Software
Version: 0.1
The Apache Wink User Guide document
is a broad scope document that provides detailed information about the Apache Wink
0.1 design and implementation.
2..... Apache Wink Architecture
2.1. Wink Runtime Architecture Overview
3..... Registration and Configuration
3.1.1. Specifying the Simple Application File Location
3.5.1. Custom Properties File Definition
4.2. The “alt” Query Parameter
4.5. Generating Absolute or Relative Links
5.3.1. Entity Producing Methods
5.3.2. Entity Consuming Methods
5.8.1. Request Entity Matching
5.8.2. Response Entity Matching
6.3. Out-of-the-Box Implementations
7.1.1. @Workspace Annotation Example
8..... Resource Matching - Continued Search
8.1. Resource Matching Overview
9.5. Atom Publishing Protocol (APP)
9.6. Comma Separated Values (CSV)
10.1. Enabling the APP Service Document Auto Generation
10.2. Adding Resources to APP Service Document
10.3. APP Service Document HTML Styling
11.1.1. Spring Context Loading
11.1.2. Registering Resources and Providers
11.2. Custom Properties File Definition
11.3. Customizing Media-Type Mappings
11.4. Customizing Alternative Shortcuts
11.4.1. External Properties File
12.3. Resource Method Definition
12.4. Creating a Multistatus Response
12.4.1. Using WebDAVResponseBuilder
12.4.2. WebDAVResponseBuilder Example
13.3.1. System Request Handlers
13.4.1. System Response Handlers
13.4.2. User Response Handlers
14.1. This chapter contains the following sections
14.6. High Level Architecture Overview
14.7. Getting Started with the Wink Client
14.8.3. Apache Http Client Configuration
14.8.4. Custom Provider Configuration
14.9.2. Custom Handler Implementation
14.9.3. Input and Output Stream Adapters
14.9.4. Stream Adapters Example
Table 1: Deployment Configuration Customizable Methods
Table 2: Wink Customization Properties
Table 6: AtomFeedSyndFeedProvider
Table 7: AtomFeedJAXBElementProvider
Table 9: AtomEntrySyndEntryProvider
Table 10: AtomEntryJAXBElementProvider
Table 12: AppCategoriesProvider
Table 14: OpenSearchDescriptionProvider
Table 17: JsonSyndEntryProvider
Table 18: JsonSyndFeedProvider
Table 21: HtmlSyndEntryProvider
Table 23: CsvSerializerProvider
Table 24: CsvDeserializerProvider
Table 25: @Workspace Annotation Specification
Table 26: @Asset Annotation Specification
Table 27: @Scope Annotation Specification
Table 28: @Parent Annotation Specification
The purpose of this document is to provide detailed information about Wink and describe the additional features that the Wink runtime provides in addition to the JAX-RS Java API for REST Web Service specification.
In addition to the features description, this document also provides information regarding implementation specific issues.
This document provides the developer with a rudimentary understanding of the Wink implementation in order to highlight the underlying concepts and precepts that make up the framework to create a basis for understanding, cooperation and open development of Wink.
|
|
This User Guide is a Preliminary Draft This document a preliminary draft and is subject
to change in future a release. |
In order to understand the contents of this
document the reader is required to have read the JAX-RS v1.0 specification and
have a rudimentary understanding of the specification and the terminology used
to describe the feature set.
|
For more information on the JAX-RS functionality, refer to the JAX-RS specification document, available at the following location: http://jcp.org/aboutJava/communityprocess/final/jsr311/index.html |
Apache Wink 0.1 is a complete and TCK compliant implementation of the JAX-RS v1.0 specification.
The following chapter describes the basic concepts and building blocks of Wink and explains the high-level architecture of the Wink runtime.
2.1. Wink Runtime Architecture Overview
The Wink runtime is deployed on a JEE environment and is
configured by defining the RestServlet in the web.xml file of the
application. This servlet is the entry point of all the Http requests targeted
for web services, and passes the request and response instances to the Wink
engine for processing.
Figure 1: Request Processor Architecture
The above diagram illustrates the core components of the Wink runtime. The Wink engine is the RequestProcessor. It builds an instance of a MessageContext with all of the required information for the request and passes it through the engine handler chains. The handler chains are responsible for serving the request, invoking the required resource method and finally for generating a response.
In case of an error, the RequestProcessor invokes the Error chain with the generated exception for producing the appropriate response.
The Wink runtime maintains providers and resources in two registries, the Providers Registry and the Resource Registry utilizing them during request processing.
The RequestProcessor is the Wink engine that is initialized by the RestServlet and is populated with an instance of a DeploymentConfiguration.
When a request is passed to the handleRequest() method of the RequestProcessor, a new instance of a MessageContext is created.
The MessageContext contains all of the information that is required for the Wink runtime to handle the request. The RequestProcessor first runs the Request Handler Chain to invoke the resource method and then the Response Handler Chain to produce the response.
If an exception occurs during any stage of the request processing, the RequestProcessor invokes the Error Handler Chain for processing the exception.
The Wink runtime is initialized with an instance of a DeploymentConfiguration. The Deployment Configuration holds the runtime configuration, including the handler chains, registries and configuration properties.
The Deployment Configuration is initialized with an instance of a JAX-RS Application used for obtaining user resources and providers.
The Deployment Configuration is customized by extending the DeplymentConfiguration class, overriding specific methods and specifying the new class in the web.xml file of the application.
In order to specify a different Deployment Configuration class instead of the default Deployment Configuration, the value of the deploymentConfiguration init parameter must be set to be the fully qualified name of the customized configuration class.
|
<servlet> <servlet-name>restSdkService</servlet-name> <servlet-class> org.apache.wink.server.internal.servlet.RestServlet </servlet-class> <init-param> <param-name>deploymentConfiguration</param-name> <param-value>org.apache.example.MyDeploymentConfig</param-value>
</init-param> </servlet> |
The following table details the customizable methods of the DeploymentConfiguration class.
Deployment
Configuration
Table 1: Deployment
Configuration Customizable Methods
|
Method |
Description |
|
initAlternateShortcutMap |
Initializes the AlternateShortcutMap. Refer to section 3.8 |
|
initMediaTypeMapper |
Initializes the MediaTypeMapper. Refer to section 3.7 |
|
initRequestUserHandlers |
Return a list of User Handler instances to embed in the Request chain. Refer to section 13.3 |
|
initResponseUserHandlers |
Return a list of User Handler instances to embed in the Response chain. Refer to section 13.4 |
|
initErrorUserHandlers |
Return a list of User Handler instances to embed in the Error chain. Refer to section 13.5 |
The handler chain pattern is used by the Wink runtime for implementing the core functionalities.
There are three handler chains utilized by the Wink runtime:
·
RequestHandlersChain
·
ResponseHandlersChain
·
ErrorHandlersChain
|
Refer to chapter 13 for more information on Handler Chains. |
The Wink runtime utilizes two registries for maintaining the JAX-RS resources and providers. Both registries maintain their elements in a sorted state according to the JAX-RS specification for increasing performance during request processing. In addition to the JAX-RS specification sorting, Wink supports the prioritization of resources and providers.
|
Refer to chapter 3, section 3.4 for more information on Priorities. |
Figure 2: Resource Registry
The resources registry maintains all of the root resources in the form of Resource Records.
A Resource Record holds the following:
· URI Template Processor – represents a URI template associated with a resource. Used during the resource matching process.
· Resource Metadata – holds the resource metadata collected from the resource annotations.
· Sub-Resource Records – records of all the sub-resources (methods and locators) collected from the sub-resource annotations.
· Resource Factory – a factory that retrieves an instance of the resource in accordance to the creation method defined for the resource. Possible creation methods include:
— singleton
— prototype
— spring configuration
— user customizable
The providers registry maintains of all of the system and user providers and manages them in an efficient way.
3. Registration and Configuration
Wink provides several methods for registering resources and providers. This chapter describes registration methods and Wink configuration options.
Wink provides the SimpleWinkApplication class in order to support the loading of resources and providers through a simple text file that contains a list of fully qualified class names of the resource and provider classes.
Each line contains a single fully qualified class name that is
either a resource or a provider. Empty lines and lines that begin with a number
sign (#) are permitted and ignored.
|
com.example.MyXmlProvider com.example.MyJSONProvider # Resources com.example.FooResource com.example.BarResource |
3.1.1. Specifying the Simple Application
File Location
The path to a simple application file is configured via the applicationConfigLocation
init-param in the web.xml file. It is possible to specify multiple files by
separating them with a semicolon.
|
<servlet-name>restSdkService</servlet-name> <servlet-class> org.apache.wink.server.internal.servlet.RestServlet </servlet-class> <init-param> <param-name>applicationConfigLocation</param-name> <param-value>/WEB-INF/providers;/WEB-INF/resources</param-value> </init-param> </servlet> |
Wink extends the javax.ws.rs.core.Application
class with the org.apache.wink.common.WinkApplication
class in order to provide the Dynamic Resources and the Priorities
functionality.
|
Refer to chapter 3, sections 3.3
and 3.4
for more information on Dynamic Resources and Priorities. |
An application may provide an instance of WinkApplication to the Wink runtime as
specified by the JAX-RS specification.
Dynamic Resources enable the binding of a Resource class to a URI path during runtime instead of by using the @Path annotation. A dynamic resource must implement the org.apache.wink.server.DynamicResource interface and must not be annotated with the @Path annotation.
A Dynamic Resource is
useful for situations where a resource class must be bound to multiple paths, for
example, a sorting resource:
|
public class SortingResource<E extends Comparable<? super E>> { private
List<E> list; @POST public
void sort() { Collections.sort(list); } public
void setList(List<E> list) { this.list = list; } public
List<E> getList() { return
list; } } |
In this example, the SortingResource class can sort any list. If the
application manages a library of books and exposes the following resource paths,
then the SortingResource class can be used for the implementation of all these
resource paths, assuming that it could be bound to more than one path.
|
/sort-books /sort-authors /sort-titles |
A dynamic resource is also useful for situations where the resource path is unknown
during development, and is only known during the application startup.
A Dynamic Resource is a resource class that implements the org.apache.wink.server.DynamicResource interface or extends the org.apache.wink.server.AbstractDynamicResource convenience class.
A Dynamic Resource is not registered in Wink through the Application#getClasses() method or the Application#getSignletons() method, since the same class can be used for multiple resources.
In order to register Dynamic
Resources in the system, the WinkApplication#getInstances()method must be used.
|
Refer to chapter 3, section 3.2 for more information about Wink Application. |
The scope of a Dynamic Resource is limited to singleton as it is initialized prior to its registration, and the system does not have enough information to create it in runtime. This limitation is irrelevant when working with Spring.
|
Refer to chapter 11 for more information about Spring Integration. |
Although JAX-RS defines the algorithm for searching for resources and providers, Wink extends this algorithm by providing the ability to specify priorities on them. This is achieved by enabling the registration of multiple Application instances with different priorities, rendering the order of their registration irrelevant as long as they have different priorities.
In order to register a prioritized Application, it is necessary to register an instance of a WinkApplication class.
Priority values range between 0 and 1. In the event that the priority was not specified, a default priority of 0.5 is used.
Priorities on resources are useful in situations where an application registers core resources bound to paths, and allows extensions to register resources on the same paths in order to override the core resources.
The Wink runtime first sorts the resources based on their priority and then based on the JAX-RS specification, thus if two resources have the same path, the one with higher priority is invoked.
JAX-RS requires that application-provided providers be used in preference to implementation pre-packaged providers. Wink extends this requirement by allowing applications to specify a priority for providers.
The Wink runtime initially sorts the matching providers according to the JAX-RS specification, and uses the priority as the last sorting key for providers of equal standing.
If two providers have the same priority, the order in which they are registered determines their priority such that the latest addition receives the highest priority.
In order to meet the JAX-RS requirements, the pre-packages providers are registered using a priority of 0.1.
Wink provides a properties file in order to enable simple customizations. By default, Wink predefines default values for all possible properties.
Customization
Properties
Table 2: Wink Customization Properties
|
Property Name |
Description |
Default Value |
Ref |
|
wink.http.uri |
URI that is used by the Link Builders in case of HTTP |
Use the URI from the request. |
chapter 4 |
|
wink.https.uri |
URI used by the Link Builders in case of HTTPS. |
Use the URI from the request. |
chapter 4 |
|
wink.context.uri |
Context path used by the Link Builders. |
Use the context path from the request. |
chapter 4 |
|
wink.defaultUrisRelative |
Indicates if URIs generated by the Link Builders are
absolute or relative. Valid values: true or false |
true – links will be relative. |
chapter 4 |
|
wink.addAltParam |
Indicates if the “alt” query parameter should be added to URIs
generated by the Link Builders. Valid values are: true, false. |
true – add the alt query parameter |
chapter 4 |
|
wink.searchPolicyContinuedSearch |
Indicates if continues search is enabled. Valid values:
true, false |
false – continued search is disabled. |
chapter 8 |
|
wink.rootResource |
Indicates if a root resource with Service Document generation capabilities should be added. Valid values are: none, atom, atom+html |
atom+html –atom and HTML Service Document generation capabilities |
chapter 10 |
|
wink.serviceDocumentCssPath |
Defines path to a css file that is used in the HTML
Service Document generation. Relevant only if HTML Service Document is
defined. |
No css file defined. |
chapter 10 |
3.5.1. Custom Properties File
Definition
In order to provide a custom properties file, the application
should define the propertiesLocation init-param in the Wink Servlet
definition.
|
<servlet-name>restSdkService</servlet-name> <servlet-class> org.apache.wink.server.internal.servlet.RestServlet </servlet-class> <init-param> <param-name>propertiesLocation</param-name> <param-value>/WEB-INF/configuration.properties</param-value> </init-param> <init-param> <param-name>applicationConfigLocation</param-name> <param-value>/WEB-INF/application</param-value> </init-param> <load-on-startup>0</load-on-startup> </servlet> |
Wink provides several APIs for Runtime Registration. The APIs appear in the org.apache.wink.server.utils.RegistrationUtils class.
The most important method is the one that registers an instance
of the javax.ws.rs.core.Application class
|
static void registerApplication(Application
application, ServletContext servletContext) |
Note
|
|
Double
Registration Registration is ignored and a warning is printed to the log if the same instance is registered more than once. |
It is sometimes necessary to override the Content-Type response header based on the client user agent. For example, the Firefox browser cannot handle the application/atom+xml media type for Atom content, unless it is defined as a text/xml.
Wink provides a set of predefined Media-Type mappings for use in such cases by supplying the MediaTypeMapper class. Applications may extend or override the MediaTypeMapper class to define additional mappings.
Mappings
Table 3: Predefined Mappings
|
User Agent |
Content-Type |
Map To |
|
Mozilla/ |
application/atom+xml |
text/xml |
|
Mozilla/ |
application/atomsvc+xml |
text/xml |
|
Mozilla/ |
application/opensearchdescription+xml |
text/xml |
In order to customize these mappings the application should
create an instance of a org.apache.wink.server.internal.MediaTypeMapper
class and set it on the DeploymentConfiguration instance.
|
Refer to chapter 2, section 2.3.1 for more information on Customizing the Default Deployment Configuration. |
Clients specify the requested media type by setting the Http Accept header. Wink provides an alternate method for specifying the requested media type via use of the “alt” request parameter. This functionality is useful for situations where the client has little affect on the Accept header, for example when requesting a resource using a browser.
A request to “/entry?alt=application/xml” specifies that the requested response media type is application/xml.
Wink provides a shortcut mechanism for specifying the media type of the alt query parameter and provides a predefined set of shortcuts for common media types.
Shortcuts
Table 4: Predefined Shortcuts
|
Shortcut |
Media
type |
|
json |
text/javascript |
|
atom |
application/atom+xml |
|
xml |
application/xml |
|
text |
text/plain |
|
html |
text/html |
|
csv |
text/csv |
|
opensearch |
application/opensearchdescription+xml |
The shortcuts table can be customized by overriding the DeploymentConfiguration
class.
|
Refer to chapter 2, section 2.3 for more information about Deployment Configuration. |
The LinkBuilders interface enables access to two types of links builders, the SystemLinksBuilder and the SingleLinkBuilder. An instance of LinkBuilders is injected into a class field or method parameter using the @Context annotation. Upon creation, the LinkBuilders automatically detects if the target method being invoked is a resource method or a sub-resource method. The “resource” and “subResource” properties of the builder are initialized according to the invoked method type. The link builder interfaces reside in the org.apache.wink.server.utils package.
The JAX-RS specification defines the UriBuilder interface used to construct a URI from a template, but does not specify any mechanism that can automatically generate all resource links.
Wink provides the SystemLinksBuilder for automatic generation of all the alternate links to a resource, one link per every supported media type. For example, this is useful for an application that produces Atom feeds to include in the feed all the alternate representations of the resource.
Wink provides a mechanism for defining if the generated links should be absolute links or relative to a base URI. For example, links embedded in an Atom feed should be as short as possible in order to optimize the payload size.
4.2. The “alt” Query Parameter
Wink supports the special query parameter “alt” that is used to override the value of the request Accept header. When the link builders generate a link that specifies the “type” attribute, then the “alt” query parameter is automatically added to the generated link. This is controlled by setting the wink.addAltParam key of the configuration properties file or by calling the LinksBuilder#addAltParam() method.
|
Refer to chapter 3, section 3.5 for more information on Configuration Properties. |
The SystemLinksBuilder
interface enables the generation of all, or a subset of, the system links to a
resource or its sub-resources. The links are generated as absolute URIs or as
relative to the base URI according to the SystemLinksBuilder state, request
information or the application configuration.
|
@Path(“defects/{id}”) public class DefectResource { @GET
@Produces(“application/atom+xml”) public SyndEntry
getAtom() { ... } @GET
@Produces(“application/json”) public JSONObject
getJson() { ... } @GET @Produces(“application/xml”) public Defect
getXml(@Context LinkBuilders linkBuilders) { SystemLinksBuilder builder =
linkBuilders.systemLinksBuilder();
List<SyndLink> systemLinks = builder.build(null); ... } } |
The DefectResource#getXml() method is invoked when a GET request for application/xml is made to /defects/3. The Wink runtime injects an instance of LinkBuilders to the linkBuilder parameter and a new instance of a SystemLinksBuilder is created by invoking the systemLinksBuilder() method.
The call to the build() method of the SystemLinksBuilder
generates three alternate links to the DefectResource and the self link:
·
<link rel=”self”
href=”/defects/3”/>
·
<link rel=”alternate”
type=”application/json” href=”/defects/3”/>
·
<link rel=”alternate”
type=”application/xml” href=”/defects/3”/>
·
<link rel=”alternate”
type=”application/xtom+xml” href=”/defects/3”/>
The SingleLinkBuilder interface enables the generation of
a single link referencing a resource or a sub-resource, allowing the
specification of the ‘rel’ and ‘type’ attributes of the generated
link. The links
are generated as absolute URIs or as relative to the base URI according to the SingleLinkBuilder
state, request information or the application configuration.
4.5. Generating Absolute or Relative Links
The link builders generate
absolute or relative links based on the following algorithm:
1 Use the value that was passed to the relativize() method of the builder.
2 If the relativize() method was not called, then use the value of the “relative-urls” query parameter from the request. The value must be either true or false.
3 If the request does not contain the “relative-urls” query
parameter, then use the value of the wink.defaultUrisRelative key set in
the application configuration properties file. The value must be either true or
false.
|
Refer to chapter 3, section 3.5 for more information on the Configuration Properties file. |
4 If the configuration key does not exist, then use true.
An Asset is a special entity that is returned by a resource method or is injected into a resource method as an entity parameter. The asset is used for retrieving the actual request entity or response entity.
The purpose of an asset is to act as a container of an entity data model while providing the transformation methods of the data model into data models of other representations.
Asset classes are POJOs, annotated with the @Asset
annotation, that have any number of entity methods.
When an asset instance is returned from a resource method or is
set as the entity on a Response instance, it is used by the Wink runtime to
retrieve the actual response entity by invoking the appropriate entity-producing
method of the asset.
|
Refer to chapter 5, section 5.3.1
for more information on Entity-Producing Methods. |
When an asset is the entity parameter of a resource method, it is used by the Wink
runtime to set the actual request entity by invoking the appropriate entity-consuming
method of the asset.
|
Refer to chapter 5, section 5.3.2 for more information on Entity-Consuming Methods. |
A typical application exposes each resource in a number of representations. Some form of data model usually backs the resource, and the application business logic relies on the manipulation of that data model.
The application will most likely expose resource methods allowing the consumption of the data model in more than one representation (for example Atom and XML) and the production of the data model in other representation (for example Atom, XML and JSON).
According to the JAX-RS specification, the optimal method for implementing a resource is one that consumes and produces an application data model and makes use of a different provider for every media type.
For example, if a resource implements methods that consume and produce a ”Defect” bean, then a provider must be implemented for each representation of the “Defect” (Atom, XML and JSON). However, there are times that the transformation of the application data model into a representation requires information that may only be available to the resource but is unavailable to a provider (for example, a connection to the Database).
There are several solutions for dealing with the problem of a provider not having sufficient information to perform application data transformations. The following is a description of two possible solutions:
·
Passing the information as
members on the resource and accessing the resource from the provider via the
UriInfo context.
This solution is only plausible if the resource scope is “per request” and does
not work if the resource is a singleton.
·
Passing the information
from the resource to the provider via the attributes of the HttpServletRequest.
This solution is only plausible when the application is deployed in a JEE
container and is not the optimal solution.
As a result, the selection of the actual provider from the set of potential
providers is non-deterministic, because the selection between them is
undefined.
Note
|
|
Performance Degradation An additional side effect of provider inflation
is performance degradation. |
The use of an asset solves the problem of passing information between a resource and a provider and reduces the amount of registered providers in the system.
Resource methods can use an asset as a response entity and as a request entity. The Wink runtime applies different lifecycles for each case.
The lifecycle of an asset as a response entity is as follows:
· The application creates and returns the asset from the resource method.
· The appropriate entity-producing method is invoked by the Wink runtime to retrieve the actual response entity.
· The appropriate message body writer as obtained from the Providers#getMessageBodyWriter() method serializes the entity obtained at the previous step.
· The asset is made available for garbage collection.
The lifecycle of an asset as a request entity is as follows:
·
An asset class is
instantiated by the Wink runtime by invoking the asset default constructor. Note
that this implies that the asset class must have a public default constructor.
·
The appropriate message
body reader as obtained from the Providers#getMessageBodyReader() method is
invoked by the Wink runtime to read the request entity.
·
The appropriate
entity-consuming method is invoked on the asset to populate the asset
with the request entity.
·
The asset is injected into the resource method as the entity parameter.
·
The asset is made available
for garbage collection after returning from the resource method.
Asset Entity methods are the public methods of an asset annotated with either @Consumes or @Produces annotation. Annotating a method with both @Consumes and @Produces annotations is not supported and may result in unexpected behavior.
5.3.1. Entity Producing Methods
An Entity Producing Method is a public asset method annotated with the @Produces annotation, designating it to produce the actual response entity. Such methods produce an entity only for the media types declared in the @Produces annotation. Note that under this definition, wildcard (“*/*”) is allowed.
The Wink runtime will not invoke an entity-producing method whose effective value of @Produces does not match the request Accept header
5.3.2. Entity Consuming Methods
An Entity Consuming Method is a public asset method annotated with the @Consumes annotation, designating it to consume the actual request entity for populating the asset. Such methods consume an entity only for the media types declared in the @Consumes annotation. Note that under this definition, wildcard (“*/*”) is allowed.
The Wink runtime will not invoke an entity-consuming method whose effective value of @Consumes does not match the request Content-Type header.
Asset Entity methods support the same parameter types as JAX-RS
specifies for a resource method.
Entity methods may return any
type that is permissible to return from a resource method.
Exceptions thrown from an
entity method are treated as exceptions thrown from a resource method.
The @Produces and @Consumes annotations
are not inherited when an asset sub-class overrides an asset entity method.
Asset sub-classes must re-declare the @Produces and @Consumes annotations for
the overriding method to be an entity method.
Asset classes are handled by
the AssetProvider which is a JAX-RS provider that is capable of
consuming and producing all media types.
|
Refer
to chapter 3, section 6.3.5
for more information on Asset Providers. |
5.8.1. Request Entity Matching
The following points describe
the process of selecting the asset entity-consuming method to
handle the request entity. This process occurs during the invocation of the
AssetProvider#isReadable() method.
·
Collect all the entity-consuming methods of the asset. These are the public
methods annotated with @Consumes annotation.
·
Sort the collected entity-consuming methods in descending order, where methods
with more specific media types precede methods with less specific media types,
following the rule n/m > n/* > */*.
·
Select the first method that supports the media type of the request entity
body as provided to the AssetProvider#isReadable()
method, and
return true.
·
If no entity-consuming method supports the media type of the request entity
body, return false. The Wink runtime continues searching for a different provider to handle
the asset as a regular entity.
5.8.2. Response Entity Matching
The following points describe the process of selecting an
entity-producing method to produce the actual response entity. The following
process occurs during the invocation of the AssetProvider#isWriteable()method.
·
Collect all the entity-producing methods of the asset. These are the public
methods annotated with @Produces annotation.
·
Sort the collected entity-producing methods in descending order, where methods
with more specific media types precede methods with less specific media types,
following the rule n/m > n/* > */*.
·
Select the first method that supports the media type of the response entity
body as provided to the AssetProvider#isWriteable()method and return true.
·
If no entity-producing method supports the media type of the response
entity body, return false. The Wink runtime continues searching for a
different provider to handle the asset as a regular entity.
The following example illustrates the use of an asset. The “Defect” bean is a JAXB annotated class.
The DefectAsset class is the asset backed by an instance of a
“Defect” bean. The DefectResource class is a resource that is anchored to the
URI path “defects/{id}” within the Wink runtime.
DefectAsset Class
|
@Asset public class DefectAsset { public Defect defect; public DefectAsset(Defect defect) { this.defect = defect;
} @Produces("application/xml") public Defect getDefect() { return this.defect;
} @Produces("text/html") public String getDefectAsHtml() { String html = ...; return html;
} @Produces("application/atom+xml") public AtomEntry getDefectAsAtom() { AtomEntry entry = ...; return entry;
} @Consumes("application/xml") public void setDefect(Defect defect) { this.defect = defect;
} } |
DefectResource Class
|
public class DefectResource { @GET public DefectAsset getDefect(@PathParam("id") String id) { return new DefectAsset(defects.get(id)); } @PUT public DefectAsset updateDefect(DefectAsset defectAsset, @PathParam("id") String id) { defects.put(id, defectAsset.getDefect()); return defectAsset; } } |
Scenario Explanation 1
· A client issues an HTTP GET request with a URI=”/defects/1” and Accept Header= “application/xml”
· The Wink runtime analyzes the request and invokes the DefectResource#getDefect() resource method.
· The DefectResource#getDefect() resource method creates an instance of DefectAsset and populates it with defect “1” data.
· The DefectResource#getDefect() resource method returns the DefectAsset instance back to Wink runtime.
· The Wink runtime analyzes the asset and invokes the DefectAsset#getDefect() entity-producing method to obtain the reference to the “Defect” bean.
· The “Defect” bean is serialized by Wink runtime as an XML using the appropriate provider.
·
A Client issues an HTTP GET
request with a URI=”/defects/1” and Accept Header= “text/html”
·
The Wink runtime analyzes
the request and invokes the DefectResource#getDefect() resource method
· The DefectResource#getDefect() resource method creates an instance of DefectAsset and populates it with defect “1” data.
· The DefectResource#getDefect() method returns the populated asset back to the Wink runtime.
· The Wink runtime analyzes the asset and invokes the DefectAsset#getDefectAsHtml() entity-producing method in order to obtain the reference to the “Defect” bean.
· The “Defect” is serialized by Wink runtime as an HTML using the appropriate provider.
·
A Client issues an HTTP PUT
request with a URI=”/defects/1” and Accept Header= “text/html”
· The Wink runtime analyzes the request and invokes the DefectResource#updateDefect() method with an instance of DefectAsset populated with the request entity.
— A DefectAsset is instantiated by the Wink runtime
— The DefectAsset#setDefect() entity-consuming method is invoked in order to populate the DefectAsset with the defect data.
In addition to JAX-RS standard
providers (section 4.2 of the JAX-RS specification), Wink provides a set of complementary
providers. The purpose of these providers is to provide mapping services
between various representations (for example Atom, APP, OpenSearch, CSV, JSON
and HTML) and their associated Java data models.
The Wink providers are pre-registered and delivered with the Wink runtime along with the JAX-RS standard providers.
The JAX-RS specification
defines that by default, a singleton instance of each provider class is
instantiated for each JAX-RS application. Wink fully supports this requirement
and in addition provides a “Prototype” lifecycle, which is an instance
per-request lifecycle.
Prototype means that a new
instance of a provider class is instantiated for each request. The @Scope
annotation (section0) is used on a provider class to specify its
lifecycle. The lifecycle of a provider that does not specify the @Scope annotation
defaults to the singleton lifecycle.
The following example shows
how to define a provider with a prototype lifecycle.
|
@Scope(ScopeType.PROTOTYPE) @Provider public class MyProvider implements
MessageBodyReader<String>{
... } |
The following example shows
how to define a provider with a singleton lifecycle.
|
@Scope(ScopeType.SINGELTON) @Provider public class MyProvider implements
MessageBodyReader<String>{
... } |
The following example shows
that when the @Scope annotation is not used, the provider will be a singleton,
as per the JAX-RS specification.
|
@Provider public class MyProvider implements
MessageBodyReader<String>{
... } |
Wink provides a method for
setting a priority for a provider.
|
Refer to chapter 3, section 3.4.2 for more information on Provider Priorities. |
6.3. Out-of-the-Box Implementations
The following section describes the Wink providers that are an addition to the JAX-RS requirements.
Wink provides a set of entity providers that are capable of
mapping Atom Feed and Atom Entry XML documents to and from an Atom data model.
|
Refer to chapter 9 for more information on Data Models. |
The following tables list these providers.
AtomFeedProvider
Table 5: AtomFeedProvider
|
|
Supported |
Media Types |
Entity |
|
Read |
Yes |
application/atom+xml |
AtomFeed |
|
Write |
Yes |
application/atom+xml |
AtomFeedSyndFeedProvider
Table 6: AtomFeedSyndFeedProvider
|
|
Supported |
Media Types |
Entity |
|
Read |
Yes |
application/atom+xml |
SyndFeed |
|
Write |
Yes |
application/atom+xml |
AtomFeedJAXBElementProvider
Table 7: AtomFeedJAXBElementProvider
|
|
Supported |
Media Types |
Entity |
|
Read |
Yes |
application/atom+xml |
JAXBElement<AtomFeed> |
|
Write |
Yes |
application/atom+xml |
AtomEntryProvider
Table 8: AtomEntryProvider
|
|
Supported |
Media Types |
Entity |
|
Read |
Yes |
application/atom+xml |
AtomEntry |
|
Write |
Yes |
application/atom+xml |
AtomEntrySyndEntryProvider
Table 9: AtomEntrySyndEntryProvider
|
|
Supported |
Media Types |
Entity |
|
Read |
Yes |
application/atom+xml |
SyndEntry |
|
Write |
Yes |
application/atom+xml |
AtomEntryJAXBElementProvider
Table 10: AtomEntryJAXBElementProvider
|
|
Supported |
Media Types |
Entity |
|
Read |
Yes |
application/atom+xml |
JAXBElement<AtomEntry> |
|
Write |
Yes |
application/atom+xml |
Wink provides a set of providers that are capable of mapping APP Service Document and APP Categories data models to their xml representations. The following tables list these providers.
|
Refer to chapter 9, section 9.5 in chapter 9 for more information on the Atom Publishing Protocol. |
AppServiceProvider
Table 11: AppServiceProvider
|
|
Supported |
Media Types |
Entity |
|
Read |
No |
N/A |
N/A |
|
Write |
Yes |
application/atomsvc+xml |
AppService |
AppCategoriesProvider
Table 12: AppCategoriesProvider
|
|
Supported |
Media Types |
Entity |
|
Read |
No |
N/A |
N/A AppCategories |
|
Write |
Yes |
application/atomcat+xml |
Table 13: CategoriesProvider
|
|
Supported |
Media Types |
Entity |
|
Read |
No |
N/A |
N/A |
|
Write |
Yes |
application/atomcat+xml |
Categories |
Wink provides a single provider that is capable of serializing the OpenSearch data model.
|
Refer to the xml representations chapter 9, section 9.7 for more information on OpenSearch. |
Table 14: OpenSearchDescriptionProvider
|
|
Supported |
Media Types |
Entity |
|
Read |
No |
N/A |
N/A |
|
Write |
Yes |
application/opensearchdescription+xml |
OpenSearchDescription |
Wink provides a set providers that are capable of serializing a number of data models (JSONObject, JAXBElement, SyndEntry, SyndFeed) into JSON representations. The following tables list these providers.
JsonProvider
Table 15: JsonProvider
|
|
Supported |
Media Types |
Entity |
|
Read |
No |
N/A |
N/A |
|
Write |
Yes |
application/json , application/javascript |
JSONObject |
JsonJAXBProvider
Table 16: JsonJAXBProvider
|
|
Supported |
Media Types |
Entity |
|
Read |
No |
N/A |
N/A |
|
Write |
Yes |
application/json , application/javascript |
JAXB object, JAXBElement<?> |
JsonSyndEntryProvider
Table 17: JsonSyndEntryProvider
|
|
Supported |
Media Types |
Entity |
|
Read |
No |
N/A |
N/A |
|
Write |
Yes |
application/json , application/javascript |
SyndEntry |
Table 18: JsonSyndFeedProvider
|
|
Supported |
Media Types |
Entity |
|
Read |
No |
N/A |
N/A |
|
Write |
Yes |
application/json , application/javascript |
SyndFeed |
Wink provides a special provider that is responsible for reading and writing Asset objects.
|
Refer to chapter 5 for more information on Assets. |
AssetProvider
Table 19: AssetProvider
|
|
Supported |
Media Types |
Entity |
|
Read |
Yes |
*/* |
POJOs annotated with @Asset annotation. |
|
Write |
Yes |
*/* |
POJOs annotated with @Asset annotation. |
Wink provides a set of providers that are capable of serializing a number of data models (SyndEntry, SyndFeed and HtmlDescriptor) as HTML. The following tables list these providers.
HtmlProvider
Table 20: HtmlProvider
|
|
Supported |
Media Types |
Entity |
|
Read |
NO |
N/A |
N/A |
|
Write |
Yes |
text/html |
HtmlDescriptor |
HtmlSyndEntryProvider
Table 21: HtmlSyndEntryProvider
|
|
Supported |
Media Types |
Entity |
|
Read |
NO |
N/A |
N/A |
|
Write |
Yes |
text/html |
SyndEntry |
HtmlSyndFeedProvid
Table 22: HtmlSyndFeedProvid
|
|
Supported |
Media Types |
Entity |
|
Read |
NO |
N/A |
N/A |
|
Write |
Yes |
text/html |
SyndFeed |
Wink supports the serializing and de-serializing of data as a CSV.
|
Refer to chapter 9, section 9.6 for more information on Comma Separated Values. |
The following tables list the providers that provide this
functionality.
CsvSerializerProvider
Table 23: CsvSerializerProvider
|
|
Supported |
Media Types |
Entity |
|
Read |
NO |
N/A |
N/A |
|
Write |
Yes |
text/csv |
CsvSerializer |
CsvDeserializerProvider
Table 24: CsvDeserializerProvider
|
|
Supported |
Media Types |
Entity |
|
Read |
Yes |
text/csv |
CsvDeserializer |
|
Write |
NO |
N/A |
N/A |
Wink provides several annotations in addition to those defined by the JAX-RS specification. The following section describes these annotations in detail.
7.1. @Workspace Annotation
The purpose of the @Workspace annotation is to associate a “Collection Resource” with a workspace element and collection elements in an APP Service Document.
|
Refer to chapter 10 for more information on APP Service Document. |
The workspaceTitle annotation parameter specifies the title of the workspace and the collectionTitle annotation parameter specifies the title of the collection.
Annotation
Specification
Table 25: @Workspace Annotation Specification
|
Value |
Description |
|
|
Mandatory |
No |
|
|
Target |
Resource class |
|
|
Parameters |
Name |
Type |
|
workspaceTitle |
String |
|
|
collectionTitle |
String |
|
|
Example |
@Workspace(workspaceTitle = "Title", collectionTitle = "Collection") |
|
7.1.1. @Workspace Annotation Example
The following example demonstrates the use of @Workspace annotation on two resources in order to have the auto-generated APP service document contain the information about them.
Given the following collection Resources definitions, ResourceA and ResourceB, the result is displayed in the “Auto Generated APP Service Document” table that follows.
ResourceA Definition
|
@Workspace(workspaceTitle
= "Services", collectionTitle = "Service1") @Path("services/service1") public class ResourceA { @POST @Produces("text/plain")
@Consumes({"application/atom+xml",
"application/xml"})
public String getText() {return "hey
there1";} } |
ResourceB Definition
|
@Workspace(workspaceTitle
= "Services", collectionTitle = "Service2") @Path("services/service2") public class ResourceB { @POST @Produces("text/plain")
@Consumes({"application/atom+xml",
"application/xml"})
public String getText() {return "hey
there2";} } |
The auto-generated APP Service Document is as follows:
Auto Generated APP Service Document
|
<service xmlns:atom=http://www.w3.org/2005/Atom
xmlns="http://www.w3.org/2007/app">
<workspace>
<atom:title>Services</atom:title> <collection href="services/service1"> <atom:title>Service1</atom:title> <accept>application/xml</accept> <accept>application/atom+xml</accept>
</collection>
<collection href="services/service2"> <atom:title>Service2</atom:title> <accept>application/xml</accept> <accept>application/atom+xml</accept>
</collection>
</workspace> </service> |
The @Asset annotation is a marker annotation used by the Wink
runtime in order to identify an entity as an Asset.
|
Refer to chapter 5 for more information on Assets. |
Annotation
Specification
Table 26: @Asset Annotation Specification
|
Value |
Description |
|
Mandatory |
No |
|
Target |
Resource class |
|
Parameters |
None |
|
Example |
@Asset |
7.3. @Scope Annotation
The JAX-RS specification defines the default lifecycle behavior for resources and providers, and the option for controlling the lifecycle through the javax.ws.rs.core.Application class.
Wink provides the @Scope annotation to specify the lifecycle of a provider or resource.
Annotation Specification
Table 27: @Scope Annotation Specification
|
Value |
Description |
|
|
Mandatory |
No |
|
|
Target |
Provider class or Resource class |
|
|
Parameters |
Name |
Type |
|
value |
ScopeType
enum |
|
|
Example |
@Scope(ScopeType.PROTOTYPE) |
|
The following example illustrates how to define a resource with a singleton lifecycle.
|
@Scope(ScopeType.SINGLETON) @Path("service1") public class ResourceA {
... } |
The following example illustrates how to define a provider with a prototype lifecycle.
|
@Scope(ScopeType.PROTOTYPE) @Provider public class EntityProvider implements MessageBodyReader<String> {
... } |
The @Parent annotation provides the ability to define a base template URI for the URI specified in a resources @Path annotation.
If a resource is annotated with the @Parent annotation, the Wink runtime calculates the final resource template by first retrieving the value of the @Parent annotation, which holds the parent resource class, and then concatenates the resource path template definition to the path template definition of the parent resource.
Annotation
Specification
Table 28: @Parent Annotation Specification
|
Value |
Description |
|
|
Mandatory |
No |
|
|
Target |
Resource class |
|
|
Parameters |
Name |
Type |
|
value |
Class<?> |
|
|
Example |
@Parent(ParentResource.class) |
|
Example
|
@Path("services") public class ParentResource {
... } |
|
@Parent(BaseResource.class) @Path("service1") public class ResourceA {
... } |
Explanation
In the example, the user defined two resources: A ParentResource and ResourceA. ParentResource defines the @Path annotation to associate it with “services” URI. ResourceA defines the @Path annotation to associate it with “service1” URI and defines ParentResource to be its parent by specifying it in the @Parent annotation. In this case, the final URI path for ResourceA is “services/service1”.
8. Resource Matching - Continued Search
Wink provides a Continued Search mode when searching for a resource method to invoke during request processing, which is an extended search mode to the algorithm defined by the JAX-RS specification.
8.1. Resource Matching Overview
Section 3.7.2 of the JAX-RS specification describes the process of matching requests to resource methods. The fact that only the first matching root resource (section 1(f) of the algorithm) and only the first matching sub-resource locator (section 2(g) of the algorithm) are selected during the process makes it difficult for application developers to implement certain scenarios.
For example, it is impossible to have two resources anchored to
the same URI, each having its own set of supported methods:
|
public class ResourceA { @GET @Produces("text/plain") public String getText() {...} } @Path("my/service") public class ResourceB { @GET @Produces("text/html") public String getHtml() {...} } |
Explanation
In order to implement this according to the JAX-RS specification, ResourceB must extend ResourceA and be registered instead of ResourceA. However, this may not always be possible, such as in an application that uses JAX-RS as the web service frontend while providing an open architecture for registering extending services. For example, Firefox that provides an Extensions mechanism. The extending service must be aware of the core implementation workings and classes, that may not always be plausible. Moreover, it is impossible for a service to extend the functionality of another service without knowing the inner workings of that service, that creates an “evil” dependency between service implementations.
In order to solve this problem, Wink provides a special resource Continued Search mode when searching for a resource and method to invoke. By default, this mode is off, meaning that the search algorithm is strictly JAX-RS compliant. When this mode is activated, and a root resource or sub-resource locator proves to be a dead-end, the Wink runtime will continue to search from the next root-resource or sub-resource locator, as if they were the first match.
In the previous example, there is no way to know which of the resources is a first match for a request to “/my/service”. If the Continued Search mode is off, either the getText() method is unreachable or the getHtml() method is unreachable. However, when the Continued Search mode is active, a request for text/plain reaches the getText() method in ResourceA, and a request for text/html reaches the getHtml() method in ResourceB.
The Continued Search mode is activated by setting the value of the wink.searchPolicyContinuedSearch key in the application configuration properties file to true.
If the key is set to anything else but true or if it does not exist in the properties file, then the Continued Search mode is set to off, and the behavior is strictly JAX-RS compliant.
The following chapter describes the out-of-the-box data models provided and supported by the Wink runtime.
Wink supports JAXB objects for consuming and producing XML (application/xml), and for producing JSON (application/json).
An application may provide a ContextResolver for obtaining the JAXBContext of the JAXB object. If no suitable JAXBContext is obtained from a ContextResolver, then the Wink runtime uses a default JAXBContext initialized with the JAXB object.
Wink utilizes the json.org implementation for producing JSON (application/json).
Wink provides a syndication data model for producing Atom (application/atom+xml), HTML (text/html), JSON (application/json) and CSV (text/csv), and for consuming Atom and CSV. All of the model classes are located under the org.apache.wink.common.model.synd package.
Wink provides an Atom 1.0 data model for consuming and producing Atom feeds and entries (application/atom+xml). All of the model classes are located under the org.apache.wink.common.model.atom package.
9.5. Atom Publishing Protocol (APP)
Wink provides an Atom Publishing Protocol data model for producing Service Documents (application/atomsvc+xml) and Categories Documents (application/atomcat+xml). The APP data model can also be used to produce Service and Categories documents in HTML (text/html) and JSON (application/json) formats. All of the model classes are located under the org.apache.wink.common.model.app package.
9.6. Comma Separated Values (CSV)
Wink provides a CSV data model for producing and consuming CSV (text/csv). The model is based on a Serialization and a Deserialization interface, in addition to a simple CSV Table class. All of the model classes are located under the org.apache.wink.common.model.csv package.
Wink provides an OpenSearch data model for producing OpenSearch
Description Documents (application/opensearchdescription+xml). All of the model
classes are located under the org.apache.wink.common.model.opensearch
package.
Wink supports the automatic and manual generation of APP Service Documents by providing an APP data model and set of complementary providers.
Atom Publishing Protocol Service Documents are designed to support the auto-discovery of services. APP Service Documents represent server-defined groups of Collections used to initialize the process of creating and editing resources. These groups of collections are called Workspaces. The Service Document can indicate which media types and categories a collection accepts.
The Wink runtime supports the generation of the APP Service Documents in the XML (application/atomsvc+xml) and HTML (text/html) representations.
10.1. Enabling the APP Service Document Auto Generation
APP Service Document generation is activated by setting the wink.rootResource key in the configuration properties file. By default, the key value is set to “atom+html”, indicating that both XML (application/atomsvc+xml) and HTML (text/html) representations are available.
Once activated, the auto-generated APP Service Document is available at the application root URL “http://host:port/application”.
10.2. Adding Resources to APP Service Document
Wink provides the @Workspace annotation used to associate a Collection Resource with an APP Service Document workspace and collection elements. The only requirement to incorporate a collection resource in a service document is to place the @Workspace annotation on the resource.
|
Refer to chapter 7, section 7.1 for more information on the @Workspace annotation. |
Given the following collection resource definition:
|
@Path("my/service") public class ResourceA { ... } |
The auto-generated APP Service Document is:
|
10.3. APP Service Document HTML Styling
Wink provides the ability to change the default styling of the APP Service Document HTML representation. The styling is changed by setting the value of the wink.serviceDocumentCssPath key in the configuration properties file to the application specific CSS file location.
The following classes implement the APP Service Document support:
·
org.apache.wink.server.internal.resources.RootResource
– generates the XML (application/atomsvc+xml)
representation of the APP Service Document.
·
org.apache.wink.server.internal.resources. HtmlServiceDocumentResource - generates
the HTML (text/html) representation of the APP Service
Document.
Wink provides an additional module deployed as an external jar in
order to provide Spring integration.
The Spring integration provides the following features:
· The ability to register resources and providers from the Spring context, registered as classes or as Spring beans.
· The ability to define the lifecycle of resources or providers that are registered as Spring beans, overriding the default scope specified by the JAX-RS specification.
· Resources and providers can benefit from Spring features such as IoC and post-processors.
· Customize Wink from the Spring context. When working with Spring, Wink defines a core spring context that contains customization hooks, enabling easy customization that would otherwise require coding.
Spring makes it convenient to register resources and providers as spring beans.
11.1.1.
Spring Context Loading
In order to load the Spring Context, it is necessary to add a
Context Load Listener definition to the web.xml file. The contextConfigLocation
context-param must specify the location of the Wink core context file and the
application context file, as described in the following example:
|
<context-param> <param-name>contextConfigLocation</param-name> <param-value>classpath:META-INF/server/wink-core-context.xml classpath:mycontext.xml </param-value> </context-param> <listener> <listener-class>
org.springframework.web.context.ContextLoaderListener </listener-class> </listener> |
11.1.2.
Registering Resources and Providers
Wink provides the org.apache.wink.spring.Registrar class in order to register resources and providers through a Spring context. The Registrar class extends the WinkApplication class and must be registered as a singleton spring bean. It is possible to define multiple registrars in the same context.
All registrars are automatically collected by the runtime and registered as WinkApplication objects during the context loading.
The registrar provides the following properties:
· instances – instances of resources and providers. Ordinarily, these instances are Spring beans, so they can benefit from IoC and other Spring features.
· classes – a set of resources and providers class names. This property is similar to the getClasses() method of the Application class.
· priority – the priority of the WinkApplication
|
Refer to chapter 3, section 3.4 for more information on Priorities. |
|
<bean class="org.apache.wink.spring.Registrar"> <property name="classes"> <set
value-type="java.lang.Class"> <value>package.className</value> </set> </property> <property name="instances"> <set> <ref
bean="resources.resource1" /> <ref
bean="resources.resource2" /> <ref
bean="providers.provider1" /> </set> </property> </bean> |
11.2. Custom Properties File Definition
Wink provides a set of customizable properties. When working with
Spring, the user should redefine the custom properties file using the Spring
context:
|
<bean
id="customPropertiesFactory" class="org.springframework.beans.factory.config.PropertiesFactoryBean"> <property name="locations"> <list> <value>WEB-INF/configuration.properties</value> </list> </property> </bean> <bean
id=”customConfigurer”
class="org.springframework.beans.factory.config.PropertyPlaceholderConfigurer"> <property
name="ignoreUnresolvablePlaceholders" value="true" /> <property name="order"
value="1" /> <property
name="propertiesArray">
<list> <props> <prop
key="winkInternalPropertiesFactory">customPropertiesFactory</prop> </props> </list> </property> </bean> |
· The customPropertiesFactory bean loads the properties file.
· The customConfigurer bean overrides the default factory with a custom factory.
· The order is set to “1”. This makes the customConfigurer bean run before the default Wink configurer.
· In addition, notice that ignoreUnresolvablePlaceholders must be set to true, otherwise the configurer will fail, since some unresolved properties can remain in the context.
11.3. Customizing Media-Type Mappings
Wink provides the ability to customize the Media-Type mappings
using Spring context.
|
Refer to chapter 3, section 3.7 for more information on Media-Type Mapping. |
|
<property name="mappings"> <list> <map> <entry
key="userAgentStartsWith" value="Mozilla/" /> <entry
key="resultMediaType"> <util:constant
static-field=" javax.ws.rs.core.MediaType.ATOM" /> </entry> <entry key="typeToSend"> <util:constant
static-field="javax.ws.rs.core.MediaType.TEXT_XML" /> </entry> </map> </list> </property> </bean> <bean
id=”customConfigurer” class="org.springframework.beans.factory.config.PropertyPlaceholderConfigurer"> <property
name="ignoreUnresolvablePlaceholders" value="true" /> <property name="order"
value="1" /> <property
name="propertiesArray"> <list> <props> <prop key="winkMediaTypeMapper">custom.MediaTypeMapper</prop> </props> </list> </property> </bean> |
· The custom.MediaTypeMapper bean creates a new Media-Type mapper.
· The customConfigurer bean overrides the default factory with a custom factory.
Note
|
|
customConfigurer The order is set to “1”. This makes the customConfigurer run before the default Wink configurer. |
· In addition, notice that ignoreUnresolvablePlaceholders must be set to true, otherwise the configurer will fail, since some unresolved properties can remain in the context.
11.4. Customizing Alternative Shortcuts
Wink provides the ability to customize the Alternative Shortcuts in one of two ways.
|
Refer to chapter 3, section 3.8 for more information on Alternative Shortcuts Mappings. |
11.4.1.
External Properties File
The shortcuts are defined in a properties file. The shortcuts properties file is loaded in the same way that the configuration properties file is loaded.
|
<bean id="custom.Shortcuts" class="org.springframework.beans.factory.config.PropertiesFactoryBean"> <property
name="locations">
<list> <value>WEB-INF/shortcuts</value>
</list>
</property> </bean> <bean id=”customConfigurer”
class="org.springframework.beans.factory.config.PropertyPlaceholderConfigurer"> <property
name="ignoreUnresolvablePlaceholders" value="true" /> <property
name="order" value="1" /> <property
name="propertiesArray">
<list>
<props>
<prop key="winkAlternateShortcutsMap">custom.Shortcuts</prop> </props> </list> </property> </bean> |
Defines the map of the shortcuts in the Spring context.
The WebDAV extension is a single jar wink-webdav-<version>.jar, and
it has no special dependencies.
The WebDAV extension provides a Java data model that reflects the WebDAV XMLs defined in the WebDAV RFC. All classes of the data model are located in the org.apache.wink.webdav.model package.
The WebDAV extension provides several classes that applications can use in order to receive basic support for common WebDAV methods
The WebDAVModelHelper class provides helper methods for XML marshaling and unmarshaling of the WebDAV data model classes. It also provides helper methods for creating generic properties as DOM element classes to populate the WebDAV Prop element.
The WebDAVResponseBuilder class is used in order to create responses to WebDAV PROPFIND requests. It takes a SyndEntry or SyndFeed as input in order to create the response.
12.3. Resource Method Definition
A resource method is defined to handle the desired WebDAV method by annotating it with one of the WebDAV method designators defined in the WebDAVMethod enum.
The supported WebDAV Http methods are as follows:
· PROPFIND
· PROPPATCH
· MKCOL
· COPY
· MOVE
· LOCK
· UNLOCK.
12.4. Creating a Multistatus Response
In order to create a MULTISTATUS
response to a PROPFIND request the user can use the WebDAVResponseBuilder
class, or create the response manually.
12.4.1.
Using WebDAVResponseBuilder
In order to create a multistatus response using the WebDAVResponseBuilder class, call one of the propfind() methods.
The WebDAVResponseBuilder class also enables the user to provide the properties to include in the response by extending the PropertyProvider class, overriding the setPropertyValue() method and passing the property provider instance to the response builder propfind() method.
12.4.2.
WebDAVResponseBuilder Example
|
public class DefectResource { @WebDAVMethod.PROPFIND @Consumes(“application/xml”) @Produces(application/xml”) public Response propfindDefect(@PathParam("defect")
String defected) { SyndFeed feed = ... return
WebDAVResponseBuilder.propfind(feed); } } |
The propfindDefect() method is associated with the PROPFIND WebDAV Http method
using the @WebDAVMethod.PROPFIND annotation.
When the propfindDefect() method is invoked, an instance of a org.apache.wink.common.model.synd.SyndFeed is created and passed to the WebDAVResponseBuilder.propfind() method in order to create the actual response.
In order to create a Multistatus response manually, perform the following steps:
1 Create a new org.apache.wink.webdav.model.Multistatus instance and set its fields according to the application logic.
2 Create a new javax.ws.rs.core.Response instance, set the response code to MULTI_STATUS (207), and set its entity to be the Multistatus instance.
3 Return the Response instance from the resource method
The Wink runtime utilizes three Handler Chains for the complete processing of a request: Request chain, Response chain and Error chain.
A handler receives a MessageContext instance for accessing and manipulating the current request information and a HandlerChain instance for advancing the chain. It is the responsibility of the handler to pass control to the next handler on the chain by invoking the doChain() method on the HandlerChain instance.
A handler may call the doChain() method several times if needed, so handlers are required to consider the possibility they will be invoked more than once for the same request.
All handler related interfaces reside in the org.apache.wink.server.handlers package.
The implementation of separate chains provides the ability to move up and down one chain before moving on to the next chain. This is particularly useful for the implementation of the JAX-RS resource-method search algorithm that includes invoking sub-resource locators, and implementing the Continued Search mode.
There are two types of handlers:
· System Handler
· User Handler
System Handlers are the handlers that implement the core engine of the Wink runtime. The Wink runtime will not function correctly if any of the system handlers are removed from the chain.
User Handlers are the handlers that are provided by an application to customize a chains behavior and to add unique functionality to it. User handlers are not part of the core functionality of Wink.
|
Refer to chapter 2, section 2.3.1 for more details on User Handlers Customization. |
The MessageContext allows the following:
· Allows handlers to access and manipulate the current request information
· Allows handlers to maintain a state by setting attributes on the message context, as the handlers themselves are singletons and therefore stateless
· Allows handlers to pass information to other handlers on the chain
The Request Handler Chain is responsible for processing a request according to the JAX-RS specification by accepting the request, searching for the resource method to invoke, de-serializing the request entity and finally for invoking the resource method. It is responsible for invoking sub-resource locators by moving up and down the chain as needed.
A Request handler is a class that implements the org.apache.wink.server.handlers.RequestHandler interface.
13.3.1.
System Request Handlers
The following is a list of system handlers comprising the request handler chain in the order that they appear in the chain.
Request
Handlers
Table 29: Request Handlers
|
Handler |
Description |
|
SearchResultHandler |
Responsible for throwing the search result error if there was one during the search for the resource method |
|
OptionsMethodHandler |
Generates a response for an OPTIONS request in case that there is no resource method that is associated with OPTIONS, according to the JAX-RS spec |
|
HeadMethodHandler |
Handles a response for a HEAD request in case that there is no resource method that is associated with HEAD, according to the JAX-RS spec |
|
FindRootResourceHandler |
Locates the root resource that best matches the request |
|
FindResourceMethodHandler |
Locates the actual method to invoke that matches the request, invoking sub-resource locators as needed |
|
CreateInvocationParametersHandler |
Creates the parameters of the resource method to invoke and de-serializes the request entity using the appropriate MessageBodyReader |
|
InvokeMethodHandler |
Invokes the resource method |
User request handlers are inserted before the InvokeMethodHandler
handler.
|
Refer to chapter 2, section 2.3.1 for more details on User Handlers Customization. |
The Response Handler Chain is responsible for handling the object returned from invoking a resource method or sub-resource method according to the JAX-RS specification. It is responsible for determining the response status code, selecting the response media type and for serializing the response entity.
A Response handler is a class that implements the org.apache.wink.server.handlers.ResponseHandler interface.
13.4.1.
System Response Handlers
The following is a list of system handlers comprising the response handler chain in the order that they appear in the chain.
Response
Handlers
Table 30: Response Handlers
|
Handler |
Description |
|
PopulateResponseStatusHandler |
Determines the response status code, according to the JAX-RS spec |
|
PopulateResponseMediaTypeHandler |
Determines the response media type, according to the JAX-RS spec |
|
FlushResultHandler |
Serializes the response entity using the appropriate MessageBodyWriter |
|
HeadMethodHandler |
Performs cleanup operations in case that there was no resource method that was associated with HEAD. |
13.4.2.
User Response Handlers
User response handlers are inserted before the FlushResultHandler
handler. Wink initializes the user response handler chain with the CheckLocationHeaderHandler
handler that verifies that the “Location” response header is present on a
response when there is a status code that requires it, for example, status
code: 201.
|
Refer to chapter 2, section 2.3.1 for more details on User Handlers Customization. |
The Error Handler Chain is responsible for handling all of the exceptions that are thrown during the invocation of the Request and Response handler chains, according to the JAX-RS specification for handling exceptions. It is responsible for determining the response status code, selecting the response media type and for serializing the response entity.
An Error handler is a class that implements the org.apache.wink.server.handlers.ResponseHandler interface.
The following is a list of system handlers comprising the error handler chain in the order that they appear in the chain.
Error
Handlers
Table 31: Error Handlers
|
Handler |
Description |
|
PopulateErrorResponseHandler |
Prepares the response entity from a thrown exception according to the JAX-RS specification |
|
PopulateResponseStatusHandler |
Determines the response status code according to the JAX-RS spec |
|
PopulateResponseMediaTypeHandler |
Determines the response media type, according to the JAX-RS spec |
|
FlushResultHandler |
Serializes the response entity using the appropriate MessageBodyWriter |
User error handlers are inserted before the FlushResultHandler handler.
|
Refer to chapter 2, section 2.3.1 for more details on User Handlers Customization. |
The following details how the Wink runtime performs request processing:
1 Create new instances of the three handler chains. The handlers themselves are singletons.
2 Create a new instance of a MessageContext to pass between the handlers.
3 Invoke the first handler on the Request chain.
4 Once the request chain is complete, invoke the Response chain and pass it the MessageContext that was used in the Request chain.
5 Make both chains and the MessageContext available for garbage collection.
6 If at any time during the execution of a Request or Response chain an exception is thrown, catch the exception, wrap it in a new MessageContext instance and invoke the Error chain to produce an appropriate response.
The following chapter describes the Wink Client and provides a detailed description of the Wink Client component and its functionality.
14.1. This chapter contains the following sections
· Dependencies
· Main Features
· High Level Architecture Overview
· Getting Started with the Wink Client
· Configuration
· Handlers
14.2. Wink Client Overview
The Wink Client is an easy-to-use, high level Java API for writing clients that consume HTTP-based RESTful Web Services. It utilizes JAX-RS concepts, encapsulates Rest standards and protocols and maps Rest principles concepts to Java classes, which facilitates the development of clients for any HTTP-based Rest Web Services.
The Wink Client also provides a Handlers mechanism that enables the manipulation of HTTP request/response messages.
Table 32: Wink Client Dependencies
|
3-rd Party |
Java
1.5 |
Java
1.6 |
Comments |
|
xercesImpl-2.6.2.jar |
Required |
Required |
|
|
json-20080701.jar |
Required |
Required |
|
|
jsr311-api.jar |
Required |
Required |
|
|
wink-common-<VERSION>.jar |
Required |
Required |
|
|
slf4j-simple-1.5.8.jar |
Required |
Required |
May be replaced with another SLF4J bindings, e.g. application that uses log4j will replace this one by slf4j-log4j12-1.5.8.jar |
|
slf4j-api-1.5.8.jar |
Required |
Required |
|
|
jaxb-api-2.1.jar |
Required |
Not Required |
|
|
jaxb-impl-2.1.4.jar |
Required |
Not Required |
|
|
activation-1.1.jar |
Required |
Not Required |
|
|
stax-api-1.0-2.jar |
Required |
Not Required |
|
The Wink Clients main features
are as follows:
· Utilizes JAX-RS Providers for resource serialization and deserialization
· Provides Java object models, such as Atom, APP, OpenSearch and Json along with providers to serialize and deserialize these models
· Uses the JDK HttpUrlConnection as default underlying Http client
· Provides integration with Apache Http Client 4.0
· Allows for the easy replacement of the underlying Http transport
· Provides a Handlers mechanism for manipulation of HTTP request and response messages.
Supports
· Http proxy
· SSL
14.6. High Level Architecture Overview
The following diagram
illustrates the high-level architecture of the Wink Client.
Figure 3: Wink Client high-level view
The RestClient
class is the Wink Client entry point and is responsible for holding different
configuration options and the provider registry.
The RestClient is used
to create instances of the Resource class. The Resource class represents a web
resource associated with a specific URI and is used to perform uniform
interface operations on the resource it represents.
Every method invocation
goes through a user defined handlers chain that enables for manipulation of the
request and response.
14.7. Getting Started with the Wink Client
The following section details the getting started examples that demonstrate how to write a simple client that consume RESTful Web Services with the Wink Client.
|
// create the rest client instance
|
Explanation
The RestClient is the entry point for building a RESTful Web Service client. I order to start working with the Wink Client, a new instance of RestClient needs to be created, as the example shows in line 1 of the example. A new Resource is then created with the given URI, by calling the RestClient#resource() method as appears in line 2.
Finally, the Resource#get() method is invoked in order to issue an Http GET request as appears in line 3.
Once the Http response is returned, the client invokes the relevant provider to desterilizes the response in line 3.
|
// create the rest client instance 1 RestClient client = new RestClient(); // create the resource instance to interact with 2 Resource resource = client.resource("http://services.co"); // issue the request 3 String response = resource.contentType("text/plain").accept("text/plain").post(String.class, "foo"); |
The POST Request example demonstrates how to issue a simple Http POST request that sends and receives resources as strings.
First, a new instance of a Resource is created through the RestClient. The Http POST request is then issued by specifying the request and response media types and the response entity type (String.class).
|
// create the rest client instance 1 RestClient client = new RestClient(); // create the resource instance to interact with 2 Resource resource =
client.resource("http://services.co"); 3 AtomEntry request = getAtomEntry(); // issue the
request 4 AtomEntry response =
resource.contentType("application/atom+xml").accept("application/atom+xml").post(AtomEntry.class, request); |
Explanation
The Wink Client provides an object model for Atom (atom feed and atom entry), and supplies out-of-the-box providers that enable sending and receiving atom feeds and entries. The example demonstrates how to issue an Http POST request that sends and receives atom entries.
14.7.4.
Using ClientResponse
|
// create the rest client instance 1 RestClient client = new RestClient(); // create the resource instance to interact with 2 Resource resource =
client.resource("http://services.co"); // issue the
request 3 ClientResponse response = resource.accept("text/plain").get(); //
deserialize response 4 String responseAsString =
response.getEntity(String.class); |
Explanation
This example demonstrates how to use the ClientResponse object in order to deserialize the response entity. If the response entity type is not provided when invoking the Resource#get() method that appears in line 3, the response will be returned as the raw ClientResponse. In order to trigger the response deserialization mechanism, the ClientResponse#getEntity() method needs to be invoked as it appears in line 4 with the required response entity type.
The RestClient configuration
is performed by using the ClientConfig class. An instance of the
configuration class is passed to the constructor of the RestClient when
constructing a new RestClient.
|
|
ApacheHttpClientConfig
is used
instead of default ClientConfig , if
integration with Apache Http Client 4.0 is required. |
The following options can be configured
in the RestClient:
·
Custom providers via JAX-RS Application
·
Handler chain
·
Proxy host & port
·
Connect and read timeouts
·
Redirect
|
// Create new JAX-RS
Application 2 config.handlers(new DummyHandler()); // create the rest client instance // create the resource instance to interact with //
the resource will be returned as plain text |
Explanation
This example demonstrates how to register a custom handler. First, a new instance of a ClientConfig is created as it appears in line 1. Then the new handler is added to the handlers chain by invoking the handlers() method on the ClientConfig instance as it appears in line 2. Finally, a new instance of a RestClient is created with this configuration as it appears in line 3.
14.8.3.
Apache Http Client Configuration
|
// Create new JAX-RS
Application 2 config.handlers(new SimpleHandler()); // create the rest client instance // create the resource instance to interact with //
the resource will be returned as plain text |
Explanation
This example demonstrates how to use Apache Http Client 4.0 as Wink underlying Http client. By default, Wink Client uses HttpUrlConnection to perform to HTTP request execution. User, that wants to use Apache Http Client 4.0 instead, needs to create RestClient with ApacheHttpClientConfig, as it appears in line 3.
14.8.4.
Custom Provider Configuration
|
// Create new JAX-RS Application 2 Application app = new Application() { @Override public Set<Class<?>>
getClasses() { HashSet<Class<?>> set = new
HashSet<Class<?>>(); set.add(FooProvider.class); return set;}}; 3 conf.applications(app); // create the rest client instance // create the resource instance to interact with |
Explanation
This example demonstrates how to register a custom entity provider. First, a new instance of ClientConfig is created as it appears in line 1. Then a new anonymous Application is instantiated and set on the ClientConfig as it appears in line 2 and 3. Finally, a new instance of a RestClient is created with this configuration as it appears in line 4.
The Wink Client provides a Handlers mechanism that intercepts Http requests and responses. This mechanism is used to manipulate the request and response headers and allows the manipulation of the input and output entity streams by use of adapters.
An application develops custom handlers by implementing the ClientHandler interface. Custom handlers are registered via the ClientConfig configuration object. All registered handlers are invoked for every issued request, according to their registration order.
A custom handler implements the ClientHandler interface. The entry point of the handler is the handle() method. It receives the ClientRequest instance that encapsulates request information and allows for request data manipulation. It also receives the HandlerContext instance that is used to pass control to the next handler on the chain and to set input and output stream adapters.
Handlers are responsible for the flow control. It is handler’s responsibility to call the next handler on the chain by invoking the doChain() method on the HandlerContext instance.
14.9.2.
Custom Handler Implementation
A typical implementation of the “handle” method appears as follows:
|
public class MyHandler implements ClientHandler { public ClientResponse
handle(ClientRequest rqs, HandlerContext ctx) { // Do something before request is issued to the web resource 1 rqs.getHeaders().add("CUSTOM-REQUEST-HEADER", "Foo-Request"); 2 ClientResponse resp =
ctx.doChain(request); // Do something before response is returned to the client 3 resp.getHeaders().add("CUSTOM-RESPONSE-HEADER", "Foo-Response"); 4 return
resp; } } |
Explanation
This example illustrates a typical implementation of the custom handler. First, the handler adds a custom header to the request as it appears in line 1, then it calls the next handler on the chain by invoking the doChain() method (line 2), adds a custom header to a response as it appears in line 3 and finally returns the response as it appears in line 4.
14.9.3.
Input and Output Stream Adapters
The Wink Client provides the ability to manipulate raw Http input and output entity streams through the InputStreamAdapter and the OutputStreamAdapter interfaces. This is useful for modifying the input and output streams, regardless of the actual entity, for example when adding compression capabilities.
The adapt() method of the output stream adapter is called before the request headers are committed, in order to allow the adapter to manipulate them.
The adapt() method of the input stream adapter is called after the response status code and the headers are received in order to allow the adapter to behave accordingly.
14.9.4.
Stream Adapters Example
The following example demonstrates how to implement input and output adapters.
Gzip Handler
|
public class GzipHandler implements ClientHandler { public ClientResponse handle(ClientRequest request, HandlerContext context) {
request.getHeaders().add("Accept-Encoding", "gzip");
context.addInputStreamAdapter(new GzipInputAdapter());
context.addOutputStreamAdapter(new GzipOutputAdapter());
return
context.doChain(request); }} |
Gzip Input Stream Adapter
|
class
GzipInputAdapter implements InputStreamAdapter{
public
InputStream adapt(InputStream is, ClientResponse
response) { String header =
response.getHeaders().getFirst("Content-Encoding"); if (header != null &&
header.equalsIgnoreCase("gzip")) {
return new GZIPInputStream(is);
} return is; }} |
Gzip Output Stream Adapter
|
class
GzipOutputAdapter implements OutputStreamAdapter { public OutputStream adapt(OutputStream os, ClientRequest
request) {
request.getHeaders().add("Content-Encoding", "gzip");
return new GZIPOutputStream(os); }} |
Explanation
The Gzip handler creates instances of the GzipInputAdapter and the GzipOutputAdapter and adds them to the stream adapters of the current request by invoking the addInputStreamAdapter() and addOutputStreamAdapter() on the HandlerContext instance.