You may want to look at the Javadoc, particularly that for the ModuleInstall class. Other classes in the package are generally not useful to module authors.


Modules API

What are Modules?

Modules permit NetBeans to be extended dynamically. All of the NetBeans APIs are designed to be used for purposes of implementing modules. Modules may range in complexity from a single Java class, properly packaged, to do something elementary such as add a menu item to the Edit menu to display the contents of the clipboard; to a full-scale integration of a major external application, such as a Java profiling suite.

All modules are distributed and installed as JAR files. The basic format should be rather familiar; classes constituting the module are archived in the JAR, and special entries in the manifest file are recognized.

Related Standards

To the greatest extent possible, NetBeans has designed the module system to reuse standard technologies when they are sufficient, and to follow the style of others when not.

The basic idea for the format of modules is taken from the Java Extension Mechanism. The basic ideas behind the Package Versioning Specification is used to handle dependencies both between modules and of modules to the system.

All modules have some set of basic properties that indicate which types of features they provide, which Java classes implement these features, and what special option settings should be used when installing these features. Some of this information is listed in the manifest file using the customary format, and NetBeans-specific attributes. The Java Activation Framework, as well as JDK-internal features such as support for executable JAR files, was used as a model for how to specify the useful contents of a JAR in a data-driven fashion: many modules will need no special installation code other than attributes in the manifest, and an XML layer giving additional more specific deployment information.

How to Create a New Module

For basic cases, you should need to do very little to create a module besides writing the basic source code.

Build a JAR

All module implementation classes must reside in a JAR file. If you want to split up a large application into several pieces, perhaps so as to make independent upgrades possible, you should do so by creating multiple modules and relating them using versioning.

Writing the manifest

A module is recognized as such by NetBeans, by virtue of its having a special magic tag in the global section of the manifest: OpenIDE-Module. Its value should be an arbitrary identifier (with a format similar to that of a Java package name) identifying the module for purposes of upgrades and dependencies. You are encouraged (but not required) to use as this tag the name of a Java package containing the principal classes for the module; this ensures that there will not be conflicts between modules produced by different developers or institutions, provided that you follow the JavaSoft recommendations on naming packages according to an Internet domain name you control. See the section on versioning for details on what this tag is used for.

There are a few other global tags which are optional but encouraged:

Gives a human-presentable display name for the module. The name may be localized by adding additional tags for each locale, e.g. OpenIDE-Module-Name_fr.
A short description of what the module does (about one sentence, like a tool tip). May be localized as for the display name.
A longer description of what the module does (roughly paragraph-length). May be localized as for the display name.
A phrase giving a category for the module. Modules with the same category may be visually grouped together in various parts of the UI. May be localized as for the display name.
The name of a custom module class.
The name of an installation layer.
Various versioning- and dependency-specific tags
Please see the section on versioning for details on these.
OpenIDE-Module-Module-Dependency-Message and OpenIDE-Module-Package-Dependency-Message
Localizable pleasant messages to display to a user in case a module or package dependency fails. In some cases it may be quite normal for a dependency to fail and it is desirable to provide a specific and helpful message to the user explaining where to get the required dependency or why the module depending on it is not needed by this user. May be localized as for the display name. Since 1.26
As above, localizable pleasant message to display when a required token is not found. Since 2.3
The presentation-oriented tags (display name and category, short and long description) may be in HTML if you prefer; this should be done in the standard Swing fashion, by beginning the text with the magic string <html>.

Since 1.24: A more flexible way to provide human-readable information is to declare the attribute OpenIDE-Module-Localizing-Bundle. Its value should be the resource path to the (base locale of) a bundle file providing localizable attributes for the module (display name, category, short and long description). The bundle file may have localized variants as usual, and the keys should be the same as the desired manifest attribute names, e.g. OpenIDE-Module-Name. If it is necessary to localize an attribute from a section (currently only filesystem sections with their Display-Name attribute), you may again place these in the bundle, where the key will be prefixed by the section name and a slash, e.g. org/foo/MyFileSystem.class/Display-Name.

All other tags are bound to a particular module section. Naturally you may use other standard manifest attributes.

In summary, here is an example manifest file that could be included with the JAR tool's -m option:

Manifest-Version: 1.0
OpenIDE-Module: com.modulemakers.clip_disp/2
OpenIDE-Module-Specification-Version: 2.0.1
OpenIDE-Module-Implementation-Version: 2.0-beta-rewrite
OpenIDE-Module-Build-Version: 2003-12-31 00:23
OpenIDE-Module-Name: Clipboard Displayer
OpenIDE-Module-Name_cs: Prohlizec schranky
OpenIDE-Module-Install: com/modulemakers/clip_disp/Installer.class
OpenIDE-Module-Layer: com/modulemakers/clip_disp/Layer.xml
X-Comment-1: I am a comment (just a deliberately meaningless
X-Comment-2: header) - "Sealed" is a standard manifest attribute.
Sealed: true

Name: com/modulemakers/clip_disp/DisplayClipboardAction.class
OpenIDE-Module-Class: Action

Module authors are strongly encouraged to use the module development support in the NetBeans IDE which among other advantages, provides interactive parsing of manifests that can help the beginning API developer immediately see how NetBeans will parse his manifest, including possible parse errors.

If you have troubles with a manifest, check to make sure you have the suggested extra blank line at the end. Some JDKs may have trouble parsing it otherwise.

Using a custom module class

With the OpenIDE-Module-Install attribute, you may specify a custom class which will handle any complex aspects of the module's installation (or uninstallation). This class is only necessary to write if the standard module sections and layers do not cover everything you need to do. Even if you do write such a class, standard sections and layers may still be used for any part of the module's integration which is conventional - the main class need only handle the exceptional parts.

To use a main install class, just extend the ModuleInstall base class. Your class must be able to be instantiated as a JavaBean. There are several methods which you may override, and may do anything which is required to make the module cleanly enter and exit NetBeans.

For example:

package com.modulemakers.clip_disp;
import org.openide.modules.ModuleInstall;
import org.openide.filesystems.FileUtil;

public class ModuleHandler extends ModuleInstall {
  public void installed() {
    // This module has been installed for the first time! Notify authors.
    HttpURLConnection conn = (HttpURLConnection)
      (new URL ("").openConnection ());
    conn.getResponseCode ();
    conn.disconnect ();
    // Handle setup within this session too:
    restored ();

  // Nothing special required here.
  // public void restored() {
  // }

  // Do not need to do anything special on uninstall.
  // Tools action will be removed automatically.
  // public void uninstalled() {
  // }

  public boolean closing() {
    // Ask the user to save any open, modified clipboard contents.
    // If the user selects "Cancel" on one of these dialogs, don't exit yet!
    return DisplayClipboardAction.askAboutExiting ();

The installed handler may do more or less what it wishes - it will be called in a running NetBeans instance. The same applies to uninstalled and closing. However, restored is more delicate in that it may be called during earlier phases of NetBeans initialization. Therefore, it should not use presentation-oriented features of NetBeans, such as the Explorer or Window System APIs. However, the other APIs are acceptable to use in restored, including DialogDisplayer.

The ModuleInstall.updated(...) method will be called just once when a module is updated to a new version - when the new version is loaded into NetBeans for the first time (in a new session), the method is called and the previous version number is accessible. Neither installed nor uninstalled will be (automatically) called in this case. It is a module author's responsibility to make sure that new versions of a module are capable of "cleaning up" obsoleted installations created by older versions, as far back as a user is likely to be directly upgrading.

In some cases, a module relies on some external resource to be present in order for it to be used. For example, an external application may need to be installed in order for it to do anything. Or it may require a valid license key. In such cases, the ModuleInstall.validate() method may be overridden to check for this external resource and throw a (preferably politely localized) IllegalStateException if something is wrong. Throwing this exception will cancel the module installation (or restoration) cleanly. Note that such an installer should not expect anything related to the module to already be loaded when this method is called, as it may be done when deciding whether to even begin loading.

"Installation-clean" modules

Since NetBeans can better manage modules when their resources are declared to exist, rather than procedurally installed, it is desirable to use declarative APIs whenever possible. Consider the following definition of an "installation-clean module":
  1. Either the module has no specified ModuleInstall; or
  2. It does have a ModuleInstall but this installer:
    1. Does nothing of consequence during initialization of the ModuleInstall object (static or instance fields with initializers or initializer blocks or the initialize method).
    2. Does not override installed nor updated (these will then just call restored).
    3. May override uninstalled but only to undo the effects of restored or other changes made by the module while running. May override closing and/or close but only to undo the effects of changes made by the module while running.
    4. May override restored and/or validate.

Additionally it is recommended not to use restored to add an object to the running NetBeans instance where use of the module layer would suffice, nor to modify persistent state in restored or validate that might affect a future call to the same method. When possible it is best not to have a ModuleInstall at all.

Furthermore, the following practices should be avoided wherever possible in order to simplify installation of the module from Auto Update and via "ad-hoc" addition of the module JAR by a user (note that mentioning options here does not imply that they are officially supported by the APIs or even unofficially possible at any particular time):

  1. Including any libraries in the lib/ext/ directory, as these cannot be added to or reloaded while NetBeans is running.
  2. Using the docs/ directory as a place to store module JavaHelp rather than inside the JAR. (@HelpSetRegistration makes this obsolete anyway.)
  3. Using Class-Path from within the module JAR or its extensions to point to resources which are not in or below the directory containing the referring JAR (i.e. inclusion of ../ or absolute paths).
  4. Including any files in the NetBeans installation other than the module JAR in the modules/ directory and any extensions declared directly or indirectly via Class-Path beneath the modules/ directory (for example in modules/ext/) and any locale variants of the above JARs; except insofar as the presence of such files does not in and of itself change the functionality of NetBeans and is not required for the module to operate (for example mounts of documentation ZIPs declared in the layer); even then this is discouraged if there is an alternative as it complicates ad-hoc module installation though Auto Update may be fine.

Using an installation layer

You may specify the global tag OpenIDE-Module-Layer in addition to or instead of a module main class; as a rule, use a layer for a particular task in preference to a module installer, if you can. The tag value should point to an XML file inside the module which is in the format understood by XMLFileSystem. Its contents specify some files that the module will add to the system filesystem controlling much of NetBeans' configuration. This filesystem is composed of many read-only XML layer filesystems as well as a writable layer corresponding to the config subdirectory of the user directory.

For many APIs, there is no need to write a layer explicitly; layer-generating "registration" annotations do everything you need.

The XML format is relatively simple. There is an online DTD for it, but descriptively: the document element is <filesystem> and corresponds to the root folder; subfolders are represented with the <folder> element; and files within folders with the <file> element. Files and folders must have names, with the name attribute. Files need not specify contents, in which case they will be zero-length; or they may specify contents loaded from some other resource (url attribute, treated as relative to the base URL of the document itself); or for small textual contents, the contents may be included inline inside the element, typically using the CDATA syntax, though this usage is deprecated. Attributes may be specified on folders or files as empty <attr> elements; the name must be supplied, and the value in one of several formats: primitive types, strings, URLs, arbitrary serialized objects in hexadecimal, or computed on the fly by calling the default constructor of some class, or a static method (the method may be passed the file object in question and/or the attribute name, if you wish).

The primary advantage of using layers is that they are declarative rather than procedural, so you can install many kinds of extensions to NetBeans' behavior without any Java code, only XML. A related advantage is that unlike ModuleInstall, there is no need for multiple kinds of logic for module installation, restoration, uninstallation, and upgrading; the "files" added by the layer are not stored to disk and are loaded by NetBeans in every session from the XML, so when the module is uninstalled or upgraded its associated files are correctly removed or changed, respectively, without any extra work. (If the user customizes the files, however, their customizations are stored to disk, and thus form a permanent "patch" against the baseline configuration provided by the module.) Not all parts of NetBeans' configuration can be customized using files on the system filesystem and thus by layers, but many things can.

Some common things that layers tend to be used for:

  1. Install actions into NetBeans' global menus, toolbars, or keymap.
  2. Create templates in the folder Templates/.
  3. Other things such as bookmarks, Component Palette beans, Welcome panel buttons, and so on - according to the structure of the system filesystem.
  4. Most generally, to install arbitrary services into the system.

By default files listed in XML layers are not ordered in any particular way, just as files found on disk would not have a particular order. For purposes of some kinds of installation, it is desirable to order data objects in data folders in a particular way - for example, menus are built from their menu items in the order the instance-bearing data objects occur in the data folder. The call DataFolder.setOrder(DataObject[]) suffices to arbitrarily change folder order, but usually it is desirable to create the proper order declaratively in the XML. For this reason, DataFolder understands special attributes (set on the files in the folder) which order the objects in the folder. Specifically: if there are data objects A and B in the folder, represented by primary files afile and bfile, and afile has an attribute named position whose numeric value is less than the corresponding attribute on bfile, then the folder will attempt to place A before B in its ordering. For example, the XML:

<folder name="SomeFolder">
    <file name="first.txt" url="first.txt">
        <attr name="position" intvalue="100"/>
    <file name="second.txt" url="second.txt">
        <attr name="position" intvalue="200"/>
will cause NetBeans to try to keep first.txt before second.txt. Things to remember:
  1. If the user reorders the folder manually or DataFolder.setOrder(DataObject[]) is called, the explicit order overrides the existing positions. Subsequently added constraints might have an effect, however.
  2. Only the names of primary files from data objects have any bearing on the ordering.

There is also an older, now-deprecated system based on relative ordering attributes.

More details are available in FileUtil.getOrder.

The resource path pointing to the layer is automatically localized by NetBeans every time the module is installed or restored; if there are locale-specific variants, they are merged with the main layer. More-specific variants can simply add files to the set installed by the module; however they take precedence over the less-specific variants, and thus can replace files, or even remove (suppress) them, using *_hidden masks as used by MultiFileSystem. In fact, if module A depends on module B, then A's layer(s) will take precedence over B's layers, and it may replace or remove files installed by B. In the same way, any module may replace or remove files installed by the core.

Display-oriented file attributes

NetBeans recognizes several special file attributes, typically set in layers, which can control UI. For example, the labels of menus created from folders beneath Menu/ are derived from the "localized display name" of the layer folder, when defined. See FileSystem.getDecorator() (formerly getStatus())for details.

Reverting user's modifications

When a user makes any changes in the installation layer - usually through the user interface by changing the default values for some application options or any other customizations - it may be desirable to revert these changes back to their defaults as defined in XML layers. There changes are stored in user's working dir.

Since version 7.2 the FileObject supports a new attribute "removeWritable" returning an instance of Callable which removes the local writable version of the given FileObject thus reverting the folder or file to its initial state as defined in XML layers. Please note that is *not* possible to reset FileObject's attributes.

Using versioning

Module versioning provides a way for modules to specify which module they are (i.e. that one JAR is an upgrade from another); which version they are; whether they have introduced incompatible API changes since a previous version; and (importantly) whether they depend on other modules or system features, and if so how. While very simple modules may not require special versioning support, this system should be used for any module published on a general release schedule, or which it is expected other modules may want to make use of.

Modules can do three things with versioning:

  1. Specify what they are. This is done by the special OpenIDE-Module tag, whose value should be a unique (programmatic) identifier for the module, as mentioned above. Not be confused with the display name, which is free-form and may be changed at will, this code name should not be changed arbitrarily - pick a name and stick with it throughout module releases.
  2. Specify which version they are. In line with the Java Versioning Specification, modules can indicate two pieces of version information about themselves using the OpenIDE-Module-Specification-Version and the OpenIDE-Module-Implementation-Version tags. Modules are also permitted to use OpenIDE-Module-Build-Version to give information about when or by whom they were physically built, in case there is more specialized semantics given to the implementation version.
  3. Specify which features they depend on. Again, this is done using the Versioning Specification - modules can request general or specific versions of other modules (OpenIDE-Module-Module-Dependencies), Java packages (OpenIDE-Module-Package-Dependencies), or Java itself (OpenIDE-Module-Java-Dependencies).

    The tags OpenIDE-Module-Provides and OpenIDE-Module-Requires can also be used to specify dependencies between modules without naming the exact module to depend on. A module may provide one or more tokens. These are strings of conventional meaning, in the format of a Java package or class name - perhaps taken to be the name of a class which will be supplied to the lookup system, though there could be other meanings. A module may also require one or more tokens. A module which requires some tokens may only be enabled by the system if for each such token, there is at least one other module which provides that token and is already enabled. Since version 7.1 there is also support for OpenIDE-Module-Needs which is a weaker version of requires as it does not impose any restriction on the ordering of module. The OpenIDE-Module-Needs is useful for modules that define some API and require an implementation of it. Just specify the need for an implementation and make other modules depend on your module and OpenIDE-Module-Provides the implementation token. Moreover there is also OpenIDE-Module-Recommends which is even weaker version as it creates a conditional dependency - e.g. enables the module providing the token only if it is available, however if it is not, no dependency is broken.

At the heart of all these tags are the conventions used in the Package Versioning Specification. While this documentation should be referred to for the full details and justification of this system, the basic idea is that features (modules) have two significant version identifiers: a specification version, in Dewey-decimal format (e.g. 1.2.1), and an implementation version, which is some free-form text. Specification versions may be incremented to indicate compatible API extensions, in which case the check to make sure that the feature requested is available may be done using a (lexicographical) compare on the Dewey-decimal numbers (e.g. 1.0 < 1.0.1 < 1.1). Implementation versions may be requested according to an exact match only. Thus, specification versions are generally used when you depend on some general and specified behavior of another feature; implementation versions are used to tie builds of different features together closely, as when you maintain and release all the features yourself, and wish to distribute them in a well-tested unit.

(You may also specify a build version in your manifest, typically giving a date. This is used only for diagnostic purposes and is otherwise ignored by the module infrastructure.)

So, modules may specify either or both kinds of versions in their manifest, and correspondingly request such versions from other modules. (You may have at most one dependency between any single pair of modules, however.) The Versioning Specification provides similar numbering for (some, but not all) Java packages, as well as the core Java Platform APIs and Virtual Machine Specification. NetBeans also has such versions which may be used to request a general level of Open API support (using specification versions) or a particular NetBeans build (using implementation versions).

Since the Versioning Specification does not address incompatible changes (those which would break existing code), but these are in practice occasionally necessary (however painful), modules may provide a separate integral number giving the incompatible release version. You may only request a particular release version, not subsequent ones, and you must specify the release version if there is one when giving any module dependency. It only differs from a complete change of the feature in that the module installer tool may prompt the user to make a "major upgrade" if a new release version of a module is available.

Since 2.3 a module dependency may also use a range of release versions. The syntax is that in place of a single major release version, you give a minimum then maximum version separated by dashes:

OpenIDE-Module-Module-Dependencies: base.module/1-2 > 1.0

where the base module might either have the minimum major release version (and the given specification version or later, if that is also requested), or other major release versions up to the maximum (in which case the specification version is irrelevant). You may not ask for an implementation version with this syntax.

To use all of these tags once you understand them is not too hard. First of all, feature names: a module is named according to the OpenIDE-Module tag, which should look like a Java package name, but may be followed by a slash and release number (e.g. com.mycom.mymodule/3); Java packages are just named by the package name; the Java Platform APIs are named by Java; and the Java Virtual Machine by VM.

Now, a module may list its own specification and/or implementation versions using the tags above. To specify a dependency on other features, it may use some or all of the four dependency tags. The value of each will be a comma-separated list of dependencies of that general type, each of which can be of the form:

Just requests that the feature be present, not any particular version. Useful for modules and Java packages (usually, Java standard extensions) that need to be installed, but that is all. This style is also used for requiring tokens, which cannot have versions.
Requests that the feature be present, that it state a specification version, and that this version be greater than or equal to the requested version. Note that you may not request an exact specification version. This is the preferred form for module dependencies.

Remember, if requesting a dependency on a module which has a release number, you must give that release number as part of the feature name, whether or not you also ask for a specification version.

Requests that the feature be present, that it state an implementation version, and that this version exactly match the requested one. Note that you may not request a comparison on implementation versions, as they are generally non-numeric and not comparable.

In summary, here is an (unlikely) example that specifies and requests all sorts of versions:

OpenIDE-Module: com.mycom.mymodule/1
OpenIDE-Module-Specification-Version: 1.0.1
OpenIDE-Module-Implementation-Version: 1.0-release-g
 com.mycom.mysistermodule/1 = 1.0-release-g,
 com.othercom.anothermodule > 2.1,
 org.netbeans.modules.applet/1 > 1.0
OpenIDE-Module-Package-Dependencies: javax.television > 0.9
OpenIDE-Module-Java-Dependencies: Java = 1.2.1b4, VM > 1.0
OpenIDE-Module-Provides: javax.television.TunerProvider, javax.television.RemoteControl
OpenIDE-Module-Requires: org.netbeans.javahelp.api.Help

There is further special treatment for handling of package dependencies for several reasons:

  1. In practice, the Java Versioning Specification is not all that widely followed, and many needed extensions will not list this information in their manifest.
  2. Class loaders only define packages when the first class from that package is actually loaded. This makes it more difficult to verify whether a package is really there or not.
  3. The standard manifest attribute Class-Path must be recognized and used; typically this attribute is used to actually add extensions to the module classloader, while the Modules API attributes are used to ensure that specific versions are available.

You may specify a sample class name in square brackets immediately after the package name (or indeed instead of it). Giving a class name together with a package name requests that NetBeans first try to load that class (it must be able to, so choose a class in the extension you know will be there); then the versioning information is checked. (If the sample class is simply in the desired package, you may omit the package qualification as a shortcut.) This addresses the second problem. Giving just a class name in square brackets with no preceding package name indicates that NetBeans should only ensure that the named class is loadable, bypassing the Versioning specification mechanisms. This addresses the first problem.

Here then is a sample manifest which depends on an extension called again javax.television, where it is known that a class javax.television.TunerProvider is part of the package. The extension is stored in modules/ext/television.jar relative to the cluster directory:

OpenIDE-Module: com.mycom.mymodule/1
OpenIDE-Module-Package-Dependencies: javax.television[TunerProvider] > 0.9
Class-Path: ext/television.jar

Where can you get the version information to depend upon?

  1. For installed modules, this information is listed in the module's node in the Modules area under Session Settings. This includes information about provided tokens.
  2. For packages, use the Java Package class, or examine the manifest of the JAR you depend upon.
  3. For the Java platform, use the system properties java.specification.version and java.version; for the VM, java.vm.specification.version and java.vm.version.
  4. For NetBeans, this information is printed to the console during start-up, and also appears in var/log/messages.log.

Important! If your module has compile-time references to classes in another module, you must specify a direct dependency on that module using OpenIDE-Module-Module-Dependencies. This ensures that the modules will be installed in the correct order; otherwise a NoClassDefFoundError or similar problem could result.

Since 2.19 modules which provide Java-level APIs can specify that only certain packages in the module form part of the public API and should be accessible to other modules depending on that module. The tag OpenIDE-Module-Public-Packages is optional; if not present, all packages are considered fair game. If present, it gives a list of package names to export to other modules, for example:


indicates that only classes (and resources) in the package should be available to client modules. Attempts to use classes from other packages will fail, for example with a NoClassDefFoundError.

More than one package can be given; separate them with commas or spaces. A package name may end in .** rather than .* to indicate that any subpackages are also exported, rather than just the package itself. The special value - (a single dash) indicates that no packages are to be exported. (The module might still provide a non-Java-level API, for example by defining and handling a custom XML DTD.) "Private" classes and resources may still be accessed using reflection from the system classloader, just not from a module classloader.

Additionally, sometimes a module with an API in public packages wishes to provide access only to certain "friend" modules. This is possible if the module declares public packages together with a list of code base names of "friend" modules that can access them:


Only enumerated modules can access the public packages; access from others is forbidden.

Additionally, sometimes a module wishes to get unrestricted access to non-public packages of an API module. This is discouraged, but possible if such module declares a direct dependency on the API module using an implementation version dependency - this kind of dependency indicates that the client module is prepared to track every idiosyncrasy of the API module, and knows how to safely use undocumented classes, as if both modules formed part of the same code base.

Confused by all these restrictions on classloading? See the Class Path document which gives a fuller, more informal explanation.

Writing an OS dependent module

Since 4.44 a module can request to be enabled only on certain class of an operating system (see issue 46833). This is done by requesting a special token to be present and the system makes sure that these tokens are enabled only when NetBeans run on requested class of OS.

The tokens supported in version 4.44 are:

OpenIDE-Module-Requires: org.openide.modules.os.Windows
OpenIDE-Module-Requires: org.openide.modules.os.Unix
OpenIDE-Module-Requires: org.openide.modules.os.MacOSX
In version 6.3 additional tokens have been added:
OpenIDE-Module-Requires: org.openide.modules.os.OS2
OpenIDE-Module-Requires: org.openide.modules.os.PlainUnix    
Version 7.3 further added:
OpenIDE-Module-Requires: org.openide.modules.os.Linux
OpenIDE-Module-Requires: org.openide.modules.os.Solaris

Please note, that Mac OS X is in fact also Unix, so requesting Unix also enables your module on Mac OS X. If you want all unix types but Mac OS X you want to request PlainUnix token.

So if one wants a module to be automatically enabled on Mac OS X and silently disabled on other platforms the best way is to create an eager module which requests the MacOSX token and the module system takes care of enabling it only on Mac OS X (as is the case of the NetBeans applemenu module).

Localization and branding support

Existing Internationalization, Localization, and Branding documentation describes how IDE and platform is localized and general principles are valid for all modules.

Standard Module Sections

Formerly some items in NetBeans were installed via JAR manifest sections using the OpenIDE-Module-Class attribute. All such registrations are now deprecated, generally replaced with layer-based registrations.

Deployment of Modules

This section describes how a module may be deployed to a user's NetBeans instance.


The standard module system permits modules to be in several states, controlled by external configuration:

Regular modules are used when their functionality is somehow visible just by virtue of being enabled - typically because they make layer registrations. Since this functionality might or might not be wanted it is important for the user or deployer to retain control over the enablement status.

Autoload modules are used for libraries. If there is no "client" of the library, there is no purpose in loading its JAR at all. Only when some regular module requires it (directly, via tokens, etc.) will it be loaded.

Eager modules are often used for "bridges" between otherwise independent pieces of functionality, represented as regular modules. If both of those modules are enabled, the eager bridge will be as well, integrating them using some optional service. They may also be used as add-ons to regular modules distributed via other channels; or as platform-specific modules that will be enabled only according to operating system tokens.

Note that these enablement states are not intrinsic to the module, which is why they are not specified in the JAR; they are part of its deployment. Another module system might not make any use of such distinctions. In particular, modules deployed via JNLP or OSGi are simply enabled by virtue of being included in the deployment set, or at the mercy of the container.

Related Files

Sometimes a module may need to bundle other files besides the module JAR alongside it. No concrete mechanism for doing so is specified in the Modules API. However, if there is such a mechanism, then it is possible for the module to find these other files. InstalledFileLocator permits such packaging mechanisms to let modules find their associated files, as of 3.21.

In the current implementation, modules may be bundled with other files using NBM files as provided by Auto Update, and the NetBeans build process premerges modules in the selected module config into one large installation directory, accessible via several system properties. Correspondingly, the default locator finds files in this structure. The installation structure might however change in the future, so InstalledFileLocator is the only safe way to find such bundled resources.


Sometimes you may have an API module which you wish to deprecate in its entirely - it is only available for purposes of backwards compatibility. Normally such modules are autoloads. To ensure that remaining clients of the module are properly warned of its status, you may specify the manifest attribute OpenIDE-Module-Deprecated with the value true. Generally you should also supply a message using the localized manifest attribute OpenIDE-Module-Deprecation-Message. This message may be displayed somehow if a non-deprecated module depending on your deprecated module is enabled.


Sometimes as the developer of an API module, you may wish to make major changes in how your APIs are laid out physically in modules. Most commonly, you determine that it would be desirable to split one big API module into several smaller pieces. However you wish to retain compatibility for existing client modules, so that if they used your old monolithic module, they will now automatically get access to the newer, smaller pieces.

This is straightforward: create an XML file according to the DTD -//NetBeans//DTD Module Automatic Dependencies 1.0//EN and install it in the system filesystem under ModuleAutoDeps/ (system/ModuleAutoDeps/*.xml). Note that it will probably not work to do this using an XML layer since the information must be available before any module is even loaded.

As of 3.33

Module install order

It may be possible for multiple modules to be installed at once, or for a module to specify a dependency which is not satisfied. How does NetBeans handle such cases?

First of all, when NetBeans starts up, all previously-installed modules are restored, calling the restored methods on their install classes if present. (Sections are installed before this method is called.) If multiple modules are being restored (which is normally the case), NetBeans installs them in an arbitrary order. However, if some of them specify dependencies on other modules, the order may be adjusted so as to make sure that the one specifying the dependency is installed after the one it depends on.

Now, when NetBeans is running, modules may be installed into it, possibly a cluster of them at once. In such a case, NetBeans first checks to make sure that all the prospective modules satisfy their dependencies, either on system or Java features; already-installed modules; or other modules in the prospective cluster. If any modules fail their dependencies (or had syntactical errors in their manifest files, etc.), they are removed from the list and the user is given an explanation of what is missing. The remainder are then ordered according to dependencies as above, and then installed in that order.

Caution: it is forbidden to install modules which have cyclic dependencies on one another, as NetBeans would be unable to determine which order to install them in! In fact, it will signal an error and not install such modules. Generally such a situation means that you should "factor out" the common required functionality into a new module which the original ones will then specify legal dependencies on.

List of all modules

Though a module should not generally need to know or care what other modules are installed - anything it needs should be a dependency, and anything which can use it, it should not know about - in a few cases it is desirable to obtain the list of all modules in the system. This can be easily accomplished as follows:
Collection<ModuleInfo> modules = Lookup.getDefault().lookupAll(ModuleInfo.class);
The resulting ModuleInfo objects give basic information about known modules (both enabled and disabled), such as their names and versioning information, and current enablement status. This API is strictly read-only and informational.

A limited ability to modify the installation status of modules is provided by the APIs as of version 1.31. In the folder Modules/ on the system filesystem, there will be XML files corresponding to all known modules. In each case the name of the XML file is derived from the code name base of the module with . replaced by -, and followed by .xml; for example, org-netbeans-modules-properties.xml. The contents of the XML file are given by a fixed DTD.

For purposes of the API, only parts of these files are defined. The root element must be <module> and its name attribute must be the code name base of the module. Inside the root element are various <param> elements, each with a name and some textual contents. The APIs define only one parameter, enabled, which if present must be either true or false.

Autoload (and eager) modules do not use the enabled parameter, since their enablement status can never be specified directly. Rather, they are marked with a parameter named autoload (resp. eager) with the value true.

The APIs do not currently permit arbitrary changes to these files. Specifically, addition or deletion of these files, or modification of other files that may be in the same folder, is not permitted. Modification of these files is permitted in only one way: if a module XML file already contains the parameter enabled, you may rewrite the file to be identical except with the opposite value of this parameter. The module system will then make a best effort to enable or disable the module accordingly (subject to dependencies and other constraints).

Doing this is not recommended except in unusual circumstances, and is intended primarily for session support to be able to enable and disable modules via layer. If your module just needs to prevent itself from being turned on under some circumstances (for example if it is missing a valid license key), simply use ModuleInstall.validate.

When rewriting the module XML be sure to use FileSystem.runAtomic(FileSystem.AtomicAction) to wrap the reading of the old XML and the writing of the new, to prevent file changes from being fired halfway through.

Like any file in the system filesystem, these configuration files are loaded from the config/ subdirectory of all registered clusters including the user directory plus XML layers. Normally a module's config file is simply bundled with its installation and that is what is used; user-initiated changes are stored in the user directory. But clusters can also override configuration from other clusters, for example. And the presence of a Modules/*.xml_hidden mask file will suppress knowledge of the existence of a module from the system (not just disable it).


In the current API there is no particular provision for security in modules: all modules are assumed to be trusted, and have access to all NetBeans' features (including the abilities of the Java VM running as an application) if they require them. So, users should not install arbitrary modules from potentially dangerous sources. Given the density of callbacks and the fine-grained object model of the APIs, providing a thread-based security model for API code is not feasible.

Code which creates new classloaders and loads other code indirectly should, however, be aware that the created classloaders are generally subject to regular security restrictions, unless code is loaded from within the NetBeans installation, or certain forms of NbClassLoader are used. When in doubt, explicitly define the protection domains for classloaders you create.

NetBeans currently loads each module in its own classloader, which means illegal dependencies between modules will result in errors.

The Update Center supports certificate-based signing of downloaded modules, so that the user can be sure that the contents have not been tampered with or accidentally corrupted since their creation.


It is possible to run modules making use of JNI native implementations inside NetBeans. You may place the native libraries (DLL or shared-object) beneath a modules/lib directory (i.e. a subdirectory lib/ beneath the directory where the module JAR resides). If your native library file names for different architectures or operating systems clash, you may create subdirectories under modules/lib for each supported platform and nested subdirectories for each supported operating system. The directory names must match System.getProperty("os.arch") and System.getProperty("").toLowerCase(Locale.ENGLISH) respectively. The System.loadLibrary call originating from the module code will try to locate the library file in the following order of directories:

so you may place e.g. 64-bit Linux version of a foo library in a file modules/lib/amd64/linux/ The module may distinguish additional library variants itself or even override the platform selection logic by naming the library file appropriately and calling System.loadLibrary with such a name. Use of JNI is of course not recommended and should be restricted to cases where it is unavoidable.

Example of usage with a fully specified library name: if on Linux a module located in /home/app/cluster/modules/something.jar calls System.loadLibrary("stuff-linux-i386-gnome"), the library should be in /home/app/cluster/modules/lib/ On 64bit Windows, if C:\app\cluster\modules\something.jar calls System.loadLibrary("stuff"), the library should be in C:\app\cluster\modules\lib\amd64\stuff.dll. (Remember that Java has platform-specific prefixes and suffixes it adds to plain library names before trying to find it on disk.)

If a native library refers to other native libraries, they are likely to be found using the normal search path for the platform. This may mean that if you have several libraries used in a module, you must either put all but the directly referenced one in the system's global library search path, or merge them all together.

Warning: since the JVM cannot load the same native library twice even in different classloaders, a module making use of this feature cannot be enabled more than once in a single VM session. JARs loaded from the classpath (application classloader) are never reloaded, so it may be possible to include the native-dependent classes in such a JAR and make use of it from a module JAR.

NetBeans currently includes a JNA wrapper module which can also be used for native access. As of this writing, however, this module exports only a friend API, so it is not available for use from arbitrary modules.