STS on Eclipse 3.6

Engineering | Christian Dupuis | July 01, 2010 | ...

Last week the Eclipse Foundation released the much anticipated next version of Eclipse. You can download Eclipse 3.6 aka Helios from SpringSource's member distribution page. Also check out the New & Noteworthy for this release.

The Tools Team at SpringSource has been busy updating our developer tools to support Eclipse 3.6 and while we haven't released a new version of SpringSource Tool Suite that builds on and bundles 3.6 yet, users can now install STS on top of Eclipse 3.6.

Detailed steps to install STS from our nightly update sites can be found in the installation instructions. Please…

First Eclipse Gemini Blueprint Milestone Ships

Engineering | Costin Leau | July 01, 2010 | ...

Hot on the heels of the STS on Eclipse 3.6 and Gemini Web milestone announcements, I am glad to report that the first milestone of Gemini Blueprint is available for download. Part of the Gemini project, Blueprint builds on top of the Spring Dynamic Modules v2 code base and is the Reference Implementation for the OSGi 4.2 Blueprint specification. Besides the changes reflecting the transition to the Eclipse Foundation, 1.0.0.M1 code base has been upgraded to the latest Spring framework release. Gemini Blueprint is dual licensed under Apache License and Eclipse Public License.

While the migration of existing Spring DM applications to Gemini Blueprint should be straight forward, a guide

First Eclipse Gemini Web Milestone Ships

Engineering | Glyn Normington | June 30, 2010 | ...

Gemini The first milestone (1.1.0.M01) of Eclipse Gemini Web is now available for download, dual-licensed under the Eclipse Public License and the Apache License 2.0.

SpringSource developed the Reference Implementation of the OSGi Web Container and then contributed the code to Eclipse as the Web sub-project of Gemini. The goal of Gemini is to provide modular implementations of Java EE technology. Gemini Web provides servlet and JSP technology.

Gemini Web runs on the Equinox OSGi framework and embeds Tomcat. It is also integrated into the Eclipse Virgo web server.

For more information see the documentation and the wiki

GORM Gotchas (Part 1)

Engineering | Peter Ledbrook | June 23, 2010 | ...

Are you new to Grails? Or have you perhaps run into your first GORM "oddity"? If so, then you'll want to read this series on GORM gotchas. Not only will the articles highlight those little idiosyncrasies that often catch people out, but they will also explain why GORM behaves in these ways.

Hopefully you will already know that GORM is the database access library that comes with Grails. It's based on probably the most popular Java ORM out there: Hibernate. As you can imagine, Hibernate is a powerful and flexible library and it brings big benefits to GORM. But there is a cost to using it: many…

First Virgo Milestone Ships

Engineering | Glyn Normington | June 17, 2010 | ...

Virgo from EclipseRT The first milestone (2.1.0.M01) of Eclipse Virgo is now available for download under the Eclipse Public License. This consists of an application server, known as the Virgo Web Server, and a stand-alone kernel.

The goal of this milestone is for dm Server 2.0.x users to be able to migrate to it relatively painlessly and have an equally stable environment. SpringSource is offering commercial support for Virgo and we encourage all dm Server users to migrate to Virgo. The main communication channel with users is now the Virgo forum. There is also a Virgo developer mailing list and a weekly Virgo community call

Spring Framework 3.0.3 released

Engineering | Juergen Hoeller | June 15, 2010 | ...

After several weeks of fine-tuning and community feedback, Spring Framework 3.0.3 is now available. This release fixes more than a hundred minor issues reported against Spring 3.0.2, in particular in the JSP tag library and in Portlet session handling, as well as in ConversionService details. Once again, this release catches up with recent third-party releases: OpenJPA 2.0 final, Hibernate 3.5.2, and JBoss 6.0.0 M3, all of which are fully supported in combination with Spring 3 now.

Note that, in the meantime, all major persistence providers have released GA versions with JPA 2.0 support, even…

Understanding AMQP, the protocol used by RabbitMQ

Engineering | Peter Ledbrook | June 14, 2010 | ...

Update I changed the first paragraph to clarify the relationship between RabbitMQ and JMS.

RabbitMQ is a lightweight, reliable, scalable and portable message broker. But unlike many message brokers familiar to Java developers, it's not based on JMS. Instead, your applications communicate with it via a platform-neutral, wire-level protocol: the Advanced Message Queuing Protocol (AMQP). Fortunately there's already a Java client library and SpringSource is working on first class Spring and Grails integration - so don't worry about having to do low-level stuff to use RabbitMQ. You can even find AMQP client libraries that expose a JMS interface. But AMQP is sufficiently different in operation from JMS that it might cause headaches for Java developers that are used to the JMS model.

In order to ease the transition, I'll be looking in this post at the basic concepts that underpin AMQP along with three common usage scenarios. By the end, you will hopefully have a good enough understanding to configure RabbitMQ and use it via the APIs provided by Spring and Grails.

Exchanges, queues, and bindings

Like any messaging system, AMQP is a message protocol that deals with publishers and consumers. The publishers produce the messages, the consumers pick them up and process them. It's the job of the message broker (such as RabbitMQ) to ensure that the messages from a publisher go to the right consumers. In order to do that, the broker uses two key components: exchanges and queues. The following diagram shows how they connect a publisher to a consumer:

rabbit-basics

As you can see, the setup is pretty straightforward. A publisher sends messages to a named exchange and a consumer pulls messages from a queue (or the queue pushes them to the consumer depending on the configuration). Of course, the connections have to be made in the first place, so how do publishers and consumers discover each other? Via the name of the exchange. Usually, either the publisher or consumer creates the exchange with a given name and then makes that name public. How that publication happens depends on the circumstances, but one might put it in public API documentation or send it to known clients.

How are the messages routed from the exchange to the queue? Good question. First, the queue has to be attached to the given exchange. Typically, a consumer creates a queue and attaches it to an exchange at the same time. Second, messages received by the exchange have to be matched to the queue - a process called "binding".

To understand binding, it's useful to understand the structure of an AMQP message:

rabbit-message

The headers and properties of the message are basically key/value pairs. The difference between them is that headers are defined by the AMQP specification whereas properties can contain arbitrary, application-specific information. The actual message content is just a sequence of bytes, so if you want to pass text around in your messages, then you should standardise on an encoding. UTF-8 is a good bet. You can specify a content type and encoding in the message headers if you want, but that's apparently not particularly common.

What does this have to do with binding? One of the standard headers is called routing-key and it is this that the broker uses to match messages to queues. Each queue specifies a "binding key" and if that key matches the value of the routing-key header, the queue receives the message.

Things are slightly complicated by the concept of exchange types. The AMQP spec. defines the following four types:

Exchange type Behaviour
Direct The binding key must match the routing key exactly - no wildcard support.
Topic Same as Direct, but wildcards are allowed in the binding key. '#' matches zero or more dot-delimited words and '*' matches exactly one such word.
Fanout The routing and binding keys are ignored - all published messages go to all bound queues.
Headers

Update I corrected the information on wildcards, which work on the basis of dot-delimited words or terms.

For example, say a publisher sends a message with a routing key of "NYSE" to a topic exchange called "Stocks". If a consumer creates a queue attached to "Stocks" with a binding key of "#", "*", or "NYSE", then that consumer will get the message because all three binding keys match "NYSE". However, if the message is published to a direct exchange, then the consumer will not get the message if the binding key is "#" or "*" since those characters are treated as literals, not wildcards. Interestingly, "#.#" will also match "NYSE" despite the routing key not having a dot.

Now consider a message with a routing key of "NYSE.TECH.MSFT". What binding keys will match it given that the message is going to a topic exchange?

Binding key Match?
NYSE.TECH.MSFT Yes
# Yes
NYSE.# Yes
*.* No
NYSE.* No
NYSE.TECH.* Yes
NYSE.*.MSFT Yes

That's really all there is to it. Flexibility is provided by support for multiple consumers per queue and multiple queues per exchange. In fact, a single queue can even be bound to multiple exchanges. Now let's look at some of those scenarios.

RPC

An AMQP broker can act as an RPC mechanism between a client and a service. The general setup is like this, using a direct exchange:

rabbit-rpc

The general sequence goes:

  1. Client sends message to the queue, specifying: (a) a routing key that matches the service; and (b) the name of a queue to pick the response up from.
  2. Exchange passes the message to the service's queue ("ops_q" in this case).
  3. The queue pushes the message to the service, which then does some work and sends a response message back to the exchange, specifying a routing_key that matches the reply queue.
  4. The client picks the response message off the reply queue.

From the perspective of the client, the call could either be blocking or non-blocking. How easy it is to do one or the other, though, depends on the client library in use.

The key to the RPC scenario is making sure that the client and service are using the same exchange for the initial request and that the client knows what to specify for the routing key.

As for the reply queue, it's typically created by the client, which then populates the reply_to header appropriately. Also, although you can use a different exchange for the replies compared to the requests, it's much more common to use the same exchange for both requests and replies.

Pub(lish)/Sub(scribe)

JMS has the concept of topic queues that ensure that messages from a publisher go to all subscribers. You can easily achieve the same behaviour in AMQP by binding multiple queues to an exchange like so:

rabbit-pub-sub

Even better, the queues can filter which messages they receive via the binding key. If a consumer wants to receive all messages, then it can specify a binding key of "#" - the "match any number of words" wildcard. Rather confusingly for your average developer, "*" matches zero or one (dot-delimited) words as mentioned earlier.

Work distribution

Imagine you have an application that has a bunch of jobs that need executing. With AMQP, you can hook up multiple consumers such that each job goes to one, and only one, of those consumers. The publisher doesn't care which consumer does the work, just that the work is done. This is work distribution.

Configuring it is pretty straightforward, as shown in this diagram:

rabbit-work

So you have one queue bound to the exchange with multiple consumers sharing that queue. This setup guarantees that only one consumer processes a given message, no matter how many consumers there are.

Those are the three main usage patterns for AMQP brokers. Although I have described each individually, it's fairly common to combine them. For example, you could have multiple services sharing the same queue (work distribution) in the RPC pattern. It's really up to you to decide how to configure the exchanges and queues, and now you should have a good enough understanding to work out the appropriate setup for your situation.

If you want to go further into AMQP, then check out the specification itself, particularly the section on General Architecture. And to get started with RabbitMQ, just go to its website.

Spring: the foundation for Grails

Engineering | Peter Ledbrook | June 08, 2010 | ...

In the SpringSource training course for Groovy & Grails, we highlight that Grails stands on the shoulders of giants. One of those giants is Spring. Without it, Grails simply wouldn't have been developed as quickly as it was. It probably wouldn't have the flexibility to integrate easily with enterprise Java systems either. Just look at the number of plugins available: many are based on Java libraries with Spring support.

In this post, I want to start by looking at how Grails uses Spring and then cover the various ways in which you can access that raw power and flexibility.

A child of Spring

You may not be aware of this, but when you create a Grails application you are also creating a Spring MVC one. Under the hood, Grails creates a variant of Spring MVC's DispatcherServlet and configures a bunch of beans to do the heavy lifting. Of course, this means that there is a Spring context underpinning your application - one that you have access to as you'll see later.

Here are some…

Using SpringSource Tool Suite 2.3.3.M1 with Roo and GWT

Engineering | Christian Dupuis | June 02, 2010 | ...

By now, most of you probably have heard about the announcements at Google I/O around Spring, Roo, STS and GWT. Ben and Rod covered this in their respective blog posts recently. If you missed the keynote I strongly recommend to watch the recording on YouTube to catch up (the relevant section starts at 1:09:00 into the recording).

Today I'd like to provide some detailed steps and instructions on how you can use Roo and STS to create your first GWT application.

Installation

Before we can fire up the Roo shell and start typing commands, we need to download and install all pre-requisites. Although a lot of…

What's a plugin-oriented architecture?

Engineering | Peter Ledbrook | June 01, 2010 | ...

Grails is a fantastic framework for developing web applications quickly and easily. You also have access to a plethora of plugins that provide features or make integration with other systems nice and easy. That's all good, but in this article I want to talk about what happens when your application grows and you start drowning in a sea of controllers, domain classes, and other files.

Separation of concerns

One of the most useful patterns in software architecture is called separation of concerns. The idea is that you group everything related to a particular feature or concern into a single, self-contained unit. The code in that unit should not take on any other responsibility. For example, the business logic of a web service should be in one class while the handling of SOAP messages should be in another: the business logic and SOAP handling are two different concerns.

The real beauty of this pattern is that you can aggregate these units into coarser-grained concerns, so you end up using the pattern at multiple levels. For example, say that the web service mentioned above…

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