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Virgo/Concepts

Artifacts

Virgo supports the deployment of various types of artifacts. Standard artifact types are:

  • bundle - an OSGi bundle.
  • configuration - a properties file with name of the form <pid>.properties which when deployed produces a Configuration Admin dictionary with PID <pid>.
  • plan - an XML file which refers to arbitrary other artifacts in the Virgo repository. Plans may be scoped or unscoped, as described below, and atomic or non-atomic in terms of whether the lifecycle of the plan is tied to the lifecycle of the plan's artifacts.
  • PAR - a Plan ARchive which contains a collection of artifacts and is equivalent to a scoped, atomic plan referencing those artifacts (except the artifacts need not be present in the Virgo repository).

In addition, it is possible to add user defined artifact types.

Kernel

The Virgo kernel is the core runtime which may be used on its own or to deploy one or more server types and applications for those server types. The kernel houses the deployment pipeline, described below, as well as support for common artifact types (bundle, configuration, plan, and PAR), regions, scoping, and other core Virgo features.

Currently, for example, the Virgo web server packaging build uses the kernel to deploy a web server plan which includes the Gemini web container and the Virgo web bundle (which integrates Gemini web into Virgo).

The startup scripts launch the kernel which then installs, and optionally starts, each of a configurable collection of bundles to provide kernel function. The kernel bundles are located in lib/kernel and are referenced by the launcher.bundles property in the configuration file lib/org.eclipse.virgo.kernel.launch.properties. This property specifies a list of bundles, which is transitively closed with respect to dependencies, and specifies which of these bundles are started after all the bundles in the list are installed.

The following properties may be specified in the kernel launch properties configuration file (lib/org.eclipse.virgo.kernel.launch.properties):

Kernel Launch Properties
Property name Definition Default value
launcher.bundles Comma separate list of bundles to be installed in the kernel region. The list must be transitively closed with respect to non-optional dependencies. Each item in the list is a "file:" URL optionally followed by "@start" if the bundle is to be started. None.
org.eclipse.virgo.kernel.config The file path, relative to the current working directory, of the directory containing kernel configuration files. config
org.eclipse.virgo.medic.log.config.path The file path, relative to the current working directory, of the medic serviceability configuration file, typically named serviceability.xml None.

See also the standard OSGi and Equinox framework properties that may be specified in the kernel launch properties configuration file.

Regions

The kernel uses the nested framework support in Equinox to isolate the kernel from application artifacts, including artifacts which implement servers. The Equinox support is being standardised, with some changes, in OSGi. As shown in the figure below, the kernel starts in a normal OSGi framework, known as the kernel region, and then creates a nested framework known as the user region.

Virgo regions.png

Region support was added to enable applications to run with a different version of Spring than that used by the kernel. A minimal set of Spring bundles is installed into the kernel region with very few optional dependencies which keeps the kernel footprint and startup time low. In principle, Spring could be entirely removed from the kernel region if the kernel was modified not to depend on Spring (most of these dependencies are because the kernel uses Spring DM to publish and find kernel services).

Certain packages and services are imported from the kernel region into the user region and certain services, but no packages, are exported from the user region to the kernel region. This isolates the kernel region from interference due to types and package wirings in the user region. The configuration file config/org.eclipse.virgo.kernel.userregion.properties controls the importing of packages and services into and the exporting of services out of the user region.

The content of the kernel region is controlled by the configuration file lib/org.eclipse.virgo.kernel.launch.properties.

So, apart from the basic principle that no packages are exported from the user region to the kernel region, there is a lot of flexibility for changing the contents of both kernel and user regions and for specifying which packages and services are shared between the regions.

In future, Virgo could be extended to support multiple user regions in order to isolate applications from each other.

Scoping

Virgo adds the concept of scoping to OSGi. The main use case for scoping is where a group of bundles form an application which needs to avoid clashing with other applications and which needs reliable behaviour when it calls third party bundles which use thread context class loading. Clashes can occur because of bundles, packages, or services conflicting in some way.

Metadata Rewriting

Virgo rewrites the metadata of bundles in a scope to prefix the bundle symbolic names with a scope-specific prefix and to add a mandatory matching attribute, with a scope-specific value, to packages exported by bundles in the scope.

Virgo also uses the standard OSGi service registry hooks to limit the visibility of services published by bundles in a scope.

However, a bundle in a scope may access bundles, packages, and services not provided in the scope but which are available outside the scope, that is from unscoped bundles. So a scope acts similarly to a programming language scope such as Java's curly braces:

int x;
// b is not visible here
{
    int b;
    // both b and x are visible here
}

Synthetic Context Generation

To ensure reliable thread context class loading when third party bundles are called from a scope, Virgo generates a synthetic context bundle in the scope. The class loader of the synthetic context bundle is used as the thread context class loader when bundles in the scope make calls outside the scope. The synthetic bundle imports each of the other bundles in the scope using the Virgo import-bundle header. This is semantically equivalent to importing all the exported packages of the other bundles in the scope. So to make a package of a scoped application available for thread context class loading, it is simply necessary to export the package.

Example of Scoping

The figure below shows a scoped plan referring to two bundles A and B being deployed. The result is a scope containing the bundles A and B as well as the synthetic context bundle. Note that bundles inside the scope can access bundles, such as X, outside the scope. Also, bundles outside the scope, such as Y, cannot access bundles inside the scope.

Virgo scoping.png

Pipeline

Artifacts are deployed into Virgo using a deployment pipeline consisting of several pipeline stages some of which have pipelines nested inside them as shown in the figure below.

Virgo Pipeline Stages.png

The pipeline, and each pipeline stage, accepts a tree of install artifacts as input and outputs a possibly modified tree. The deployment pipeline is constructed by the Plumber class.

Transformers

Many of the interesting modifications to the tree are performed by the transform stage which uses the whiteboard pattern to drive all services of a Transformer type in order of service ranking. A number of standard Transformer services are defined in the Spring context file deployer-context.xml in the kernel's deployer bundle. Some interesting examples of standard Transformers are:

  • PlanResolver which takes as input a tree consisting of a single plan node and adds a subtree representing the content of the plan, including any nested plans and their subtrees,
  • ScopingTransformer which rewrites the metadata of a subtree rooted in a scoped plan and gathers service scoping information for the subtree,
  • SyntheticContextBundleCreatingTransformer which adds a synthetic context bundle as a child node of a scoped plan, and
  • ImportExpandingTransformer which converts Virgo-specific headers such as import-bundle into standard OSGi import-package statements.

Quasi Framework

The quasi framework is an abstraction of the Equinox State and is used in auto-provisioning missing dependencies during deployment. The quasiInstall stage installs the bundles in the input tree into an instance of the quasi framework. The quasiResolve stage attempts to resolve these bundles and auto-provision any missing dependencies from the Virgo repository by installing them in the quasi framework instance. The commit stage attempts to install the bundles in the input tree, along with any auto-provisioned bundles, into the OSGi framework.

Exception Handling

There are two approaches to handling exceptions thrown by a pipeline stage. In general, unexpected exceptions are allowed to percolate upward and result in diagnostics and a failed deployment. However, certain expected exceptions, such as failure to resolve the dependencies of the install artifact tree, need to be handled more gracefully. In these cases, a compensating pipeline stage is defined which drives a compensation stage if an exception is thrown. failInstall and failResolve in the figure above are examples of compensation stages.


Repositories

Virgo repositories contain artifact URLs and metadata and are indexed by the Cartesian product of artifact type, name, and version. There are three kinds of repository: external, watched, and remote. Repositories are passive in the sense that changes to repository content do not cause artifacts to be deployed into Virgo, refreshed, or undeployed. Repositories support queries which allow sets of artifacts satisfying certain criteria, for example with a version in a given version range, to be determined.

External Repositories

External repositories are created by scanning a directory which contains artifacts, possibly in nested directories. The repository configuration specifies a pattern which says which files should be treated as artifacts. After the repository is created, changes to the directory do not affect the repository content.

The Virgo kernel's default repository configuration, in config/org.eclipse.virgo.repository.properties,  specifies an external repository created from the repository/ext directory.

Watched Repositories

Watched repositories are created by scanning a directory which contains artifacts but no nested directories. All files in the directory are treated as artifacts. The directory is re-scanned periodically and the interval between re-scans is specified in the repository configuration. Changes detected by re-scanning are reflected in the repository content. Note that changing the content of a watched repository does not cause artifacts to be deployed into Virgo, refreshed, or undeployed.

The Virgo kernel's default repository configuration specifies a watched repository based on the contents of the repository/usr directory.

Remote Repositories

A remote repository refers to a repository hosted by a Virgo instance sometimes known as a repository server. The hosted repository is configured using the file config/org.eclipse.virgo.apps.repository.properties and may be either an external or a watched repository.

The remote repository is accessed by a Virgo instance sometimes known as a repository client. The repository client is normally a different instance of Virgo to the instance hosting the repository, but it can be the same instance which is handy for testing. The remote repository periodically downloads its content from the hosted repository. The period between downloads may be configured in the repository configuration. The remote repository also caches artifacts which have secure hashes associated with them in the hosted repository. Only bundles currently have secure hashes associated with them. The secure hash is used to determine when a cached artifact is stale and needs to be freshly downloaded.

Repository Chains

The Virgo repository is configured as a chain of external, watched, and remote repositories. The chain is a list which is searched in the configured order. The effect of this search order is that an artifact with a given type, name, and version which appears in more than one repository in the chain is only accessed from the first repository in the chain in which it appears. Abstractly, the repository chain behaves as a single repository, but its content may mutate in quite a different way to the content of an individual external, watched, or remote repository.

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