotation with its endpointInterface attribute set MUST have its interface defined by the referenced interface instead of annotated Java class. [JCA100014] |
|
portName |
None |
|
@WebMethod |
|
|
operationName |
For a Java method annotated with the @WebMethod annotation with the operationName set, an SCA runtime MUST use the value of the operationName attribute as the SCA operation name. [JCA100024] |
|
action |
None |
|
exclude |
An SCA runtime MUST NOT include a Java method annotated with the @WebMethod annotation with the exclude attribute set to true in an SCA interface. [JCA100025] |
|
@OneWay |
|
The SCA runtime MUST treat an @org.oasisopen.sca.annotation.OneWay annotation as a synonym for the @javax.jws.OneWay annotation. [JCA100002] |
@WebParam |
|
|
name |
Sets parameter name |
|
targetNamespace |
None |
|
mode |
For a Java parameter annotated with the @WebParam annotation with the mode attribute set, an SCA runtime MUST apply the value of the mode attribute when comparing interfaces. [JCA100026] |
|
header |
A Java class or interface containing an @WebParam annotation with its header attribute set to “true” MUST be treated as if the SOAP intent is applied to the Java class or interface. [JCA100015] |
|
partName |
Overrides name |
|
@WebResult |
|
|
name |
Sets parameter name |
|
targetNamespace |
None |
|
header |
A Java class or interface containing an @WebResult annotation with its header attribute set to “true” MUST be treated as if the SOAP intent is applied to the Java class or interface. [JCA100016] |
|
partName |
Overrides name |
|
@SOAPBinding |
|
A Java class or interface containing an @SOAPBinding annotation MUST be treated as if the SOAP intent is applied to the Java class or interface. [JCA100021] |
style |
|
|
use |
|
|
parameterStyle |
|
|
@HandlerChain |
|
None |
file |
|
|
name |
|
Table 11‑1: JSR 181 Annotations and SCA Interfaces
Annotation |
Property |
Impact to SCA Interface |
@ServiceMode |
|
A Java class containing an @ServiceMode annotation MUST be treated as if the SOAP intent is applied to the Java class. [JCA100017] |
value |
|
|
@WebFault |
|
|
name |
None |
|
targetNamespace |
None |
|
faultBean |
None |
|
@RequestWrapper |
|
None |
localName |
|
|
targetNamespace |
|
|
className |
|
|
@ResponseWrapper |
|
None |
localName |
|
|
targetNamespace |
|
|
className |
|
|
@WebServiceClient |
|
An interface or class annotated with @WebServiceClient MUST NOT be used to define an SCA interface. [JCA100018] |
name |
|
|
targetNamespace |
|
|
wsdlLocation |
|
|
@WebEndpoint |
|
None |
name |
|
|
@WebServiceProvider |
|
A class annotated with @WebServiceProvider MUST be treated as if annotated with the SCA @Remotable annotation. [JCA100019] |
wsdlLocation |
A Java class annotated with the @WebServiceProvider annotation with its wsdlLocation attribute set MUST have its interface defined by the referenced WSDL definition is used instead of the annotated Java class. [JCA100020] |
|
serviceName |
None |
|
portName |
None |
|
targetNamespace |
None |
|
@BindingType |
|
None |
value |
|
|
@WebServiceRef |
|
See JEE specification |
name |
|
|
wsdlLocation |
|
|
type |
|
|
value |
|
|
mappedName |
|
|
@WebServiceRefs |
|
See JEE specification |
value |
|
|
@Action |
|
None |
fault |
|
|
input |
|
|
output |
|
|
@FaultAction |
|
None |
value |
|
|
output |
|
Table 11‑2: JSR 224 Annotations and SCA Interfaces
The JAX-WS specification defines a mapping of a synchronous service invocation, which provides a client application with a means of invoking that service asynchronously, so that the client can invoke a service operation and proceed to do other work without waiting for the service operation to complete its processing. The client application can retrieve the results of the service either through a polling mechanism or via a callback method which is invoked when the operation completes.
For SCA service interfaces
defined using interface.java, the Java interface MUST NOT contain the
additional client-side asynchronous polling and callback methods defined by
JAX-WS. [JCA100006]
For SCA reference interfaces defined using
interface.java, the SCA runtime MUST support a Java interface which contains
the additional client-side asynchronous polling and callback methods defined by
JAX-WS. [JCA100007]
If the additional client-side asynchronous
polling and callback methods defined by JAX-WS are present in the interface
which declares the type of a reference in the implementation, SCA Runtimes MUST
NOT include these methods in the SCA reference interface in the component type
of the implementation. [JCA100008]
The additional client-side asynchronous polling and callback methods defined by
JAX-WS are recognized in a Java interface according to the steps:
For each method M in the interface, if another method P in the interface has
a. a method name that is M's method name with the characters "Async" appended, and
b. the same parameter signature as M, and
c. a return type of Response<R> where R is the return type of M
then P is a JAX-WS polling method that isn't part of the SCA interface contract.
For each method M in the interface, if another method C in the interface has
a. a method name that is M's method name with the characters "Async" appended, and
b. a parameter signature that is M's parameter signature with an additional final parameter of type AsyncHandler<R> where R is the return type of M, and
c. a return type of Future<?>
then C is a JAX-WS callback method that isn't part of the SCA interface contract.
As an example, an interface can be defined in WSDL as shown in Snippet 11‑1:
<!-- WSDL extract -->
<message name="getPrice">
<part name="ticker" type="xsd:string"/>
</message>
<message name="getPriceResponse">
<part name="price" type="xsd:float"/>
</message>
<portType name="StockQuote">
<operation name="getPrice">
<input message="tns:getPrice"/>
<output message="tns:getPriceResponse"/>
</operation>
</portType>
Snippet 11‑1: Example WSDL Interface
The JAX-WS asynchronous mapping will produce the Java interface in Snippet 11‑2:
// asynchronous mapping
@WebService
public interface StockQuote {
float getPrice(String ticker);
Response<Float> getPriceAsync(String ticker);
Future<?> getPriceAsync(String ticker, AsyncHandler<Float>);
}
Snippet 11‑2: JAX-WS Asynchronous Interface for WSDL Interface in Snippet 11‑1
For SCA interface definition purposes, this is treated as equivalent to the interface in Snippet 11‑3:
// synchronous mapping
@WebService
public interface StockQuote {
float getPrice(String ticker);
}
Snippet 11‑3: Equivalent SCA Interface Correspoining to Java Interface in Snippet 11‑2
SCA runtimes MUST support the use of the JAX-WS client asynchronous model. [JCA100009] If the client implementation uses the asynchronous form of the interface, the two additional getPriceAsync() methods can be used for polling and callbacks as defined by the JAX-WS specification.
For SCA service interfaces defined using interface.java, the SCA runtime MUST support a Java interface which contains the server-side asynchronous methods defined by SCA. [JCA100010]
Asynchronous service methods are identified as described in the section "Asynchronous handling of Long Running Service Operations" and are mapped to WSDL in the same way as the equivalent synchronous method described in that section.
Generating an asynchronous service method from a WSDL request/response operation follows the algorithm described in the same section.
The XML schema pointed to by the RDDL document at the namespace URI, defined by this specification, are considered to be authoritative and take precedence over the XML schema defined in the appendix of this document.
Normative code artifacts related to this specification are considered to be authoritative and take precedence over specification text.
There are three categories of artifacts for which this specification defines conformance:
a) SCA Java XML Document,
b) SCA Java Class
c) SCA Runtime.
An SCA Java XML document is an SCA Composite Document, or an SCA ComponentType Document, as defined by the SCA Assembly Model specification [ASSEMBLY], that uses the <interface.java> element. Such an SCA Java XML document MUST be a conformant SCA Composite Document or SCA ComponentType Document, as defined by the SCA Assembly Model specification [ASSEMBLY], and MUST comply with the requirements specified in the Interface section of this specification.
An SCA Java Class is a Java class or interface that complies with Java Standard Edition version 5.0 and MAY include annotations and APIs defined in this specification. An SCA Java Class that uses annotations and APIs defined in this specification MUST comply with the requirements specified in this specification for those annotations and APIs.
The APIs and annotations defined in this specification are meant to be used by Java-based component implementation models in either partial or complete fashion. A Java-based component implementation specification that uses this specification specifies which of the APIs and annotations defined here are used. The APIs and annotations an SCA Runtime has to support depends on which Java-based component implementation specification the runtime supports. For example, see the SCA POJO Component Implementation Specification [JAVA_CI].
An implementation that claims to conform to this specification MUST meet the following conditions:
1. The implementation MUST meet all the conformance requirements defined by the SCA Assembly Model Specification [ASSEMBLY].
2. The implementation MUST support <interface.java> and MUST comply with all the normative statements in Section 3.
3. The implementation MUST reject an SCA Java XML Document that does not conform to the sca-interface-java.xsd schema.
4. The implementation MUST support and comply with all the normative statements in Section 10.
<?xml version="1.0" encoding="UTF-8"?>
<!-- Copyright(C) OASIS(R) 2005,2010. All Rights Reserved.
OASIS trademark, IPR and other policies apply. -->
<schema xmlns="http://www.w3.org/2001/XMLSchema"
targetNamespace="http://docs.oasis-open.org/ns/opencsa/sca/200912"
xmlns:sca="http://docs.oasis-open.org/ns/opencsa/sca/200912"
elementFormDefault="qualified">
<include schemaLocation="sca-core-1.1-cd06.xsd"/>
<!-- Java Interface -->
<element name="interface.java" type="sca:JavaInterface"
substitutionGroup="sca:interface"/>
<complexType name="JavaInterface">
<complexContent>
<extension base="sca:Interface">
<sequence>
<any namespace="##other" processContents="lax" minOccurs="0"
maxOccurs="unbounded"/>
</sequence>
<attribute name="interface" type="NCName" use="required"/>
<attribute name="callbackInterface" type="NCName"
use="optional"/>
</extension>
</complexContent>
</complexType>
</schema>
B.1 SCAClient Classes and Interfaces
SCA provides an abstract base class SCAClientFactory. Vendors can provide subclasses of this class which create objects that implement the SCAClientFactory class suitable for linking to services in their SCA runtime.
/*
* Copyright(C) OASIS(R) 2005,2010. All Rights Reserved.
* OASIS trademark, IPR and other policies apply.
*/
package org.oasisopen.sca.client;
import java.net.URI;
import java.util.Properties;
import org.oasisopen.sca.NoSuchDomainException;
import org.oasisopen.sca.NoSuchServiceException;
import org.oasisopen.sca.client.SCAClientFactoryFinder;
import org.oasisopen.sca.client.impl.SCAClientFactoryFinderImpl;
/**
* The SCAClientFactory can be used by non-SCA managed code to
* lookup services that exist in a SCADomain.
*
* @see SCAClientFactoryFinderImpl
*
* @author OASIS Open
*/
public abstract class SCAClientFactory {
/**
* The SCAClientFactoryFinder.
* Provides a means by which a provider of an SCAClientFactory
* implementation can inject a factory finder implementation into
* the abstract SCAClientFactory class - once this is done, future
* invocations of the SCAClientFactory use the injected factory
* finder to locate and return an instance of a subclass of
* SCAClientFactory.
*/
protected static SCAClientFactoryFinder factoryFinder;
/**
* The Domain URI of the SCA Domain which is accessed by this
* SCAClientFactory
*/
private URI domainURI;
/**
* Prevent concrete subclasses from using the no-arg constructor
*/
private SCAClientFactory() {
}
/**
* Constructor used by concrete subclasses
* @param domainURI - The Domain URI of the Domain accessed via this
* SCAClientFactory
*/
protected SCAClientFactory(URI domainURI) throws NoSuchDomainException {
this.domainURI = domainURI;
}
/**
* Gets the Domain URI of the Domain accessed via this SCAClientFactory
* @return - the URI for the Domain
*/
protected URI getDomainURI() {
return domainURI;
}
/**
* Creates a new instance of the SCAClientFactory that can be
* used to lookup SCA Services.
*
* @param domainURI URI of the target domain for the SCAClientFactory
* @return A new SCAClientFactory
*/
public static SCAClientFactory newInstance( URI domainURI )
throws NoSuchDomainException {
return newInstance(null, null, domainURI);
}
/**
* Creates a new instance of the SCAClientFactory that can be
* used to lookup SCA Services.
*
* @param properties Properties that may be used when
* creating a new instance of the SCAClientFactory
* @param domainURI URI of the target domain for the SCAClientFactory
* @return A new SCAClientFactory instance
*/
public static SCAClientFactory newInstance(Properties properties,
URI domainURI)
throws NoSuchDomainException {
return newInstance(properties, null, domainURI);
}
/**
* Creates a new instance of the SCAClientFactory that can be
* used to lookup SCA Services.
*
* @param classLoader ClassLoader that may be used when
* creating a new instance of the SCAClientFactory
* @param domainURI URI of the target domain for the SCAClientFactory
* @return A new SCAClientFactory instance
*/
public static SCAClientFactory newInstance(ClassLoader classLoader,
URI domainURI)
throws NoSuchDomainException {
return newInstance(null, classLoader, domainURI);
}
/**
* Creates a new instance of the SCAClientFactory that can be
* used to lookup SCA Services.
*
* @param properties Properties that may be used when
* creating a new instance of the SCAClientFactory
* @param classLoader ClassLoader that may be used when
* creating a new instance of the SCAClientFactory
* @param domainURI URI of the target domain for the SCAClientFactory
* @return A new SCAClientFactory instance
*/
public static SCAClientFactory newInstance(Properties properties,
ClassLoader classLoader,
URI domainURI)
throws NoSuchDomainException {
final SCAClientFactoryFinder finder =
factoryFinder != null ? factoryFinder :
new SCAClientFactoryFinderImpl();
final SCAClientFactory factory
= finder.find(properties, classLoader, domainURI);
return factory;
}
/**
* Returns a reference proxy that implements the business interface <T>
* of a service in the SCA Domain handled by this SCAClientFactory
*
* @param serviceURI the relative URI of the target service. Takes the
* form componentName/serviceName.
* Can also take the extended form componentName/serviceName/bindingName
* to use a specific binding of the target service
*
* @param interfaze The business interface class of the service in the
* domain
* @param <T> The business interface class of the service in the domain
*
* @return a proxy to the target service, in the specified SCA Domain
* that implements the business interface <B>.
* @throws NoSuchServiceException Service requested was not found
* @throws NoSuchDomainException Domain requested was not found
*/
public abstract <T> T getService(Class<T> interfaze, String serviceURI)
throws NoSuchServiceException, NoSuchDomainException;
}
B.1.2 SCAClientFactoryFinder interface
The SCAClientFactoryFinder interface is a Service Provider Interface representing a SCAClientFactory finder. SCA provides a default reference implementation of this interface. SCA runtime vendors can create alternative implementations of this interface that use different class loading or lookup mechanisms.
/*
* Copyright(C) OASIS(R) 2005,2010. All Rights Reserved.
* OASIS trademark, IPR and other policies apply.
*/
package org.oasisopen.sca.client;
import java.net.URI;
import java.util.Properties;
import org.oasisopen.sca.NoSuchDomainException;
/* A Service Provider Interface representing a SCAClientFactory finder.
* SCA provides a default reference implementation of this interface.
* SCA runtime vendors can create alternative implementations of this
* interface that use different class loading or lookup mechanisms.
*/
public interface SCAClientFactoryFinder {
/**
* Method for finding the SCAClientFactory for a given Domain URI using
* a specified set of properties and a a specified ClassLoader
* @param properties - properties to use - may be null
* @param classLoader - ClassLoader to use - may be null
* @param domainURI - the Domain URI - must be a valid SCA Domain URI
* @return - the SCAClientFactory or null if the factory could not be
* @throws - NoSuchDomainException if the domainURI does not reference
* a valid SCA Domain
* found
*/
SCAClientFactory find(Properties properties,
ClassLoader classLoader,
URI domainURI )
throws NoSuchDomainException ;
}
B.1.3 SCAClientFactoryFinderImpl class
This class provides a default implementation for finding a provider's SCAClientFactory implementation class. It is used if the provider does not inject its SCAClientFactoryFinder implementation class into the base SCAClientFactory class.
It discovers a provider's SCAClientFactory implementation by referring to the following information in this order:
/*
* Copyright(C) OASIS(R) 2005,2010. All Rights Reserved.
* OASIS trademark, IPR and other policies apply.
*/
package org.oasisopen.sca.client.impl;
import org.oasisopen.sca.client.SCAClientFactoryFinder;
import java.io.BufferedReader;
import java.io.Closeable;
import java.io.IOException;
import java.io.InputStream;
import java.io.InputStreamReader;
import java.lang.reflect.Constructor;
import java.net.URI;
import java.net.URL;
import java.util.Properties;
import org.oasisopen.sca.NoSuchDomainException;
import org.oasisopen.sca.ServiceRuntimeException;
import org.oasisopen.sca.client.SCAClientFactory;
/**
* This is a default implementation of an SCAClientFactoryFinder which is
* used to find an implementation of the SCAClientFactory interface.
*
* @see SCAClientFactoryFinder
* @see SCAClientFactory
*
* @author OASIS Open
*/
public class SCAClientFactoryFinderImpl implements SCAClientFactoryFinder {
/**
* The name of the System Property used to determine the SPI
* implementation to use for the SCAClientFactory.
*/
private static final String SCA_CLIENT_FACTORY_PROVIDER_KEY =
SCAClientFactory.class.getName();
/**
* The name of the file loaded from the ClassPath to determine
* the SPI implementation to use for the SCAClientFactory.
*/
private static final String SCA_CLIENT_FACTORY_PROVIDER_META_INF_SERVICE
= "META-INF/services/" + SCA_CLIENT_FACTORY_PROVIDER_KEY;
/**
* Public Constructor
*/
public SCAClientFactoryFinderImpl() {
}
/**
* Creates an instance of the SCAClientFactorySPI implementation.
* This discovers the SCAClientFactorySPI Implementation and instantiates
* the provider's implementation.
*
* @param properties Properties that may be used when creating a new
* instance of the SCAClient
* @param classLoader ClassLoader that may be used when creating a new
* instance of the SCAClient
* @return new instance of the SCAClientFactory
* @throws ServiceRuntimeException Failed to create SCAClientFactory
* Implementation.
*/
public SCAClientFactory find(Properties properties,
ClassLoader classLoader,
URI domainURI )
throws NoSuchDomainException, ServiceRuntimeException {
if (classLoader == null) {
classLoader = getThreadContextClassLoader ();
}
final String factoryImplClassName =
discoverProviderFactoryImplClass(properties, classLoader);
final Class<? extends SCAClientFactory> factoryImplClass
= loadProviderFactoryClass(factoryImplClassName,
classLoader);
final SCAClientFactory factory =
instantiateSCAClientFactoryClass(factoryImplClass,
domainURI );
return factory;
}
/**
* Gets the Context ClassLoader for the current Thread.
*
* @return The Context ClassLoader for the current Thread.
*/
private static ClassLoader getThreadContextClassLoader () {
final ClassLoader threadClassLoader =
Thread.currentThread().getContextClassLoader();
return threadClassLoader;
}
/**
* Attempts to discover the class name for the SCAClientFactorySPI
* implementation from the specified Properties, the System Properties
* or the specified ClassLoader.
*
* @return The class name of the SCAClientFactorySPI implementation
* @throw ServiceRuntimeException Failed to find implementation for
* SCAClientFactorySPI.
*/
private static String
discoverProviderFactoryImplClass(Properties properties,
ClassLoader classLoader)
throws ServiceRuntimeException {
String providerClassName =
checkPropertiesForSPIClassName(properties);
if (providerClassName != null) {
return providerClassName;
}
providerClassName =
checkPropertiesForSPIClassName(System.getProperties());
if (providerClassName != null) {
return providerClassName;
}
providerClassName = checkMETAINFServicesForSPIClassName(classLoader);
if (providerClassName == null) {
throw new ServiceRuntimeException(
"Failed to find implementation for SCAClientFactory");
}
return providerClassName;
}
/**
* Attempts to find the class name for the SCAClientFactorySPI
* implementation from the specified Properties.
*
* @return The class name for the SCAClientFactorySPI implementation
* or <code>null</code> if not found.
*/
private static String
checkPropertiesForSPIClassName(Properties properties) {
if (properties == null) {
return null;
}
final String providerClassName =
properties.getProperty(SCA_CLIENT_FACTORY_PROVIDER_KEY);
if (providerClassName != null && providerClassName.length() > 0) {
return providerClassName;
}
return null;
}
/**
* Attempts to find the class name for the SCAClientFactorySPI
* implementation from the META-INF/services directory
*
* @return The class name for the SCAClientFactorySPI implementation or
* <code>null</code> if not found.
*/
private static String checkMETAINFServicesForSPIClassName(ClassLoader cl)
{
final URL url =
cl.getResource(SCA_CLIENT_FACTORY_PROVIDER_META_INF_SERVICE);
if (url == null) {
return null;
}
InputStream in = null;
try {
in = url.openStream();
BufferedReader reader = null;
try {
reader =
new BufferedReader(new InputStreamReader(in, "UTF-8"));
String line;
while ((line = readNextLine(reader)) != null) {
if (!line.startsWith("#") && line.length() > 0) {
return line;
}
}
return null;
} finally {
closeStream(reader);
}
} catch (IOException ex) {
throw new ServiceRuntimeException(
"Failed to discover SCAClientFactory provider", ex);
} finally {
closeStream(in);
}
}
/**
* Reads the next line from the reader and returns the trimmed version
* of that line
*
* @param reader The reader from which to read the next line
* @return The trimmed next line or <code>null</code> if the end of the
* stream has been reached
* @throws IOException I/O error occurred while reading from Reader
*/
private static String readNextLine(BufferedReader reader)
throws IOException {
String line = reader.readLine();
if (line != null) {
line = line.trim();
}
return line;
}
/**
* Loads the specified SCAClientFactory Implementation class.
*
* @param factoryImplClassName The name of the SCAClientFactory
* Implementation class to load
* @return The specified SCAClientFactory Implementation class
* @throws ServiceRuntimeException Failed to load the SCAClientFactory
* Implementation class
*/
private static Class<? extends SCAClientFactory>
loadProviderFactoryClass(String factoryImplClassName,
ClassLoader classLoader)
throws ServiceRuntimeException {
try {
final Class<?> providerClass =
classLoader.loadClass(factoryImplClassName);
final Class<? extends SCAClientFactory> providerFactoryClass =
providerClass.asSubclass(SCAClientFactory.class);
return providerFactoryClass;
} catch (ClassNotFoundException ex) {
throw new ServiceRuntimeException(
"Failed to load SCAClientFactory implementation class "
+ factoryImplClassName, ex);
} catch (ClassCastException ex) {
throw new ServiceRuntimeException(
"Loaded SCAClientFactory implementation class "
+ factoryImplClassName
+ " is not a subclass of "
+ SCAClientFactory.class.getName() , ex);
}
}
/**
* Instantiate an instance of the specified SCAClientFactorySPI
* Implementation class.
*
* @param factoryImplClass The SCAClientFactorySPI Implementation
* class to instantiate.
* @return An instance of the SCAClientFactorySPI Implementation class
* @throws ServiceRuntimeException Failed to instantiate the specified
* specified SCAClientFactorySPI Implementation class
*/
private static SCAClientFactory instantiateSCAClientFactoryClass(
Class<? extends SCAClientFactory> factoryImplClass,
URI domainURI)
throws NoSuchDomainException, ServiceRuntimeException {
try {
Constructor<? extends SCAClientFactory> URIConstructor =
factoryImplClass.getConstructor(domainURI.getClass());
SCAClientFactory provider =
URIConstructor.newInstance( domainURI );
return provider;
} catch (Throwable ex) {
throw new ServiceRuntimeException(
"Failed to instantiate SCAClientFactory implementation class "
+ factoryImplClass, ex);
}
}
/**
* Utility method for closing Closeable Object.
*
* @param closeable The Object to close.
*/
private static void closeStream(Closeable closeable) {
if (closeable != null) {
try{
closeable.close();
} catch (IOException ex) {
throw new ServiceRuntimeException("Failed to close stream",
ex);
}
}
}
}
B.1.4 SCAClient Classes and Interfaces - what does a vendor need to do?
The SCAClient classes and interfaces are designed so that vendors can provide their own implementation suited to the needs of their SCA runtime. This section describes the tasks that a vendor needs to consider in relation to the SCAClient classes and interfaces.
· Implement their SCAClientFactory implementation class
Vendors need to provide a subclass of SCAClientFactory that is capable of looking up Services in their SCA Runtime. Vendors need to subclass SCAClientFactory and implement the getService() method so that it creates reference proxies to services in SCA Domains handled by their SCA runtime(s).
· Configure the Vendor SCAClientFactory implementation class so that it gets used
Vendors have several options:
Option 1: Set System Property to point to the Vendor’s implementation
Vendors set the org.oasisopen.sca.client.SCAClientFactory System Property to point to their implementation class and use the reference implementation of SCAClientFactoryFinder
Option 2: Provide a META-INF/services file
Vendors provide a META-INF/services/org.oasisopen.sca.client.SCAClientFactory file that points to their implementation class and use the reference implementation of SCAClientFactoryFinder
Option 3: Inject a vendor implementation of the SCAClientFactoryFinder interface into SCAClientFactory
Vendors inject an instance of the vendor implementation of SCAClientFactoryFinder into the factoryFinder field of the SCAClientFactory abstract class. The reference implementation of SCAClientFactoryFinder is not used in this scenario. The vendor implementation of SCAClientFactoryFinder can find the vendor implementation(s) of SCAClientFactory by any means.
This section contains a list of conformance items for the SCA-J Common Annotations and APIs specification.
Conformance ID |
Description |
[JCA20001] |
|
[JCA20002] |
|
[JCA20003] |
|
[JCA20004] |
|
[JCA20005] |
|
[JCA20006] |
|
[JCA20007] |
|
[JCA20008] |
|
[JCA20009] |
|
[JCA20010] |
|
[JCA30001] |
The value of the @interface attribute MUST be the fully qualified name of the Java interface class |
[JCA30002] |
|
[JCA30003] |
|
[JCA30004] |
The interface.java element MUST conform to the schema defined in the sca-interface-java.xsd schema. |
[JCA30005] |
|
[JCA30006] |
@AllowsPassByReference, @ComponentName, @Constructor, @Context, @Destroy, @EagerInit, @Init, @Intent, @Property, @Qualifier, @Reference, @Scope, @Service. |
[JCA30007] |
@AllowsPassByReference, @Callback, @ComponentName, @Constructor, @Context, @Destroy, @EagerInit, @Init, @Intent, @Property, @Qualifier, @Reference, @Scope, @Service. |
[JCA30009] |
|
[JCA30010] |
|
[JCA40001] |
|
[JCA40002] |
|
[JCA40003] |
|
[JCA40004] |
|
[JCA40005] |
|
[JCA40006] |
|
[JCA40007] |
|
[JCA40008] |
|
[JCA40009] |
|
[JCA40010] |
|
[JCA40011] |
|
[JCA40012] |
|
[JCA40013]
|
|
[JCA40014] |
|
[JCA40015] |
|
[JCA40016] |
|
[JCA40017] |
|
[JCA40018] |
|
[JCA40019] |
|
[JCA40020] |
|
[JCA40021] |
|
[JCA40022] |
|
[JCA40023] |
|
[JCA40024] |
|
[JCA60001] |
|
[JCA60002] |
|
[JCA60003] |
The interface is annotated with the "asyncInvocation" intent. For each service operation in the WSDL, the Java interface contains an operation with – a name which is the JAX-WS mapping of the WSDL operation name, with the suffix "Async" added – a void return type – a set of input parameter(s) which match the JAX-WS mapping of the input parameter(s) of the WSDL operation plus an additional last parameter which is a ResponseDispatch object typed by the JAX-WS Response Bean mapping of the output parameter(s) of the WSDL operation, where ResponseDispatch is the type defined in the SCA Java Common Annotations and APIs specification. |
[JCA60004] |
|
[JCA60005] |
|
[JCA60006] |
Asynchronous service methods are characterized by: – void return type – a method name with the suffix "Async" – a last input parameter with a type of ResponseDispatch<X> – annotation with the asyncInvocation intent – possible annotation with the @AsyncFault annotation The mapping of each such method is as if the method had the return type "X", the method name without the suffix "Async" and all the input parameters except the last parameter of the type ResponseDispatch<X>, plus the list of exceptions contained in the @AsyncFault annotation. |
[JCA70001] |
|
[JCA70002] |
Intent annotations MUST NOT be applied to the following: · A method of a service implementation class, except for a setter method that is either annotated with @Reference or introspected as an SCA reference according to the rules in the appropriate Component Implementation specification · A service implementation class field that is not either annotated with @Reference or introspected as an SCA reference according to the rules in the appropriate Component Implementation specification · A service implementation class constructor parameter that is not annotated with @Reference |
[JCA70003] |
|
[JCA70004] |
|
[JCA70005] |
The @PolicySets annotation MUST NOT be applied to the following: · A method of a service implementation class, except for a setter method that is either annotated with @Reference or introspected as an SCA reference according to the rules in the appropriate Component Implementation specification · A service implementation class field that is not either annotated with @Reference or introspected as an SCA reference according to the rules in the appropriate Component Implementation specification · A service implementation class constructor parameter that is not annotated with @Reference |
[JCA70006] |
|
[JCA80001] |
|
[JCA80002] |
|
[JCA80003] |
|
[JCA80004] |
|
[JCA80005] |
|
[JCA80006] |
|
[JCA80007][JCA80007] |
|
[JCA80008] |
|
[JCA80009] |
|
[JCA80010] |
|
[JCA80011] |
|
[JCA80012] |
|
[JCA80013] |
|
[JCA80014] |
|
[JCA80015] |
|
[JCA80016] |
|
[JCA80017] |
|
The ComponentContext.getServices method MUST throw an IllegalArgumentException if the service reference with the name supplied in the referenceName does not have an interface compatible with the interface supplied in the businessInterface parameter.[JCA80018] |
|
[JCA80019] |
|
[JCA80020] |
|
[JCA80021] |
|
[JCA80022] |
|
[JCA80023] |
|
[JCA80024] |
|
[JCA80025] |
|
[JCA80026] |
|
[JCA80027] |
|
[JCA80028] |
|
[JCA80029] |
|
[JCA80030] |
|
[JCA80031] |
|
[JCA80032] |
|
[JCA80033] |
|
[JCA80034] |
|
[JCA80035] |
|
[JCA80036] |
|
[JCA80037] |
|
[JCA80038] |
|
[JCA80039] |
|
[JCA80040] |
|
[JCA80041] |
|
[JCA80042] |
|
[JCA80043] |
|
[JCA80044] |
|
[JCA80045] |
|
[JCA80046] |
|
[JCA80047] |
|
[JCA80048] |
|
[JCA80049] |
|
[JCA80050] |
|
[JCA80051] |
|
[JCA80052] |
|
[JCA80053] |
|
[JCA80054] |
|
The implementation of the SCAClientFactoryFinder.find method MUST return an object which is an implementation of the SCAClientFactory interface, for the SCA Domain represented by the doaminURI parameter, using the supplied properties and classloader. [JCA80055] |
|
[JCA80056] |
|
[JCA50057] |
|
[JCA80058] |
|
[JCA80059] |
|
[JCA80060] |
|
[JCA90001] |
|
[JCA90001] |
|
[JCA90003] |
|
[JCA90004] |
|
[JCA90005] |
|
[JCA90007] |
|
[JCA90008] |
|
[JCA90009] |
|
[JCA90011] |
The @Property annotation MUST NOT be used on a class field that is declared as final. |
[JCA90013] |
|
[JCA90014] |
|
[JCA90015] |
|
[JCA90016] |
The @Reference annotation MUST NOT be used on a class field that is declared as final. |
[JCA90018] |
|
[JCA90019] |
|
[JCA90020] |
|
[JCA90021] |
|
[JCA90022] |
An unwired reference with a multiplicity of 0..1 MUST be presented to the implementation code by the SCA runtime as null (either via injection or via API call). |
[JCA90023] |
An unwired reference with a multiplicity of 0..n MUST be presented to the implementation code by the SCA runtime as an empty array or empty collection (either via injection or via API call). |
[JCA90024] |
|
[JCA90025] |
In order for reinjection to occur, the following MUST be true: 1. The component MUST NOT be STATELESS scoped. 2. The reference MUST use either field-based injection or setter injection. References that are injected through constructor injection MUST NOT be changed. |
[JCA90026] |
|
[JCA90027] |
|
[JCA90028] |
|
[JCA90029] |
|
[JCA90030] |
|
[JCA90031] |
|
[JCA90032] |
|
[JCA90033] |
|
[JCA90034] |
|
[JCA90035] |
|
[JCA90036] |
|
[JCA90037] |
|
[JCA90038] |
|
[JCA90039] |
|
[JCA90040] |
|
[JCA90041] |
|
[JCA90042] |
|
[JCA90045] |
|
[JCA90046] |
|
[JCA90047] |
|
[JCA90050] |
|
[JCA90052] |
The @AllowsPassByReference annotation MUST only annotate the following locations: · a service implementation class · an individual method of a remotable service implementation · an individual reference which uses a remotable interface, where the reference is a field, a setter method, or a constructor parameter |
[JCA90053] |
|
[JCA90054] |
|
[JCA90055] |
|
[JCA90056] |
|
[JCA90057] |
|
[JCA90058] |
|
[JCA90060] |
|
[JCA90061] |
|
[JCA100001] |
|
[JCA100002] |
|
[JCA100003] |
|
[JCA100004] |
SCA runtimes MUST support the JAXB 2.1 mapping from XML Schema to Java and from Java to XML Schema. |
[JCA100005] |
|
[JCA100006] |
|
[JCA100007] |
|
[JCA100008] |
|
[JCA100009] |
SCA runtimes MUST support the use of the JAX-WS client asynchronous model. |
[JCA100010] |
|
[JCA100011] |
An SCA runtime MUST apply the JAX-WS annotations as described in Table 11‑1 and Table 11‑2 when introspecting a Java class or interface class. |
[JCA100012] |
|
[JCA100013] |
|
[JCA100014] |
|
[JCA100015] |
|
[JCA100016] |
|
[JCA100017] |
|
[JCA100018] |
An interface or class annotated with @WebServiceClient MUST NOT be used to define an SCA interface. |
[JCA100019] |
|
[JCA100020] |
|
[JCA100021] |
|
[JCA100022] |
SCA runtimes MUST support the JAX-WS 2.1 mappings from WSDL to Java and from Java to WSDL. |
[JCA100023] |
|
[JCA100024] |
|
[JCA100025] |
|
[JCA100026] |
|
The value of the name attribute of the @WebService annotation, if present, MUST be used to define the name of an SCA service when the @Service annotation is present without the names attribute and indicates that the Java interface or class annotated with the @WebService annotation defines an SCA service interface. [JCA100028] |
The following individuals have participated in the creation of this specification and are gratefully acknowledged:
Participants:
Participant Name |
Affiliation |
Bryan Aupperle |
IBM |
Ron Barack |
SAP AG* |
Mirza Begg |
Individual |
Michael Beisiegel |
IBM |
Henning Blohm |
SAP AG* |
David Booz |
IBM |
Martin Chapman |
Oracle Corporation |
Graham Charters |
IBM |
Shih-Chang Chen |
Oracle Corporation |
Chris Cheng |
Primeton Technologies, Inc. |
Vamsavardhana Reddy Chillakuru |
IBM |
Roberto Chinnici |
Sun Microsystems |
Pyounguk Cho |
Oracle Corporation |
Eric Clairambault |
IBM |
Mark Combellack |
Avaya, Inc. |
Jean-Sebastien Delfino |
IBM |
Derek Dougans |
Individual |
Mike Edwards |
IBM |
Ant Elder |
IBM |
Raymond Feng |
IBM |
Bo Ji |
Primeton Technologies, Inc. |
Uday Joshi |
Oracle Corporation |
Anish Karmarkar |
Oracle Corporation |
Khanderao Kand |
Oracle Corporation |
Michael Keith |
Oracle Corporation |
Rainer Kerth |
SAP AG* |
Meeraj Kunnumpurath |
Individual |
Simon Laws |
IBM |
Yang Lei |
IBM |
Mark Little |
Red Hat |
Ashok Malhotra |
Oracle Corporation |
Jim Marino |
Individual |
Jeff Mischkinsky |
Oracle Corporation |
Sriram Narasimhan |
TIBCO Software Inc. |
Simon Nash |
Individual |
Sanjay Patil |
SAP AG* |
Plamen Pavlov |
SAP AG* |
Peter Peshev |
SAP AG* |
Ramkumar Ramalingam |
IBM |
Luciano Resende |
IBM |
Michael Rowley |
Active Endpoints, Inc. |
Vladimir Savchenko |
SAP AG* |
Pradeep Simha |
TIBCO Software Inc. |
Raghav Srinivasan |
Oracle Corporation |
Scott Vorthmann |
TIBCO Software Inc. |
Feng Wang |
Primeton Technologies, Inc. |
Paul Yang |
Changfeng Open Standards Platform Software |
Revision |
Date |
Editor |
Changes Made |
1 |
2007-09-26 |
Anish Karmarkar |
Applied the OASIS template + related changes to the Submission |
2 |
2008-02-28 |
Anish Karmarkar |
Applied resolution of issues: 4, 11, and 26 |
3 |
2008-04-17 |
Mike Edwards |
Ed changes |
4 |
2008-05-27 |
Anish Karmarkar David Booz Mark Combellack |
Added InvalidServiceException in Section 7 Various editorial updates |
WD04 |
2008-08-15 |
Anish Karmarkar |
* Applied resolution of issue 9 (it was applied before, not sure by whom, but it was applied incorrectly) * Applied resolution of issue 12, 22, 23, 29, 31, 35, 36, 37, 44, 45 * Note that issue 33 was applied, but not noted, in a previous version * Replaced the osoa.org NS with the oasis-open.org NS |
WD05 |
2008-10-03 |
Anish Karmarkar |
* Fixed the resolution of issue 37 but re-adding the sentence: "However, the @... annotation must be used in order to inject a property onto a non-public field. -- in the @Property and @Reference section * resolution of issue 9 was applied incorrectly. Fixed that -- removed the requirement for throwing an exception on ComponentContext.getServiceReferences() when multiplicity of references > 1 * minor ed changes |
cd01-rev1 |
2008-12-11 |
Anish Karmarkar |
* Fixed reference style to [RFC2119] instead of [1]. * Applied resolutions of issues 20, 21, 41, 42, 43, 47, 48, 49. |
cd01-rev2 |
2008-12-12 |
Anish Karmarkar |
* Applied resolutions of issues 61, 71, 72, 73, 79, 81, 82, 84, 112 |
cd01-rev3 |
2008-12-16 |
David Booz |
* Applied resolution of issues 56, 75, 111 |
cd01-rev4 |
2009-01-18 |
Anish Karmarkar |
* Applied resolutions of issues 28, 52, 94, 96, 99, 101 |
cd02 |
2009-01-26 |
Mike Edwards |
Minor editorial cleanup. All changes accepted. All comments removed. |
cd02-rev1 |
2009-02-03 |
Mike Edwards |
Issues 25+95 Issue 120 |
cd02-rev2 |
2009-02-08 |
Mike Edwards |
Merge annotation definitions contained in section 10 into section 8 Move remaining parts of section 10 to section 7. Accept all changes. |
cd02-rev3 |
2009-03-16 |
Mike Edwards |
Issue 104 - RFC2119 work and formal marking of all normative statements - all sections - Completion of Appendix B (list of all normative statements) Accept all changes |
cd02-rev4 |
2009-03-20 |
Mike Edwards |
Editorially removed sentence about componentType side files in Section1 Editorially changed package name to org.oasisopen from org.osoa in lines 291, 292 Issue 6 - add Section 2.3, modify section 9.1 Issue 30 - Section 2.2.2 Issue 76 - Section 6.2.4 Issue 27 - Section 7.6.2, 7.6.2.1 Issue 77 - Section 1.2 Issue 102 - Section 9.21 Issue 123 - conersations removed Issue 65 - Added a new Section 4 ** Causes renumbering of later sections ** ** NB new numbering is used below ** Issue 119 - Added a new section 12 Issue 125 - Section 3.1 Issue 130 - (new number) Section 8.6.2.1 Issue 132 - Section 1 Issue 133 - Section 10.15, Section 10.17 Issue 134 - Section 10.3, Section 10.18 Issue 135 - Section 10.21 Issue 138 - Section 11 Issue 141 - Section 9.1 Issue 142 - Section 10.17.1 |
cd02-rev5 |
2009-04-20 |
Mike Edwards |
Issue 154 - Appendix A Issue 129 - Section 8.3.1.1 |
cd02-rev6 |
2009-04-28 |
Mike Edwards |
Issue 148 - Section 3 Issue 98 - Section 8 |
cd02-rev7 |
2009-04-30 |
Mike Edwards |
Editorial cleanup throughout the spec |
cd02-rev8 |
2009-05-01 |
Mike Edwards |
Further extensive editorial cleanup throughout the spec Issue 160 - Section 8.6.2 & 8.6.2.1 removed |
cd02-rev8a |
2009-05-03 |
Simon Nash |
Minor editorial cleanup |
cd03 |
2009-05-04 |
Anish Karmarkar |
Updated references and front page clean up |
cd03-rev1 |
2009-09-15 |
David Booz |
Applied Issues: 1,13,125,131,156,157,158,159,161,165,172,177 |
cd03-rev2 |
2010-01-19 |
David Booz |
Updated to current Assembly namespace Applied issues: 127,155,168,181,184,185,187,189,190,194 |
cd03-rev3 |
2010-02-01 |
Mike Edwards |
Applied issue 54. Editorial updates to code samples. |
cd03-rev4 |
2010-02-05 |
Bryan Aupperle, Dave Booz |
Editorial update for OASIS formatting |
CD04 |
2010-02-06 |
Dave Booz |
Editorial updates for Committee Draft 04 All changes accepted |
CD04-rev1 |
2010-07-13 |
Dave Booz |
Applied issues 199, 200 |
CD04-rev2 |
2010-10-19 |
Dave Booz |
Applied issues 201,212,213 |
CSD04-rev3 |
2010-11-05 |
Dave Booz |
Applied issue 216, ed. updates for CSD vote |