If you are not sure if a DGS instance provides a certain extension, just have a look at the metadata of the service, e.g. http://www.restful.ws/datagridservice/meta. You will find the all the available extensions with the predicate http://www.webcomposition.net/2008"02/dgs/meta/extension (we say "has extension"). In the example below we find the SA-REST extension I have introduced yesterday.

  1: <rdf:RDF xmlns:rdf="http://www.w3.org/1999/02/22-rdf-syntax-ns#" 
  2:          xmlns:ns="http://purl.org/dc/elements/1.1/" 
  3:          xmlns:crud="http://www.webcomposition.net/2008/02/dgs/crud#" 
  4:          xmlns:meta="http://www.webcomposition.net/2008/02/dgs/meta/" 
  5:          xmlns:sarest="http://lsdis.cs.uga.edu/SAREST#">
  6:   <rdf:Description rdf:about="http://www.restful.ws/DataGridService">
  7:     <!-- ... -->
  8:       <meta:extension>WebComposition.Dgs.Extensions.SaRest.SaRestHandler</meta:extension>
  9:     <!-- ... -->
 10:   </rdf:Description>
 11: <rdf:RDF>

[vsr]The last few evenings I spend writing an extension concept for the WebComposition/DGS approach. Initially, I was looking for a semantic description for the RESTful interface of the DGS. There are plenty approaches and a lot of research is going on for extending the WSDL interfaces with semantics. OWL-S and WSMO might be the most important examples within this field. However, it appears to be a bit more tricky for REST-driven approaches. For the DGS, I decided to try the SA-REST approach of the Kno.e.sis Services Science Lab of the Wright State University, Ohio.

However, I did not want to make this as a internal component of the DGS as is a research project, and no recommendation or standard is out there yet. So I came along with the extension concept of the DGS that allows dynamically loading of additional extensions in addition to the core components of the DGS.

The IExtension interface provides hotspots were own code can be executed right before and after one of the CRUD (Create, Read, Update, Delete) events.

  1: namespace WebComposition.Dgs.Extension
  2: {
  3:     public interface IExtension
  4:     {
  5:         bool CreateStartUp(ref ExecutionContext context);
  6:         bool CreateTearDown(ref ExecutionContext context);
  7:         bool ReadStartUp(ref ExecutionContext context);
  8:         //...
  9:     }
 10: }

The ExecutionContext contains the request URI, the corresponding data adapter and (if already available)  the current content to be returned with the response.

The extension can modify or create the content to be returned. In this case the return value must be set to false. Returning this dirty flag the DGS knows that the extension provided a new content to be returned. Any further internal functionality by the DGS is thus skipped and the newly provided content from the extension is returned.

To keep the WebComposition/DGS approach as flexible as possible, extensions can be deployed at runtime. The DGS is instructed to use extension by specifying them within the web.config file.

  1: <webComposition>
  2:     <dataGridService>
  3:     <extensions>          
  4:         <extension type="WebComposition.Dgs.Extensions.SaRest.SaRestHandler, 
  5:                    WebComposition.Dgs.Extensions.SaRest, 
  6:                    Version=1.0.0.0, 
  7:                    Culture=neutral, 
  8:                    PublicKeyToken=null" />            
  9:       </extensions> 
 10:       ...
 11:     </dataGridService>
 12: </webComposition>

Based in this extension mechanism I created my very first extension to provide SA-REST support. If you have a closer look to SA-REST you might realize a drawback of the approach (one that is directly related to the REST principles). When using RDFa or any other microformat in HTML/XHTML the description of the service is rather static. The DGS on the other hand provides a highly flexible solution. Here, the full power of the DGS turn up. Analyzing the SA-REST annotation you will realize that you have RDF triples, e.g. metadata. This metadata can be stored within the DGS of course.

If we have a closer look on this metadata we can add this metadata by performing an updated on your service's meta URI. In my case it is http://localhost/datagridservice/DataGridService/meta.  Below we use some RDF based on the originally SA-REST example.

  1: <rdf:Description rdf:about="http://localhost/datagridservice/DataGridService">
  2:     <SAREST:input rdf:resource="http://lsdis.cs.uga.edu/ont.owl#Location_Query" />
  3:     <SAREST:output rdf:resource="http://lsdis.cs.uga.edu/ont.owl#Location" />
  4:     <SAREST:action>HTTP GET</SAREST:action>
  5:     <SAREST:lifting rdf:resource="http://www.restful.ws/lifting.xsl" />
  6:     <SAREST:lowering rdf:resource="http://www.restful.ws/lowering.xsl" />
  7:     <SAREST:operation rdf:resource="http://lsdis.cs.uga.edu/ont.owl#Location_Search" />
  8: </rdf:Description>

The SA-REST extension now extends the URI scope of the DGS - which is actually a very cool feature. Once deployed, the /meta scope is extended with /meta/sarest. If you now perform a GET request to http://localhost/datagridservice/DataGridService/meta/sarest. The extension will return the corresponding SA-REST metadata we used above.

To round up this exercise I've also created a set of XSL transformations that create XHTML to be used within any Web page. E.g. the SA-REST annotation mixed with the content, again based on the original SA-REST example, would look like below. Keep in mind, the XHTML snippet you see here was dynamically created by the DGS itself using a transformation.

  1: <p about="http://localhost/datagridservice/DataGridService" xmlns="http://www.w3.org/1999/xhtml" xmlns:rdf="http://www.w3.org/1999/02/22-rdf-syntax-ns#" xmlns:sarest="http://lsdis.cs.uga.edu/SAREST#">
  2:     The logical input of this service is an
  3:     <span property="sarest:input">http://lsdis.cs.uga.edu/ont.owl#Location_Query</span>
  4:     object. The logical output of this service is a list of
  5:     <span property="sarest:output">http://lsdis.cs.uga.edu/ont.owl#Location</span>
  6:     objects. This service should be invoked using an
  7:     <span property="sarest:action">HTTP GET</span>
  8:     request.
  9:     <meta property="sarest:lifting" content="http://www.restful.ws/lifting.xsl" />
 10:     <meta property="sarest:lowering" content="http://www.restful.ws/lowering.xsl" />
 11:     <meta property="sarest:operation" content="http://lsdis.cs.uga.edu/ont.owl#Location_Search" />
 12: </p>

The extension concept allows to add new custom components and to customize the DGS even more while the SA-REST extension provides a very first capability to describe the DGS' RESTful interface in a semantic way.

I am going to do a second proof of concept using another approach describing RESTful services soon to show the flexibility of the extension concept.

Today, we updated the WebComposition/DGS to support the HTTP Accept Header as specified in RFC 2616.

By receiving a HTTP request using GET, the WebComposition/DGS now replies corresponding to the Accept header specified within the request.

Ok, how would you describe the core architecture of your current project? Inspired by Ralf's idea, I really thought about the WebComposition/DGS architecture. What are the e core concepts and the key ideas of it? If everything has to fit on a napkin, you really have to restrict yourself in drawing different components. The interactive NapkinNotebook thus cam in very handy. Let's look at the first try of the architecture sketch?

What are the core components we find in the WebComposition/DGS? Well, there is the Data Grid Service (DGS) as central entity? What else? Some storage solution for data and some other storage solution for metadata. Ok, here we have to think the first time? Two of them? Definitely yes. Metadata might be saved a completely different way than the data itself. You don't think so? Let's see, think about our images as digital photos and the metadata created from the EXIF data extracted from the imaged. The EXIF data is stored as RDF in some triple store, the images are stored on the file system. Consequently, we need two storage solutions.

OK, next component on the diagram: Users; do the interact directly with the DGS? No, usually the use a Web-based application. The user also might be another application or a service - but that's no information to be on this sketch. The important thing is: there is usually only interaction through some other component - usually a Web-based application.

[Update 6/15/2008]
After some feedback from Ralf, I've updated my sketch using another software cell for the Web application. Makes much more sense though, what do you think?

With the last update on the WebComposition/DGS, we now provide RSS feeds for CRUD events. Therefore, the Meta-URI /meta is extended by the additional path segments /meta/crud, /meta/crud and /meta/crud/rss. The Meta-URI /meta/crud can be extended to /meta/crud/create,  /meta/crud/read, /meta/crud/update and /meta/crud/delete. Each URI points to a certain set of events. The event URIs in form of http://www.foo.bar/meta/crud/abab1c07-9262-4e6a-9f52-3dc497ef92f1 point directly to the RDF of the corresponding event.

Following this HTTP-URI will lead directly to corresponding description of the events as seen below. Therefore, we take care of our carefully chosen URI concept within the WebComposition/DGS approach.

<rdf:RDF xmlns:rdf="http://www.w3.org/1999/02/22-rdf-syntax-ns#"
          xmlns:meta="http://www.webcomposition.net/2008/02/dgs/meta/"
          xmlns:ns="http://purl.org/dc/elements/1.1/"
          xmlns:crud="http://www.webcomposition.net/2008/02/dgs/crud#">
    <rdf:Description rdf:about="http://www.foo.bar/DataGridService">
        <meta:event>
            <rdf:Description rdf:about="http://www.foo.bar/DataGridService/meta/crud/abab1c07-9262-4e6a-9f52-3dc497ef92f1">
                <ns:date>2008-05-15T19:20:13.7+02:00</ns:date>
                <ns:creator />
                <crud:read rdf:resource="http://www.foo.bar/DataGridService/foobar" />
            </rdf:Description>
        </meta:event>
    </rdf:Description>
</rdf:RDF>

A more visual depiction of the event can looks like below. Following the RDF data you are pointed to the resource that was affected by the event.

[svn] Another major forward integration of the student branch of the WebComposition/DGS: With revision 1228, CRUD events are supported on service level. I.e. each create, read, update or delete operation on the service (or it's lists) is stored within the meta data of the service. The vocabulary supported for the CRUD events is therefore defined as follows:

• http://www.webcomposition.net/2008/02/dgs/crud#create for create events.
• http://www.webcomposition.net/2008/02/dgs/crud#read for read events.
• http://www.webcomposition.net/2008/02/dgs/crud#update for update events.
• http://www.webcomposition.net/2008/02/dgs/crud#delete for delete events.

Exemplary meta data fore creating, updating, reading from and deleting an information store on a service running at 'http://localhost/dgs' would look like

<?xml version="1.0"?>
<rdf:RDF xmlns:rdf="http://www.w3.org/1999/02/22-rdf-syntax-ns#"
        xmlns:dc="http://purl.org/dc/elements/1.1/"
        xmlns:dm="http://www.webcomposition.net/2008/02/dgs/meta/"
        xmlns:crud="http://www.webcomposition.net/2008/02/dgs/crud">
    <rdf:Description rdf:about="http://localhost/dgs">
        <crud:create rdf:resource="http://localhost/dgs/store" />
        <crud:update rdf:resource="http://localhost/dgs/store" />
        <crud:read rdf:resource="http://localhost/dgs/store" />
        <crud:delete rdf:resource="http://localhost/dgs/store" />
    </rdf:Description>
    ...
</rdf:RDF>

The CRUD event meta data can be obtained as by the /meta URL of the corresponding service.