This page describes an older version of the product. The latest stable version is 16.4.

Running and Debugging Within Your IDE

As part of your development process, you may want to run/debug your processing unit within your IDE, or create unit tests (with JUnit for example) to tests in isolation certain aspects of it.

The Integrated processing unit container allows you to run a processing unit within such “embedded” environment. It’s implementation class is IntegratedProcessingUnitContainer.

The Integrated Processing Unit Container is built around Spring’s ApplicationContext with several extensions relevant to GigaSpaces, such as ClusterInfo.

The Integrated Processing Unit Container runs directly in your IDE using its main() method, or can be started by another class in your code by using the ProcessingUnitContainerProvider abstraction.

Executable IntegratedProcessingUnitContainer

The IntegratedProcessingUnitContainer class provides an executable main() method, allowing the IDE to run it directly via a simple Java application configuration. The main() method uses the IntegratedProcessingUnitContainerProvider class and program arguments in order to create the IntegratedProcessingUnitContainer. The following is a list of all the possible program arguments that can be specified to the IntegratedProcessingUnitContainer:

Option Description
-config [configLocation] Allows you to set/add a processing unit deployment descriptor location.
Follows the Spring Resource Loader including ant style patterns. This parameter can be specified multiple times.
The default is classpath*:/META-INF/spring/pu.xml.
-cluster [cluster options] Allows you to control the ClusterInfo injected into the container and the runtime topology
of the processing unit (Note that the integrated processing unit container can run multiple processing
unit instances in the same JVM to more accurately emulate the behavior of the actual runtime environment).
The following options are available (they are used automatically by any embedded space included
in the processing unit):
* schema - the cluster schema used by the processing unit. Possible values are sync_replicated, async_replicated and partitioned-sync2backup
* total_members - Determines the total members in the emulated cluster. Format is numberOfInstances[,numberOfBackups], e.g. total_members=2,1
* id – If you want the container to run a single processing unit instance, use this parameter. It will force the container to run one instance and will determines the instance ID of that instance.
* backup_id – If you want the container to run a single processing unit instance, use this parameter in conjunction with the id parameter. It will force the container to run one instance and will determines the backup ID of that instance.
-properties [property file location] Allows you to inject properties to the processing unit at deployment time.
-properties embed://[property1 name]=
[property1 value];
[property2 name]=
[property2 value]
Allows you to directly inject properties to the processing unit at startup time.


To run a clustered PU with an embedded space with 2 partitions and a backup for each partition , having a separate eclipse configuration (and a hosting JVM) for each cluster member , have 3 run configuration each have the following:

-cluster schema=partitioned-sync2backup total_members=2,1 id=1
-cluster schema=partitioned-sync2backup total_members=2,1 id=2
-cluster schema=partitioned-sync2backup total_members=2,1 backup_id=1 id=1
-cluster schema=partitioned-sync2backup total_members=2,1 backup_id=1 id=2

Start these using the order above. The first 2 will be primary members and the other two will be backup members. You can terminate any of the primary instances to test failover scenario.

You can run the Integrated Processing Unit Container without actually specifying the instance id (and backup id). In this case, the container will automatically start all the relevant instances that form a complete cluster based on the _totalmembers parameter provided.

Using IntegratedProcessingUnitContainer in the IDE

The main usage of the IntegratedProcessingUnitContainer is to execute processing units in your IDE. The following screenshot displays the Create, manage, and run configurations Eclipse dialog for executing the processor processing unit of the data example:


In the screenshot above, we run the data processor module using the integrated processing unit container from within the Eclipse IDE (we simply imported the Eclipse project provided with the example into our Eclipse workspace). There are no arguments provided in this example, which means that the integrated processing unit container will use its defaults. Since our project source includes a META-INF/spring/pu.xml file, it is automatically detected by the IntegratedProcessingUnitContainer class and used as the processing unit’s deployment descriptor (since it’s part of the processor module’s classpath). The processor Eclipse project also has all the required libraries in its project definition. These include all the jars located under the XAP root>/lib/required directory, namely gs-openspaces.jar, gs-runtime.jar, commons-logging.jar and the Spring framework jars (all start with com.spring*), so the integrated processing unit container is running with these libraries.

Classpath Settings of the IntegratedProcessingUnitContainer

The IntegratedProcessingUnitContainer is a simple class that wraps the processing unit with Spring application context and makes all the proper initializations around it. Note that as with any other code you run within your IDE, you will have to manually include the classes your processing unit code depends on in your project classpath. In contrast, when running your processing unit on the GigaSpaces service grid or in standalone mode, all of the jars located under the processing unit’s lib directory are automatically added to the classpath and GigaSpaces specific jar files (gs-runtime.jar and gs-openspaces.jar are added automatically).

The following screenshot shows how to run a data processor instance with a partitioned cluster schema and ID 1, and the arguments that should provided in this configuration:


Using Lookup Groups/Locators

You can isolate your environment by defining Lookup Groups/Locators. You can set lookup groups/locators in your IDE run configuration using system variables as VM arguments. If you have LOOKUPGROUPS/LOOKUPLOCATORS OS environment variables, you can use their values for the system variables. For example, to set lookup groups in Eclipse IDE using LOOKUPGROUPS environment variable you need to add the following as VM argument to the run configuration:${env_var:LOOKUPGROUPS}

To set the lookup locators:${env_var:LOOKUPLOCATORS}

Starting an IntegratedProcessingUnitContainer Programmatically

The integrated processing unit container can be created programmatically using the IntegratedProcessingUnitContainerProvider class. This is very useful when writing unit and integration tests (though Spring’s own mock library can also be used for testing using pure Spring application context).

Here is an example of using a IntegratedProcessingUnitContainerProvider in order to create one:

IntegratedProcessingUnitContainerProvider provider = new IntegratedProcessingUnitContainerProvider();
// provide cluster information for the specific PU instance
ClusterInfo clusterInfo = new ClusterInfo();

// set the config location (override the default one - classpath:/META-INF/spring/pu.xml)

// Build the Spring application context and "start" it
ProcessingUnitContainer container = provider.createContainer();

// ...


When using a cluster and not specifying an instance Id (see setInstanceId()), the createContainer() method will return a CompoundProcessingUnitContainer filled with processing unit containers (IntegratedProcessingUnitContainer) for each instance in the cluster.

Remote Debugging

The Java Debugger

The Java Debugger (jdb) is a dynamic, controlled, assignment-based debugging tool. It helps find and fix bugs in the Java language programs both locally and on the server. To use jdb in a Java application you must first launch it with debugging enabled and attach to the Java process from the debugger through a JPDA port (Default port is 1044).

The default JPDA options for Java applications are as follows:

-Xdebug -Xnoagent -Xrunjdwp:transport=dt_socket,server=y,suspend=y,address=8000

The jdb parameters specify the way the debugger will operate. For instance transport=dt_socket instructs the JVM that the debugger connections will be made through a socket while the address=1044 parameter informs it that the port number will be 1044. Similarly, if you substitute suspend=y , the JVM starts in suspended mode and stays suspended until a debugger is attached to it. This may be helpful if you want to start debugging as soon as the JVM starts.

Debugging Your Application

Debugging your application running within the GSC is no different than debugging any other Java application. Make sure you launch the GSC with the required debugging arguments and attach a debugger. You should use the GSC or gsc.bat startup script found within the XAP root/bin/ by extracting it from the zip file and place it within the XAP root/bin folder. It should be started in debug mode.

Step 1

Start an agent and deploy your PU as usual. The agent will start GSCs in non-debug mode.

Step 2

Start a command window and set IDE_REMOTE_DEBUG and the GSC_JAVA_OPTIONS variables:

export IDE_REMOTE_DEBUG="-Xdebug -Xnoagent -Xrunjdwp:transport=dt_socket,server=y,suspend=y"
set IDE_REMOTE_DEBUG=-Xdebug -Xnoagent -Xrunjdwp:transport=dt_socket,server=y,suspend=y

If you would like to specify a specific listening port, use the address parameter:

set IDE_REMOTE_DEBUG=-Xdebug -Xnoagent -Xrunjdwp:transport=dt_socket,server=y,suspend=y,address=8000

Step 3

Start a GSC in debug mode:


If you have started the agent with a specific zone, have the GSC running in debug mode to use the same zone as well:


Make sure you see the Listening for transport dt_socket at address message:


Listening for transport dt_socket at address: 8000

Make sure you identify the process id of the newly started GSC. You will need it in step 7.

Step 4

Open your eclipse and setup a remote debug configuration:


Place the right host name and port where the GSC in debug mode been started.

Step 5

Set a break point.

Step 6

Click the Debug button. The IDE will connect to the GSC.

Step 7

Move a running PU instance to the newly started GSC. Use the GS-UI Hosts tab to move the PU instance by dragging and dropping the PU instance from its existing GSC to the newly started GSC running in debug mode. You can identify the GSC running in debug mode using its process id.


The debugger will stop at the specified break point once the relevant method will be triggered.