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The Java Platform Module System

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The Java Platform Module System

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Although Java 9 is not the latest JDK release (to be more specific, it was released back in 2017), it was the biggest update in the history of the JDK. Despite that, most Java programmers hardly mention its most significant feature — the Java Platform Module System.

This is primarily because most business applications still use Java 8. For now, it has demonstrated stability and newer releases need time to spread across the IT world.

That’s why I decided to write this article. In the future, if you facing this technology, you will be able to get a flying start.

Java 9: A Historical Perspective

Java Platform Module System
  • 2006: Java 6 by Sun Microsystems (compare to previous releases it was fairly minor)
  • 2011: Java 7 was the first Oracle release; it contained far fewer features than anticipated. Mainly low-level API changes.
  • 2014: Java 8: Serious innovations, specifically lamdas and streams.
  • 2017: The Java 9 release was postponed several times due to setbacks regarding the module system implementation. But finally, in September 2017, it was released.

Since Java 9, there has been a new release every six months. Before that, there was only one release once the planned features were complete.

The Java Platform Module System

One of the biggest changes in Java, ever.

It affects the followings:

  • Language (new features and keywords)
  • Compiler (needs to translate new features and must know module boundaries)
  • JVM (All module metadata around modules are preserved in a binary format and loaded by the JVM)
  • Tooling (IDEs, libraries need to adapt to modularity)

Reasons Why the Module System Added to the Language

There are a few reasons why modularizing was necessary.

Modularize the JDK Itself

The Java JDK is over 20 years old, and it was one big file. It was hardly maintainable. Everything was chained together and they would like to work down this technical debt to make it maintainable again.

Modularize Applications

Along with the modularized JDK, developers should modularize their applications as well. Although, it is important to note that modularization is optional!

If you switch to Java 9, you can keep using Java as you used to, or you can switch to the module system and start to modularize your application and make it more maintainable.

Although you will still run on modularized JDK, this can still affect your code!

Before the Modular JDK

  • One huge library: rt.jar (runtime.jar)
  • This library was only grown and nothing removed from it in the last 20 years.
  • Many inner libraries have been used by outer applications even that they do not suppose to do that, but there was no way to restrict that.

The Modular JDK: Explicit Dependencies

Java Platform Module System

This is how the new Java platform looks like.

They divided JDK into more than 90 separate modules. Each module encapsulates its own piece of functionality of the Java runtime library. The picture above represents the dependencies between the modules.

The most important one is the java.base module. It represents the most basic classes of the language, like streams, strings, and objects. Since this module is essential, all other modules depend on this library.

Here, we see a more complex graph about the different libraries and how they connect to each other. The ones with names starting with java indicate that these are part of the Java SE specifications.

In the dependency graph above, you can also see two modules in blue; these do not start with java but jdk. These are JDK-specific.

You may notice that all arrows are pointing down. This means that there are no circular dependencies. Hence, it has very clean modularization.

Let’s see some examples:

Corba is ancient technology, and it's still part of the JDK. However, it is isolated into its module. This means that unless your application has a dependency on java.corba, this old technology won’t get in.

Java Platform Module System

Another module in this graph you may be more familiar: Java.desktop. It contains all the swing GUI toolkits of the Java platform. Hence, your application doesn’t need any of these GUI dependencies; and you do not need to reference the java.desktop module.

The Modular JDK Advantages

Increased Security

That’s a one we didn’t touch upon yet. This is due that the fact a module can explicitly expose some of the packages and strongly encapsulate other packages. As I mentioned earlier, there are many internal implementations in classes in the JDK that need to be public because it is used among different packages, but at the same time, they should not be used outside of JDK. These later ones are encapsulated.

Reduced Footprint

If you start, make modularized applications on top of the Modularized JDK. You do not need to scan and load all the classes that the rt.jar contains, which you cannot avoid before you can only include the necessary modules.

Easy Deprecation

Having clearly separate modules also helps deprecation. The idea is that, at some point, a module can be marked as deprecated. Every application that uses that module should look to another solution. After that, in the next major release, it can be removed from the JDK.

It is already happening because in Java 9, the java.corba module has been marked as deprecated.

Future Proof

The deprecation example is true from the other way as well. It is much easier to ship new features to the language. They can add incubator modules, and if it is stable, it can be converted to a real module with the next major release.

There is an example as well as the jdk.incubator.httpclient module.

What Is a Module?

Now, we see the new modularized JDK, but a big question remains: What exactly is a module?

A module has a name; it has a distinct identity; it has groups related code. Furthermore, it fully self-contained, which means that it needs to contain everything to do its functions. If it hasn’t, it must reference another module from the library.

Module Descriptors

The below image shows how a module builds up.

Java Platform Module System descriptors

This structure is described in the module-info.java.

module java.base {
  exports java.lang;
  exports java.util;
  exports java.io;
  //etc.
}


We do not see any external module dependencies here because java.base do not reference any.

Let us see another example.

The java.sql references to two other modules, these are marked in our descriptor.

As you may have noticed, we have three new keywords in this context.

  • module
  • exports
  • requires

These keywords are live in the context of the module, so you do not need to be aware of them in your application code.

If you have Java 9 > installed, you can list out all modules that are currently in the JDK by the java –list-modules keyword typed in your operating system console.

Another good function is that you can get a definition overview of every module independently with the java –describe-module keyword.

Java Platform Module System console keywords

Summary

Hope you enjoyed my article. Here, I described the Java Platform Module System and what Java 9 brought to the language. This was the most major update to the JDK in the last 20 years.

In my upcoming articles, I would like to mention some other features of Java 9 and also introduce the most recent versions of the JDK —10, 11, and 12.

Please don't forget to share your thoughts and ideas in the comment section below. 

Topics:
java ,java platform module system ,jdk ,dependencies ,run-time ,java 9 ,streams ,modules

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