Introduction and getting started with jBPM
Table of Contents
jBPM is a flexible Business Process Management (BPM) Suite. It is light-weight, fully open-source (distributed under Apache license) and written in Java. It allows you to model, execute, and monitor business processes throughout their life cycle.
A business process allows you to model your business goals by describing the steps that need to be executed to achieve those goals, and the order of those goals are depicted using a flow chart. This process greatly improves the visibility and agility of your business logic. jBPM focuses on executable business processes, which are business processes that contain enough detail so they can actually be executed on a BPM engine. Executable business processes bridge the gap between business users and developers as they are higher-level and use domain-specific concepts that are understood by business users but can also be executed directly.
Business processes need to be supported throughout their entire life cycle: authoring, deployment, process management and task lists, and dashboards and reporting.
The core of jBPM is a light-weight, extensible workflow engine written in pure Java that allows you to execute business processes using the latest BPMN 2.0 specification. It can run in any Java environment, embedded in your application or as a service.
On top of the core engine, a lot of features and tools are offered to support business processes throughout their entire life cycle:
BPM creates the bridge between business analysts, developers and end users by offering process management features and tools in a way that both business users and developers like. Domain-specific nodes can be plugged into the palette, making the processes more easily understood by business users.
jBPM supports adaptive and dynamic processes that require flexibility to model complex, real-life situations that cannot easily be described using a rigid process. We bring control back to the end users by allowing them to control which parts of the process should be executed; this allows dynamic deviation from the process.
jBPM is not just an isolated process engine. Complex business logic can be modeled as a combination of business processes with business rules and complex event processing. jBPM can be combined with the Drools project to support one unified environment that integrates these paradigms where you model your business logic as a combination of processes, rules and events.
This figure gives an overview of the different components of the jBPM project.
Each of the components are described in more detail below.
The core jBPM engine is the heart of the project. It's a light-weight workflow engine that executes your business processes. It can be embedded as part of your application or deployed as a service (possibly on the cloud). Its most important features are the following:
The core engine can also be integrated with a few other (independent) core services:
The web-based designer allows you to model your business processes in a web-based environment. It is targeted towards business users and offers a graphical editor for viewing and editing your business processes (using drag and drop), similar to the Eclipse plugin. It supports round-tripping between the Eclipse editor and the web-based designer. It also supports simulation of processes.
Processes almost always have some kind of data to work with. The data modeler allows non-technical users to view, edit or create these data models.
Typically, a business process analyst or data analyst will capture the requirements for a process or application and turn these into a formal set of interrelated data structures. The new Data Modeler tool provides an easy, straightforward and visual aid for building both logical and physical data models, without the need for advanced development skills or explicit coding. The data modelers is transparently integrate into the workbench. Its main goals are to make data models into first class citizens in the process improvement cycle and allow for full process automation through the integrated use of data structures (and the forms that will be used to interact with them).
The jBPM Form Modeler is a form engine and editor that enables users to create forms to capture and display information during process or task execution, without needing any coding or template markup skills.
It provides a WYSIWYG environment to model forms that it's easy to use for less technical users.
Key features:
Form Modeling WYSIWYG UI for forms
Form autogeneration from data model / Java objects
Data binding for Java objects
Formula and expressions
Customized forms layouts
Forms embedding
The form modeler's user interfaces is aimed both at process analyst and developers for building and testing forms.
Developers or advanced used will also have some advanced features to customize form behavior and look&feel.
Business processes can be managed through a web-based management console. It is targeted towards business users and its main features are the following:
As of version 6.0, jBPM comes with a full-featured BAM tooling which allows non-technical users to visually compose business dashboards. With this brand new module, to develop business activity monitoring and reporting solutions on top of jBPM has never been so easy!
Key features:
Visual configuration of dashboards (Drag'n'drop).
Graphical representation of KPIs (Key Performance Indicators).
Configuration of interactive report tables.
Data export to Excel and CSV format.
Filtering and search, both in-memory or SQL based.
Data extraction from external systems, through different protocols.
Granular access control for different user profiles.
Look'n'feel customization tools.
Pluggable chart library architecture.
Chart libraries provided: NVD3 & OFC2.
Target users:
Managers / Business owners. Consumer of dashboards and reports.
IT / System architects. Connectivity and data extraction.
Analysts. Dashboard composition & configuration.
To get further information about the new and noteworthy BAM capabilities of jBPM please read the chapter Business Activity Monitoring.
The workbench is the web-based application that combines all of the above web-based tools into one configurable solution.
It supports the following:
Workbench application covers complete life cycle of BPM projects starting at authoring phase, going through implementation, execution and monitoring.
The Eclipse-based tools are a set of plugins to the Eclipse IDE and allow you to integrate your business processes in your development environment. It is targeted towards developers and has some wizards to get started, a graphical editor for creating your business processes (using drag and drop) and a lot of advanced testing and debugging capabilities.
It includes the following features:
All releases can be downloaded from SourceForge. Select the version you want to download and then select which artifact you want:
bin: all the jBPM binaries (JARs) and their dependencies
src: the sources of the core components
docs: the documentation
examples: some jBPM examples, can be imported into Eclipse
installer: the jbpm-installer, downloads and installs a demo setup of jBPM
installer-full: the jbpm-installer, downloads and installs a demo setup of jBPM, already contains a number of dependencies prepackages (so they don't need to be downloaded separately)
If you like to take a quick tutorial that will guide you through most of the components using a simple example, take a look at the Installer chapter. This will teach you how to download and use the installer to create a demo setup, including most of the components. It uses a simple example to guide you through the most important features. Screencasts are available to help you out as well.
If you like to read more information first, the following chapters first focus on the core engine (API, BPMN 2.0, etc.). Further chapters will then describe the other components and other more complex topics like domain-specific processes, flexible processes, etc. After reading the core chapters, you should be able to jump to other chapters that you might find interesting.
You can also start playing around with some examples that are offered in a separate download. Check out the examples chapter to see how to start playing with these.
After reading through these chapters, you should be ready to start creating your own processes and integrate the engine with your application. These processes can be started from the installer or be started from scratch.
Here are a lot of useful links part of the jBPM community:
A feed of blog entries related to jBPM
A user forum for asking questions and giving answers
A JIRA bug tracking system for bugs, feature requests and roadmap
A continuous build server for getting the latest snapshots
Please feel free to join us in our IRC channel at chat.freenode.net #jbpm. This is where most of the real-time discussion about the project takes place and where you can find most of the developers most of their time as well. Don't have an IRC client installed? Simply go to http://webchat.freenode.net/, input your desired nickname, and specify #jbpm. Then click login to join the fun.
The jBPM code itself is using the Apache License v2.0.
Some other components we integrate with have their own license:
The new Eclipse BPMN2 plugin is Eclipse Public License (EPL) v1.0.
The web-based designer is based on Oryx/Wapama and is MIT License
The Drools project is Apache License v2.0.
jBPM now uses git for its source code version control system. The sources of the jBPM project can be found here (including all releases starting from jBPM 5.0-CR1):
https://github.com/droolsjbpm/jbpm
The source of some of the other components we integrate with can be found here:
If you're interested in building the source code, contributing, releasing, etc. make sure to read this README.
We are often asked "How do I get involved". Luckily the answer is simple, just write some code and submit it :) There are no hoops you have to jump through or secret handshakes. We have a very minimal "overhead" that we do request to allow for scalable project development. Below we provide a general overview of the tools and "workflow" we request, along with some general advice.
If you contribute some good work, don't forget to blog about it :)
Signing to jboss.org will give you access to the JBoss wiki, forums and JIRA. Go to http://www.jboss.org/ and click "Register".
The only form you need to sign is the contributor agreement, which is fully automated via the web. As the image below says "This establishes the terms and conditions for your contributions and ensures that source code can be licensed appropriately"
To be able to interact with the core development team you will need to use JIRA, the issue tracker. This ensures that all requests are logged and allocated to a release schedule and all discussions captured in one place. Bug reports, bug fixes, feature requests and feature submissions should all go here. General questions should be undertaken at the mailing lists.
Minor code submissions, like format or documentation fixes do not need an associated JIRA issue created.
https://issues.jboss.org/browse/JBRULES (Drools)
With the contributor agreement signed and your requests submitted to JIRA you should now be ready to code :) Create a GitHub account and fork any of the Drools, jBPM or Guvnor repositories. The fork will create a copy in your own GitHub space which you can work on at your own pace. If you make a mistake, don't worry blow it away and fork again. Note each GitHub repository provides you the clone (checkout) URL, GitHub will provide you URLs specific to your fork.
When writing tests, try and keep them minimal and self contained. We prefer to keep the DRL fragments within the test, as it makes for quicker reviewing. If their are a large number of rules then using a String is not practical so then by all means place them in separate DRL files instead to be loaded from the classpath. If your tests need to use a model, please try to use those that already exist for other unit tests; such as Person, Cheese or Order. If no classes exist that have the fields you need, try and update fields of existing classes before adding a new class.
There are a vast number of tests to look over to get an idea, MiscTest is a good place to start.
When you commit, make sure you use the correct conventions. The commit must start with the JIRA issue id, such as JBRULES-220. This ensures the commits are cross referenced via JIRA, so we can see all commits for a given issue in the same place. After the id the title of the issue should come next. Then use a newline, indented with a dash, to provide additional information related to this commit. Use an additional new line and dash for each separate point you wish to make. You may add additional JIRA cross references to the same commit, if it's appropriate. In general try to avoid combining unrelated issues in the same commit.
Don't forget to rebase your local fork from the original master and then push your commits back to your fork.
With your code rebased from original master and pushed to your personal GitHub area, you can now submit your work as a pull request. If you look at the top of the page in GitHub for your work area their will be a "Pull Request" button. Selecting this will then provide a gui to automate the submission of your pull request.
The pull request then goes into a queue for everyone to see and comment on. Below you can see a typical pull request. The pull requests allow for discussions and it shows all associated commits and the diffs for each commit. The discussions typically involve code reviews which provide helpful suggestions for improvements, and allows for us to leave inline comments on specific parts of the code. Don't be disheartened if we don't merge straight away, it can often take several revisions before we accept a pull request. Luckily GitHub makes it very trivial to go back to your code, do some more commits and then update your pull request to your latest and greatest.
It can take time for us to get round to responding to pull requests, so please be patient. Submitted tests that come with a fix will generally be applied quite quickly, where as just tests will often way until we get time to also submit that with a fix. Don't forget to rebase and resubmit your request from time to time, otherwise over time it will have merge conflicts and core developers will general ignore those.
You can always contact the jBPM community for assistance.
IRC: #jbpm at chat.freenode.net
This script assumes you have Java JDK 1.6+ (set as JAVA_HOME), and Ant 1.7+ installed. If you don't, use the following links to download and install them:
Java: http://java.sun.com/javase/downloads/index.jsp
Ant: http://ant.apache.org/bindownload.cgi
To check whether Java and Ant are installed correctly, type the following commands inside a command prompt:
java -version
ant -version
This should return information about which version of Java and Ant you are currently using.
First of all, you need to download the installer and unzip it to your local file system. There are two versions
full installer - which already contains a lot of the dependencies that are necessary during the installation
minimal installer - which only contains the installer and will download all dependencies
In general, it is probably best to download the full installer: jBPM-{version}-installer-full.zip
You can also find the latest snapshot release here (only minimal installer) here:
https://hudson.jboss.org/jenkins/job/jBPM/lastSuccessfulBuild/artifact/jbpm-distribution/target/
The easiest way to get started is to simply run the installation script to install the demo setup. The demo install will setup all the web tooling (on top of WildFly) and Eclipse tooling in a pre-configured setup. Go into the jbpm-installer folder where you unzipped the installer and (from a command prompt) run:
ant install.demo
This will:
Download WildFly application server
Configure and deploy the web tooling
Download Eclipse
Install the Drools and jBPM Eclipse plugin
Install the Eclipse BPMN 2.0 Modeler
Running this command could take a while (REALLY, not kidding, we are for example downloading an Eclipse installation, even if you downloaded the full installer, specifically for your operating system).
The script always shows which file it is downloading (you could for example check whether it is still downloading by checking the whether the size of the file in question in the jbpm-installer/lib folder is still increasing). If you want to avoid downloading specific components (because you will not be using them or you already have them installed somewhere else), check below for running only specific parts of the demo or directing the installer to an already installed component.
Once the demo setup has finished, you can start playing with the various components by starting the demo setup:
ant start.demo
This will:
Start H2 database server
Start WildFly application server
Start Eclipse
Now wait until the process management console comes up:
http://localhost:8080/jbpm-console
It could take a minute to start up the application server and web application. If the web page doesn't show up after a while, make sure you don't have a firewall blocking that port, or another application already using the port 8080. You can always take a look at the server log jbpm-installer/wildfly-8.1.0.Final/standalone/log/server.log
Finally, if you also want to use the DashBuilder for reporting (which is implemented as a separate war), you can now also install this:
ant install.dashboard.into.jboss
Once everything is started, you can start playing with the Eclipse and web tooling, as explained in the following sections.
If you only want to try out the web tooling and do not wish to download and install the Eclipse tooling, you can use these alternative commands:
ant install.demo.noeclipse
ant start.demo.noeclipse
Similarly, if you only want to try out the Eclipse tooling and do not wish to download and install the web tooling, you can use these alternative commands:
ant install.demo.eclipse
ant start.demo.eclipse
Now continue with the 10-minute tutorials. Once you're done playing and you want to shut down the demo setup, you can use:
ant stop.demo
If at any point in time would like to start over with a clean demo setup - meaning all changes you did inside the web tooling and/or saved in the database will be lost, you can run the following command (after which you can run the installer again from scratch, note that this cannot be undone):
ant clean.demo
Open up the process management console:
http://localhost:8080/jbpm-console
It could take a minute to start up the AS and web application. If the web page doesn't show up after a while, make sure you don't have a firewall blocking that port, or another application already using the port 8080. You can always take a look at the server log jbpm-installer/jboss-as-7.1.1.Final/standalone/log/server.log
Log in, using krisv / krisv as username / password.
Using a prebuilt Evaluation example, the following screencast gives an overview of how to manage your process instances. It shows you:
Figure 3.1.
The workbench supports the entire life cycle of your business processes: authoring, deployment, process management, tasks and dashboards.
The following screencast gives an overview of how to use the Eclipse tooling. It shows you:
Figure 3.2.
You can import the evaluation project - a sample included in the jbpm-installer - by selecting "File -> Import ...", select "Existing Projects into Workspace" and browse to the jbpm-installer/sample/evaluation folder and click "Finish". You can open up the evaluation process and the ProcessTest class. To execute the class, right-click on it and select "Run as ... - Java Application". The console should show how the process was started and how the different actors in the process completed the tasks assigned to them, to complete the process instance.
You could also create a new project using the jBPM project wizard. The sample projects contain a process and an associated Java file to start the process. Select "File - New ... - Project ..." and under the "jBPM" category, select "jBPM project" and click "Next". Give the project a name and click "Next". You can choose from a simple HelloWorld example or a slightly more advanced example using persistence and human tasks. If you select the latter and click Finish, you should see a new project containing a "sample.bpmn" process and a "com.sample.ProcessTest" JUnit test class. You can open the BPMN2 process by double-clicking it. To execute the process, right-click on ProcessTest.java and select "Run As - Java Application".
The workbench by default brings two sample playground repositories (by cloning the jbpm-playground repository hosted on GitHub). In cases where this is not wanted (access to Internet might not be available or there might be a need to start with a completely clean installation of the workbench) this default behavior can be turned off. To do so, change the following system property in the start.jboss target to false in the build.xml:
-Dorg.kie.demo=false
Note that this will create a completely empty version of the workbench. To be able to start modeling processes, the following elements need to be created first:
The workbench web application is using the "default" security domain for authenticating and authorizing users (as specified in the WEB-INF/jboss-web.xml inside the WARs).
The application server is configured by default to use properties files for specifying users. Note that this is for demo purposes only (as passwords and roles are stored in simple property files). The security domain is configured in the standalone.xml configuration file as follows:
<security-domain name="other" cache-type="default">
<authentication>
<login-module code="UsersRoles" flag="required">
<module-option name="usersProperties" value="${jboss.server.config.dir}/users.properties"/>
<module-option name="rolesProperties" value="${jboss.server.config.dir}/roles.properties"/>
</login-module>
</authentication>
</security-domain>
By default, these configuration files contain the following users:
Table 3.1. Default users
Name | Password | Workbench roles | Task roles |
---|---|---|---|
admin | admin | admin,analyst | |
krisv | krisv | admin,analyst | |
john | john | analyst | Accounting,PM |
mary | mary | analyst | HR |
sales-rep | sales-rep | analyst | sales |
jack | jack | analyst | IT |
katy | katy | analyst | HR |
salaboy | salaboy | admin,analyst | IT,HR,Accounting |
Authentication can be customized by editing the authentication and configuration files in the jbpm-installer/auth folder and/or by changing the standalone-*.xml files in the jbpm-installer folder. Note that you need to rerun the installer to make sure the modified files are copied and picked correctly.
By default, the jbpm-installer uses an H2 database for persisting runtime data. In this section we will:
modify the persistence settings for runtime persistence of process instance state
test the startup with our new settings!
You will need a local instance of a database, in this case we will use MySQL.
First though, let's look at the persistence setup that jBPM uses. In the demo, and in general, there are following types of persistent entities used by jBPM:
“persistent entities” in this context, are Java classes that represent information in the database.
In the MySQL database used in this quickstart, create a single user:
If you end up using different names for your user/schemas, please make a note of where we insert "jbpm" in the configuration files.
If you want to try this quickstart with another database, a section at the end of this quickstart describes what you may need to modify.
The following files define the persistence settings for the jbpm-installer demo:
There are multiple standalone.xml files available (depending on whether you are using JBoss AS 7.1.1 or JBoss EAP 6.1.1 and whether you are running the normal or full profile). The full profile is required to use the JMS component for remote integration. Best practice is to update all standalone.xml files to have consistent setup but most important is to have standalone-full-as-7.1.1.Final.xml properly configured as this is used by default by the installer.
Do the following:
# default is H2
# H2.version=1.3.168
# db.name=h2
# db.driver.jar.name=${db.name}.jar
# db.driver.download.url=http://repo1.maven.org/maven2/com/h2database/h2/${H2.version}/h2-${H2.version}.jar
#mysql
db.name=mysql
db.driver.module.prefix=com/mysql
db.driver.jar.name=${db.name}-connector-java.jar
db.driver.download.url=https://repository.jboss.org/nexus/service/local/repositories/central/content/mysql/mysql-connector-java/5.1.18/mysql-connector-java-5.1.18.jar
db/jbpm-persistence-JPA2.xml
:
This is the JPA persistence file that defines the persistence settings used by jBPM for both the process engine information, the logging/BAM information and task service.
In this file, you will have to change the name of the hibernate dialect used for your database.
The original line is:
<property name="hibernate.dialect" value="org.hibernate.dialect.H2Dialect"/>
In the case of a MySQL database, you need to change it to:
<property name="hibernate.dialect" value="org.hibernate.dialect.MySQLDialect"/>
For those of you who decided to use another database, a list of the available hibernate dialect classes can be found here.
standalone.xml
:
This file is the configuration for the standalone JBoss application server. When the
installer installs the demo, it copies these files to the standalone/configuration
directory in the JBoss server directory.
We need to change the datasource configuration in standalone.xml
so that the jBPM process engine can use our MySQL database
The original file contains the following lines:
<datasource jndi-name="java:jboss/datasources/jbpmDS" enabled="true" use-java-context="true" pool-name="H2DS">
<connection-url>jdbc:h2:tcp://localhost/runtime/jbpm-demo</connection-url>
<driver>h2</driver>
<pool></pool>
<security>
<user-name>sa</user-name>
<password></password>
</security>
</datasource>
<drivers>
<driver name="h2" module="com.h2database.h2">
<xa-datasource-class>org.h2.jdbcx.JdbcDataSource</xa-datasource-class>
</driver>
</drivers>
Change the lines to the following:
<datasource jndi-name="java:jboss/datasources/jbpmDS" pool-name="MySQLDS" enabled="true" use-java-context="true">
<connection-url>jdbc:mysql://localhost:3306/jbpm</connection-url>
<driver>mysql</driver>
<pool></pool>
<security>
<user-name>jbpm</user-name>
<password>jbpm</password>
</security>
</datasource>
<drivers>
<driver name="mysql" module="com.mysql">
<xa-datasource-class>com.mysql.jdbc.jdbc2.optional.MysqlXADataSource</xa-datasource-class>
</driver>
</drivers>
Starting the demo
We've modified all the necessary files at this point. Now would be a good time to make sure your database is started up as well!
The installer script copies this file into the jbpm-console WAR before the WAR is installed on the server. If you have already run the installer, it is recommended to stop the installer and clean it first using
ant stop.demo
and
ant clean.demo
before continuing.
Run
ant install.demo
to (re)install the wars and copy the necessary configuration files. Once you've done that, (re)start the demo using
ant start.demo
.
Problems?
If this isn't working for you, please try the following:
If you decide to use a different database with this demo, you need to remember the following when going through the steps above:
standalone/deployments
directory.
# default is H2
# H2.version=1.3.168
# db.name=h2
# db.driver.jar.name=${db.name}.jar
# db.driver.download.url=http://repo1.maven.org/maven2/com/h2database/h2/${H2.version}/h2-${H2.version}.jar
#postgresql
db.name=postgresql
db.driver.module.prefix=org/postgresql
db.driver.jar.name=${db.name}-jdbc.jar
db.driver.download.url=https://repository.jboss.org/nexus/content/repositories/thirdparty-uploads/postgresql/postgresql/9.1-902.jdbc4/postgresql-9.1-902.jdbc4.jar
db.name
property in build.properties
to the name of the downloaded jdbc driver JAR you placed in db/drivers
.
<driver>
information in
the <datasource>
section of standalone.xml
so
that it refers to the name of your driver module (see next step). For example:
<driver>postgresql</driver>
standalone.xml
is the
<drivers>
section of the
<datasources>
(note the plural: drivers,
datasources). We need to do the following with this file:
<drivers>
<driver name="postgresql" module="org.postgresql">
<xa-datasource-class>org.postgresql.xa.PGXADataSource</xa-datasource-class>
</driver>
</drivers>
db.driver.module.prefix
property
in build.properties
to the same “value” you used for the module name
in standalone.xml
. In the example above, I used
“org.postgresql
” which means that I should then use
org/postgresql
for the db.driver.module.prefix
property.
db/${db.name}_module.xml
file. As an example you can use db/mysql_module.xml, so just make a copy of it and:
db.driver.module.prefix
property above<module xmlns="urn:jboss:module:1.0" name="com.mysql">
<resources>
<resource-root path="mysql-connector-java.jar"/>
</resources>
Change those lines to look like this, for example:
<module xmlns="urn:jboss:module:1.0" name="org.postgresql">
<resources>
<resource-root path="postgresql-9.1-902.jdbc4.jar"/>
</resources>
By default the demo setup makes use of Hibernate auto DDL generation capabilities to build up the complete database schema, including all tables, sequences, etc. This might not always be welcomed (by your database administrator), and thus the installer provides DDL scripts for most popular databases.
Table 3.2. DDL scripts
Database name | Location |
---|---|
db2 | jbpm-installer/db/ddl-scripts/db2 |
derby | jbpm-installer/db/ddl-scripts/derby |
h2 | jbpm-installer/db/ddl-scripts/h2 |
hsqldb | jbpm-installer/db/ddl-scripts/hsqldb |
mysql5 | jbpm-installer/db/ddl-scripts/mysql5 |
mysqlinnodb | jbpm-installer/db/ddl-scripts/mysqlinnodb |
oracle | jbpm-installer/db/ddl-scripts/oracle |
postgresql | jbpm-installer/db/ddl-scripts/postgresql |
sqlserver | jbpm-installer/db/ddl-scripts/sqlserver |
sqlserver2008 | jbpm-installer/db/ddl-scripts/sqlserver2008 |
DDL scripts are provided for both jBPM and Quartz schemas although Quartz schema DDL script is only required when the timer service should be configured with Quartz database job store. See the section on timers for additional details.
This can be used to initially create the database schema, but it can also serve as the basis for any\ optimization that needs to be applied - such as indexes, etc.
jBPM installer ant script performs most of the work automatically and usually does not require additional attention but in case it does, here is a list of available targets that might be needed to perform some of the steps manually.
Table 3.3. jBPM installer available targets
Target | Description |
---|---|
clean.db | cleans up database used by jBPM demo (applies only to H2 database) |
clean.demo | cleans up entire installation so new installation can be performed |
clean.demo.noeclipse | same as clean.demo but does not remove Eclipse |
clean.eclipse | removes Eclipse and its workspace |
clean.generated.ddl | removes DDL scripts generated if any |
clean.jboss | removes application server with all its deployments |
clean.jboss.repository | removes repository content for demo setup (guvnor Maven repo, niogit, etc) |
download.dashboard | downloads jBPM dashboard component (BAM) |
download.db.driver | downloads DB driver configured in build.properties |
download.ddl.dependencies | downloads all dependencies required to run DDL script generation tool |
download.droolsjbpm.eclipse | downloads Drools and jBPM Eclipse plugin |
download.eclipse | downloads Eclipse distribution |
download.jboss | downloads JBoss Application Server |
download.jBPM.bin | downloads jBPM binary distribution (jBPM libs and its dependencies) |
download.jBPM.console | downloads jBPM console for JBoss AS |
install.dashboard.into.jboss | installs jBPM dashboard into JBoss AS |
install.db.files | installs DB driver as JBoss module |
install.demo | installs complete demo environment |
install.demo.eclipse | installs Eclipse with all jBPM plugins, no server installation |
install.demo.noeclipse | similar to install.demo but skips Eclipse installation |
install.dependencies | installs custom libraries (such as work item handlers, etc) into the jBPM console |
install.droolsjbpm-eclipse.into.eclipse | installs droolsjbpm Eclipse plugin into Eclipse |
install.eclipse | install Eclipse IDE |
install.jboss | installs JBoss AS |
install.jBPM-console.into.jboss | installs jBPM console application into JBoss AS |
Some common issues are explained below.
Q: What if the installer complains it cannot download component X?
A: Are you connected to the Internet? Do you have a firewall turned on? Do you require a proxy? It might be possible that one of the locations we're downloading the components from is temporarily offline. Try downloading the components manually (possibly from alternate locations) and put them in the jbpm-installer/lib folder.
Q: What if the installer complains it cannot extract / unzip a certain JAR/WAR/zip?
A: If your download failed while downloading a component, it is possible that the installer is trying to use an incomplete file. Try deleting the component in question from the jbpm-installer/lib folder and reinstall, so it will be downloaded again.
Q: What if I have been changing my installation (and it no longer works) and I want to start over again with a clean installation?
A: You can use ant clean.demo to remove all the installed components, so you end up with a fresh installation again.
Q: I sometimes see exceptions when trying to stop or restart certain services, what should I do?
A: If you see errors during shutdown, are you sure the services were still running? If you see exceptions during restart, are you sure the service you started earlier was successfully shutdown? Maybe try killing the services manually if necessary.
Q: Something seems to be going wrong when running Eclipse but I have no idea what. What can I do?
A: Always check the consoles for output like error messages or stack traces. You can also check the Eclipse Error Log for exceptions. Try adding an audit logger to your session to figure out what's happening at runtime, or try debugging your application.
Q: Something seems to be going wrong when running the a web-based application like the jbpm-console. What can I do?
A: You can check the server log for possible exceptions: jbpm-installer/jboss-as-{version}/standalone/log/server.log (for JBoss AS7).
For all other questions, try contacting the jBPM community as described in the Getting Started chapter.
The web-based workbench by default will install two sample repositories that contain various sample projects that help you getting started. This section shows different examples that can be found in the jbpm-playground repository (also available here: https://github.com/droolsjbpm/jbpm-playground). All these examples are high level and business oriented.
If you want to contribute with these examples please get in touch with any member of the jBPM/Drools Team.
Let’s imagine for a second that you work for a Software company that works with several projects and from time to time the company wants to hire new developers. So, which employees, Departments and Systems are required to Hire a new Developer in your company? Trying to answering these questions will help you to define your business process. The following figure, represents how does this process works for Acme Inc. We can clearly see that three Departments are involved: Human Resources, IT and Accounting teams are involved. Inside our company we have Katy from the Human Resources Team, Jack on the IT team and John from the Accounting team involved. Notice that there are other people inside each team, but we will be using Katy, Jack and John to demonstrate how to execute the business process.
Notice that there are 6 activities defined inside this business process, 4 of them are User Tasks, which means that will be handled by people. The other two are Service Tasks, which means an interaction with another system will be required.
The process diagram is self explanatory, but just in case and to avoid confusions this is what is supposed to happen for each instance of the process that is started a particular candidate:
The Human Resources Team perform the initial interview to the candidate to see if he/she fits the profile that the company is looking for.
The IT Department perform a technical interview to evaluate the candidate skills and experience.
Based on output of the Human Resources and IT teams, the accounting team create a Job Proposal which includes the yearly salary for the candidate. The proposal is created based on the output of both of the interviews (Human Resources and Technical).
As soon as the proposal has being created it is automatically sent to the candidate via email.
If the candidate accept the proposal, a new meeting is created with someone from the Human Resource team to sign the contract.
If everything goes well, as soon as the process is notified that the candidate was hired, the system will automatically post a tweet about the new Hire using the Twitter service connector.
As you can see Jack, John and Katy will be performing the tasks for this example instance of the business process, but any person inside the company that have those Roles will be able to claim and interact with those tasks.
Let's take a look at the Project content in the Authoring Perspective:
As you can see it contains the hiring.bpmn2 process and a set of forms for each human task. You can explore these knowledge assets by clicking on them. You will notice that different editors will open for different types of assets. If you click on the Business Process file you will be able to edit the process definition using the Process Designer:
Feel free to inspect the forms as well. Notice that the Form Modeller will be opened and there you can edit the forms to fit your requirements.
In order to build the Project so it gets available in the Process Definitions List you need to go to the Authoring Perspective and open the Project Editor panel:
Once you open the Project Editor, you will see on the top right corner of the panel the button called Build & Deploy. This button will allow you to create a new JAR artifact that will be deployed to the Runtime environment as a new Deployment Unit.
Once you get the visual notification that the project was built and deployed successfully you can go to the Deployments screen to verify that your artifact is there. In order to do that go to the top level menu called Deploy -> Deployments
In the Deployments screen you will find all the deployed units. By default when you Build & Deploy a project from the Project Editor, it will be automatically deployed using the default configurations. That is Singleton Strategy, the default KIE Base and the default KIE Session will be used.
If you want a more advanced deployment, that is selecting a different strategy or using non defaults KIE Base or KIE Session you will be able to undeploy and re-deploy your artifacts using their GAV and selecting non default options.
Once your artifact that contains the process definition is deployed, the Process Definition will be available under Process Management -> Process Definitions.
In order to create new Process Instances you need to go to Process Management -> Process Definitions.
Here you will find all the available process definitions in the runtime environment. If you want to add new process definitions look at the previous sections where it is explained how to build and deploy KIE Projects.
You can start process instances using any of the two options highlighted in the previous screen.
In order to create a new process instance most of the processes will require you to fill in some information and for that a form will be displayed. For this specific use case the name of the candidate that we are interviewing is required:
If we hit the big Start button, the new process instance will be created and the first task of the process will be create for the Human Resources Team. Depending on the assigned roles of the user that you are using to create the process instance you will be able to see the created task or not. In order to see the first task of the process we will need to logout tot he application and log in as someone from the Human Resources team.
After starting the process you can go to the Task -> Tasks section to interact with the created human tasks. Notice that in order to see the tasks in the task lists you will need to belong to some specific user Groups. For example the HR Interview task will be visitable for any member of the HR group, the Tech Interview will be visible by any member of the IT Group.
Using the jBPM Core Engine
Table of Contents
This chapter introduces the API you need to load processes and execute them. For more detail on how to define the processes themselves, check out the chapter on BPMN 2.0.
To interact with the process engine (for example, to start a process), you need to set up a session. This session will be used to communicate with the process engine. A session needs to have a reference to a knowledge base, which contains a reference to all the relevant process definitions. This knowledge base is used to look up the process definitions whenever necessary. To create a session, you first need to create a knowledge base, load all the necessary process definitions (this can be from various sources, like from classpath, file system or process repository) and then instantiate a session.
Once you have set up a session, you can use it to start executing processes. Whenever a process is started, a new process instance is created (for that process definition) that maintains the state of that specific instance of the process.
For example, imagine you are writing an application to process sales orders. You could then define one or more process definitions that define how the order should be processed. When starting up your application, you first need to create a knowledge base that contains those process definitions. You can then create a session based on this knowledge base so that, whenever a new sales order comes in, a new process instance is started for that sales order. That process instance contains the state of the process for that specific sales request.
A knowledge base can be shared across sessions and usually is only created once, at the start of the application (as creating a knowledge base can be rather heavy-weight as it involves parsing and compiling the process definitions). Knowledge bases can be dynamically changed (so you can add or remove processes at runtime).
Sessions can be created based on a knowledge base and are used to execute processes and interact with the engine. You can create as many independent session as you need and creating a session is considered relatively lightweight. How many sessions you create is up to you. In general, most simple cases start out with creating one session that is then called from various places in your application. You could decide to create multiple sessions if for example you want to have multiple independent processing units (for example, if you want all processes from one customer to be completely independent from processes for another customer, you could create an independent session for each customer) or if you need multiple sessions for scalability reasons. If you don't know what to do, simply start by having one knowledge base that contains all your process definitions and create one session that you then use to execute all your processes.
The jBPM project has a clear separation between the API the users should be interacting with and the actual implementation classes. The public API exposes most of the features we believe "normal" users can safely use and should remain rather stable across releases. Expert users can still access internal classes but should be aware that they should know what they are doing and that the internal API might still change in the future.
As explained above, the jBPM API should thus be used to (1) create a knowledge base that contains your process definitions, and to (2) create a session to start new process instances, signal existing ones, register listeners, etc.
The jBPM API allows you to first create a knowledge base. This knowledge base should include all your process definitions that might need to be executed by that session. To create a knowledge base, use a KieHelper to load processes from various resources (for example from the classpath or from the file system), and then create a new knowledge base from that helper. The following code snippet shows how to create a knowledge base consisting of only one process definition (using in this case a resource from the classpath).
KieHelper kieHelper = new KieHelper();
KieBase kieBase = kieHelper
.addResource(ResourceFactory.newClassPathResource("MyProcess.bpmn"))
.build();
The ResourceFactory has similar methods to load files from file system, from URL, InputStream, Reader, etc.
This is considered manual creation of knowledge base and while it is simple it is not recommended for real application development but more for try outs. Following you'll find recommended and much more powerful way of building knowledge base, knowledge session and more - RuntimeManager.
Once you've loaded your knowledge base, you should create a session to interact with the engine. This session can then be used to start new processes, signal events, etc. The following code snippet shows how easy it is to create a session based on the previously created knowledge base, and to start a process (by id).
KieSession ksession = kbase.newKieSession();
ProcessInstance processInstance = ksession.startProcess("com.sample.MyProcess");
The ProcessRuntime
interface defines all the session methods
for interacting with processes, as shown below.
/**
* Start a new process instance. The process (definition) that should
* be used is referenced by the given process id.
*
* @param processId The id of the process that should be started
* @return the ProcessInstance
that represents the instance of the process that was started
*/
ProcessInstance startProcess(String processId);
/**
* Start a new process instance. The process (definition) that should
* be used is referenced by the given process id. Parameters can be passed
* to the process instance (as name-value pairs), and these will be set
* as variables of the process instance.
*
* @param processId the id of the process that should be started
* @param parameters the process variables that should be set when starting the process instance
* @return the ProcessInstance
that represents the instance of the process that was started
*/
ProcessInstance startProcess(String processId,
Map<String, Object> parameters);
/**
* Signals the engine that an event has occurred. The type parameter defines
* which type of event and the event parameter can contain additional information
* related to the event. All process instances that are listening to this type
* of (external) event will be notified. For performance reasons, this type of event
* signaling should only be used if one process instance should be able to notify
* other process instances. For internal event within one process instance, use the
* signalEvent method that also include the processInstanceId of the process instance
* in question.
*
* @param type the type of event
* @param event the data associated with this event
*/
void signalEvent(String type,
Object event);
/**
* Signals the process instance that an event has occurred. The type parameter defines
* which type of event and the event parameter can contain additional information
* related to the event. All node instances inside the given process instance that
* are listening to this type of (internal) event will be notified. Note that the event
* will only be processed inside the given process instance. All other process instances
* waiting for this type of event will not be notified.
*
* @param type the type of event
* @param event the data associated with this event
* @param processInstanceId the id of the process instance that should be signaled
*/
void signalEvent(String type,
Object event,
long processInstanceId);
/**
* Returns a collection of currently active process instances. Note that only process
* instances that are currently loaded and active inside the engine will be returned.
* When using persistence, it is likely not all running process instances will be loaded
* as their state will be stored persistently. It is recommended not to use this
* method to collect information about the state of your process instances but to use
* a history log for that purpose.
*
* @return a collection of process instances currently active in the session
*/
Collection<ProcessInstance> getProcessInstances();
/**
* Returns the process instance with the given id. Note that only active process instances
* will be returned. If a process instance has been completed already, this method will return
* null.
*
* @param id the id of the process instance
* @return the process instance with the given id or null if it cannot be found
*/
ProcessInstance getProcessInstance(long processInstanceId);
/**
* Aborts the process instance with the given id. If the process instance has been completed
* (or aborted), or the process instance cannot be found, this method will throw an
* IllegalArgumentException.
*
* @param id the id of the process instance
*/
void abortProcessInstance(long processInstanceId);
/**
* Returns the WorkItemManager related to this session. This can be used to
* register new WorkItemHandlers or to complete (or abort) WorkItems.
*
* @return the WorkItemManager related to this session
*/
WorkItemManager getWorkItemManager();
The session provides methods for registering and removing listeners.
A ProcessEventListener
can be used to listen to process-related events,
like starting or completing a process, entering and leaving a node, etc. Below,
the different methods of the ProcessEventListener
class are shown.
An event object provides access to related information, like the process instance
and node instance linked to the event. You can use this API to register your own
event listeners.
public interface ProcessEventListener {
void beforeProcessStarted( ProcessStartedEvent event );
void afterProcessStarted( ProcessStartedEvent event );
void beforeProcessCompleted( ProcessCompletedEvent event );
void afterProcessCompleted( ProcessCompletedEvent event );
void beforeNodeTriggered( ProcessNodeTriggeredEvent event );
void afterNodeTriggered( ProcessNodeTriggeredEvent event );
void beforeNodeLeft( ProcessNodeLeftEvent event );
void afterNodeLeft( ProcessNodeLeftEvent event );
void beforeVariableChanged(ProcessVariableChangedEvent event);
void afterVariableChanged(ProcessVariableChangedEvent event);
}
A note about before and after events: these events typically act like a stack, which means that any events that occur as a direct result of the previous event, will occur between the before and the after of that event. For example, if a subsequent node is triggered as result of leaving a node, the node triggered events will occur inbetween the beforeNodeLeftEvent and the afterNodeLeftEvent of the node that is left (as the triggering of the second node is a direct result of leaving the first node). Doing that allows us to derive cause relationships between events more easily. Similarly, all node triggered and node left events that are the direct result of starting a process will occur between the beforeProcessStarted and afterProcessStarted events. In general, if you just want to be notified when a particular event occurs, you should be looking at the before events only (as they occur immediately before the event actually occurs). When only looking at the after events, one might get the impression that the events are fired in the wrong order, but because the after events are triggered as a stack (after events will only fire when all events that were triggered as a result of this event have already fired). After events should only be used if you want to make sure that all processing related to this has ended (for example, when you want to be notified when starting of a particular process instance has ended.
Also note that not all nodes always generate node triggered and/or node left events. Depending on the type of node, some nodes might only generate node left events, others might only generate node triggered events. Catching intermediate events for example are not generating triggered events (they are only generating left events, as they are not really triggered by another node, rather activated from outside). Similarly, throwing intermediate events are not generating left events (they are only generating triggered events, as they are not really left, as they have no outgoing connection).
jBPM out-of-the-box provides a listener that can be used to create an audit log (either to the console or the a file on the file system). This audit log contains all the different events that occurred at runtime so it's easy to figure out what happened. Note that these loggers should only be used for debugging purposes. The following logger implementations are supported by default:
Console logger: This logger writes out all the events to the console.
File logger: This logger writes out all the events to a file using an XML representation. This log file might then be used in the IDE to generate a tree-based visualization of the events that occurred during execution.
Threaded file logger: Because a file logger writes the events to disk only when closing the logger or when the number of events in the logger reaches a predefined level, it cannot be used when debugging processes at runtime. A threaded file logger writes the events to a file after a specified time interval, making it possible to use the logger to visualize the progress in realtime, while debugging processes.
The KieServices
lets you add a KieRuntimeLogger
to
your session, as shown below. When creating a console logger, the knowledge session
for which the logger needs to be created must be passed as an argument. The file
logger also requires the name of the log file to be created, and the threaded file
logger requires the interval (in milliseconds) after which the events should be saved.
You should always close the logger at the end of your application.
import org.kie.api.KieServices;
import org.kie.api.logger.KieRuntimeLogger;
...
KieRuntimeLogger logger = KieServices.Factory.get().getLoggers().newFileLogger(ksession, "test");
// add invocations to the process engine here,
// e.g. ksession.startProcess(processId);
...
logger.close();
The log file that is created by the file-based loggers contains an XML-based overview of all the events that occurred at runtime. It can be opened in Eclipse, using the Audit View in the Drools Eclipse plugin, where the events are visualized as a tree. Events that occur between the before and after event are shown as children of that event. The following screenshot shows a simple example, where a process is started, resulting in the activation of the Start node, an Action node and an End node, after which the process was completed.
A common requirement when working with processes is ability to assign a given process instance some sort of business identifier that can be later on referenced without knowing the actual (generated) id of the process instance. To provide such capabilities, jBPM allows to use CorrelationKey that is composed of CorrelationProperties. CorrelationKey can have either single property describing it (which is in most cases) but it can be represented as multi valued properties set.
Correlation capabilities are provided as part of interface
CorrelationAwareProcessRuntime
that exposes following methods:
/**
* Start a new process instance. The process (definition) that should
* be used is referenced by the given process id. Parameters can be passed
* to the process instance (as name-value pairs), and these will be set
* as variables of the process instance.
*
* @param processId the id of the process that should be started
* @param correlationKey custom correlation key that can be used to identify process instance
* @param parameters the process variables that should be set when starting the process instance
* @return the ProcessInstance
that represents the instance of the process that was started
*/
ProcessInstance startProcess(String processId, CorrelationKey correlationKey, Map<String, Object> parameters);
/**
* Creates a new process instance (but does not yet start it). The process
* (definition) that should be used is referenced by the given process id.
* Parameters can be passed to the process instance (as name-value pairs),
* and these will be set as variables of the process instance. You should only
* use this method if you need a reference to the process instance before actually
* starting it. Otherwise, use startProcess.
*
* @param processId the id of the process that should be started
* @param correlationKey custom correlation key that can be used to identify process instance
* @param parameters the process variables that should be set when creating the process instance
* @return the ProcessInstance
that represents the instance of the process that was created (but not yet started)
*/
ProcessInstance createProcessInstance(String processId, CorrelationKey correlationKey, Map<String, Object> parameters);
/**
* Returns the process instance with the given correlationKey. Note that only active process instances
* will be returned. If a process instance has been completed already, this method will return
* null
.
*
* @param correlationKey the custom correlation key assigned when process instance was created
* @return the process instance with the given id or null
if it cannot be found
*/
ProcessInstance getProcessInstance(CorrelationKey correlationKey);
Correlation is usually used with long running processes and thus require persistence to be enabled to be able to permanently store correlation information.
In the following text, we will refer to two types of "multi-threading": logical and technical. Technical multi-threading is what happens when multiple threads or processes are started on a computer, for example by a Java or C program. Logical multi-threading is what we see in a BPM process after the process reaches a parallel gateway, for example. From a functional standpoint, the original process will then split into two processes that are executed in a parallel fashion.
Of course, the jBPM engine supports logical multi-threading: for example, processes that include a parallel gateway. We've chosen to implement logical multi-threading using one thread: a jBPM process that includes logical multi-threading will only be executed in one technical thread. The main reason for doing this is that multiple (technical) threads need to be be able to communicate state information with each other if they are working on the same process. This requirement brings with it a number of complications. While it might seem that multi-threading would bring performance benefits with it, the extra logic needed to make sure the different threads work together well means that this is not guaranteed. There is also the extra overhead incurred because we need to avoid race conditions and deadlocks.
In general, the jBPM engine executes actions in serial. For example,
when the engine encounters a script task in a process, it will synchronously
execute that script and wait for it to complete before continuing execution.
Similarly, if a process encounters a parallel gateway, it will sequentially
trigger each of the outgoing branches, one after the other. This is possible
since execution is almost always instantaneous, meaning that it is extremely
fast and produces almost no overhead. As a result, the user will usually
not even notice this. Similarly, action scripts in a process are also synchronously
executed, and the engine will wait for them to finish before continuing the
process. For example, doing a Thread.sleep(...)
as part of
a script will not make the engine continue execution elsewhere but will
block the engine thread during that period.
The same principle applies to service tasks. When a service task is
reached in a process, the engine will also invoke the handler of this service
synchronously. The engine will wait for the completeWorkItem(...)
method to return before continuing execution. It is important that your
service handler executes your service asynchronously if its execution is
not instantaneous.
An example of this would be a service task that invokes an external service. Since the delay in invoking this service remotely and waiting for the results might be too long, it might be a good idea to invoke this service asynchronously. This means that the handler will only invoke the service and will notify the engine later when the results are available. In the mean time, the process engine then continues execution of the process.
Human tasks are a typical example of a service that needs to be invoked asynchronously, as we don't want the engine to wait until a human actor has responded to the request. The human task handler will only create a new task (on the task list of the assigned actor) when the human task node is triggered. The engine will then be able to continue execution on the rest of the process (if necessary) and the handler will notify the engine asynchronously when the user has completed the task.
RuntimeManager has been introduced to simplify and empower usage of knowledge API especially in context of processes. It provides configurable strategies that control actual runtime execution (how KieSessions are provided) and by default provides following:
Runtime Manager is primary responsible for managing and delivering instances of RuntimeEngine to the caller. In turn, RuntimeEngine encapsulates two the most important elements of jBPM engine:
KieSession
TaskService
Both of these components are already configured to work with each other smoothly without additional configuration from end user. No more need to register human task handler or keeping track if it's connected to the service or not.
public interface RuntimeManager {
/**
* Returns <code>RuntimeEngine</code> instance that is fully initialized:
* <ul>
* <li>KiseSession is created or loaded depending on the strategy</li>
* <li>TaskService is initialized and attached to ksession (via listener)</li>
* <li>WorkItemHandlers are initialized and registered on ksession</li>
* <li>EventListeners (process, agenda, working memory) are initialized and added to ksession</li>
* </ul>
* @param context the concrete implementation of the context that is supported by given <code>RuntimeManager</code>
* @return instance of the <code>RuntimeEngine</code>
*/
RuntimeEngine getRuntimeEngine(Context<?> context);
/**
* Unique identifier of the <code>RuntimeManager</code>
* @return
*/
String getIdentifier();
/**
* Disposes <code>RuntimeEngine</code> and notifies all listeners about that fact.
* This method should always be used to dispose <code>RuntimeEngine</code> that is not needed
* anymore. <br/>
* ksession.dispose() shall never be used with RuntimeManager as it will break the internal
* mechanisms of the manager responsible for clear and efficient disposal.<br/>
* Dispose is not needed if <code>RuntimeEngine</code> was obtained within active JTA transaction,
* this means that when getRuntimeEngine method was invoked during active JTA transaction then dispose of
* the runtime engine will happen automatically on transaction completion.
* @param runtime
*/
void disposeRuntimeEngine(RuntimeEngine runtime);
/**
* Closes <code>RuntimeManager</code> and releases its resources. Shall always be called when
* runtime manager is not needed any more. Otherwise it will still be active and operational.
*/
void close();
}
RuntimeEngine interface provides the most important methods to get access to engine components:
public interface RuntimeEngine {
/**
* Returns <code>KieSession</code> configured for this <code>RuntimeEngine</code>
* @return
*/
KieSession getKieSession();
/**
* Returns <code>TaskService</code> configured for this <code>RuntimeEngine</code>
* @return
*/
TaskService getTaskService();
}
RuntimeManager will ensure that regardless of the strategy it will provide same capabilities when it comes to initialization and configuration of the RuntimeEngine. That means
KieSession will be loaded with same factories (either in memory or JPA based)
WorkItemHandlers will be registered on every KieSession (either loaded from db or newly created)
Event listeners (Process, Agenda, WorkingMemory) will be registered on every KieSession (either loaded from db or newly created)
TaskService will be configured with:
JTA transaction manager
same entity manager factory as for the KieSession
UserGroupCallback from environment
On the other hand, RuntimeManager maintains the engine disposal as well by providing dedicated methods to dispose RuntimeEngine when it's no more needed to release any resources it might have acquired.
Singleton strategy - instructs RuntimeManager to maintain single instance of RuntimeEngine (and in turn single instance of KieSession and TaskService). Access to the RuntimeEngine is synchronized and by that thread safe although it comes with a performance penalty due to synchronization. This strategy is similar to what was available by default in jBPM version 5.x and it's considered easiest strategy and recommended to start with.
It has following characteristics that are important to evaluate while considering it for given scenario:
small memory footprint - single instance of runtime engine and task service
simple and compact in design and usage
good fit for low to medium load on process engine due to synchronized access
due to single KieSession instance all state objects (such as facts) are directly visible to all process instances and vice versa
not contextual - meaning when retrieving instances of RuntimeEngine from singleton RuntimeManager Context instance is not important and usually EmptyContext.get() is used although null argument is acceptable as well
keeps track of id of KieSession used between RuntimeManager restarts to ensure it will use same session - this id is stored as serialized file on disc in temp location that depends on the environment can be one of following:
value given by jbpm.data.dir system property
value given by jboss.server.data.dir system property
value given by java.io.tmpdir system property
Per request strategy - instructs RuntimeManager to provide new instance of RuntimeEngine for every request. As request RuntimeManager will consider one or more invocations within single transaction. It must return same instance of RuntimeEngine within single transaction to ensure correctness of state as otherwise operation done in one call would not be visible in the other. This is sort of "stateless" strategy that provides only request scope state and once request is completed RuntimeEngine will be permanently destroyed - KieSession information will be removed from the database in case persistence was used.
It has following characteristics:
completely isolated process engine and task service operations for every request
completely stateless, storing facts makes sense only for the duration of the request
good fit for high load, stateless processes (no facts or timers involved that shall be preserved between requests)
KieSession is only available during life time of request and at the end is destroyed
not contextual - meaning when retrieving instances of RuntimeEngine from per request RuntimeManager Context instance is not important and usually EmptyContext.get() is used although null argument is acceptable as well
Per process instance strategy - instructs RuntimeManager to maintain a strict relationship between KieSession and ProcessInstance. That means that KieSession will be available as long as the ProcessInstance that it belongs to is active. This strategy provides the most flexible approach to use advanced capabilities of the engine like rule evaluation in isolation (for given process instance only), maximum performance and reduction of potential bottlenecks intriduced by synchronization; and at the same time reduces number of KieSessions to the actual number of process instances rather than number of requests (in contrast to per request strategy).
It has following characteristics:
most advanced strategy to provide isolation to given process instance only
maintains strict relationship between KieSession and ProcessInstance to ensure it will always deliver same KieSession for given ProcessInstance
merges life cycle of KieSession with ProcessInstance making both to be disposed on process instance completion (complete or abort)
allows to maintain data (such as facts, timers) in scope of process instance - only process instance will have access to that data
introduces bit of overhead due to need to look up and load KieSession for process instance
validates usage of KieSession so it cannot be (ab)used for other process instances, in such a case exception is thrown
is contextual - accepts following context instances:
EmptyContext or null - when starting process instance as there is no process instance id available yet
ProcessInstanceIdContext - used after process instance was created
CorrelationKeyContext - used as an alternative to ProcessInstanceIdContext to use custom (business) key instead of process instance id
Regular usage scenario for RuntimeManager is:
At application startup
build RuntimeManager and keep it for entire life time of the application, it's thread safe and can be (or even should be) accessed concurrently
At request
get RuntimeEngine from RuntimeManager using proper context instance dedicated to strategy of RuntimeManager
get KieSession and/or TaskService from RuntimeEngine
perform operations on KieSession and/or TaskService such as startProcess, completeTask, etc
once done with processing dispose RuntimeEngine using RuntimeManager.disposeRuntimeEngine method
At application shutdown
close RuntimeManager
When RuntimeEngine is obtained from RuntimeManager within an active JTA transaction, then there is no need to dispose RuntimeEngine at the end, as RuntimeManager will automatically dispose the RuntimeEngine on transaction completion (regardless of the completion status commit or rollback).
Here is how you can build RuntimeManager and get RuntimeEngine (that encapsulates KieSession and TaskService) from it:
// first configure environment that will be used by RuntimeManager
RuntimeEnvironment environment = RuntimeEnvironmentBuilder.Factory.get()
.newDefaultInMemoryBuilder()
.addAsset(ResourceFactory.newClassPathResource("BPMN2-ScriptTask.bpmn2"), ResourceType.BPMN2)
.get();
// next create RuntimeManager - in this case singleton strategy is chosen
RuntimeManager manager = RuntimeManagerFactory.Factory.get().newSingletonRuntimeManager(environment);
// then get RuntimeEngine out of manager - using empty context as singleton does not keep track
// of runtime engine as there is only one
RuntimeEngine runtime = manager.getRuntimeEngine(EmptyContext.get());
// get KieSession from runtime runtimeEngine - already initialized with all handlers, listeners, etc that were configured
// on the environment
KieSession ksession = runtimeEngine.getKieSession();
// add invocations to the process engine here,
// e.g. ksession.startProcess(processId);
// and last dispose the runtime engine
manager.disposeRuntimeEngine(runtimeEngine);
This example provides simplest (minimal) way of using RuntimeManager and RuntimeEngine although it provides few quite valuable information:
KieSession will be in memory only - by using newDefaultInMemoryBuilder
there will be single process available for execution - by adding it as an asset
TaskService will be configured and attached to KieSession via LocalHTWorkItemHandler to support user task capabilities within processes
The complexity of knowing when to create, dispose, register handlers, etc is taken away from the end user and moved to the runtime manager that knows when/how to perform such operations but still allows to have a fine grained control over this process by providing comprehensive configuration of the RuntimeEnvironment.
public interface RuntimeEnvironment {
/**
* Returns <code>KieBase</code> that shall be used by the manager
* @return
*/
KieBase getKieBase();
/**
* KieSession environment that shall be used to create instances of <code>KieSession</code>
* @return
*/
Environment getEnvironment();
/**
* KieSession configuration that shall be used to create instances of <code>KieSession</code>
* @return
*/
KieSessionConfiguration getConfiguration();
/**
* Indicates if persistence shall be used for the KieSession instances
* @return
*/
boolean usePersistence();
/**
* Delivers concrete implementation of <code>RegisterableItemsFactory</code> to obtain handlers and listeners
* that shall be registered on instances of <code>KieSession</code>
* @return
*/
RegisterableItemsFactory getRegisterableItemsFactory();
/**
* Delivers concrete implementation of <code>UserGroupCallback</code> that shall be registered on instances
* of <code>TaskService</code> for managing users and groups.
* @return
*/
UserGroupCallback getUserGroupCallback();
/**
* Delivers custom class loader that shall be used by the process engine and task service instances
* @return
*/
ClassLoader getClassLoader();
/**
* Closes the environment allowing to close all depending components such as ksession factories, etc
*/
void close();
While RuntimeEnvironment interface provides mostly access to data kept as part of the environment and will be used by the RuntimeManager, users should take advantage of builder style class that provides fluent API to configure RuntimeEnvironment with predefined settings.
public interface RuntimeEnvironmentBuilder {
public RuntimeEnvironmentBuilder persistence(boolean persistenceEnabled);
public RuntimeEnvironmentBuilder entityManagerFactory(Object emf);
public RuntimeEnvironmentBuilder addAsset(Resource asset, ResourceType type);
public RuntimeEnvironmentBuilder addEnvironmentEntry(String name, Object value);
public RuntimeEnvironmentBuilder addConfiguration(String name, String value);
public RuntimeEnvironmentBuilder knowledgeBase(KieBase kbase);
public RuntimeEnvironmentBuilder userGroupCallback(UserGroupCallback callback);
public RuntimeEnvironmentBuilder registerableItemsFactory(RegisterableItemsFactory factory);
public RuntimeEnvironment get();
public RuntimeEnvironmentBuilder classLoader(ClassLoader cl);
public RuntimeEnvironmentBuilder schedulerService(Object globalScheduler);
Instances of the RuntimeEnvironmentBuilder can be obtained via RuntimeEnvironmentBuilderFactory that provides preconfigured sets of builder to simplify and help users to build the environment for the RuntimeManager.
public interface RuntimeEnvironmentBuilderFactory {
/**
* Provides completely empty <code>RuntimeEnvironmentBuilder</code> instance that allows to manually
* set all required components instead of relying on any defaults.
* @return new instance of <code>RuntimeEnvironmentBuilder</code>
*/
public RuntimeEnvironmentBuilder newEmptyBuilder();
/**
* Provides default configuration of <code>RuntimeEnvironmentBuilder</code> that is based on:
* <ul>
* <li>DefaultRuntimeEnvironment</li>
* </ul>
* @return new instance of <code>RuntimeEnvironmentBuilder</code> that is already preconfigured with defaults
*
* @see DefaultRuntimeEnvironment
*/
public RuntimeEnvironmentBuilder newDefaultBuilder();
/**
* Provides default configuration of <code>RuntimeEnvironmentBuilder</code> that is based on:
* <ul>
* <li>DefaultRuntimeEnvironment</li>
* </ul>
* but it does not have persistence for process engine configured so it will only store process instances in memory
* @return new instance of <code>RuntimeEnvironmentBuilder</code> that is already preconfigured with defaults
*
* @see DefaultRuntimeEnvironment
*/
public RuntimeEnvironmentBuilder newDefaultInMemoryBuilder();
/**
* Provides default configuration of <code>RuntimeEnvironmentBuilder</code> that is based on:
* <ul>
* <li>DefaultRuntimeEnvironment</li>
* </ul>
* This one is tailored to works smoothly with kjars as the notion of kbase and ksessions
* @param groupId group id of kjar
* @param artifactId artifact id of kjar
* @param version version number of kjar
* @return new instance of <code>RuntimeEnvironmentBuilder</code> that is already preconfigured with defaults
*
* @see DefaultRuntimeEnvironment
*/
public RuntimeEnvironmentBuilder newDefaultBuilder(String groupId, String artifactId, String version);
/**
* Provides default configuration of <code>RuntimeEnvironmentBuilder</code> that is based on:
* <ul>
* <li>DefaultRuntimeEnvironment</li>
* </ul>
* This one is tailored to works smoothly with kjars as the notion of kbase and ksessions
* @param groupId group id of kjar
* @param artifactId artifact id of kjar
* @param version version number of kjar
* @param kbaseName name of the kbase defined in kmodule.xml stored in kjar
* @param ksessionName name of the ksession define in kmodule.xml stored in kjar
* @return new instance of <code>RuntimeEnvironmentBuilder</code> that is already preconfigured with defaults
*
* @see DefaultRuntimeEnvironment
*/
public RuntimeEnvironmentBuilder newDefaultBuilder(String groupId, String artifactId, String version, String kbaseName, String ksessionName);
/**
* Provides default configuration of <code>RuntimeEnvironmentBuilder</code> that is based on:
* <ul>
* <li>DefaultRuntimeEnvironment</li>
* </ul>
* This one is tailored to works smoothly with kjars as the notion of kbase and ksessions
* @param releaseId <code>ReleaseId</code> that described the kjar
* @return new instance of <code>RuntimeEnvironmentBuilder</code> that is already preconfigured with defaults
*
* @see DefaultRuntimeEnvironment
*/
public RuntimeEnvironmentBuilder newDefaultBuilder(ReleaseId releaseId);
/**
* Provides default configuration of <code>RuntimeEnvironmentBuilder</code> that is based on:
* <ul>
* <li>DefaultRuntimeEnvironment</li>
* </ul>
* This one is tailored to works smoothly with kjars as the notion of kbase and ksessions
* @param releaseId <code>ReleaseId</code> that described the kjar
* @param kbaseName name of the kbase defined in kmodule.xml stored in kjar
* @param ksessionName name of the ksession define in kmodule.xml stored in kjar
* @return new instance of <code>RuntimeEnvironmentBuilder</code> that is already preconfigured with defaults
*
* @see DefaultRuntimeEnvironment
*/
public RuntimeEnvironmentBuilder newDefaultBuilder(ReleaseId releaseId, String kbaseName, String ksessionName);
/**
* Provides default configuration of <code>RuntimeEnvironmentBuilder</code> that is based on:
* <ul>
* <li>DefaultRuntimeEnvironment</li>
* </ul>
* It relies on KieClasspathContainer that requires to have kmodule.xml present in META-INF folder which
* defines the kjar itself.
* Expects to use default kbase and ksession from kmodule.
* @return new instance of <code>RuntimeEnvironmentBuilder</code> that is already preconfigured with defaults
*
* @see DefaultRuntimeEnvironment
*/
public RuntimeEnvironmentBuilder newClasspathKmoduleDefaultBuilder();
/**
* Provides default configuration of <code>RuntimeEnvironmentBuilder</code> that is based on:
* <ul>
* <li>DefaultRuntimeEnvironment</li>
* </ul>
* It relies on KieClasspathContainer that requires to have kmodule.xml present in META-INF folder which
* defines the kjar itself.
* @param kbaseName name of the kbase defined in kmodule.xml
* @param ksessionName name of the ksession define in kmodule.xml
* @return new instance of <code>RuntimeEnvironmentBuilder</code> that is already preconfigured with defaults
*
* @see DefaultRuntimeEnvironment
*/
public RuntimeEnvironmentBuilder newClasspathKmoduleDefaultBuilder(String kbaseName, String ksessionName);
Besides KieSession Runtime Manager provides access to TaskService too as integrated component of a RuntimeEngine that will always be configured and ready for communication between process engine and task service.
Since the default builder was used, it will already come with predefined set of elements that consists of:
Persistence unit name will be set to org.jbpm.persistence.jpa (for both process engine and task service)
Human Task handler will be automatically registered on KieSession
JPA based history log event listener will be automatically registered on KieSession
Event listener to trigger rule task evaluation (fireAllRules) will be automatically registered on KieSession
To extend it with your own handlers or listeners a dedicated mechanism is provided that comes as implementation of RegisterableItemsFactory
/**
* Returns new instances of <code>WorkItemHandler</code> that will be registered on <code>RuntimeEngine</code>
* @param runtime provides <code>RuntimeEngine</code> in case handler need to make use of it internally
* @return map of handlers to be registered - in case of no handlers empty map shall be returned.
*/
Map<String, WorkItemHandler> getWorkItemHandlers(RuntimeEngine runtime);
/**
* Returns new instances of <code>ProcessEventListener</code> that will be registered on <code>RuntimeEngine</code>
* @param runtime provides <code>RuntimeEngine</code> in case listeners need to make use of it internally
* @return list of listeners to be registered - in case of no listeners empty list shall be returned.
*/
List<ProcessEventListener> getProcessEventListeners(RuntimeEngine runtime);
/**
* Returns new instances of <code>AgendaEventListener</code> that will be registered on <code>RuntimeEngine</code>
* @param runtime provides <code>RuntimeEngine</code> in case listeners need to make use of it internally
* @return list of listeners to be registered - in case of no listeners empty list shall be returned.
*/
List<AgendaEventListener> getAgendaEventListeners(RuntimeEngine runtime);
/**
* Returns new instances of <code>WorkingMemoryEventListener</code> that will be registered on <code>RuntimeEngine</code>
* @param runtime provides <code>RuntimeEngine</code> in case listeners need to make use of it internally
* @return list of listeners to be registered - in case of no listeners empty list shall be returned.
*/
List<WorkingMemoryEventListener> getWorkingMemoryEventListeners(RuntimeEngine runtime);
A best practice is to just extend those that come out of the box and just add your own. Extensions are not always needed as the default implementations of RegisterableItemsFactory provides possibility to define custom handlers and listeners. Following is a list of available implementations that might be useful (they are ordered in the hierarchy of inheritance):
org.jbpm.runtime.manager.impl.SimpleRegisterableItemsFactory - simplest possible implementations that comes empty and is based on reflection to produce instances of handlers and listeners based on given class names
org.jbpm.runtime.manager.impl.DefaultRegisterableItemsFactory - extension of the Simple implementation that introduces defaults described above and still provides same capabilities as Simple implementation
org.jbpm.runtime.manager.impl.KModuleRegisterableItemsFactory - extension of default implementation that provides specific capabilities for kmodule and still provides same capabilities as Simple implementation
org.jbpm.runtime.manager.impl.cdi.InjectableRegisterableItemsFactory - extension of default implementation that is tailored for CDI environments and provides CDI style approach to finding handlers and listeners via producers
Alternatively, simple (stateless or requiring only KieSession) work item handlers might be registered in the well known way - defined as part of CustomWorkItem.conf file that shall be placed on class path. To use this approach do following:
create file "drools.session.conf" inside META-INF of the root of the class path, for web applications it will be WEB-INF/classes/META-INF
add following line to drools.session.conf file "drools.workItemHandlers = CustomWorkItemHandlers.conf"
create file "CustomWorkItemHandlers.conf" inside META-INF of the root of the class path, for web applications it will be WEB-INF/classes/META-INF
define custom work item handlers in MVEL style inside CustomWorkItemHandlers.conf
[
"Log": new org.jbpm.process.instance.impl.demo.SystemOutWorkItemHandler(),
"WebService": new org.jbpm.process.workitem.webservice.WebServiceWorkItemHandler(ksession),
"Rest": new org.jbpm.process.workitem.rest.RESTWorkItemHandler(),
"Service Task" : new org.jbpm.process.workitem.bpmn2.ServiceTaskHandler(ksession)
]
And that's it, now all these work item handlers will be registered for any KieSession created by that application, regardless if it uses RuntimeManager or not.
When using RuntimeManager in CDI environment there are dedicated interfaces that can be used to provide custom WorkItemHandlers and EventListeners to the RuntimeEngine.
public interface WorkItemHandlerProducer {
/**
* Returns map of (key = work item name, value work item handler instance) of work items
* to be registered on KieSession
* <br/>
* Parameters that might be given are as follows:
* <ul>
* <li>ksession</li>
* <li>taskService</li>
* <li>runtimeManager</li>
* </ul>
*
* @param identifier - identifier of the owner - usually RuntimeManager that allows the producer to filter out
* and provide valid instances for given owner
* @param params - owner might provide some parameters, usually KieSession, TaskService, RuntimeManager instances
* @return map of work item handler instances (recommendation is to always return new instances when this method is invoked)
*/
Map<String, WorkItemHandler> getWorkItemHandlers(String identifier, Map<String, Object> params);
}
Event listener producer shall be annotated with proper qualifier to indicate what type of listeners they provide, so pick one of following to indicate they type:
@Process - for ProcessEventListener
@Agenda - for AgendaEventListener
@WorkingMemory - for WorkingMemoryEventListener
public interface EventListenerProducer<T> {
/**
* Returns list of instances for given (T) type of listeners
* <br/>
* Parameters that might be given are as follows:
* <ul>
* <li>ksession</li>
* <li>taskService</li>
* <li>runtimeManager</li>
* </ul>
* @param identifier - identifier of the owner - usually RuntimeManager that allows the producer to filter out
* and provide valid instances for given owner
* @param params - owner might provide some parameters, usually KieSession, TaskService, RuntimeManager instances
* @return list of listener instances (recommendation is to always return new instances when this method is invoked)
*/
List<T> getEventListeners(String identifier, Map<String, Object> params);
}
Implementations of these interfaces shall be packaged as bean archive (includes beans.xml inside META-INF) and placed on application classpath (e.g. WEB-INF/lib for web application). THat is enough for CDI based RuntimeManager to discover them and register on every KieSession that is created or loaded from data store.
Some parameters are provided to the producers to allow handlers/listeners to be more stateful and be able to do more advanced things with the engine - like signal of the engine or process instance in case of an error. Thus all components are provided:
KieSession
TaskService
RuntimeManager
Whenever there is a need to interact with the process engine/task service from within handler or listener, recommended approach is to use RuntimeManager and retrieve RuntimeEngine (and then KieSession and/or TaskService) from it as that will ensure proper state managed according to strategy
In addition, some filtering can be applied based on identifier (that is given as argument to the methods) to decide if given RuntimeManager shall receive handlers/listeners or not.
On top of RuntimeManager API a set of high level services has been provided from jBPM version 6.2. These services are meant to be the easiest way to embed (j)BPM capabilities into custom application. A complete set of modules are delivered as part of these services. They are partitioned into several modules to ease thier adoptions in various environments.
jbpm-services-api
contains only api classes and interfaces
jbpm-kie-services
rewritten code implementation of services api - pure java, no framework dependencies
jbpm-services-cdi
CDI wrapper on top of core services implementation
jbpm-services-ejb-api
extension to services api for ejb needs
jbpm-services-ejb-impl
EJB wrappers on top of core services implementation
jbpm-services-ejb-timer
scheduler service based on EJB TimerService to support time based operations e.g. timer events, deadlines, etc
jbpm-services-ejb-client
EJB remote client implementation - currently only for JBoss
Service modules are grouped with its framework dependencies, so developers are free to choose which one is suitable for them and use only that.
As the name suggest, its primary responsibility is to deploy (and undeploy) units. Deployment unit is kjar that brings in business assets (like processes, rules, forms, data model) for execution. Deployment services allow to query it to get hold of available deployment units and even their RuntimeManager instances.
there are some restrictions on EJB remote client to do not expose RuntimeManager as it won't make any sense on client side (after it was serialized).
So typical use case for this service is to provide dynamic behavior into your system so multiple kjars can be active at the same time and be executed simultaneously.
// create deployment unit by giving GAV
DeploymentUnit deploymentUnit = new KModuleDeploymentUnit(GROUP_ID, ARTIFACT_ID, VERSION);
// deploy
deploymentService.deploy(deploymentUnit);
// retrieve deployed unit
DeployedUnit deployed = deploymentService.getDeployedUnit(deploymentUnit.getIdentifier());
// get runtime manager
RuntimeManager manager = deployed.getRuntimeManager();
Complete DeploymentService interface is as follows:
public interface DeploymentService {
void deploy(DeploymentUnit unit);
void undeploy(DeploymentUnit unit);
RuntimeManager getRuntimeManager(String deploymentUnitId);
DeployedUnit getDeployedUnit(String deploymentUnitId);
Collection<DeployedUnit> getDeployedUnits();
void activate(String deploymentId);
void deactivate(String deploymentId);
boolean isDeployed(String deploymentUnitId);
}
Upon deployment, every process definition is scanned using definition service that parses the process and extracts valuable information out of it. These information can provide valuable input to the system to inform users about what is expected. Definition service provides information about:
process definition - id, name, description
process variables - name and type
reusable subprocesses used in the process (if any)
service tasks (domain specific activities)
user tasks including assignment information
task data input and output information
So definition service can be seen as sort of supporting service that provides quite a few information about process definition that are extracted directly from BPMN2.
String processId = "org.jbpm.writedocument";
Collection<UserTaskDefinition> processTasks =
bpmn2Service.getTasksDefinitions(deploymentUnit.getIdentifier(), processId);
Map<String, String> processData =
bpmn2Service.getProcessVariables(deploymentUnit.getIdentifier(), processId);
Map<String, String> taskInputMappings =
bpmn2Service.getTaskInputMappings(deploymentUnit.getIdentifier(), processId, "Write a Document" );
While it usually is used with combination of other services (like deployment service) it can be used standalone as well to get details about process definition that do not come from kjar. This can be achieved by using buildProcessDefinition method of definition service.
public interface DefinitionService {
ProcessDefinition buildProcessDefinition(String deploymentId, String bpmn2Content,
ClassLoader classLoader, boolean cache) throws IllegalArgumentException;
ProcessDefinition getProcessDefinition(String deploymentId, String processId);
Collection<String> getReusableSubProcesses(String deploymentId, String processId);
Map<String, String> getProcessVariables(String deploymentId, String processId);
Map<String, String> getServiceTasks(String deploymentId, String processId);
Map<String, Collection<String>> getAssociatedEntities(String deploymentId, String processId);
Collection<UserTaskDefinition> getTasksDefinitions(String deploymentId, String processId);
Map<String, String> getTaskInputMappings(String deploymentId, String processId, String taskName);
Map<String, String> getTaskOutputMappings(String deploymentId, String processId, String taskName);
}
Process service is the one that usually is of the most interest. Once the deployment and definition service was already used to feed the system with something that can be executed. Process service provides access to execution environment that allows:
start new process instance
work with existing one - signal, get details of it, get variables, etc
work with work items
At the same time process service is a command executor so it allows to execute commands (essentially on ksession) to extend its capabilities.
Important to note is that process service is focused on runtime operations so use it whenever there is a need to alter (signal, change variables, etc) process instance and not for read operations like show available process instances by looping though given list and invoking getProcessInstance method. For that there is dedicated runtime data service that is described below.
An example on how to deploy and run process can be done as follows:
KModuleDeploymentUnit deploymentUnit = new KModuleDeploymentUnit(GROUP_ID, ARTIFACT_ID, VERSION);
deploymentService.deploy(deploymentUnit);
long processInstanceId = processService.startProcess(deploymentUnit.getIdentifier(), "customtask");
ProcessInstance pi = processService.getProcessInstance(processInstanceId);
As you can see start process expects deploymentId as first argument. This is extremely powerful to enable service to easily work with various deployments, even with same processes but coming from different versions - kjar versions.
public interface ProcessService {
Long startProcess(String deploymentId, String processId);
Long startProcess(String deploymentId, String processId, Map<String, Object> params);
void abortProcessInstance(Long processInstanceId);
void abortProcessInstances(List<Long> processInstanceIds);
void signalProcessInstance(Long processInstanceId, String signalName, Object event);
void signalProcessInstances(List<Long> processInstanceIds, String signalName, Object event);
ProcessInstance getProcessInstance(Long processInstanceId);
void setProcessVariable(Long processInstanceId, String variableId, Object value);
void setProcessVariables(Long processInstanceId, Map<String, Object> variables);
Object getProcessInstanceVariable(Long processInstanceId, String variableName);
Map<String, Object> getProcessInstanceVariables(Long processInstanceId);
Collection<String> getAvailableSignals(Long processInstanceId);
void completeWorkItem(Long id, Map<String, Object> results);
void abortWorkItem(Long id);
WorkItem getWorkItem(Long id);
List<WorkItem> getWorkItemByProcessInstance(Long processInstanceId);
public <T> T execute(String deploymentId, Command<T> command);
public <T> T execute(String deploymentId, Context<?> context, Command<T> command);
}
Runtime data service as name suggests, deals with all that refers to runtime information:
started process instances
executed node instances
executed node instances
and more
Use this service as main source of information whenever building list based UI - to show process definitions, process instances, tasks for given user, etc. This service was designed to be as efficient as possible and still provide all required information.
Some examples:
get all process definitions
Collection definitions = runtimeDataService.getProcesses(new QueryContext());
get active process instances
Collection<processinstancedesc> instances = runtimeDataService.getProcessInstances(new QueryContext());
get active nodes for given process instance
Collection<nodeinstancedesc> instances = runtimeDataService.getProcessInstanceHistoryActive(processInstanceId, new QueryContext());
get tasks assigned to john
List<tasksummary> taskSummaries = runtimeDataService.getTasksAssignedAsPotentialOwner("john", new QueryFilter(0, 10));
There are two important arguments that the runtime data service operations supports:
QueryContext
QueryFilter - extension of QueryContext
These provide capabilities for efficient management result set like pagination, sorting and ordering (QueryContext). Moreover additional filtering can be applied to task queries to provide more advanced capabilities when searching for user tasks.
public interface RuntimeDataService {
// Process instance information
Collection<ProcessInstanceDesc> getProcessInstances(QueryContext queryContext);
Collection<ProcessInstanceDesc> getProcessInstances(List<Integer> states, String initiator, QueryContext queryContext);
Collection<ProcessInstanceDesc> getProcessInstancesByProcessId(List<Integer> states, String processId, String initiator, QueryContext queryContext);
Collection<ProcessInstanceDesc> getProcessInstancesByProcessName(List<Integer> states, String processName, String initiator, QueryContext queryContext);
Collection<ProcessInstanceDesc> getProcessInstancesByDeploymentId(String deploymentId, List<Integer> states, QueryContext queryContext);
ProcessInstanceDesc getProcessInstanceById(long processInstanceId);
Collection<ProcessInstanceDesc> getProcessInstancesByProcessDefinition(String processDefId, QueryContext queryContext);
Collection<ProcessInstanceDesc> getProcessInstancesByProcessDefinition(String processDefId, List<Integer> states, QueryContext queryContext);
// Node and Variable instance information
NodeInstanceDesc getNodeInstanceForWorkItem(Long workItemId);
Collection<NodeInstanceDesc> getProcessInstanceHistoryActive(long processInstanceId, QueryContext queryContext);
Collection<NodeInstanceDesc> getProcessInstanceHistoryCompleted(long processInstanceId, QueryContext queryContext);
Collection<NodeInstanceDesc> getProcessInstanceFullHistory(long processInstanceId, QueryContext queryContext);
Collection<NodeInstanceDesc> getProcessInstanceFullHistoryByType(long processInstanceId, EntryType type, QueryContext queryContext);
Collection<VariableDesc> getVariablesCurrentState(long processInstanceId);
Collection<VariableDesc> getVariableHistory(long processInstanceId, String variableId, QueryContext queryContext);
// Process information
Collection<ProcessDefinition> getProcessesByDeploymentId(String deploymentId, QueryContext queryContext);
Collection<ProcessDefinition> getProcessesByFilter(String filter, QueryContext queryContext);
Collection<ProcessDefinition> getProcesses(QueryContext queryContext);
Collection<String> getProcessIds(String deploymentId, QueryContext queryContext);
ProcessDefinition getProcessById(String processId);
ProcessDefinition getProcessesByDeploymentIdProcessId(String deploymentId, String processId);
// user task query operations
UserTaskInstanceDesc getTaskByWorkItemId(Long workItemId);
UserTaskInstanceDesc getTaskById(Long taskId);
List<TaskSummary> getTasksAssignedAsBusinessAdministrator(String userId, QueryFilter filter);
List<TaskSummary> getTasksAssignedAsBusinessAdministratorByStatus(String userId, List<Status> statuses, QueryFilter filter);
List<TaskSummary> getTasksAssignedAsPotentialOwner(String userId, QueryFilter filter);
List<TaskSummary> getTasksAssignedAsPotentialOwner(String userId, List<String> groupIds, QueryFilter filter);
List<TaskSummary> getTasksAssignedAsPotentialOwnerByStatus(String userId, List<Status> status, QueryFilter filter);
List<TaskSummary> getTasksAssignedAsPotentialOwner(String userId, List<String> groupIds, List<Status> status, QueryFilter filter);
List<TaskSummary> getTasksAssignedAsPotentialOwnerByExpirationDateOptional(String userId, List<Status> status, Date from, QueryFilter filter);
List<TaskSummary> getTasksOwnedByExpirationDateOptional(String userId, List<Status> strStatuses, Date from, QueryFilter filter);
List<TaskSummary> getTasksOwned(String userId, QueryFilter filter);
List<TaskSummary> getTasksOwnedByStatus(String userId, List<Status> status, QueryFilter filter);
List<Long> getTasksByProcessInstanceId(Long processInstanceId);
List<TaskSummary> getTasksByStatusByProcessInstanceId(Long processInstanceId, List<Status> status, QueryFilter filter);
List<AuditTask> getAllAuditTask(String userId, QueryFilter filter);
}
User task service covers complete life cycle of individual task so it can be managed from start to end. It explicitly eliminates queries from it to provide scoped execution and moves all query operations into runtime data service. Besides lifecycle operations user task service allows:
modification of selected properties
access to task variables
access to task attachments
access to task comments
On top of that user task service is a command executor as well that allows to execute custom task commands.
Complete example with start process and complete user task done by services:
long processInstanceId =
processService.startProcess(deployUnit.getIdentifier(), "org.jbpm.writedocument");
List<Long> taskIds =
runtimeDataService.getTasksByProcessInstanceId(processInstanceId);
Long taskId = taskIds.get(0);
userTaskService.start(taskId, "john");
UserTaskInstanceDesc task = runtimeDataService.getTaskById(taskId);
Map<String, Object> results = new HashMap<String, Object>();
results.put("Result", "some document data");
userTaskService.complete(taskId, "john", results);
The most important thing when working with services is that there is no more need to create your own implementations of Process service that simply wraps runtime manager, runtime engine, ksession usage. Services make use of RuntimeManager API best practices and thus eliminate various risks when working with that API.
Deployment Service provides convinient way to put business assets to an execution environment but there are cases that requires some additional management to make them available in right context.
Activation and Deactivation of deployments
Imagine situation where there are number of processes already running of given deployment and then new version of these processes comes into the runtime environment. With that administrator can decide that new instances of given process definition should be using new version only while already active instances should continue with the previous version.
To help with that deployment service has been equipped with following methods:
activate
allows to activate given deployment so it can be available for interaction meaning will show its process definition and allow to start new process instances of that project's processes
deactivate
allows to deactivate deployment which will disable option to see or start new process instances of that project's processes but will allow to continue working with already active process instances, e.g. signal, work with user task etc
This feature allows smooth transition between project versions whitout need of process instance migration.
Deployment synchronization
Prior to jBPM 6.2, jbpm services did not have deployment store by default. When embedded in jbpm-console/kie-wb they utilized sistem.git VFS repository to preserve deployed units across server restarts. While that works fine, it comes with some drawbacks:
not available for custom systems that use services
requires complex setup in cluster - zookeeper and helix
With version 6.2 jbpm services come with deployment synchronizer that stores available deployments into data base, including its deployment descriptor. At the same time it constantly monitors that table to keep it in sync with other installations that might be using same data source. This is especially important when running in cluster or when jbpm console runs next to custom application and both should be able to operate on the same artifacts.
By default synchronization must be configured (when runing as core services while it is automatically enabled for ejb and cdi extensions). To configure synchronization following needs to be configured:
TransactionalCommandService commandService = new TransactionalCommandService(emf);
DeploymentStore store = new DeploymentStore();
store.setCommandService(commandService);
DeploymentSynchronizer sync = new DeploymentSynchronizer();
sync.setDeploymentService(deploymentService);
sync.setDeploymentStore(store);
DeploymentSyncInvoker invoker = new DeploymentSyncInvoker(sync, 2L, 3L, TimeUnit.SECONDS);
invoker.start();
....
invoker.stop();
With this, deployments will be synchronized every 3 seconds with initial delay of two seconds.
Invoking latest version of project's processes
In case there is a need to always work with latest version of project's process, services allow to interact with various operations using deployment id with latest keyword. Let's go over an example to better understand the feature.
Initially deployed unit is org.jbpm:HR:1.0 which has the first version of an hiring process. After several weeks, new version is developed and deployed to the execution server - org.jbpm:HR.2.0 with version 2 of the hiring process.
To allow callers of the services to interact without being worried if they work with latest version, they can use following deployment id:
org.jbpm.HR:latest
this will alwyas find out latest available version of project that is identified by:
groupId: org.jbpm
artifactId: HR
version comparizon is based on Maven version numbers and relies on Maen based algorithm to find the latest one.
This is only supported when process identifier remains the same in all project versions
Here is a complete example with deployment of multiple versions and interacting always with the latest:
KModuleDeploymentUnit deploymentUnitV1 = new KModuleDeploymentUnit("org.jbpm", "HR", "1.0");
deploymentService.deploy(deploymentUnitV1);
long processInstanceId = processService.startProcess("org.jbpm:HR:LATEST", "customtask");
ProcessInstanceDesc piDesc = runtimeDataService.getProcessInstanceById(processInstanceId);
// we have started process with project's version 1
assertEquals(deploymentUnitV1.getIdentifier(), piDesc.getDeploymentId());
// next we deploy version 1
KModuleDeploymentUnit deploymentUnitV2 = new KModuleDeploymentUnit("org.jbpm", "HR", "2.0");
deploymentService.deploy(deploymentUnitV2);
processInstanceId = processService.startProcess("org.jbpm:HR:LATEST", "customtask");
piDesc = runtimeDataService.getProcessInstanceById(processInstanceId);
// this time we have started process with project's version 2
assertEquals(deploymentUnitV2.getIdentifier(), piDesc.getDeploymentId());
As illustrated this provides very powerful feature when interacting with frequently chaning environment that allows to always be up to date when it comes to use of process definitions.
This feature is also available in REST interface so whenever sending request with deployment id, it's enough to replace concrete version with LATEST keyword to make use of this feature.
There are several control parameters available to alter engine default behavior. This allows to fine tune the execution for the environment needs and actual requirements. All of these parameters are set as JVM system properties, usually with -D when starting program e.g. application server.
Table 5.1. Control parameters
Name | Possible values | Default value | Description | |
---|---|---|---|---|
jbpm.ut.jndi.lookup | String | Alternative JNDI name to be used when there is no access to the default one (java:comp/UserTransaction) | ||
jbpm.enable.multi.con | true|false | false | Enables multiple incoming/outgoing sequence flows support for activities | |
jbpm.business.calendar.properties | String | /jbpm.business.calendar.properties | Allows to provide alternative classpath location of business calendar configuration file | |
jbpm.overdue.timer.delay | Long | 2000 | Specifies delay for overdue timers to allow proper initialization, in milliseconds | |
jbpm.process.name.comparator | String | Allows to provide alternative comparator class to empower start process by name feature, if not set NumberVersionComparator is used | ||
jbpm.loop.level.disabled | true|false | true | Allows to enable or disable loop iteration tracking, to allow advanced loop support when using XOR gateways | |
org.kie.mail.session | String | mail/jbpmMailSession | Allows to provide alternative JNDI name for mail session used by Task Deadlines | |
jbpm.usergroup.callback.properties | String | /jbpm.usergroup.callback.properties | Allows to provide alternative classpath location for user group callback implementation (LDAP, DB) | |
jbpm.user.group.mapping | String | ${jboss.server.config.dir}/roles.properties | Allows to provide alternative location of roles.properties for JBossUserGroupCallbackImpl | |
jbpm.user.info.properties | String | /jbpm.user.info.properties | Allows to provide alternative classpath location of user info configuration (used by LDAPUserInfoImpl) | |
org.jbpm.ht.user.separator | String | , | Allows to provide alternative separator of actors and groups for user tasks, default is comma (,) | |
org.quartz.properties | String | Allows to provide location of the quartz config file to activate quartz based timer service | ||
jbpm.data.dir | String | ${jboss.server.data.dir} is available otherwise ${java.io.tmpdir} | Allows to provide location where data files produced by jbpm should be stored | |
org.kie.executor.pool.size | Integer | 1 | Allows to provide thread pool size for jbpm executor | |
org.kie.executor.retry.count | Integer | 3 | Allows to provide number of retries attempted in case of error by jbpm executor | |
org.kie.executor.interval | Integer | 3 | Allows to provide frequency used to check for pending jobs by jbpm executor, in seconds | |
org.kie.executor.disabled | true|false | true | Enables or disable jbpm executor |
"The primary goal of BPMN is to provide a notation that is readily understandable by all business users, from the business analysts that create the initial drafts of the processes, to the technical developers responsible for implementing the technology that will perform those processes, and finally, to the business people who will manage and monitor those processes."
The Business Process Model and Notation (BPMN) 2.0 specification is an OMG specification that not only defines a standard on how to graphically represent a business process (like BPMN 1.x), but now also includes execution semantics for the elements defined, and an XML format on how to store (and share) process definitions.
jBPM6 allows you to execute processes defined using the BPMN 2.0 XML format. That means that you can use all the different jBPM6 tooling to model, execute, manage and monitor your business processes using the BPMN 2.0 format for specifying your executable business processes. Actually, the full BPMN 2.0 specification also includes details on how to represent things like choreographies and collaboration. The jBPM project however focuses on that part of the specification that can be used to specify executable processes.
Executable processes in BPMN consist of a different types of nodes being connected to each other using sequence flows. The BPMN 2.0 specification defines three main types of nodes:
jBPM6 does not implement all elements and attributes as defined in the BPMN 2.0 specification. We do however support a significant subset, including the most common node types that can be used inside executable processes. This includes (almost) all elements and attributes as defined in the "Common Executable" subclass of the BPMN 2.0 specification, extended with some additional elements and attributes we believe are valuable in that context as well. The full set of elements and attributes that are supported can be found below, but it includes elements like:
For example, consider the following "Hello World" BPMN 2.0 process, which does nothing more that writing out a "Hello World" statement when the process is started.
An executable version of this process expressed using BPMN 2.0 XML would look something like this:
<?xml version="1.0" encoding="UTF-8"?>
<definitions id="Definition"
targetNamespace="http://www.example.org/MinimalExample"
typeLanguage="http://www.java.com/javaTypes"
expressionLanguage="http://www.mvel.org/2.0"
xmlns="http://www.omg.org/spec/BPMN/20100524/MODEL"
xmlns:xs="http://www.w3.org/2001/XMLSchema-instance"
xs:schemaLocation="http://www.omg.org/spec/BPMN/20100524/MODEL BPMN20.xsd"
xmlns:bpmndi="http://www.omg.org/spec/BPMN/20100524/DI"
xmlns:dc="http://www.omg.org/spec/DD/20100524/DC"
xmlns:di="http://www.omg.org/spec/DD/20100524/DI"
xmlns:tns="http://www.jboss.org/drools">
<process processType="Private" isExecutable="true" id="com.sample.HelloWorld" name="Hello World" >
<!-- nodes -->
<startEvent id="_1" name="StartProcess" />
<scriptTask id="_2" name="Hello" >
<script>System.out.println("Hello World");</script>
</scriptTask>
<endEvent id="_3" name="EndProcess" >
<terminateEventDefinition/>
</endEvent>
<!-- connections -->
<sequenceFlow id="_1-_2" sourceRef="_1" targetRef="_2" />
<sequenceFlow id="_2-_3" sourceRef="_2" targetRef="_3" />
</process>
<bpmndi:BPMNDiagram>
<bpmndi:BPMNPlane bpmnElement="Minimal" >
<bpmndi:BPMNShape bpmnElement="_1" >
<dc:Bounds x="15" y="91" width="48" height="48" />
</bpmndi:BPMNShape>
<bpmndi:BPMNShape bpmnElement="_2" >
<dc:Bounds x="95" y="88" width="83" height="48" />
</bpmndi:BPMNShape>
<bpmndi:BPMNShape bpmnElement="_3" >
<dc:Bounds x="258" y="86" width="48" height="48" />
</bpmndi:BPMNShape>
<bpmndi:BPMNEdge bpmnElement="_1-_2" >
<di:waypoint x="39" y="115" />
<di:waypoint x="75" y="46" />
<di:waypoint x="136" y="112" />
</bpmndi:BPMNEdge>
<bpmndi:BPMNEdge bpmnElement="_2-_3" >
<di:waypoint x="136" y="112" />
<di:waypoint x="240" y="240" />
<di:waypoint x="282" y="110" />
</bpmndi:BPMNEdge>
</bpmndi:BPMNPlane>
</bpmndi:BPMNDiagram>
</definitions>
To create your own process using BPMN 2.0 format, you can
The jBPM Designer is an open-source web-based editor that supports the BPMN 2.0 format. We have embedded it into jbpm console for BPMN 2.0 process visualization and editing. You could use the Designer (either standalone or integrated) to create / edit BPMN 2.0 processes and then export them to BPMN 2.0 format or save them into repository and import them so they can be executed.
A new BPMN2 Eclipse plugin is being created to support the full BPMN2 specification.
You can always manually create your BPMN 2.0 process files by writing the XML directly. You can validate the syntax of your processes against the BPMN 2.0 XSD, or use the validator in the Eclipse plugin to check both syntax and completeness of your model.
Drools Eclipse Process editor has been deprecated in favor of BPMN2 Modeler for process modeling. It can still be used for limited number of supported elements but should be faced out as it is not being developed any more.
Create a new Process file using the Drools Eclipse plugin wizard and in the last page of the wizard, make sure you select Drools 5.1 code compatibility. This will create a new process using the BPMN 2.0 XML format. Note however that this is not exactly a BPMN 2.0 editor, as it still uses different attributes names etc. It does however save the process using valid BPMN 2.0 syntax. Also note that the editor does not support all node types and attributes that are already supported in the execution engine.
The following code fragment shows you how to load a BPMN2 process into your knowledge base ...
private static KnowledgeBase createKnowledgeBase() throws Exception {
KieHelper kieHelper = new KieHelper();
KieBase kieBase = kieHelper
.addResource(ResourceFactory.newClassPathResource("sample.bpmn2"))
.build();
return kieBase;
}
... and how to execute this process ...
KieBase kbase = createKnowledgeBase();
KieSession ksession = kbase.newKieSession();
ksession.startProcess("com.sample.HelloWorld");
For more detail, check out the chapter on the API and the basics.
A business process is a graph that describes the order in which a series of steps need to be executed, using a flow chart. A process consists of a collection of nodes that are linked to each other using connections. Each of the nodes represents one step in the overall process while the connections specify how to transition from one node to the other. A large selection of predefined node types have been defined. This chapter describes how to define such processes and use them in your application.
Processes can be created by using one of the following three methods:
The graphical BPMN2 editor is an editor that allows you to create a process by dragging and dropping different nodes on a canvas and editing the properties of these nodes. The graphical BPMN2 modeler is an Eclipse plugin hosted on eclipse.org that provides number of contributors where one of them is jBPM project. Once you have set up a jBPM project (see the installer for creating a working Eclipse environment where you can start), you can start adding processes. When in a project, launch the "New" wizard (use Ctrl+N) or right-click the directory you would like to put your process in and select "New", then "File". Give the file a name and the extension bpmn (e.g. MyProcess.bpmn). This will open up the process editor (you can safely ignore the warning that the file could not be read, this is just because the file is still empty).
First, ensure that you can see the Properties View down the bottom of the Eclipse window, as it will be necessary to fill in the different properties of the elements in your process. If you cannot see the properties view, open it using the menu "Window", then "Show View" and "Other...", and under the "General" folder select the Properties View.
The process editor consists of a palette, a canvas and an outline view. To add new elements to the canvas, select the element you would like to create in the palette and then add them to the canvas by clicking on the preferred location. For example, click on the "End Event" icon in the palette of the GUI. Clicking on an element in your process allows you to set the properties of that element. You can connect the nodes (as long as it is permitted by the different types of nodes) by using "Sequence Flow" from the palette.
You can keep adding nodes and connections to your process until it represents the business logic that you want to specify.
It is also possible to specify processes using the underlying BPMN 2.0 XML directly. The syntax of these XML processes is defined using the BPMN 2.0 XML Schema Definition. For example, the following XML fragment shows a simple process that contains a sequence of a Start Event, a Script Task that prints "Hello World" to the console, and an End Event.
<?xml version="1.0" encoding="UTF-8"?>
<definitions id="Definition"
targetNamespace="http://www.jboss.org/drools"
typeLanguage="http://www.java.com/javaTypes"
expressionLanguage="http://www.mvel.org/2.0"
xmlns="http://www.omg.org/spec/BPMN/20100524/MODEL"Rule Task
xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
xsi:schemaLocation="http://www.omg.org/spec/BPMN/20100524/MODEL BPMN20.xsd"
xmlns:g="http://www.jboss.org/drools/flow/gpd"
xmlns:bpmndi="http://www.omg.org/spec/BPMN/20100524/DI"
xmlns:dc="http://www.omg.org/spec/DD/20100524/DC"
xmlns:di="http://www.omg.org/spec/DD/20100524/DI"
xmlns:tns="http://www.jboss.org/drools">
<process processType="Private" isExecutable="true" id="com.sample.hello" name="Hello Process" >
<!-- nodes -->
<startEvent id="_1" name="Start" />
<scriptTask id="_2" name="Hello" >
<script>System.out.println("Hello World");</script>
</scriptTask>
<endEvent id="_3" name="End" >
<terminateEventDefinition/>
</endEvent>
<!-- connections -->
<sequenceFlow id="_1-_2" sourceRef="_1" targetRef="_2" />
<sequenceFlow id="_2-_3" sourceRef="_2" targetRef="_3" />
</process>
<bpmndi:BPMNDiagram>
<bpmndi:BPMNPlane bpmnElement="com.sample.hello" >
<bpmndi:BPMNShape bpmnElement="_1" >
<dc:Bounds x="16" y="16" width="48" height="48" />
</bpmndi:BPMNShape>
<bpmndi:BPMNShape bpmnElement="_2" >
<dc:Bounds x="96" y="16" width="80" height="48" />
</bpmndi:BPMNShape>
<bpmndi:BPMNShape bpmnElement="_3" >
<dc:Bounds x="208" y="16" width="48" height="48" />
</bpmndi:BPMNShape>
<bpmndi:BPMNEdge bpmnElement="_1-_2" >
<di:waypoint x="40" y="40" />
<di:waypoint x="136" y="40" />
</bpmndi:BPMNEdge>
<bpmndi:BPMNEdge bpmnElement="_2-_3" >
<di:waypoint x="136" y="40" />
<di:waypoint x="232" y="40" />
</bpmndi:BPMNEdge>
</bpmndi:BPMNPlane>
</bpmndi:BPMNDiagram>
</definitions>
The process XML file consists of two parts, the top part (the "process" element) contains the definition of the different nodes and their properties, the lower part (the "BPMNDiagram" element) contains all graphical information, like the location of the nodes. The process XML consist of exactly one <process> element. This element contains parameters related to the process (its type, name, id and package name), and consists of three subsections: a header section (where process-level information like variables, globals, imports and lanes can be defined), a nodes section that defines each of the nodes in the process, and a connections section that contains the connections between all the nodes in the process. In the nodes section, there is a specific element for each node, defining the various parameters and, possibly, sub-elements for that node type.
A BPMN2 process is a flow chart where different types of nodes are linked using connections. The process itself exposes the following properties:
Id: The unique id of the process.
Name: The display name of the process.
Version: The version number of the process.
Package: The package (namespace) the process is defined in.
In addition to that following can be defined as well:
Represents a script that
should be executed in this process. A Script Task should have one incoming
connection and one outgoing connection. The associated action specifies what
should be executed, the dialect used for coding the action (i.e., Java or MVEL),
and the actual action code. This code can access any variables and globals.
There is also a predefined variable kcontext
that references the
ProcessContext
object (which can,
for example, be used to access the current ProcessInstance
or
NodeInstance
, and to get and set variables, or get access to the
ksession using kcontext.getKieRuntime()
). When a Script Task
is reached in the process, it will execute the action and then continue with the
next node. It contains the following properties:
Id: The id of the node (which is unique within one node container).
Name: The display name of the node.
Action: The action script associated with this action node.
Note that you can write any valid Java code inside a script node. This basically allows you to do anything inside such a script node. There are some caveats however:
Represents an (abstract) unit of work that should be executed in this process. All work that is executed outside the process engine should be represented (in a declarative way) using a Service Task. Different types of services are predefined, e.g., sending an email, logging a message, etc. Users can define domain-specific services or work items, using a unique name and by defining the parameters (input) and results (output) that are associated with this type of work. Check the chapter on domain-specific processes for a detailed explanation and illustrative examples of how to define and use work items in your processes. When a Service Task is reached in the process, the associated work is executed. A Service Task should have one incoming connection and one outgoing connection.
Id: The id of the node (which is unique within one node container).
Name: The display name of the node.
Parameter mapping: Allows copying the value of process variables to parameters of the work item. Upon creation of the work item, the values will be copied.
Result mapping: Allows copying the value
of result parameters of the work item to a process variable. Each
type of work can define result parameters that will (potentially)
be returned after the work item has been completed. A result
mapping can be used to copy the value of the given result parameter
to the given variable in this process. For example, the "FileFinder"
work item returns a list of files that match the given search
criteria within the result parameter Files
. This list
of files can then be bound to a process variable for use within the
process. Upon completion of the work item, the values will be copied.
On-entry and on-exit actions: Actions that are executed upon entry or exit of this node, respectively.
Additional parameters: Each type of work
item can define additional parameters that are relevant for that
type of work. For example, the "Email" work item defines additional
parameters such as From
, To
, Subject
and Body
. The user can either provide values for these
parameters directly, or define a
parameter mapping that will copy the value of the given variable
in this process to the given parameter; if both are specified, the
mapping will have precedence. Parameters of type String
can use
#{expression}
to embed a value in the
string. The value will be retrieved when creating the work item, and the
substitution expression will be replaced by the result of calling
toString()
on the variable. The expression could
simply be the name of a variable (in which case it resolves
to the value of the variable), but more advanced MVEL expressions
are possible as well, e.g., #{person.name.firstname}
.
Processes can also involve tasks that need to be executed by human actors. A User Task represents an atomic task to be executed by a human actor. It should have one incoming connection and one outgoing connection. User Tasks can be used in combination with Swimlanes to assign multiple human tasks to similar actors. Refer to the chapter on human tasks for more details. A User Task is actually nothing more than a specific type of service node (of type "Human Task"). A User Task contains the following properties:
Id: The id of the node (which is unique within one node container).
Name: The display name of the node.
TaskName: The name of the human task.
Priority: An integer indicating the priority of the human task.
Comment: A comment associated with the human task.
ActorId: The actor id that is responsible for executing the human task. A list of actor id's can be specified using a comma (',') as separator.
GroupId: The group id that is responsible for executing the human task. A list of group id's can be specified using a comma (',') as separator.
Skippable: Specifies whether the human task can be skipped, i.e., whether the actor may decide not to execute the task.
Content: The data associated with this task.
Swimlane: The swimlane this human task node is part of. Swimlanes make it easy to assign multiple human tasks to the same actor. See the human tasks chapter for more detail on how to use swimlanes.
On entry and on exit actions: Action scripts that are executed upon entry and exit of this node, respectively.
Parameter mapping: Allows copying the value of process variables to parameters of the human task. Upon creation of the human tasks, the values will be copied.
Result mapping: Allows copying the value of result parameters of the human task to a process variable. Upon completion of the human task, the values will be copied. A human task has a result variable "Result" that contains the data returned by the human actor. The variable "ActorId" contains the id of the actor that actually executed the task.
A user task should define the type of task that needs to be executed (using properties like TaskName, Comment, etc.) and who needs to perform it (using either actorId or groupId). Note that if there is data related to this specific process instance that the end user needs when performing the task, this data should be passed as the content of the task. The task for example does not have access to process variables. Check out the chapter on human tasks to get more detail on how to pass data between human tasks and the process instance.
Represents the invocation of another process from within this process. A sub-process node should have one incoming connection and one outgoing connection. When a Reusable Sub-Process node is reached in the process, the engine will start the process with the given id. It contains the following properties:
Id: The id of the node (which is unique within one node container).
Name: The display name of the node.
ProcessId: The id of the process that should be executed.
Wait for completion (by default true): If this property is true, this sub-process node will only continue if the child process that was started has terminated its execution (completed or aborted); otherwise it will continue immediately after starting the subprocess (so it will not wait for its completion).
Independent (by default true): If this property is true, the child process is started as an independent process, which means that the child process will not be terminated if this parent process is completed (or this sub-process node is canceled for some other reason); otherwise the active sub-process will be canceled on termination of the parent process (or cancellation of the sub-process node). Note that you can only set independent to "false" only when "Wait for completion" is set to true.
On-entry and on-exit actions: Actions that are executed upon entry or exit of this node, respectively.
Parameter in/out mapping: A sub-process node can also define in- and out-mappings for variables. The variables given in the "in" mapping will be used as parameters (with the associated parameter name) when starting the process. The variables of the child process that are defined for the "out" mappings will be copied to the variables of this process when the child process has been completed. Note that you can use "out" mappings only when "Wait for completion" is set to true.
A Business Rule Task Represents a set of rules that need to be
evaluated. The rules are evaluated when the node is reached. A Rule
Task should have one incoming connection and one outgoing connection.
Rules are defined in separate files using the Drools rule format. Rules
can become part of a specific ruleflow group using the ruleflow-group
attribute in the header of the rule.
When a Rule Task is reached in the process, the engine will start executing rules that are part of the corresponding ruleflow-group (if any). Execution will automatically continue to the next node if there are no more active rules in this ruleflow group. As a result, during the execution of a ruleflow group, new activations belonging to the currently active ruleflow group can be added to the Agenda due to changes made to the facts by the other rules. Note that the process will immediately continue with the next node if it encounters a ruleflow group where there are no active rules at that time.
If the ruleflow group was already active, the ruleflow group will remain active and execution will only continue if all active rules of the ruleflow group has been completed. It contains the following properties:
Id: The id of the node (which is unique within one node container).
Name: The display name of the node.
RuleFlowGroup: The name of the ruleflow group that represents the set of rules of this RuleFlowGroup node.
A Sub-Process is a node that can contain other nodes so that it acts as a node container. This allows not only the embedding of a part of the process within such a sub-process node, but also the definition of additional variables that are accessible for all nodes inside this container. A sub-process should have one incoming connection and one outgoing connection. It should also contain one start node that defines where to start (inside the Sub-Process) when you reach the sub-process. It should also contain one or more end events. Note that, if you use a terminating event node inside a sub-process, you are terminating just that sub-process. A sub-process ends when there are no more active nodes inside the sub-process. It contains the following properties:
Id: The id of the node (which is unique within one node container).
Name: The display name of the node.
Variables: Additional variables can be defined to store data during the execution of this node. See section “???” for details.
A Multiple Instance sub-process is a special kind of sub-process that allows you to execute the contained process segment multiple times, once for each element in a collection. A multiple instance sub-process should have one incoming connection and one outgoing connection. It waits until the embedded process fragment is completed for each of the elements in the given collection before continuing. It contains the following properties:
Id: The id of the node (which is unique within one node container).
Name: The display name of the node.
CollectionExpression: The name of a
variable that represents the collection of elements that should
be iterated over. The collection variable should be an array or
of type java.util.Collection
. If the collection
expression evaluates to null or an empty collection, the multiple
instances sub-process will be completed immediately and follow its
outgoing connection.
VariableName: The name of the variable to contain the current element from the collection. This gives nodes within the composite node access to the selected element.
CollectionOutput: The name of a variable that represents collection of elements that will gather all output of the multi instance sub process
OutputVariableName: The name of the variable to contain the currentl output from the multi instance activitiy
CompletionCondition: MVEL expression that will be evaluated on each instance completion to check if given multi instance activity can already be completed. In case it evaluates to true all other remaining instances within multi instance activity will be canceled.
The start of the process. A process should have exactly one start node (none start node which does not have event definitions), which cannot have incoming connections and should have one outgoing connection. Whenever a process is started, execution will start at this node and automatically continue to the first node linked to this start event, and so on. It contains the following properties:
Id: The id of the node (which is unique within one node container).
Name: The display name of the node.
The end of the process. A process should have one or more end events. The End Event should have one incoming connection and cannot have any outgoing connections. It contains the following properties:
Id: The id of the node (which is unique within one node container).
Name: The display name of the node.
Terminate: An End Event can terminate the entire process or just the path. When a process instance is terminated, it means its state is set to completed and all other nodes that might still be active (on parallel paths) in this process instance are canceled. Non-terminating end events are simply end for this path (execution of this branch will end here), but other parallel paths can still continue. A process instance will automatically complete if there are no more active paths inside that process instance (for example, if a process instance reaches a non-terminating end node but there are no more active branches inside the process instance, the process instance will be completed anyway). Terminating end events are visualized using a full circle inside the event node, non-terminating event nodes are empty. Note that, if you use a terminating event node inside a sub-process, you are terminating just that sub-process and top level continues.
An Error Event can be used to signal an exceptional condition in the process. It should have one incoming connection and no outgoing connections. When an Error Event is reached in the process, it will throw an error with the given name. The process will search for an appropriate error handler that is capable of handling this kind of fault. If no error handler is found, the process instance will be aborted. An Error Event contains the following properties:
Id: The id of the node (which is unique within one node container).
Name: The display name of the node.
FaultName: The name of the fault. This name is used to search for appropriate exception handlers that are capable of handling this kind of fault.
FaultVariable: The name of the variable that contains the data associated with this fault. This data is also passed on to the exception handler (if one is found).
Error handlers can be specified using boundary events.
Represents a timer that can trigger one or multiple times after a given period of time. A Timer Event should have one incoming connection and one outgoing connection. The timer delay specifies how long the timer should wait before triggering the first time. When a Timer Event is reached in the process, it will start the associated timer. The timer is canceled if the timer node is canceled (e.g., by completing or aborting the enclosing process instance). Consult the section “???” for more information. The Timer Event contains the following properties:
Id: The id of the node (which is unique within one node container).
Name: The display name of the node.
Timer delay: The delay that the node should wait before
triggering the first time. The expression should be of the form
[#d][#h][#m][#s][#[ms]]
. This allows you to specify the number of days,
hours, minutes, seconds and milliseconds (which is the default if you don't specify
anything). For example, the expression "1h" will wait one hour before triggering the
timer. The expression could also use #{expr} to dynamically derive the delay based on
some process variable. Expr in this case could be a process variable, or a more complex
expression based on a process variable (e.g. myVariable.getValue()). It does support
CRON like expression as well.
Timer period: The period
between two subsequent triggers. If the period is 0, the timer should
only be triggered once. The expression should be of the form
[#d][#h][#m][#s][#[ms]]
. You can specify the number of days,
hours, minutes, seconds and milliseconds (which is the default if you don't
specify anything). For example, the expression "1h" will wait one hour
before triggering the timer again. The expression could also use #{expr} to
dynamically derive the period based on some process variable. Expr in this
case could be a process variable, or a more complex expression based on a
process variable (e.g. myVariable.getValue()).
Timer events could also be specified as boundary events on sub-processes and tasks that are not automatic tasks like script task that have no wait state as timer will not have a change to fire before task completion.
A Signal Event can be used to respond to internal or external events during the execution of the process. A Signal Event should have one incoming connections and one outgoing connection. It specifies the type of event that is expected. Whenever that type of event is detected, the node connected to this event node will be triggered. It contains the following properties:
Id: The id of the node (which is unique within one node container).
Name: The display name of the node.
EventType: The type of event that is expected.
VariableName: The name of the variable that will contain the data associated with this event (if any) when this event occurs.
A process instance can be signaled that a specific event occurred using
ksession.signalEvent(eventType, data, processInstanceId)
This will trigger all (active) signal event nodes in the given process instance that are waiting for that event type. Data related to the event can be passed using the data parameter. If the event node specifies a variable name, this data will be copied to that variable when the event occurs.
It is also possible to use event nodes inside sub-processes. These event nodes will however only be active when the sub-process is active.
You can also generate a signal from inside a process instance. A script (in a script task or using on entry or on exit actions) can use
kcontext.getKieRuntime().signalEvent(eventType, data, kcontext.getProcessInstance().getId());
A throwing signal event could also be used to model the signaling of an event.
Allows you to create branches in your process. A Diverging Gateway should have one incoming connection and two or more outgoing connections. There are three types of gateway nodes currently supported:
AND or parallel means that the control flow will continue in all outgoing connections simultaneously.
XOR or exclusive means that exactly one of the outgoing connections will be chosen. The decision is made by evaluating the constraints that are linked to each of the outgoing connections. The constraint with the lowest priority number that evaluates to true is selected. Constraints can be specified using different dialects. Note that you should always make sure that at least one of the outgoing connections will evaluate to true at runtime (the engine will throw an exception at runtime if it cannot find at least one outgoing connection).
OR or inclusive means that all outgoing connections whose condition evaluates to true are selected. Conditions are similar to the exclusive gateway, except that no priorities are taken into account. Note that you should make sure that at least one of the outgoing connections will evaluate to true at runtime because the engine will throw an exception at runtime if it cannot determine an outgoing connection.
It contains the following properties:
Id: The id of the node (which is unique within one node container).
Name: The display name of the node.
Type: The type of the split node, i.e., AND, XOR or OR (see above).
Constraints: The constraints linked to each of the outgoing connections (in case of an exclusive or inclusive gateway).
Allows you to synchronize multiple branches. A Converging Gateway should have two or more incoming connections and one outgoing connection. There are three types of splits currently supported:
AND or parallel means that is will wait until all incoming branches are completed before continuing.
XOR or exclusive means that it continues as soon as one of its incoming branches has been completed. If it is triggered from more than one incoming connection, it will trigger the next node for each of those triggers.
OR or inclusive means that it continues as soon as all direct active paths of its incoming branches has been completed. This is complex merge behaviour that is described in BPMN2 specification but in most cases it means that OR join will wait for all active flows that started in OR split. Some advanced cases (including other gateways in between or repeatable timers) will be causing different "direct active path" calculation.
It contains the following properties:
Id: The id of the node (which is unique within one node container).
Name: The display name of the node.
Type: The type of the Join node, i.e. AND, OR or XOR.
While the flow chart focuses on specifying the control flow of the process, it is usually also necessary to look at the process from a data perspective. Throughout the execution of a process, data can be retrieved, stored, passed on and used.
For storing runtime data, during the execution of the process, process variables can be used. A variable is defined by a name and a data type. This could be a basic data type, such as boolean, int, or String, or any kind of Object subclass (it must implement Serializable interface). Variables can be defined inside a variable scope. The top-level scope is the variable scope of the process itself. Subscopes can be defined using a Sub-Process. Variables that are defined in a subscope are only accessible for nodes within that scope.
Whenever a variable is accessed, the process will search for the appropriate variable scope that defines the variable. Nesting of variable scopes is allowed. A node will always search for a variable in its parent container. If the variable cannot be found, it will look in that one's parent container, and so on, until the process instance itself is reached. If the variable cannot be found, a read access yields null, and a write access produces an error message, with the process continuing its execution.
Variables can be used in various ways:
Process-level variables can be set when starting a process
by providing a map of parameters to the invocation of the
startProcess
method. These parameters will be set as
variables on the process scope.
Script actions can access variables directly, simply by using the name of the variable as a local parameter in their script. For example, if the process defines a variable of type "org.jbpm.Person" in the process, a script in the process could access this directly:
// call method on the process variable "person"
person.setAge(10);
Changing the value of a variable in a script can be done through the knowledge context:
kcontext.setVariable(variableName, value);
Service tasks (and reusable sub-processes) can pass the value of process
variables to the outside world (or another process instance) by mapping the variable
to an outgoing parameter. For example, the parameter mapping of a service task could define
that the value of the process variable x should be mapped to a task parameter y right
before the service is being invoked. You can also inject the value of process variable
into a hard-coded parameter String using
#{expression}
. For example, the description of a human
task could be defined as You need to contact person #{person.getName()}
(where
person is a process variable), which will replace this expression by the actual name of the
person when the service needs to be invoked. Similarly results of a service (or reusable
sub-process) can also be copied back to a variable using a result mapping.
Various other nodes can also access data. Event nodes for example can store the data associated to the event in a variable, etc. Check the properties of the different node types for more information.
Process variables can be accessed also from the Java code of your application. It is
done by casting of ProcessInstance
to WorkflowProcessInstance
.
See the following example:
variable = ((WorkflowProcessInstance) processInstance).getVariable("variableName");
To list all the process variables see the following code snippet:
org.jbpm.process.instance.ProcessInstance processInstance = ...;
VariableScopeInstance variableScope = (VariableScopeInstance) processInstance.getContextInstance(VariableScope.VARIABLE_SCOPE);
Map<String, Object> variables = variableScope.getVariables();
Note that when you use persistence then you have to use a command based approach to get all process variables:
Map<String, Object> variables = ksession.execute(new GenericCommand<Map<String, Object>>() {
public Map<String, Object> execute(Context context) {
KieSession ksession = ((KnowledgeCommandContext) context).getStatefulKnowledgesession();
org.jbpm.process.instance.ProcessInstance processInstance = (org.jbpm.process.instance.ProcessInstance) ksession.getProcessInstance(piId);
VariableScopeInstance variableScope = (VariableScopeInstance) processInstance.getContextInstance(VariableScope.VARIABLE_SCOPE);
Map<String, Object> variables = variableScope.getVariables();
return variables;
}
});
Finally, processes (and rules) all have access to globals, i.e.
globally defined variables and data in the Knowledge Session. Globals are directly
accessible in actions just like variables. Globals need to be defined as part of the
process before they can be used. You can for example define globals by clicking the
globals button when specifying an action script in the Eclipse action property
editor. You can also set the value of a global from the outside using
ksession.setGlobal(name, value)
or from inside process scripts using
kcontext.getKieRuntime().setGlobal(name,value);
.
Action scripts can be used in different ways:
Actions have access to globals and the variables that are defined
for the process and the predefined variable kcontext
. This
variable is of type
ProcessContext
and can be used for
several tasks:
Getting the current node instance (if applicable). The node instance could be queried for data, such as its name and type. You can also cancel the current node instance.
NodeInstance node = kcontext.getNodeInstance();
String name = node.getNodeName();
Getting the current process instance. A process instance can be queried for data (name, id, processId, etc.), aborted or signaled an internal event.
ProcessInstance proc = kcontext.getProcessInstance();
proc.signalEvent( type, eventObject );
Getting or setting the value of variables.
Accessing the Knowledge Runtime allows you do things like starting a process, signaling (external) events, inserting data, etc.
jBPM currently supports two dialects, Java and MVEL.
Java actions should be valid Java code. MVEL actions can use the business
scripting language MVEL to express the action. MVEL accepts any valid Java
code but additionally provides support for nested accesses of parameters
(e.g., person.name
instead of person.getName()
),
and many other scripting improvements. Thus, MVEL expressions are more
convenient for the business user. For example, an action that prints out
the name of the person in the "requester" variable of the process would
look like this:
// Java dialect
System.out.println( person.getName() );
// MVEL dialect
System.out.println( person.name );
Constraints can be used in various locations in your processes, for example in a diverging gateway. jBPM supports two types of constraints:
Code constraints are boolean expressions,
evaluated directly whenever they are reached. We currently support two
dialects for expressing these code constraints: Java and MVEL.
Both Java and MVEL code constraints have direct access
to the globals and variables defined in the process. Here is an example
of a valid Java code constraint, person
being a variable
in the process:
return person.getAge() > 20;
A similar example of a valid MVEL code constraint is:
return person.age > 20;
Rule constraints are equals to normal Drools rule conditions. They use the Drools Rule Language syntax to express possibly complex constraints. These rules can, like any other rule, refer to data in the Working Memory. They can also refer to globals directly. Here is an example of a valid rule constraint:
Person( age > 20 )
This tests for a person older than 20 being in the Working Memory.
Rule constraints do not have direct access to variables defined
inside the process. It is however possible to refer to the current process
instance inside a rule constraint, by adding the process instance to the
Working Memory and matching for the process instance in your rule
constraint. We have added special logic to make sure that a variable
processInstance
of type WorkflowProcessInstance
will only match to the current process instance and not to other process
instances in the Working Memory. Note that you are however responsible
yourself to insert the process instance into the session and, possibly,
to update it, for example, using Java code or an on-entry or on-exit or
explicit action in your process. The following example of a rule
constraint will search for a person with the same name as the value
stored in the variable "name" of the process:
processInstance : WorkflowProcessInstance()
Person( name == ( processInstance.getVariable("name") ) )
# add more constraints here ...
Timers wait for a predefined amount of time, before triggering, once or repeatedly. They can be used to trigger certain logic after a certain period, or to repeat some action at regular intervals.
A Timer node is set up with a delay and a period. The delay specifies the amount of time to wait after node activation before triggering the timer the first time. The period defines the time between subsequent trigger activations. A period of 0 results in a one-shot timer.
The (period and delay) expression should be of the form [#d][#h][#m][#s][#[ms]]. You can specify the amount of days, hours, minutes, seconds and milliseconds (which is the default if you don't specify anything). For example, the expression "1h" will wait one hour before triggering the timer (again).
Timer events can be configured with CRON like expression when timeCycle is used as timer event definition. Important is that the language attribute of timeCycle definition must be set to cron. With that such cycle of a timer is controlled in the same way as CRON jobs. CRON like expression is supported for:
start event timers
intermediate event timers
boundary event timers
Following is an example of a definition of a boundary timer with CRON like expression
<bpmn2:boundaryEvent id="1" name="Send Update Timer" attachedToRef="_77A94B54-8B7C-4F8A-84EE-C1D310A343A6" cancelActivity="false">
<bpmn2:outgoing>2</bpmn2:outgoing>
<bpmn2:timerEventDefinition id="_erIyiJZ7EeSDh8PHobjSSA">
<bpmn2:timeCycle xsi:type="bpmn2:tFormalExpression" id="_erIyiZZ7EeSDh8PHobjSSA" language="cron">0/1 * * * * ?</bpmn2:timeCycle>
</bpmn2:timerEventDefinition>
</bpmn2:boundaryEvent>
This timer will fire every second and will continue until activity this boundary event is attached to is active.
since version 6 timers can be configured with valid ISO8601 date format that supports both one shot timers and repeatable timers. Timers can be defined as date and time representation, time duration or repeating intervals
The timer service is responsible for making sure that timers get triggered at the appropriate times. Timers can also be canceled, meaning that the timer will no longer be triggered.
Timers can be used in two ways inside a process:
A Timer Event may be added to the process flow. Its activation starts the timer, and when it triggers, once or repeatedly, it activates the Timer node's successor. Subsequently, the outgoing connection of a timer with a positive period is triggered multiple times. Canceling a Timer node also cancels the associated timer, after which no more triggers will occur.
Timers can be associated with a Sub-Process or tasks as a boundary event.
While it is recommended to define processes using the graphical editor or
the underlying XML (to shield yourself from internal APIs), it is also possible
to define a process using the Process API directly. The most important process
model elements are defined in the packages org.jbpm.workflow.core
and
org.jbpm.workflow.core.node
. A "fluent API" is provided that
allows you to easily construct processes in a readable manner using factories.
At the end, you can validate the process that you were constructing manually.
This is a simple example of a basic process with a script task only:
RuleFlowProcessFactory factory =
RuleFlowProcessFactory.createProcess("org.jbpm.HelloWorld");
factory
// Header
.name("HelloWorldProcess")
.version("1.0")
.packageName("org.jbpm")
// Nodes
.startNode(1).name("Start").done()
.actionNode(2).name("Action")
.action("java", "System.out.println(\"Hello World\");").done()
.endNode(3).name("End").done()
// Connections
.connection(1, 2)
.connection(2, 3);
RuleFlowProcess process = factory.validate().getProcess();
KnowledgeBuilder kbuilder = KnowledgeBuilderFactory.newKnowledgeBuilder();
kbuilder.add(ResourceFactory.newByteArrayResource(
XmlBPMNProcessDumper.INSTANCE.dump(process).getBytes()), ResourceType.BPMN2);
KnowledgeBase kbase = kbuilder.newKnowledgeBase();
StatefulKnowledgeSession ksession = kbase.newStatefulKnowledgeSession();
ksession.startProcess("org.jbpm.HelloWorld");
You can see that we start by calling the static createProcess()
method from the RuleFlowProcessFactory
class. This method creates
a new process with the given id and returns the RuleFlowProcessFactory
that can be used to create the process. A typical process consists of three parts.
The header part comprises global elements like the name of the process, imports,
variables, etc. The nodes section contains all the different nodes that are part of the
process. The connections section finally links these nodes to each other
to create a flow chart.
In this example, the header contains the name and the version of the process and the package name. After that, you can start adding nodes to the current process. If you have auto-completion you can see that you have different methods to create each of the supported node types at your disposal.
When you start adding nodes to the process, in this example by calling
the startNode()
, actionNode()
and endNode()
methods, you can see that these methods return a specific NodeFactory
,
that allows you to set the properties of that node. Once you have finished
configuring that specific node, the done()
method returns you to the
current RuleFlowProcessFactory
so you can add more nodes, if necessary.
When you are finished adding nodes, you must connect them by creating
connections between them. This can be done by calling the method
connection
, which will link previously created nodes.
Finally, you can validate the generated process by calling the
validate()
method and retrieve the created
RuleFlowProcess
object.
Even though business processes aren't code (we even recommend you to make them as high-level as possible and to avoid adding implementation details), they also have a life cycle like other development artefacts. And since business processes can be updated dynamically, testing them (so that you don't break any use cases when doing a modification) is really important as well.
When unit testing your process, you test whether the process behaves as expected in specific use cases, for example test the output based on the existing input. To simplify unit testing, jBPM includes a helper class called JbpmJUnitBaseTestCase (in the jbpm-test module) that you can use to greatly simplify your JUnit testing, by offering:
helper methods to create a new RuntimeManager and RuntimeEngine for a given (set of) process(es)
you can select whether you want to use persistence or not
assert statements to check
the state of a process instance (active, completed, aborted)
which node instances are currently active
which nodes have been triggered (to check the path that has been followed)
get the value of variables
For example, consider the following "hello world" process containing a start event, a script task and an end event. The following JUnit test will create a new session, start the process and then verify whether the process instance completed successfully and whether these three nodes have been executed.
public class ProcessPersistenceTest extends JbpmJUnitBaseTestCase {
public ProcessPersistenceTest() {
// setup data source, enable persistence
super(true, true);
}
@Test
public void testProcess() {
// create runtime manager with single process - hello.bpmn
createRuntimeManager("hello.bpmn");
// take RuntimeManager to work with process engine
RuntimeEngine runtimeEngine = getRuntimeEngine();
// get access to KieSession instance
KieSession ksession = runtimeEngine.getKieSession();
// start process
ProcessInstance processInstance = ksession.startProcess("com.sample.bpmn.hello");
// check whether the process instance has completed successfully
assertProcessInstanceCompleted(processInstance.getId(), ksession);
// check what nodes have been triggered
assertNodeTriggered(processInstance.getId(), "StartProcess", "Hello", "EndProcess");
}
}
JbpmJUnitBaseTestCase acts as base test case class that shall be used for jBPM related tests. It provides four usage areas:
JUnit life cycle methods
setUp: executed @Before and configures data source and EntityManagerFactory, cleans up Singleton's session id
tearDown: executed @After and clears out history, closes EntityManagerFactory and data source, disposes RuntimeEngines and RuntimeManager
Knowledge Base and KnowledgeSession management methods
createRuntimeManager creates RuntimeManager for given set of assets and selected strategy
disposeRuntimeManager disposes RuntimeManager currently active in the scope of test
getRuntimeEngine creates new RuntimeEngine for given context
Assertions
assertProcessInstanceCompleted
assertProcessInstanceAborted
assertProcessInstanceActive
assertNodeActive
assertNodeTriggered
assertProcessVarExists
assertNodeExists
assertVersionEquals
assertProcessNameEquals
Helper methods
getDs - returns currently configured data source
getEmf - returns currently configured EntityManagerFactory
getTestWorkItemHandler - returns test work item handler that might be registered in addition to what is registered by default
clearHistory - clears history log
setupPoolingDataSource - sets up data source
JbpmJUnitBaseTestCase supports all three predefined RuntimeManager strategies as part of the unit testing. It's enough to specify which strategy shall be used whenever creating runtime manager as part of single test:
public class ProcessHumanTaskTest extends JbpmJUnitBaseTestCase {
private static final Logger logger = LoggerFactory.getLogger(ProcessHumanTaskTest.class);
public ProcessHumanTaskTest() {
super(true, false);
}
@Test
public void testProcessProcessInstanceStrategy() {
RuntimeManager manager = createRuntimeManager(Strategy.PROCESS_INSTANCE, "manager", "humantask.bpmn");
RuntimeEngine runtimeEngine = getRuntimeEngine(ProcessInstanceIdContext.get());
KieSession ksession = runtimeEngine.getKieSession();
TaskService taskService = runtimeEngine.getTaskService();
int ksessionID = ksession.getId();
ProcessInstance processInstance = ksession.startProcess("com.sample.bpmn.hello");
assertProcessInstanceActive(processInstance.getId(), ksession);
assertNodeTriggered(processInstance.getId(), "Start", "Task 1");
manager.disposeRuntimeEngine(runtimeEngine);
runtimeEngine = getRuntimeEngine(ProcessInstanceIdContext.get(processInstance.getId()));
ksession = runtimeEngine.getKieSession();
taskService = runtimeEngine.getTaskService();
assertEquals(ksessionID, ksession.getId());
// let john execute Task 1
List<TaskSummary> list = taskService.getTasksAssignedAsPotentialOwner("john", "en-UK");
TaskSummary task = list.get(0);
logger.info("John is executing task {}", task.getName());
taskService.start(task.getId(), "john");
taskService.complete(task.getId(), "john", null);
assertNodeTriggered(processInstance.getId(), "Task 2");
// let mary execute Task 2
list = taskService.getTasksAssignedAsPotentialOwner("mary", "en-UK");
task = list.get(0);
logger.info("Mary is executing task {}", task.getName());
taskService.start(task.getId(), "mary");
taskService.complete(task.getId(), "mary", null);
assertNodeTriggered(processInstance.getId(), "End");
assertProcessInstanceCompleted(processInstance.getId(), ksession);
}
}
Above is more complete example that uses PerProcessInstance runtime manager strategy and uses task service to deal with user tasks.
Real-life business processes typically include the invocation of external services (like for example a human task service, an email server or your own domain-specific services). One of the advantages of our domain-specific process approach is that you can specify yourself how to actually execute your own domain-specific nodes, by registering a handler. And this handler can be different depending on your context, allowing you to use testing handlers for unit testing your process. When you are unit testing your business process, you can register test handlers that then verify whether specific services are requested correctly, and provide test responses for those services. For example, imagine you have an email node or a human task as part of your process. When unit testing, you don't want to send out an actual email but rather test whether the email that is requested contains the correct information (for example the right to email, a personalized body, etc.).
A TestWorkItemHandler is provided by default that can be registered to collect all work items (a work item represents one unit of work, like for example sending one specific email or invoking one specific service and contains all the data related to that task) for a given type. This test handler can then be queried during unit testing to check whether specific work was actually requested during the execution of the process and that the data associated with the work was correct.
The following example describes how a process that sends out an email could be tested. This test case in particular will test whether an exception is raised when the email could not be sent (which is simulated by notifying the engine that the sending the email could not be completed). The test case uses a test handler that simply registers when an email was requested (and allows you to test the data related to the email like from, to, etc.). Once the engine has been notified the email could not be sent (using abortWorkItem(..)), the unit test verifies that the process handles this case successfully by logging this and generating an error, which aborts the process instance in this case.
public void testProcess2() {
// create runtime manager with single process - hello.bpmn
createRuntimeManager("sample-process.bpmn");
// take RuntimeManager to work with process engine
RuntimeEngine runtimeEngine = getRuntimeEngine();
// get access to KieSession instance
KieSession ksession = runtimeEngine.getKieSession();
// register a test handler for "Email"
TestWorkItemHandler testHandler = getTestWorkItemHandler();
ksession.getWorkItemManager().registerWorkItemHandler("Email", testHandler);
// start the process
ProcessInstance processInstance = ksession.startProcess("com.sample.bpmn.hello2");
assertProcessInstanceActive(processInstance.getId(), ksession);
assertNodeTriggered(processInstance.getId(), "StartProcess", "Email");
// check whether the email has been requested
WorkItem workItem = testHandler.getWorkItem();
assertNotNull(workItem);
assertEquals("Email", workItem.getName());
assertEquals("me@mail.com", workItem.getParameter("From"));
assertEquals("you@mail.com", workItem.getParameter("To"));
// notify the engine the email has been sent
ksession.getWorkItemManager().abortWorkItem(workItem.getId());
assertProcessInstanceAborted(processInstance.getId(), ksession);
assertNodeTriggered(processInstance.getId(), "Gateway", "Failed", "Error");
}
You can configure whether you want to execute the JUnit tests using persistence or not. By default, the JUnit tests will use persistence, meaning that the state of all process instances will be stored in a (in-memory H2) database (which is started by the JUnit test during setup) and a history log will be used to check assertions related to execution history. When persistence is not used, process instances will only live in memory and an in-memory logger is used for history assertions.
Persistence (and setup of data source) is controlled by the super constructor and allows following
default, no arg constructor - the most simple test case configuration (does NOT initialize data source and does NOT configure session persistence) - this is usually used for in memory process management, without human task interaction
super(boolean, boolean) - allows to explicitly configure persistence and data source. This is the most common way of bootstrapping test cases for jBPM
super(true, false) - to execute with in memory process management with human tasks persistence
super(true, true) - to execute with persistent process management with human tasks persistence
super(boolean, boolean, string) - same as super(boolean, boolean) but allows to use another persistence unit name than default (org.jbpm.persistence.jpa)
public class ProcessHumanTaskTest extends JbpmJUnitBaseTestCase {
private static final Logger logger = LoggerFactory.getLogger(ProcessHumanTaskTest.class);
public ProcessHumanTaskTest() {
// configure this tests to not use persistence for process engine but still use it for human tasks
super(true, false);
}
}
An important aspect of business processes is human task management. While some of the work performed in a process can be executed automatically, some tasks need to be executed by human actors.
jBPM supports a special human task node inside processes for modeling this interaction with human users. This human task node allows process designers to define the properties related to the task that the human actor needs to execute, like for example the type of task, the actor(s), or the data associated with the task.
jBPM also includes a so-called human task service, a back-end service that manages the life cycle of these tasks at runtime. The jBPM implementation is based on the WS-HumanTask specification. Note however that this implementation is fully pluggable, meaning that users can integrate their own human task solution if necessary.
In order to have human actors participate in your processes, you first need to (1) include human task nodes inside your process to model the interaction with human actors, (2) integrate a task management component (like for example the WS-HumanTask based implementation provided by jBPM) and (3) have end users interact with a human task client to request their task list and claim and complete the tasks assigned to them. Each of these three elements will be discussed in more detail in the next sections.
jBPM supports the use of human tasks inside processes using a special User Task node defined by the BPMN2 Specification(as shown in the figure above). A User Task node represents an atomic task that needs to be executed by a human actor.
[Although jBPM has a special user task node for including human tasks inside a process, human tasks are considered the same as any other kind of external service that needs to be invoked and are therefore simply implemented as a domain-specific service. See the chapter on domain-specific processes to learn more about this.]
A User Task node contains the following core properties:
Actors: The actors that are responsible for executing the human task. A list of actor id's can be specified using a comma (',') as separator.
Group: The group id that is responsible for executing the human task. A list of group id's can be specified using a comma (',') as separator.
Name: The display name of the node.
TaskName: The name of the human task. This name is used to link the task to a Form. It also represent the internal name of the Task that can be used for other purposes.
DataInputSet: all the input variables that the task will receive to work on. Usually you will be interested in copying variables from the scope of the process to the scope of the task. (Look at the data mappings section for an example)
DataOutputSet: all the output variables that will be generated by the execution of the task. Here you specify all the name of the variables in the context of the task that you are interested to copy to the context of the process. (Look at the data mappings section for an example)
Assignments: here you specify which process variable will be linked to each Data Input and Data Output mapping. (Look at the data mappings section for an example)
You can edit these variables in the properties view (see below) when selecting the User Task node.
A User Task node also contains the following extra properties:
Comment: A comment associated with the human task. Here you can use expressions.
Content: The data associated with this task.
Priority: An integer indicating the priority of the human task.
Skippable: Specifies whether the human task can be skipped, i.e., whether the actor may decide not to execute the task.
On entry and on exit actions: Action scripts that are executed upon entry and exit of this node, respectively.
Human tasks typically present some data related to the task that needs to be performed to the actor that is executing the task and usually also request the actor to provide some result data related to the execution of the task. Task forms are typically used to present this data to the actor and request results.
The data that will be used by the Task needs to be specified when we define the User Task in our Process. In order to do that we need to define which data will be copied from the process context to the task context. Notice that the data is copied, so it can be modified inside the Task context but it will not affect the process variables unless we decide to copy back the value from the task to the process context.
Most of the times Forms are used to display data to the end user. Allowing them to generate/create new data that will be propagated to the process context to be used by future activities. In order to decide how the information flow from the process to a particular task and from the task to the process we need to define which pieces of information will be automatically copied by the process engine. The following sections shows how to do these mappings by configuring the DataInputSet, DataOutputSet and the Assignments properties of a User Task.
Let's start defining the Task DataInputSet:
Both GroupId and Comment are automatically generated, so you don't need to worry about that. In this case the only user defined Data Input is called: in_name. This means that the task will be receiving information from the process context and internally this variable will be called in_name. The type is also specified here.
In the Data Outputs represent the data that will be generated by the tasks. In this case we have two variables of type String called: out_name and out_mail and two Integer variables called: out_age and out_score are defined. This means that inside the task context we will need to set the value to these variables.
Finally all the connections with the process context needs to be done in the Data Assignments. The main idea here is to define how Data Inputs and Data Outputs will be associated with process variables.
As shown in the previous screenshot, the assignments between the process variables (in this case (name, age, mail and hr_score)) and the Data Inputs and Outputs are done in the Data Assignments screen. Notice that the example uses a convention that makes it easy to know which is an internal Task variables (Data Input/Output) using the "in_" and "out_" prefix to the variable names. Using this convention you can quickly understand the Assignments screen. The first row maps the process variable called name to the data input called in_name. The second row maps the data output called out_mail to the process variable called mail, and so on.
These mappings at runtime will automatically copy the variables content from one context (process and task) to the other automatically for us.
From the perspective of a process, when a user task node is encountered during the execution, a human task is created. The process will then only leave the user task node when the associated human task has been completed or aborted.
The human task itself usually has a complete life cycle itself as well. For details beyond what is described below, please check out the WS-HumanTask specification. The following diagram is from the WS-HumanTask specification and describes the human task life cycle.
A newly created task starts in the "Created" stage. Usually, it will then automatically become "Ready", after which the task will show up on the task list of all the actors that are allowed to execute the task. The task will stay "Ready" until one of these actors claims the task, indicating that he or she will be executing it.
When a user then eventually claims the task, the status will change to "Reserved". Note that a task that only has one potential (specific) actor will automatically be assigned to that actor upon creation of the task. When the user who has claimed the task starts executing it, the task status will change from "Reserved" to "InProgress".
Lastly, once the user has performed and completed the task, the task status will change to "Completed". In this step, the user can optionally specify the result data related to the task. If the task could not be completed, the user could also indicate this by using a fault response, possibly including fault data, in which case the status would change to "Failed".
While the life cycle explained above is the normal life cycle, the specification also describes a number of other life cycle methods, including:
Delegating or forwarding a task, so that the task is assigned to another actor
Revoking a task, so that it is no longer claimed by one specific actor but is (re)available to all actors allowed to take it
Temporarly suspending and resuming a task
Stopping a task in progress
Skipping a task (if the task has been marked as skippable), in which case the task will not be executed
Only users associated with a specific task are allowed to modify or retrieve information about the task. This allows users to create a jBPM workflow with multiple tasks and yet still be assured of both the confidentiality and integrity of the task status and information associated with a task.
Some task operations will end up throwing a
org.jbpm.services.task.exception.PermissionDeniedException
when used with
information about an unauthorized user. For example, when a user is trying to directly modify
the task (for example, by trying to claim or complete the task), the
PermissionDeniedException
will be thrown if that user does not have the correct
role for that operation. Furthermore, a user will not be able to view or retrieve tasks that the
user is not involved with, especially if this is via the jBPM Console or KIE Workbench
applications.
The permisions matrix below summarizes the actions that specific user roles are allowed to do. On the left side, possible operations are listed while user roles are listed across the top of the matrix.
The cells of the permissions matrix contain one of three possible characters, each of which indicate the user role permissions for that operation:
a "+
indicates that the user role CAN do the specified operation
a "-
" indicates that the user role MAY NOT do the specified
operation
a "_
" indicates that the user role MAY NOT do the specified operation,
and that it is also not an operation that matches the user's role ("not
applicable")
Furthermore, the following words or abbreviations in the table header refer to the following roles:
Table 7.1. Task roles in the permissions table
Word | Role | Description |
---|---|---|
Initiator |
Task Initiator |
The user who creates the task instance |
Stakeholder |
Task Stakeholder |
The user involved in the task: this user can influence the progress of a task, by performing administrative actions on the task instance |
Potential |
Potential Owner |
The user who can claim the task before it has been claimed, or after it has been released or forward: only tasks that have the status "Ready" may be claimed; a potential owner becomes the actual owner of a task by claiming the task |
Actual |
Actual Owner |
The user who has claimed the task and will progress the task to completion or failure |
Administrator |
Business Adminstrator |
A "super user" who may modify the status or progress of a task at any point in a task's lifecycle |
User roles are assigned to users by the definition of the task in the jBPM (BPMN2)
process definition.
Permissions Matrices. The following matrix describes the authorizations for all operations which modify a task:
Table 7.2. Main operations permissions matrix
Operation\Role | Initiator | Stakeholder | Potential | Actual | Administrator |
---|---|---|---|---|---|
activate | + | + | _ | _ | + |
claim | - | + | + | _ | + |
complete | - | + | _ | + | + |
delegate | + | + | + | + | + |
fail | - | + | _ | + | + |
forward | + | + | + | + | + |
nominate | + | + | + | + | + |
release | + | + | + | + | + |
remove | - | _ | _ | _ | + |
resume | + | + | + | + | + |
skip | + | + | + | + | + |
start | - | + | + | + | + |
stop | - | + | _ | + | + |
suspend | + | + | + | + | + |
The matrix below describes the authorizations used when retrieving task
information. In short, it says that all users which have any role with regards to the
specific task, are allowed to see the task. This applies to all operations that are used to
retrieve any type of information about the task.
Table 7.3. Retrieval operations permissions matrix
Operation\Role | Initiator | Stakeholder | Potential | Actual | Administrator |
---|---|---|---|---|---|
get | + | + | + | + | + |
As far as the jBPM engine is concerned, human tasks are similar to any other external service that needs to be invoked and are implemented as a domain-specific service. (For more on domain-specific services, see the chapter on them here.) Because a human task is an example of such a domain-specific service, the process itself only contains a high-level, abstract description of the human task to be executed and a work item handler that is responsible for binding this (abstract) task to a specific implementation.
Users can plug in any human task service implementation, such as the one that's provided by jBPM, or they may register their own implementation. In the next paragraphs, we will describe the human task service implementation provided by jBPM.
The jBPM project provides a default implementation of a human task service based on the WS-HumanTask specification. If you do not need to integrate jBPM with another existing implementation of a human task service, you can use this service. The jBPM implementation manages the life cycle of the tasks (creation, claiming, completion, etc.) and stores the state of all the tasks, task lists, and other associated information. It also supports features like internationalization, calendar integration, different types of assignments, delegation, escalation and deadlines. The code for the implementation itself can be found in the jbpm-human-task module.
The jBPM task service implementation is based on the WS-HumanTask (WS-HT) specification. This specification defines (in detail) the model of the tasks, the life cycle, and many other features. It is very comprehensive and the first version can be found here.
The human task service exposes a Java API for managing the life cycle of tasks. This allows clients to integrate (at a low level) with the human task service. Note that end users should probably not interact with this low-level API directly, but use one of the more user-friendly task clients (see below) instead. These clients offer a graphical user interface to request task lists, claim and complete tasks, and manage tasks in general. The task clients listed below use the Java API to internally interact with the human task service. Of course, the low-level API is also available so that developers can use it in their code to interact with the human task service directly.
A task service (interface org.kie.api.task.TaskService) offers the following methods (among others) for managing the life cycle of human tasks:
...
void start( long taskId, String userId );
void stop( long taskId, String userId );
void release( long taskId, String userId );
void suspend( long taskId, String userId );
void resume( long taskId, String userId );
void skip( long taskId, String userId );
void delegate(long taskId, String userId, String targetUserId);
void complete( long taskId, String userId, Map<String, Object> results );
...
If you take a look at the method signatures you will notice that almost all of these methods take the following arguments:
taskId: The id of the task that we are working with. This is usually extracted from the currently selected task in the user task list in the user interface.
userId: The id of the user that is executing the action. This is usually the id of the user that is logged in into the application.
There is also an internal interface that you should check for more methods to interact with the Task Service, this interface is internal until it gets tested. Future version of the External (public) interface can include some of the methods proposed in the InternalTaskService interface. If you want to make use of the methods provided by this interface you need to manually cast to InternalTaskService. One method that can be useful from this interface is getTaskContent():
Map<String, Object> getTaskContent( long taskId );
This method saves you from doing all the boiler plate of getting the ContentMarshallerContext to unmarshall the serialized version of the task content. If you only want to use the stable/public API's you can just copy what this method does:
Task taskById = taskQueryService.getTaskInstanceById(taskId);
Content contentById = taskContentService.getContentById(taskById.getTaskData().getDocumentContentId());
ContentMarshallerContext context = getMarshallerContext(taskById);
Object unmarshalledObject = ContentMarshallerHelper.unmarshall(contentById.getContent(), context.getEnvironment(), context.getClassloader());
if (!(unmarshalledObject instanceof Map)) {
throw new IllegalStateException(" The Task Content Needs to be a Map in order to use this method and it was: "+unmarshalledObject.getClass());
}
Map<String, Object> content = (Map<String, Object>) unmarshalledObject;
return content;
Because the content of the Task can be any Object, the previous method assume that you are storing a Map of objects to work. If you are storing other than a Map you should do the correspondent checks.
In order to get access to the Task Service API it is recommended to let the Runtime Manager to make sure that everything is setup correctly. Look at the Runtime Manager section for more information. From the API perspective you should be doing something like this:
...
RuntimeEngine engine = runtimeManager.getRuntimeEngine(EmptyContext.get());
KieSession kieSession = engine.getKieSession();
// Start a process
kieSession.startProcess("CustomersRelationship.customers", params);
// Do Task Operations
TaskService taskService = engine.getTaskService();
List<TaskSummary> tasksAssignedAsPotentialOwner = taskService.getTasksAssignedAsPotentialOwner("mary", "en-UK");
// Claim Task
taskService.claim(taskSummary.getId(), "mary");
// Start Task
taskService.start(taskSummary.getId(), "mary");
...
If you use this approach, there is no need to register the Task Service with the Process Engine. The Runtime Manager will do that for you automatically. If you don't use the Runtime Manager, you will be responsible for setting the LocalHTWorkItemHandler in the session in order to get the Task Service notifying the Process Engine when a task is completed, or the Process Engine notifying that a task has been created.
In jBPM 6.x the Task Service runs locally to the Process and Rule Engine and for that reason multiple light clients can be created for different Process and Rule Engine's instances. All the clients will be sharing the same database (backend storage for the tasks).
jBPM allows the persistent storage of certain information. This chapter describes these different types of persistence, and how to configure them. An example of the information stored is the process runtime state. Storing the process runtime state is necessary in order to be able to continue execution of a process instance at any point, if something goes wrong. Also, the process definitions themselves, and the history information (logs of current and previous process states already) can also be persisted.
Whenever a process is started, a process instance is created, which represents the execution of the process in that specific context. For example, when executing a process that specifies how to process a sales order, one process instance is created for each sales request. The process instance represents the current execution state in that specific context, and contains all the information related to that process instance. Note that it only contains the (minimal) runtime state that is needed to continue the execution of that process instance at some later time, but it does not include information about the history of that process instance if that information is no longer needed in the process instance.
The runtime state of an executing process can be made persistent, for example, in a database. This allows to restore the state of execution of all running processes in case of unexpected failure, or to temporarily remove running instances from memory and restore them at some later time. jBPM allows you to plug in different persistence strategies. By default, if you do not configure the process engine otherwise, process instances are not made persistent.
If you configure the engine to use persistence, it will automatically store the runtime state into the database. You do not have to trigger persistence yourself, the engine will take care of this when persistence is enabled. Whenever you invoke the engine, it will make sure that any changes are stored at the end of that invocation, at so-called safe points. Whenever something goes wrong and you restore the engine from the database, you also should not reload the process instances and trigger them manually to resume execution, as process instances will automatically resume execution if they are triggered, like for example by a timer expiring, the completion of a task that was requested by that process instance, or a signal being sent to the process instance. The engine will automatically reload process instances on demand.
The runtime persistence data should in general be considered internal, meaning that you probably should not try to access these database tables directly and especially not try to modify these directly (as changing the runtime state of process instances without the engine knowing might have unexpected side-effects). In most cases where information about the current execution state of process instances is required, the use of a history log is mostly recommended (see below). In some cases, it might still be useful to for example query the internal database tables directly, but you should only do this if you know what you are doing.
jBPM uses a binary persistence mechanism, otherwise known as marshalling, which converts the state of the process instance into a binary dataset. When you use persistence with jBPM, this mechanism is used to save or retrieve the process instance state from the database. The same mechanism is also applied to the session state and any work item states.
When the process instance state is persisted, two things happen:
Apart from the process instance state, the session itself can
also store some state, such as the state of timer jobs, or the session
data that any business rules would be evaluated over.
This session state is stored separately as a binary blob, along with
the id of the session and some metadata. You can always restore session
state by reloading the session with the given id. The session id can
be retrieved using ksession.getId()
.
Note that the process instance binary datasets are usually relatively small, as they only contain the minimal execution state of the process instance. For a simple process instance, this usually contains one or a few node instances, i.e., any node that is currently executing, and any existing variable values.
As a result of jBPM using marshalling, the data model is both simple and small:
Figure 8.1. jBPM data model
The sessioninfo
entity contains the state of the
(knowledge) session in which the jBPM process instance is running.
Table 8.1. SessionInfo
Field | Description | Nullable |
---|---|---|
id | The primary key. | NOT NULL |
lastmodificationdate | The last time that the entity was saved to the database | |
rulesbytearray | The binary dataset containing the state of the session | NOT NULL |
startdate | The start time of the session | |
optlock | The version field that serves as its optimistic lock value |
The processinstanceinfo
entity contains the state
of the jBPM process instance.
Table 8.2. ProcessInstanceInfo
Field | Description | Nullable |
---|---|---|
instanceid | The primary key | NOT NULL |
lastmodificationdate | The last time that the entity was saved to the database | |
lastreaddate | The last time that the entity was retrieved (read) from the database | |
processid | The name (id) of the process | |
processinstancebytearray | This is the binary dataset containing the state of the process instance | NOT NULL |
startdate | The start time of the process | |
state | An integer representing the state of the process instance | NOT NULL |
optlock | The version field that serves as its optimistic lock value |
The eventtypes
entity contains information
about events that a process instance will undergo or has undergone.
Table 8.3. EventTypes
Field | Description | Nullable |
---|---|---|
instanceid | This references the processinstanceinfo primary
key and there is a foreign key constraint on this column. | NOT NULL |
eventTypes | A text field related to an event that the process has undergone. |
The workiteminfo
entity contains the state of a work item.
Table 8.4. WorkItemInfo
Field | Description | Nullable |
---|---|---|
workitemid | The primary key | NOT NULL |
creationDate | The name of the work item | |
name | The name of the work item | |
processinstanceid | The (primary key) id of the process: there is no foreign key constraint on this field. | NOT NULL |
state | An integer representing the state of the work item | NOT NULL |
optlock | The version field that serves as its optimistic lock value | |
workitembytearay | This is the binary dataset containing the state of the work item | NOT NULL |
The CorrelationKeyInfo
entity contains information
about correlation keys assigned to given process instance - loose relationship as this
table is considered optional used only when correlation capabilities are required.
Table 8.5. CorrelationKeyInfo
Field | Description | Nullable |
---|---|---|
keyid | The primary key | NOT NULL |
name | assigned name of the correlation key | |
processinstanceid | The id of the process instance which is assigned to this correlation key | NOT NULL |
optlock | The version field that serves as its optimistic lock value |
The CorrelationPropertyInfo
entity contains information
about correlation properties for given correlation key that is assigned to given process instance.
Table 8.6. CorrelationPropertyInfo
Field | Description | Nullable |
---|---|---|
propertyid | The primary key | NOT NULL |
name | The name of the property | |
value | The value of the property | NOT NULL |
optlock | The version field that serves as its optimistic lock value | |
correlationKey-keyid | Foregin key to map to correlation key | NOT NULL |
The ContextMappingInfo
entity contains information
about contextual information mapped to ksession. This is an internal part of RuntimeManager
and can be considered optional when RuntimeManager is not used.
Table 8.7. ContextMappingInfo
Field | Description | Nullable |
---|---|---|
mappingid | The primary key | NOT NULL |
context_id | Identifier of the context | NOT NULL |
ksession?id | Identifier of the ksession mapped to this context | NOT NULL |
optlock | The version field that serves as its optimistic lock value |
The state of a process instance is stored at so-called "safe points" during the execution of the process engine. Whenever a process instance is executing (for example when it started or continuing from a previous wait state, the engine executes the process instance until no more actions can be performed (meaning that the process instance either has completed (or was aborted), or that it has reached a wait state in all of its parallel paths). At that point, the engine has reached the next safe state, and the state of the process instance (and all other process instances that might have been affected) is stored persistently.
In many cases it will be useful (if not necessary) to store information about the execution of process instances, so that this information can be used afterwards. For example, sometimes we want to verify which actions have been executed for a particular process instance, or in general, we want to be able to monitor and analyze the efficiency of a particular process.
However, storing history information in the runtime database can result in the database rapidly increasing in size, not to mention the fact that monitoring and analysis queries might influence the performance of your runtime engine. This is why process execution history information can be stored separately.
This history log of execution information is created based on events that the process engine generates during execution. This is possible because the jBPM runtime engine provides a generic mechanism to listen to events. The necessary information can easily be extracted from these events and then persisted to a database. Filters can also be used to limit the scope of the logged information.
The jbpm-audit module contains an event listener that stores process-related information in a database using JPA. The data model itself contains three entities, one for process instance information, one for node instance information, and one for (process) variable instance information.
The ProcessInstanceLog
table contains the basic
log information about a process instance.
Table 8.8. ProcessInstanceLog
Field | Description | Nullable |
---|---|---|
id | The primary key and id of the log entity | NOT NULL |
duration | Actual duration of this process instance since its start date | |
end_date | When applicable, the end date of the process instance | |
externalId | Optional external identifier used to correlate to some elements - e.g. deployment id | |
user_identity | Optional identifier of the user who started the process instance | |
outcome | The outcome of the process instance, for instance error code in case of process instance was finished with error event | |
parentProcessInstanceId | The process instance id of the parent process instance if any | |
processid | The id of the process | |
processinstanceid | The process instance id | NOT NULL |
processname | The name of the process | |
processversion | The version of the process | |
start_date | The start date of the process instance | |
status | The status of process instance that maps to process instance state |
The NodeInstanceLog
table contains more information about which
nodes were actually executed inside each process instance. Whenever a node instance
is entered from one of its incoming connections or is exited through one of its outgoing
connections, that information is stored in this table.
Table 8.9. NodeInstanceLog
Field | Description | Nullable |
---|---|---|
id | The primary key and id of the log entity | NOT NULL |
connection | Actual identifier of the sequence flow that led to this node instance | |
log_date | The date of the event | |
externalId | Optional external identifier used to correlate to some elements - e.g. deployment id | |
nodeid | The node id of the corresponding node in the process definition | |
nodeinstanceid | The node instance id | |
nodename | The name of the node | |
nodetype | The type of the node | |
processid | The id of the process that the process instance is executing | |
processinstanceid | The process instance id | NOT NULL |
type | The type of the event (0 = enter, 1 = exit) | NOT NULL |
workItemId | Optional - only for certain node types - The identifier of work item |
The VariableInstanceLog
table contains information about changes
in variable instances. The default is to only generate log entries when (after) a variable
changes. It's also possible to log entries before the variable (value) changes.
Table 8.10. VariableInstanceLog
Field | Description | Nullable |
---|---|---|
id | The primary key and id of the log entity | NOT NULL |
externalId | Optional external identifier used to correlate to some elements - e.g. deployment id | |
log_date | The date of the event | |
processid | The id of the process that the process instance is executing | |
processinstanceid | The process instance id | NOT NULL |
oldvalue | The previous value of the variable at the time that the log is made | |
value | The value of the variable at the time that the log is made | |
variableid | The variable id in the process definition | |
variableinstanceid | The id of the variable instance |
To log process history information in a database like this, you need to register the logger on your session like this:
EntityManagerFactory emf = ...;
StatefulKnowledgeSession ksession = ...;
AbstractAuditLogger auditLogger = AuditLoggerFactory.newJPAInstance(emf);
ksession.addProcessEventListener(auditLogger);
// invoke methods one your session here
To specify the database where the information should be stored,
modify the file persistence.xml
file to include
the audit log classes as well (ProcessInstanceLog, NodeInstanceLog and
VariableInstanceLog), as shown below.
<?xml version="1.0" encoding="UTF-8" standalone="yes"?>
<persistence
version="2.0"
xsi:schemaLocation="http://java.sun.com/xml/ns/persistence http://java.sun.com/xml/ns/persistence/persistence_2_0.xsd
http://java.sun.com/xml/ns/persistence/orm http://java.sun.com/xml/ns/persistence/orm_2_0.xsd"
xmlns="http://java.sun.com/xml/ns/persistence"
xmlns:orm="http://java.sun.com/xml/ns/persistence/orm"
xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance>
<persistence-unit name="org.jbpm.persistence.jpa" transaction-type="JTA">
<provider>org.hibernate.ejb.HibernatePersistence</provider>
<jta-data-source>jdbc/jbpm-ds</jta-data-source>
<mapping-file>META-INF/JBPMorm.xml</mapping-file>
<class>org.drools.persistence.info.SessionInfo</class>
<class>org.jbpm.persistence.processinstance.ProcessInstanceInfo</class>
<class>org.drools.persistence.info.WorkItemInfo</class>
<class>org.jbpm.persistence.correlation.CorrelationKeyInfo</class>
<class>org.jbpm.persistence.correlation.CorrelationPropertyInfo</class>
<class>org.jbpm.runtime.manager.impl.jpa.ContextMappingInfo</class>
<class>org.jbpm.process.audit.ProcessInstanceLog</class>
<class>org.jbpm.process.audit.NodeInstanceLog</class>
<class>org.jbpm.process.audit.VariableInstanceLog</class>
<properties>
<property name="hibernate.dialect" value="org.hibernate.dialect.H2Dialect"/>
<property name="hibernate.max_fetch_depth" value="3"/>
<property name="hibernate.hbm2ddl.auto" value="update"/>
<property name="hibernate.show_sql" value="true"/>
<property name="hibernate.transaction.jta.platform"
value="org.hibernate.service.jta.platform.internal.BitronixJtaPlatform"/>
</properties>
</persistence-unit>
</persistence>
All this information can easily be queried and used in a lot of different use cases, ranging from creating a history log for one specific process instance to analyzing the performance of all instances of a specific process.
This audit log should only be considered a default implementation. We don't know what information you need to store for analysis afterwards, and for performance reasons it is recommended to only store the relevant data. Depending on your use cases, you might define your own data model for storing the information you need, and use the process event listeners to extract that information.
Process events are stored in the database synchronously and within the same transaction as actual process instance execution. That obviously takes some time especially in highly loaded systems and might have some impact on the database when both history log and runtime data are kept in the same database. To provide an alternative option for storing process events, a JMS based logger has been provided. It can be configured to submit messages to JMS queue instead of directly persisting them in the database. It can be configured to be transactional as well to avoid issues with inconsistent data in case of process engine transaction is rolled back.
ConnectionFactory factory = ...;
Queue queue = ...;
StatefulKnowledgeSession ksession = ...;
Map<String, Object> jmsProps = new HashMap<String, Object>();
jmsProps.put("jbpm.audit.jms.transacted", true);
jmsProps.put("jbpm.audit.jms.connection.factory", factory);
jmsProps.put("jbpm.audit.jms.queue", queue);
AbstractAuditLogger auditLogger = AuditLoggerFactory.newInstance(Type.JMS, session, jmsProps);
ksession.addProcessEventListener(auditLogger);
// invoke methods one your session here
This is just one of possible ways to configure JMS audit logger, see javadocs for AuditLoggerFactory for more details.
The jBPM engine supports JTA transactions. It also supports local transactions only when using Spring. It does not support pure local transactions at the moment. For more information about using Spring to set up persistence, please see the Spring chapter in the Drools integration guide.
Whenever you do not provide transaction boundaries inside your application, the engine will automatically execute each method invocation on the engine in a separate transaction. If this behavior is acceptable, you don't need to do anything else. You can, however, also specify the transaction boundaries yourself. This allows you, for example, to combine multiple commands into one transaction.
You need to register a transaction manager at the environment before using user-defined transactions. The following sample code uses the Bitronix transaction manager. Next, we use the Java Transaction API (JTA) to specify transaction boundaries, as shown below:
// create the entity manager factory and register it in the environment
EntityManagerFactory emf = Persistence.createEntityManagerFactory( "org.jbpm.persistence.jpa" );
Environment env = KnowledgeBaseFactory.newEnvironment();
env.set( EnvironmentName.ENTITY_MANAGER_FACTORY, emf );
env.set( EnvironmentName.TRANSACTION_MANAGER, TransactionManagerServices.getTransactionManager() );
// create a new knowledge session that uses JPA to store the runtime state
StatefulKnowledgeSession ksession = JPAKnowledgeService.newStatefulKnowledgeSession( kbase, null, env );
// start the transaction
UserTransaction ut = (UserTransaction) new InitialContext().lookup( "java:comp/UserTransaction" );
ut.begin();
// perform multiple commands inside one transaction
ksession.insert( new Person( "John Doe" ) );
ksession.startProcess( "MyProcess" );
// commit the transaction
ut.commit();
Note that, if you use Bitronix as the transaction manager, you should also add
a simple jndi.properties
file in you root classpath to register the
Bitronix transaction manager in JNDI. If you are using the jbpm-test module, this is
already included by default. If not, create a file named jndi.properties
with the following content:
java.naming.factory.initial=bitronix.tm.jndi.BitronixInitialContextFactory
If you would like to use a different JTA transaction manager, you can change the
persistence.xml
file to use your own transaction manager. For example,
when running inside JBoss Application Server v5.x or v7.x, you can use the JBoss transaction manager.
You need to change the transaction manager property in persistence.xml
to:
<property name="hibernate.transaction.jta.platform" value="org.hibernate.transaction.JBossTransactionManagerLookup" />
Special consideration need to be taken when embedding jBPM inside an application that executes in Container Managed Transaction (CMT) mode, for instance EJB beans. This especially applies to application servers that does not allow accessing UserTransaction instance from JNDI when being part of container managed transaction, e.g. WebSphere Application Server. Since default implementation of transaction manager in jBPM is based on UserTransaction to get transaction status which is used to decide if transaction should be started or not, in environments that prevent accessing UserTrancation it won't do its job. To secure proper execution in CMT environments a dedicated transaction manager implementation is provided:
org.jbpm.persistence.jta.ContainerManagedTransactionManager
This transaction manager expects that transaction is active and thus will always return ACTIVE when invoking getStatus method. Operations like begin, commit, rollback are no-op methods as transaction manager runs under managed transaction and can't affect it.
To make sure that container is aware of any exceptions that happened during process instance execution, user needs to ensure that exceptions thrown by the engine are propagated up to the container to properly rollback transaction.
To configure this transaction manager following must be done:
Environment env = EnvironmentFactory.newEnvironment();
env.set(EnvironmentName.ENTITY_MANAGER_FACTORY, emf);
env.set(EnvironmentName.TRANSACTION_MANAGER, new ContainerManagedTransactionManager());
env.set(EnvironmentName.PERSISTENCE_CONTEXT_MANAGER, new JpaProcessPersistenceContextManager(env));
env.set(EnvironmentName.TASK_PERSISTENCE_CONTEXT_MANAGER, new JPATaskPersistenceContextManager(env));
<property name="hibernate.transaction.factory_class" value="org.hibernate.transaction.CMTTransactionFactory"/>
<property name="hibernate.transaction.jta.platform" value="org.hibernate.service.jta.platform.internal.WebSphereJtaPlatform"/>
With following configuration jBPM should run properly in CMT environment.
Usually when running within container managed transaction disposing ksession directly will cause exceptions
on transaction completion as there are some transaction synchronization registered by jBPM to clean up
the state after invocation is finished. To overcome this problem specialized command has been provided
org.jbpm.persistence.jta.ContainerManagedTransactionDisposeCommand
which allows to simply
execute this command instead of regular ksession.dispose
which will ensure that ksession will
be disposed at the transaction completion.
By default, the engine does not save runtime data persistently. This means you can use the engine completely without persistence (so not even requiring an in memory database) if necessary, for example for performance reasons, or when you would like to manage persistence yourself. It is, however, possible to configure the engine to do use persistence by configuring it to do so. This usually requires adding the necessary dependencies, configuring a datasource and creating the engine with persistence configured.
You need to make sure the necessary dependencies are available in the classpath of your application if you want to user persistence. By default, persistence is based on the Java Persistence API (JPA) and can thus work with several persistence mechanisms. We are using Hibernate by default.
If you're using the Eclipse IDE and the jBPM Eclipse plugin, you should make sure the necessary JARs are added to your jBPM runtime directory. You don't really need to do anything (as the necessary dependencies should already be there) if you are using the jBPM runtime that is configured by default when using the jBPM installer, or if you downloaded and unzipped the jBPM runtime artifact (from the downloads) and pointed the jBPM plugin to that directory.
If you would like to manually add the necessary dependencies to your project, first of all,
you need the JAR file jbpm-persistence-jpa.jar
,
as that contains code for saving the runtime state whenever necessary.
Next, you also need various other dependencies, depending on the
persistence solution and database you are using. For the default
combination with Hibernate as the JPA persistence provider and using an H2
in-memory database and Bitronix for JTA-based transaction management, the
following list of additional dependencies is needed:
You can use the JPAKnowledgeService
to create your knowledge session. This
is slightly more complex, but gives you full access to the underlying configurations. You can create
a new knowledge session using JPAKnowledgeService
based on a knowledge base, a
knowledge session configuration (if necessary) and an environment. The environment
needs to contain a reference to your Entity Manager Factory. For example:
// create the entity manager factory and register it in the environment
EntityManagerFactory emf =
Persistence.createEntityManagerFactory( "org.jbpm.persistence.jpa" );
Environment env = KnowledgeBaseFactory.newEnvironment();
env.set( EnvironmentName.ENTITY_MANAGER_FACTORY, emf );
// create a new knowledge session that uses JPA to store the runtime state
StatefulKnowledgeSession ksession = JPAKnowledgeService.newStatefulKnowledgeSession( kbase, null, env );
int sessionId = ksession.getId();
// invoke methods on your method here
ksession.startProcess( "MyProcess" );
ksession.dispose();
You can also use the JPAKnowledgeService
to recreate
a session based on a specific session id:
// recreate the session from database using the sessionId
ksession = JPAKnowledgeService.loadStatefulKnowledgeSession(sessionId, kbase, null, env );
Note that we only save the minimal state that is needed to continue execution of the process instance at some later point. This means, for example, that it does not contain information about already executed nodes if that information is no longer relevant, or that process instances that have been completed or aborted are removed from the database. If you want to search for history-related information, you should use the history log, as explained later.
You need to add a persistence configuration to your classpath to
configure JPA to use Hibernate and the H2 database (or your own preference), called
persistence.xml
in the META-INF directory, as shown below.
For more details on how to change this for your own configuration, we refer to
the JPA and Hibernate documentation for more information.
<?xml version="1.0" encoding="UTF-8" standalone="yes"?>
<persistence
version="2.0"
xsi:schemaLocation="http://java.sun.com/xml/ns/persistence http://java.sun.com/xml/ns/persistence/persistence_2_0.xsd
http://java.sun.com/xml/ns/persistence/orm http://java.sun.com/xml/ns/persistence/orm_2_0.xsd"
xmlns="http://java.sun.com/xml/ns/persistence"
xmlns:orm="http://java.sun.com/xml/ns/persistence/orm"
xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance>
<persistence-unit name="org.jbpm.persistence.jpa" transaction-type="JTA">
<provider>org.hibernate.ejb.HibernatePersistence</provider>
<jta-data-source>jdbc/jbpm-ds</jta-data-source>
<mapping-file>META-INF/JBPMorm.xml</mapping-file>
<class>org.drools.persistence.info.SessionInfo</class>
<class>org.jbpm.persistence.processinstance.ProcessInstanceInfo</class>
<class>org.drools.persistence.info.WorkItemInfo</class>
<class>org.jbpm.persistence.correlation.CorrelationKeyInfo</class>
<class>org.jbpm.persistence.correlation.CorrelationPropertyInfo</class>
<class>org.jbpm.runtime.manager.impl.jpa.ContextMappingInfo</class>
<properties>
<property name="hibernate.dialect" value="org.hibernate.dialect.H2Dialect"/>
<property name="hibernate.max_fetch_depth" value="3"/>
<property name="hibernate.hbm2ddl.auto" value="update"/>
<property name="hibernate.show_sql" value="true"/>
<property name="hibernate.transaction.jta.platform"
value="org.hibernate.service.jta.platform.internal.BitronixJtaPlatform"/>
</properties>
</persistence-unit>
</persistence>
This configuration file refers to a data source called "jdbc/jbpm-ds". If you run your application in an application server (like for example JBoss AS), these containers typically allow you to easily set up data sources using some configuration (like for example dropping a datasource configuration file in the deploy directory). Please refer to your application server documentation to know how to do this.
For example, if you're deploying to JBoss Application Server v5.x, you can create a datasource by dropping a configuration file in the deploy directory, for example:
<?xml version="1.0" encoding="UTF-8"?>
<datasources>
<local-tx-datasource>
<jndi-name>jdbc/jbpm-ds</jndi-name>
<connection-url>jdbc:h2:tcp://localhost/~/test</connection-url>
<driver-class>org.h2.jdbcx.JdbcDataSource</driver-class>
<user-name>sa</user-name>
<password></password>
</local-tx-datasource>
</datasources>
If you are however executing in a simple Java environment, you can use the
JBPMHelper
class to do this for you (see below for tests only) or the following code
fragment could be used to set up a data source (where we are using the H2 in-memory
database in combination with Bitronix in this case).
PoolingDataSource ds = new PoolingDataSource();
ds.setUniqueName("jdbc/jbpm-ds");
ds.setClassName("bitronix.tm.resource.jdbc.lrc.LrcXADataSource");
ds.setMaxPoolSize(3);
ds.setAllowLocalTransactions(true);
ds.getDriverProperties().put("user", "sa");
ds.getDriverProperties().put("password", "sasa");
ds.getDriverProperties().put("URL", "jdbc:h2:mem:jbpm-db");
ds.getDriverProperties().put("driverClassName", "org.h2.Driver");
ds.init();
You need to configure the jBPM engine to use persistence, usually simply by using the appropriate constructor when creating your session. There are various ways to create a session (as we have tried to make this as easy as possible for you and have several utility classes for you, depending for example if you are trying to write a process JUnit test).
The easiest way to do this is to use the jbpm-test
module that allows you to easily
create and test your processes. The JBPMHelper
class has a method to create a session,
and uses a configuration file to configure this session, like whether you want to use persistence,
the datasource to use, etc. The helper class will then do all the setup and configuration
for you.
To configure persistence, create a jBPM.properties
file and configure the following properties
(note that the example below are the default properties, using an H2 in-memory database with persistence
enabled, if you are fine with all of these properties, you don't need to add new properties file, as it
will then use these properties by default):
# for creating a datasource
persistence.datasource.name=jdbc/jbpm-ds
persistence.datasource.user=sa
persistence.datasource.password=
persistence.datasource.url=jdbc:h2:tcp://localhost/~/jbpm-db
persistence.datasource.driverClassName=org.h2.Driver
# for configuring persistence of the session
persistence.enabled=true
persistence.persistenceunit.name=org.jbpm.persistence.jpa
persistence.persistenceunit.dialect=org.hibernate.dialect.H2Dialect
# for configuring the human task service
taskservice.enabled=true
taskservice.datasource.name=org.jbpm.task
taskservice.usergroupcallback=org.jbpm.services.task.identity.JBossUserGroupCallbackImpl
taskservice.usergroupmapping=classpath:/usergroups.properties
If you want to use persistence, you must make sure that the datasource (that you specified
in the jBPM.properties
file) is initialized correctly. This means that the database itself must
be up and running, and the datasource should be registered using the correct name. If you would like
to use an H2 in-memory database (which is usually very easy to do some testing), you can use the
JBPMHelper
class to start up this database, using:
JBPMHelper.startH2Server();
To register the datasource (this is something you always need to do, even if you're not using H2 as your database, check below for more options on how to configure your datasource), use:
JBPMHelper.setupDataSource();
Next, you can use the JBPMHelper
class to create your session (after creating your knowledge base,
which is identical to the case when you are not using persistence):
StatefulKnowledgeSession ksession = JBPMHelper.newStatefulKnowledgeSession(kbase);
Once you have done that, you can just call methods on this ksession (like startProcess
)
and the engine will persist all runtime state in the created datasource.
You can also use the JBPMHelper
class to recreate your session (by restoring its state
from the database, by passing in the session id (that you can retrieve using ksession.getId()
)):
StatefulKnowledgeSession ksession = JBPMHelper.loadStatefulKnowledgeSession(kbase, sessionId);
How to use the web-based Workbench
Table of Contents
From the workbench distribution zip, take the kie-wb-*.war
that corresponds to your
application server:
jboss-as7
: tailored for JBoss AS 7 (which is being renamed to WildFly in version
8)
tomcat7
: the generic war, works on Tomcat and Jetty
The differences between these war
files are superficial only, to allow out-of-the-box
deployment. For example, some JARs might be excluded if the application server already supplies them.
To use the workbench on a different application server (WebSphere, WebLogic, ...), use the
tomcat7
war and tailor it to your application server's version.
The workbench stores its data, by default in the directory $WORKING_DIRECTORY/.niogit
, for
example wildfly-8.0.0.Final/bin/.gitnio
, but it can be overridden with the system property -Dorg.uberfire.nio.git.dir
.
In production, make sure to back up the workbench data directory.
Here's a list of all system properties:
org.uberfire.nio.git.dir
: Location of the directory
.niogit
. Default: working directory
org.uberfire.nio.git.daemon.enabled
: Enables/disables
git daemon. Default: true
org.uberfire.nio.git.daemon.host
: If git daemon enabled,
uses this property as local host identifier. Default: localhost
org.uberfire.nio.git.daemon.port
: If git daemon enabled,
uses this property as port number. Default: 9418
org.uberfire.nio.git.ssh.enabled
: Enables/disables
ssh daemon. Default: true
org.uberfire.nio.git.ssh.host
: If ssh daemon enabled,
uses this property as local host identifier. Default: localhost
org.uberfire.nio.git.ssh.port
: If ssh daemon enabled,
uses this property as port number. Default: 8001
org.uberfire.nio.git.ssh.cert.dir
: Location of the directory
.security
where local certtificates will be stored. Default: working directory
org.uberfire.metadata.index.dir
: Place where Lucene
.index
folder will be stored. Default: working directory
org.uberfire.cluster.id
: Name of the helix cluster,
for example: kie-cluster
org.uberfire.cluster.zk
: Connection string to
zookeeper. This is of the form host1:port1,host2:port2,host3:port3
, for example:
localhost:2188
org.uberfire.cluster.local.id
: Unique id of the helix
cluster node, note that ':
' is replaced with '_
', for example:
node1_12345
org.uberfire.cluster.vfs.lock
: Name of the resource
defined on helix cluster, for example: kie-vfs
org.uberfire.cluster.autostart
: Delays VFS clustering
until the application is fully initialized to avoid conflicts when all cluster members create local clones.
Default: false
org.uberfire.sys.repo.monitor.disabled
: Disable
configuration monitor (do not disable unless you know what you're doing). Default:
false
org.uberfire.secure.key
: Secret password used by
password encryption. Default: org.uberfire.admin
org.uberfire.secure.alg
: Crypto algorithm used by
password encryption. Default: PBEWithMD5AndDES
org.uberfire.domain
: security-domain name used by
uberfire. Default: ApplicationRealm
org.guvnor.m2repo.dir
: Place where Maven repository
folder will be stored. Default: working-directory/repositories/kie
org.kie.example.repositories
: Folder from where demo
repositories will be cloned. The demo repositories need to have been obtained and placed in this folder. Demo
repositories can be obtained from the kie-wb-6.2.0-SNAPSHOT-example-repositories.zip artifact. This System
Property takes precedence over org.kie.demo and org.kie.example. Default: Not used.
org.kie.demo
: Enables external clone of a demo
application from GitHub. This System Property takes precedence over org.kie.example. Default:
true
org.kie.example
: Enables example structure composed by
Repository, Organization Unit and Project. Default: false
To change one of these system properties in a WildFly or JBoss EAP cluster:
Edit the file $JBOSS_HOME/domain/configuration/host.xml
.
Locate the XML elements server
that belong to the main-server-group
and add a system property, for example:
<system-properties>
<property name="org.uberfire.nio.git.dir" value="..." boot-time="false"/>
...
</system-properties>
These steps help you get started with minimum of effort.
They should not be a substitute for reading the documentation in full.
Create a new repository to hold your project by selecting the Administration Perspective.
Select the "New repository" option from the menu.
Enter the required information.
Select the Authoring Perspective to create a new project.
Select "Project" from the "New Item" menu.
Enter a project name first.
Enter the project details next.
Group ID follows Maven conventions.
Artifact ID is pre-populated from the project name.
Version is set as 1.0 by default.
After a project has been created you need to define Types to be used by your rules.
Select "Data Object" from the "New Item" menu.
You can also use types contained in existing JARs.
Please consult the full documentation for details.
Set the name and select a package for the new type.
Set field name and type and click on "Create" to create a field for the type.
Click "Save" to update the model.
Select "DRL file" (for example) from the "New Item" menu.
Enter a file name for the new rule.
Enter a definition for the rule.
The definition process differs from asset type to asset type.
The full documentation has details about the different editors.
Once the rule has been defined it will need to be saved.
Once rules have been defined within a project; the project can be built and deployed to the Workbench's Maven Artifact Repository.
To build a project select the "Project Editor" from the "Project" menu.
Click "Build and Deploy" to build the project and deploy it to the Workbench's Maven Artifact Repository.
When you select Build & Deploy the workbench will deploy to any repositories defined in the Dependency Management section of the pom in your workbench project. You can edit the pom.xml file associated with your workbench project under the Repository View of the project explorer. Details on dependency management in maven can be found here : http://maven.apache.org/guides/introduction/introduction-to-dependency-mechanism.html
If there are errors during the build process they will be reported in the "Problems Panel".
Now the project has been built and deployed; it can be referenced from your own projects as any other Maven Artifact.
The full documentation contains details about integrating projects with your own applications.
A workbench is structured with Organization Units, VFS repositories and projects:
Organization units are useful to model departments and divisions.
An organization unit can hold multiple repositories.
Repositories are the place where assets are stored and each repository is organized by projects and belongs to a single organization unit.
Repositories are in fact a Virtual File System based storage, that by default uses GIT as backend. Such setup allows workbench to work with multiple backends and, in the same time, take full advantage of backend specifics features like in GIT case versioning, branching and even external access.
A new repository can be created from scratch or cloned from an existing repository.
One of the biggest advantage of using GIT as backend is the ability to clone a repository from external and use your preferred tools to edit and build your assets.
Never clone your repositories directly from .niogit directory. Use always the available protocol(s) displayed in repositories editor.
The workbench authenticates its users against the application server's authentication and authorization (JAAS).
On JBoss EAP and WildFly, add a user with the script $JBOSS_HOME/bin/add-user.sh
(or
.bat
):
$ ./add-user.sh
// Type: Application User
// Realm: empty (defaults to ApplicationRealm)
// Role: admin
There is no need to restart the application server.
The Workbench uses the following roles:
admin
analyst
developer
manager
user
Administrates the BPMS system.
Manages users
Manages VFS Repositories
Has full access to make any changes necessary
Developer can do almost everything admin can do, except clone repositories.
Manages rules, models, process flows, forms and dashboards
Manages the asset repository
Can create, build and deploy projects
Can use the JBDS connection to view processes
Analyst is a weaker version of developer and does not have access to the asset repository or the ability to deploy projects.
Daily user of the system to take actions on business tasks that are required for the processes to continue forward. Works primarily with the task lists.
Does process management
Handles tasks and dashboards
It is possible to restrict access to repositories using roles and organizational groups. To let an user access a repository.
The user either has to belong into a role that has access to the repository or to a role that belongs into an orgazinational group that has access to the repository. These restrictions can be managed with the command line config tool.
Provides capabilities to manage the system repository from command line. System repository contains the data about general workbench settings: how editors behave, organizational groups, security and other settings that are not editable by the user. System repository exists in the .niogit folder, next to all the repositories that have been created or cloned into the workbench.
Online (default and recommended) - Connects to the Git repository on startup, using Git server provided by the KIE Workbench. All changes are made locally and published to upstream when:
"push-changes" command is explicitly executed
"exit" is used to close the tool
Offline - Creates and manipulates system repository directly on the server (no discard option)
Table 9.1. Available Commands
exit | Publishes local changes, cleans up temporary directories and quits the command line tool |
discard | Discards local changes without publishing them, cleans up temporary directories and quits the command line tool |
help | Prints a list of available commands |
list-repo | List available repositories |
list-org-units | List available organizational units |
list-deployment | List available deployments |
create-org-unit | Creates new organizational unit |
remove-org-unit | Removes existing organizational unit |
add-deployment | Adds new deployment unit |
remove-deployment | Removes existing deployment |
create-repo | Creates new git repository |
remove-repo | Removes existing repository ( only from config ) |
add-repo-org-unit | Adds repository to the organizational unit |
remove-repo-org-unit | Removes repository from the organizational unit |
add-role-repo | Adds role(s) to repository |
remove-role-repo | Removes role(s) from repository |
add-role-org-unit | Adds role(s) to organizational unit |
remove-role-org-unit | Removes role(s) from organizational unit |
add-role-project | Adds role(s) to project |
remove-role-project | Removes role(s) from project |
push-changes | Pushes changes to upstream repository (only in online mode) |
The tool can be found from kie-config-cli-${version}-dist.zip. Execute the kie-config-cli.sh script and by default it will start in online mode asking for a Git url to connect to ( the default value is ssh://localhost/system ). To connect to a remote server, replace the host and port with appropriate values, e.g. ssh://kie-wb-host/system.
./kie-config-cli.sh
To operate in offline mode, append the offline parameter to the kie-config-cli.sh command. This will change the behaviour and ask for a folder where the .niogit (system repository) is. If .niogit does not yet exist, the folder value can be left empty and a brand new setup is created.
./kie-config-cli.sh offline
Create a user with the role admin
and log in with those credentials.
After successfully logging in, the account username is displayed at the top right. Click on it to review the roles of the current account.
After logging in, the home screen shows. The actual content of the home screen depends on the workbench variant (Drools, jBPM, ...).
The Workbench is comprised of different logical entities:
Part
A Part is a screen or editor with which the user can interact to perform operations.
Example Parts are "Project Explorer", "Project Editor", "Guided Rule Editor" etc. Parts can be repositioned.
Panel
A Panel is a container for one or more Parts.
Panels can be resized.
Perspective
A perspective is a logical grouping of related Panels and Parts.
The user can switch between perspectives by clicking on one of the top-level menu items; such as "Home", "Authoring", "Deploy" etc.
The Workbench consists of three main sections to begin; however its layout and content can be changed.
The initial Workbench shows the following components:-
Project Explorer
This provides the ability for the user to browse their configuration; of Organizational Units (in the above "example" is the Organizational Unit), Repositories (in the above "uf-playground" is the Repository) and Project (in the above "mortgages" is the Project).
Problems
This provides the user will real-time feedback about errors in the active Project.
Empty space
This empty space will contain an editor for assets selected from the Project Explorer.
Other screens will also occupy this space by default; such as the Project Editor.
The default layout may not be suitable for a user. Panels can therefore be either resized or repositioned.
This, for example, could be useful when running tests; as the test defintion and rule can be repositioned side-by-side.
The following screenshot shows a Panel being resized.
Move the mouse pointer over the panel splitter (a grey horizontal or vertical line in between panels).
The cursor will changing indicating it is positioned correctly over the splitter. Press and hold the left mouse button and drag the splitter to the required position; then release the left mouse button.
The following screenshot shows a Panel being repositioned.
Move the mouse pointer over the Panel title ("Guided Editor [No bad credit checks]" in this example).
The cursor will change indicating it is positioned correctly over the Panel title. Press and hold the left mouse button. Drag the mouse to the required location. The target position is indicated with a pale blue rectangle. Different positions can be chosen by hovering the mouse pointer over the different blue arrows.
Projects often need external artifacts in their classpath in order to build, for example a domain model JARs. The artifact repository holds those artifacts.
The Artifact Repository is a full blown Maven repository. It follows the semantics of a Maven remote repository: all snapshots are timestamped. But it is often stored on the local hard drive.
By default the artifact repository is stored under $WORKING_DIRECTORY/repositories/kie
, but
it can be overridden with the system property
-Dorg.guvnor.m2repo.dir
. There is only 1 Maven repository per installation.
The Artifact Repository screen shows a list of the artifacts in the Maven repository:
To add a new artifact to that Maven repository, either:
Use the upload button and select a JAR. If the JAR contains a POM file under
META-INF/maven
(which every JAR build by Maven has), no further information is needed.
Otherwise, a groupId, artifactId and version need be given too.
Using Maven, mvn deploy
to that Maven repository. Refresh the list to make it show
up.
This remote Maven repository is relatively simple. It does not support proxying, mirroring, ... like Nexus or Archiva.
The Asset Editor is the principle component of the workbench User-Interface. It consists of two main views Editor and Overview.
The views
A : The editing area - exactly what form the editor takes depends on the Asset type.
B : This menu bar contains various actions for the Asset; such as Saving, Renaming, Copy etc.
C : Different views for asset content or asset information.
Editor shows the main editor for the asset
Overview contains the metadata and conversation views for this editor. Explained in more detail below.
Source shows the asset in plain DRL. Note: This tab is only visible if the asset content can be generated into DRL.
Config contains the model imports used by the asset.
Overview
A : General information about the asset and the asset's description.
"Type:" The format name of the type of Asset.
"Description:" Description for the asset.
"Used in projects:" Names the projects where this rule is used.
"Last Modified:" Who made the last change and when.
"Created on:" Who created the asset and when.
B : Version history for the asset. Selecting a version loads the selected version into this editor.
C : Meta data (from the "Dublin Core" standard)
D : Comments regarding the development of the Asset can be recorded here.
Metadata
A : Meta data:-
"Categories:" A deprecated feature for grouping the assets.
"Note:" A comment made when the Asset was last updated (i.e. why a change was made)
"URI:" URI to the asset inside the Git repository.
"Subject/Type/External link/Source" : Other miscellaneous meta data for the Asset.
The Project Explorer provides the ability to browse different Organizational Units, Repositories, Projects and their files.
The initial view could be empty when first opened.
The user may have to select an Organizational Unit, Repository and Project from the drop-down boxes.
The default configuration hides Package details from view.
In order to reveal packages click on the icon as indicated in the following screen-shot.
After a suitable combination of Organizational Unit, Repository, Project and Package have been selected the Project Explorer will show the contents. The exact combination of selections depends wholly on the structures defined within the Workbench installation and projects. Each section contains groups of related files.
Project Explorer supports multiple views.
Project View
A simplified view of the underlying project structure. Certain system files are hidden from view.
Repository View
A complete view of the underlying project structure including all files; either user-defined or system generated.
Views can be selected by clicking on the icon within the Project Explorer, as shown below.
Both Project and Repository Views can be further refined by selecting either "Show as Folders" or "Show as Links".
Download Download and Download Repository make it possible to download the project or repository as a zip file.
A branch selector will be visible if the repository has more than a single branch.
Copy, rename and delete actions are available on Links mode, for packages (in of Project View) and for files and directories as well (in Repository View). Download action is available for directories. Download downloads the selected the selected directory as a zip file.
A : Copy
B : Rename
C : Delete
D : Download
Workbench roadmap includes a refactoring and an impact analyses tools, but currenctly doesn't have it. Until both tools are provided make sure that your changes (copy/rename/delete) on packages, files or directories doesn't have a major impact on your project.
In cases that your change had an unexcepcted impact, Workbench allows you to restore your repository using the Repository editor.
The Project Editor screen can be accessed from Project Explorer. Project Editor shows the settings for the currently active project.
Unlike most of the workbench editors, project editor edits more than one file. Showing everything that is needed for configuring the KIE project in one place.
Build & Depoy builds the current project and deploys the KJAR into the workbench internal Maven repository.
Project Settings edits the pom.xml file used by Maven.
General settings provide tools for project name and GAV-data (Group, Artifact, Version). GAV values are used as identifiers to differentiate projects and versions of the same project.
The project may have any number of either internal or external dependencies. Dependency is a project that has been built and deployed to a Maven repository. Internal dependencies are projects build and deployed in the same workbench as the project. External dependencies are retrieved from repositories outside of the current workbench. Each dependency uses the GAV-values to specify the project name and version that is used by the project.
Knowledge Base Settings edits the kmodule.xml file used by Drools.
For more information about the Knowledge Base properties, check the Drools Expert documentation for kmodule.xml.
Knowledge bases and sessions lists the knowledge bases and the knowledge sessions specified for the project.
Lists all the knowledge bases by name. Only one knowledge base can be set as default.
Knowledge base can include other knowledge bases. The models, rules and any other content in the included knowledge base will be visible and usable by the currently selected knowledge base.
Rules and models are stored in packages. The packages property specifies what packages are included into this knowledge base.
Equals behavior is explained in the Drools Expert part of the documentation.
Event processing mode is explained in the Drools Fusion part of the documentation.
Settings edits the project.imports file used by the workbench editors.
Import Suggestions lists imports that are used as suggestions when using the guided editors the workbench has. Making it easier to work with the workbench, as there is no need to type each import in each file that uses the import.
Unlike in the previous version of Guvnor. The imports listed in the import suggestions are not automatically added into the knowledge base or into the packages of the workbench. Each import needs to be explicitly added into each file.
The Workbench provides a common and consistent service for users to understand whether files authored within the environment are valid.
The Problems Panel shows real-time validation results of assets within a Project.
When a Project is selected from the Project Explorer the Problems Panel will refresh with validation results of the chosen Project.
When files are created, saved or deleted the Problems Panel content will update to show either new validation errors, or remove existing if a file was deleted.
Figure 9.44. The Problems Panel
Here an invalid DRL file has been created and saved.
The Problems Panel shows the validation errors.
By default, a data model is always constrained to the context of a project. For the purpose of this tutorial, we will assume that a correctly configured project already exists and the authoring perspective is open.
To start the creation of a data model inside a project, take the following steps:
From the home panel, select the authoring perspective and use the project explorer to browse to the given project.
Open the Data Modeller tool by clicking on a Data Object file, or using the "New Item -> Data Object" menu option.
This will start up the Data Modeller tool, which has the following general aspect:
The "Editor" tab is divided into the following sections:
The new field section is dedicated to the creation of new fields.
The Data Object's "field browser" section displays a list with the data object fields.
The "Data Object / field property editor" section. This is the rightmost section of the Data Modeller editor and visualizes a tabbed pane. The "Data object" tab allows the user to edit the class level properties of the data object, and the "Field" tab allows the edition of the properties for the currently selected field.
The "Source" tab shows an editor that allows the visualization and modification of the generated java code.
Round trip between the "Editor" and "Source" tabs is possible, and also source code preservation is provided. It means that not matter where the Java code was generated (e.g. Eclipse, Data modeller), the data modeller will only update the necessary code blocks to maintain the model updated.
The "Overview" tab shows the standard metadata and version information as the other workbench editors.
A data model consists of data objects which are a logical representation of some real-world data. Such data objects have a fixed set of modeller (or application-owned) properties, such as its internal identifier, a label, description, package etc. Besides those, a data object also has a variable set of user-defined fields, which are an abstraction of a real-world property of the type of data that this logical data object represents.
Creating a data object can be achieved using the workbench "New Item - Data Object" menu option.
Both resource name and location are mandatory parameters. When the "Ok" button is pressed a new Java file will be created and a new editor instance will be opened for the file edition.
Once the data object has been created, it now has to be completed by adding user-defined properties to its definition. This can be achieved by providing the required information in the "Create new field" section (see fig. "New field creation"), and clicking on the "Create" button when finished. The following fields can (or must) be filled out:
The field's internal identifier (mandatory). The value of this field must be unique per data object, i.e. if the proposed identifier already exists within current data object, an error message will be displayed.
A label (optional): as with the data object definition, the user can define a user-friendly label for the data object field which is about to be created. This has no further implications on how fields from objects of this data object will be treated. If a label is defined, then this is how the field will be displayed throughout the data modeller tool.
A field type (mandatory): each data object field needs to be assigned with a type.
This type can be either of the following:
A 'primitive java object' type: these include most of the object equivalents of the standard Java primitive types, such as Boolean, Short, Float, etc, as well as String, Date, BigDecimal and BigInteger.
A 'data object' type: any user defined data object automatically becomes a candidate to be defined as a field type of another data object, thus enabling the creation of relationships between them. A data object field can be created either in 'single' or in 'multiple' form, the latter implying that the field will be defined as a collection of this type, which will be indicated by selecting "List" checkbox.
A 'primitive java' type: these include java primitive types byte, short, int, long, float, double, char and boolean.
When finished introducing the initial information for a new field, clicking the 'Create' button will add the newly created field to the end of the data object's fields table below:
The new field will also automatically be selected in the data object's field list, and its properties will be shown in the Field tab of the Property editor. The latter facilitates completion of some additional properties of the new field by the user (see below).
At any time, any field (without restrictions) can be deleted from a data object definition by clicking on the corresponding 'x' icon in the data object's fields table.
As stated before, both data objects as well as fields require some of their initial properties to be set upon creation. These are by no means the only properties data objects and fields have. Below we will give a detailed description of the additional data object and field properties.
Description: this field allows the user to introduce some kind of description for the current data object, for documentation purposes only. As with the label property, this is conceptual information that will not influence the use or treatment of this data object or its instances in any way.
TypeSafe: this property allows to enable/disable the type safe behaviour for current type. By default all type declarations are compiled with type safety enabled. (See Drools for more information on this matter).
ClassReactive: this property allows to mark this type to be treated as "Class Reactive" by the Drools engine. (See Drools for more information on this matter).
PropertyReactive: this property allows to mark this type to be treated as "Property Reactive" by the Drools engine. (See Drools for more information on this matter).
Role: this property allows to configure how the Drools engine should handle instances of this type: either as regular facts or as events. By default all types are handled as a regular fact, so for the time being the only value that can be set is "Event" to declare that this type should be handled as an event. (See Drools Fusion for more information on this matter).
Timestamp: this property allows to configure the "timestamp" for an event, by selecting one of his attributes. If set the engine will use the timestamp from the given attribute instead of reading it from the Session Clock. If not, the engine will automatically assign a timestamp to the event. (See Drools Fusion for more information on this matter).
Duration: this property allows to configure the "duration" for an event, by selecting one of his attributes. If set the engine will use the duration from the given attribute instead of using the default event duration = 0. (See Drools Fusion for more information on this matter).
Expires: this property allows to configure the "time offset" for an event expiration. If set, this value must be a temporal interval in the form: [#d][#h][#m][#s][#[ms]] Where [ ] means an optional parameter and # means a numeric value. e.g.: 1d2h, means one day and two hours. (See Drools Fusion for more information on this matter).
Remotable: If checked this property makes the data object available to be used with jBPM remote services as REST, JMS and WS. (See jBPM for more information on this matter).
Description: this field allows the user to introduce some kind of description for the current field, for documentation purposes only. As with the label property, this is conceptual information that will not influence the use or treatment of this data object or its instances in any way.
Equals: checking this property for a data object field implies that it will be taken into account, at the code generation level, for the creation of both the equals() and hashCode() methods in the generated Java class. We will explain this in more detail in the following section.
Position: this field requires a zero or positive integer. When set, this field will be interpreted by the Drools engine as a positional argument (see the section below and also the Drools documentation for more information on this subject).
The data model in itself is merely a visual tool that allows the user to define high-level data structures, for them to interact with the Drools Engine on the one hand, and the jBPM platform on the other. In order for this to become possible, these high-level visual structures have to be transformed into low-level artifacts that can effectively be consumed by these platforms. These artifacts are Java POJOs (Plain Old Java Objects), and they are generated every time the data model is saved, by pressing the "Save" button in the top Data Modeller Menu. Additionally when the user round trip between the "Editor" and "Source" tab, the code is auto generated to maintain the consistency with the Editor view and vice versa.
The resulting code is generated according to the following transformation rules:
The data object's identifier property will become the Java class's name. It therefore needs to be a valid Java identifier.
The data object's package property becomes the Java class's package declaration.
The data object's superclass property (if present) becomes the Java class's extension declaration.
The data object's label and description properties will translate into the Java annotations "@org.kie.api.definition.type.Label" and "@org.kie.api.definition.type.Description", respectively. These annotations are merely a way of preserving the associated information, and as yet are not processed any further.
The data object's role property (if present) will be translated into the "@org.kie.api.definition.type.Role" Java annotation, that IS interpreted by the application platform, in the sense that it marks this Java class as a Drools Event Fact-Type.
The data object's type safe property (if present) will be translated into the "@org.kie.api.definition.type.TypeSafe Java annotation. (see Drools)
The data object's class reactive property (if present) will be translated into the "@org.kie.api.definition.type.ClassReactive Java annotation. (see Drools)
The data object's property reactive property (if present) will be translated into the "@org.kie.api.definition.type.PropertyReactive Java annotation. (see Drools)
The data object's timestamp property (if present) will be translated into the "@org.kie.api.definition.type.Timestamp Java annotation. (see Drools)
The data object's duration property (if present) will be translated into the "@org.kie.api.definition.type.Duration Java annotation. (see Drools)
The data object's expires property (if present) will be translated into the "@org.kie.api.definition.type.Expires Java annotation. (see Drools)
The data object's remotable property (if present) will be translated into the "@org.kie.api.remote.Remotable Java annotation. (see jBPM)
A standard Java default (or no parameter) constructor is generated, as well as a full parameter constructor, i.e. a constructor that accepts as parameters a value for each of the data object's user-defined fields.
The data object's user-defined fields are translated into Java class fields, each one of them with its own getter and setter method, according to the following transformation rules:
The data object field's identifier will become the Java field identifier. It therefore needs to be a valid Java identifier.
The data object field's type is directly translated into the Java class's field type. In case the field was declared to be multiple (i.e. 'List'), then the generated field is of the "java.util.List" type.
The equals property: when it is set for a specific field, then this class property will be annotated with the "@org.kie.api.definition.type.Key" annotation, which is interpreted by the Drools Engine, and it will 'participate' in the generated equals() method, which overwrites the equals() method of the Object class. The latter implies that if the field is a 'primitive' type, the equals method will simply compares its value with the value of the corresponding field in another instance of the class. If the field is a sub-entity or a collection type, then the equals method will make a method-call to the equals method of the corresponding data object's Java class, or of the java.util.List standard Java class, respectively.
If the equals property is checked for ANY of the data object's user defined fields, then this also implies that in addition to the default generated constructors another constructor is generated, accepting as parameters all of the fields that were marked with Equals. Furthermore, generation of the equals() method also implies that also the Object class's hashCode() method is overwritten, in such a manner that it will call the hashCode() methods of the corresponding Java class types (be it 'primitive' or user-defined types) for all the fields that were marked with Equals in the Data Model.
The position property: this field property is automatically set for all user-defined fields, starting from 0, and incrementing by 1 for each subsequent new field. However the user can freely changes the position among the fields. At code generation time this property is translated into the "@org.kie.api.definition.type.Position" annotation, which can be interpreted by the Drools Engine. Also, the established property order determines the order of the constructor parameters in the generated Java class.
As an example, the generated Java class code for the Purchase Order data object, corresponding to its definition as shown in the following figure purchase_example.jpg is visualized in the figure at the bottom of this chapter. Note that the two of the data object's fields, namely 'header' and 'lines' were marked with Equals, and have been assigned with the positions 2 and 1, respectively).
package org.jbpm.examples.purchases;
/**
* This class was automatically generated by the data modeler tool.
*/
@org.kie.api.definition.type.Label("Purchase Order")
@org.kie.api.definition.type.TypeSafe(true)
@org.kie.api.definition.type.Role(org.kie.api.definition.type.Role.Type.EVENT)
@org.kie.api.definition.type.Expires("2d")
@org.kie.api.remote.Remotable
public class PurchaseOrder implements java.io.Serializable
{
static final long serialVersionUID = 1L;
@org.kie.api.definition.type.Label("Total")
@org.kie.api.definition.type.Position(3)
private java.lang.Double total;
@org.kie.api.definition.type.Label("Description")
@org.kie.api.definition.type.Position(0)
private java.lang.String description;
@org.kie.api.definition.type.Label("Lines")
@org.kie.api.definition.type.Position(2)
@org.kie.api.definition.type.Key
private java.util.List<org.jbpm.examples.purchases.PurchaseOrderLine> lines;
@org.kie.api.definition.type.Label("Header")
@org.kie.api.definition.type.Position(1)
@org.kie.api.definition.type.Key
private org.jbpm.examples.purchases.PurchaseOrderHeader header;
@org.kie.api.definition.type.Position(4)
private java.lang.Boolean requiresCFOApproval;
public PurchaseOrder()
{
}
public java.lang.Double getTotal()
{
return this.total;
}
public void setTotal(java.lang.Double total)
{
this.total = total;
}
public java.lang.String getDescription()
{
return this.description;
}
public void setDescription(java.lang.String description)
{
this.description = description;
}
public java.util.List<org.jbpm.examples.purchases.PurchaseOrderLine> getLines()
{
return this.lines;
}
public void setLines(java.util.List<org.jbpm.examples.purchases.PurchaseOrderLine> lines)
{
this.lines = lines;
}
public org.jbpm.examples.purchases.PurchaseOrderHeader getHeader()
{
return this.header;
}
public void setHeader(org.jbpm.examples.purchases.PurchaseOrderHeader header)
{
this.header = header;
}
public java.lang.Boolean getRequiresCFOApproval()
{
return this.requiresCFOApproval;
}
public void setRequiresCFOApproval(java.lang.Boolean requiresCFOApproval)
{
this.requiresCFOApproval = requiresCFOApproval;
}
public PurchaseOrder(java.lang.Double total, java.lang.String description,
java.util.List<org.jbpm.examples.purchases.PurchaseOrderLine> lines,
org.jbpm.examples.purchases.PurchaseOrderHeader header,
java.lang.Boolean requiresCFOApproval)
{
this.total = total;
this.description = description;
this.lines = lines;
this.header = header;
this.requiresCFOApproval = requiresCFOApproval;
}
public PurchaseOrder(java.lang.String description,
org.jbpm.examples.purchases.PurchaseOrderHeader header,
java.util.List<org.jbpm.examples.purchases.PurchaseOrderLine> lines,
java.lang.Double total, java.lang.Boolean requiresCFOApproval)
{
this.description = description;
this.header = header;
this.lines = lines;
this.total = total;
this.requiresCFOApproval = requiresCFOApproval;
}
public PurchaseOrder(
java.util.List<org.jbpm.examples.purchases.PurchaseOrderLine> lines,
org.jbpm.examples.purchases.PurchaseOrderHeader header)
{
this.lines = lines;
this.header = header;
}
@Override
public boolean equals(Object o)
{
if (this == o)
return true;
if (o == null || getClass() != o.getClass())
return false;
org.jbpm.examples.purchases.PurchaseOrder that = (org.jbpm.examples.purchases.PurchaseOrder) o;
if (lines != null ? !lines.equals(that.lines) : that.lines != null)
return false;
if (header != null ? !header.equals(that.header) : that.header != null)
return false;
return true;
}
@Override
public int hashCode()
{
int result = 17;
result = 31 * result + (lines != null ? lines.hashCode() : 0);
result = 31 * result + (header != null ? header.hashCode() : 0);
return result;
}
}
Using an external model means the ability to use a set for already defined POJOs in current project context. In order to make those POJOs available a dependency to the given JAR should be added. Once the dependency has been added the external POJOs can be referenced from current project data model.
There are two ways to add a dependency to an external JAR file:
Dependency to a JAR file already installed in current local M2 repository (typically associated the the user home).
Dependency to a JAR file installed in current KIE Workbench/Drools Workbench "Guvnor M2 repository". (internal to the application)
To add a dependency to a JAR file in local M2 repository follow this steps.
To add a dependency to a JAR file in current "Guvnor M2 repository" follow this steps.
Once the file has been loaded it will be displayed in the repository files list.
If the uploaded file is not a valid Maven JAR (don't have a pom.xml file) the system will prompt the user in order to provide a GAV for the file to be installed.
Open the project editor (see bellow) and click on the "Add from repository" button to open the JAR selector to see all the installed JAR files in current "Guvnor M2 repository". When the desired file is selected the project should be saved in order to make the new dependency available.
When a dependency to an external JAR has been set, the external POJOs can be used in the context of current project data model in the following ways:
External POJOs can be extended by current model data objects.
External POJOs can be used as field types for current model data objects.
The following screenshot shows how external objects are prefixed with the string " -ext- " in order to be quickly identified.
Current version implements roundtrip and code preservation between Data modeller and Java source code. No matter where the Java code was generated (e.g. Eclipse, Data modeller), the data modeller will only create/delete/update the necessary code elements to maintain the model updated, i.e, fields, getter/setters, constructors, equals method and hashCode method. Also whatever Type or Field annotation not managed by the Data Modeler will be preserved when the Java sources are updated by the Data modeller.
Aside from code preservation, like in the other workbench editors, concurrent modification scenarios are still possible. Common scenarios are when two different users are updating the model for the same project, e.g. using the data modeller or executing a 'git push command' that modifies project sources.
From an application context's perspective, we can basically identify two different main scenarios:
In this scenario the application user has basically just been navigating through the data model, without making any changes to it. Meanwhile, another user modifies the data model externally.
In this case, no immediate warning is issued to the application user. However, as soon as the user tries to make any kind of change, such as add or remove data objects or properties, or change any of the existing ones, the following pop-up will be shown:
The user can choose to either:
Re-open the data model, thus loading any external changes, and then perform the modification he was about to undertake, or
Ignore any external changes, and go ahead with the modification to the model. In this case, when trying to persist these changes, another pop-up warning will be shown:
The "Force Save" option will effectively overwrite any external changes, while "Re-open" will discard any local changes and reload the model.
"Force Save" overwrites any external changes!
The application user has made changes to the data model. Meanwhile, another user simultaneously modifies the data model from outside the application context.
In this alternative scenario, immediately after the external user commits his changes to the asset repository (or e.g. saves the model with the data modeller in a different session), a warning is issued to the application user:
As with the previous scenario, the user can choose to either:
Re-open the data model, thus losing any modifications that where made through the application, or
Ignore any external changes, and continue working on the model.
One of the following possibilities can now occur:
The user tries to persist the changes he made to the model by clicking the "Save" button in the data modeller top level menu. This leads to the following warning message:
The "Force Save" option will effectively overwrite any external changes, while "Re-open" will discard any local changes and reload the model.
Categories allow assets to be labelled (or tagged) with any number of categories that you define. Assets can belong to any number of categories. In the below diagram, you can see this can in effect create a folder/explorer like view of categories. The names can be anything you want, and are defined by the Workbench administrator (you can also remove/add new categories).
Categories do not have the same role in the current release of the Workbench as they had in prior versions (up to and including 5.5). Projects can no longer be built using a selector to include assets that are labelled with certain Categories. Categories are therefore considered a deprecated feature.
The Categories Editor is available from the Repository menu on the Authoring Perspective.
The below view shows the administration screen for setting up categories (there) are no categories in the system by default. As the categories can be hierarchical you chose the "parent" category that you want to create a sub-category for. From here categories can also be removed (but only if they are not in use by any current versions of assets).
Generally categories are created with meaningful name that match the area of the business the rule applies to (if the rule applies to multiple areas, multiple categories can be attached).
Assets can be assigned Categories using the MetaData tab on the assets' editor.
When you open an asset to view or edit, it will show a list of categories that it currently belongs to If you make a change (remove or add a category) you will need to save the asset - this will create a new item in the version history. Changing the categories of a rule has no effect on its execution.
As we already know, Workbench provides a set of editors to author assets in different formats. According to asset’s format a specialized editor is used.
One additional feature provided by Workbench is the ability to embed it in your own (Web) Applications thru it's standalone mode. So, if you want to edit rules, processes, decision tables, etc... in your own applications without switch to Workbench, you can.
In order to embed Workbench in your application all you'll need is the Workbench application deployed and running in a web/application server and, from within your own web applications, an iframe with proper HTTP query parameters as described in the following table.
Table 9.2. HTTP query parameters for standalone mode
Parameter Name | Explanation | Allow multiple values | Example |
---|---|---|---|
standalone | With just the presence of this parameter workbench will switch to standalone mode. | no | (none) |
path | Path to the asset to be edited. Note that asset should already exists. | no | git://master@uf-playground/todo.md |
perspective | Reference to an existing perspective name. | no | org.guvnor.m2repo.client.perspectives.GuvnorM2RepoPerspective |
header | Defines the name of the header that should be displayed (useful for context menu headers). | yes | ComplementNavArea |
Path and Perspective parameters are mutual exclusive, so can't be used together.
This section of the documentation describes the main features included that contribute to the Asset Management functionality provided in the KIE Workbench and KIE Drools Workbench. All the features described here are entirely optional, but the usage is recommended if you are planning to have multiple projects. All the Asset Management features try to impose good practices on the repository structure that will make the maintainace, versioning and distribution of the projects simple and based on standards. All the Asset Management features are implemented using jBPM Business Processes, which means that the logic can be reused for external applications as well as adapted for domain specific requirements when needed.
Since the creation of the assets management features repositories can be classified into Managed or Unmanaged.
All new assets management features are available for this type of repositories. Additionally a managed repository can be "Single Project" or "Multi Project".
A "Single Project" managed repository will contain just one Project. And a "Multi Project" managed repository can contain multiple Projects. All of them related through the same parent, and they will share the same group and version information.
There are 4 main processes which represent the stages of the Asset Management feature: Configure Repository, Promote Changes, Build and Release.
The Configure Repository process is in charge of the post initialization of the repository. This process will be automatically triggered if the user selects to create a Managed Repository on the New repository wizzard. If they decide to use the governance feature the process will kick in and as soon as the repository is created. A new development and release branches will be created. Notice that the first time that this process is called, the master branch is picked and both branches (dev and release) will be based on it.
By default the asset management feature is not enabled so make sure to select Managed Repository on the New Repository Wizzard. When we work inside a managed repository, the development branch is selected for the users to work on. If multiple dev branches are created, the user will need to pick one.
When some work is done in the developments branch and the users reach a point where the changes needs to be tested before going into production, they will start a new Promote Changes process so a more technical user can decide and review what needs to be promoted. The users belonging to the "kiemgmt" group will see a new Task in their Group Task List which will contain all the files that had being changed. The user needs to select the assets that will be promoting via the UI. The underlying process will be cherry-picking the commits selected by the user to the release branch. The user can specify that a review is needed by a more technical user.
This process can be repeated multiple times if needed before creating the artifacts for the release.
The Build process can be triggered to build our projects from different branches. This allows us to have a more flexible way to build and deploy our projects to different runtimes.
This section describes the common usage flow for the asset management features showing all the screens involved.
The first contact with the Asset Management features starts on the Repository creation.
If the user chooses to create a Managed Respository a new page in the wizzard is enabled:
When a managed repository is created the assets management configuration process is automatically launched in order to create the repository branches, and the corresponding project structure is also created.
Once a repository has been created it can be managed through the Repository Structure Screen.
To open the Repository Structure Screen for a given repository open the Project Authoring Perspective, browse to the given repository and select the "Repository -> Repository Structure" menu option.
The following picture shows an example of a single project managed repository structure.
The following picture shows an example of a multi project managed repository structure.
The following picture shows the screen areas related to managed repositories operations.
The branch selector lets to switch between the different branches created by the Configure Repository Process.
From the repository structure screen it's also possible to create, edit or delete projects from current repository.
The assets management processes can also be launched from the Project Structure Screen.
Filling the parameters bellow a new instance of the Configure Repository can be started. (see Configure Repository Process)
Filling the parameters bellow a new instance of the Promote Changes Process can be started. (see Promote Changes Process)
REST API calls to Knowledge Store allow you to manage the Knowledge Store content and manipulate the static data in the repositories of the Knowledge Store. The calls are asynchronous, that is, they continue their execution after the call was performed as a job. The job ID is returned by every calls to allow after the REST API call was performed to request the job status and verify whether the job finished successfully. Parameters of these calls are provided in the form of JSON entities.
When using Java code to interface with the REST API, the classes used in POST operations
or otherwise returned by various operations can be found in the (org.kie.workbench.services:)kie-wb-common-services
JAR. All
of the classes mentioned below can be found in the org.kie.workbench.common.services.shared.rest
package in that JAR.
Every Knowledge Store REST call returns its job ID after it was sent. This is necessary as the calls are asynchronous and you need to be able to reference the job to check its status as it goes through its lifecycle. During its lifecycle, a job can have the following statuses:
ACCEPTED
: the job was accepted and is being processed
BAD_REQUEST
: the request was not accepted as it contained incorrect content
RESOURCE_NOT_EXIST
: the requested resource (path) does not exist
DUPLICATE_RESOURCE
: the resource already exists
SERVER_ERROR
: an error on the server occurred
SUCCESS
: the job finished successfully
FAIL
: the job failed
DENIED
: the job was denied
GONE
: the job ID could not be found
A job can be GONE in the following cases:
The job was explicitly removed
The job finished and has been deleted from the status cache (the job is removed from status cache after the cache has reached its maximum capacity)
The job never existed
The following job
calls are provided:
Returns the job status
Returns a JobResult
instance
Example 10.1. An example (formatted) response body to the get job call on a repository clone request
"{
"status":"SUCCESS",
"jodId":"1377770574783-27",
"result":"Alias: testInstallAndDeployProject, Scheme: git, Uri: git://testInstallAndDeployProject",
"lastModified":1377770578194,"detailedResult":null
}"
Removes the job: If the job is not yet being processed, this will remove the job from the job queue. However, this will not cancel or stop an ongoing job
Returns a JobResult
instance
Repository calls are calls to the Knowledge Store that allow you to manage its Git repositories and their projects.
The following repositories
calls are provided:
Gets information about the repositories in the Knowledge Store
Returns a Collection<Map<String, String>>
or Collection<RepositoryRequest>
instance,
depending on the JSON serialization library being used. The keys used in the Map<String, String>
instance match
the fields in the RepositoryRequest
class
Example 10.2. An example (formatted) response body to the get repositories call
[
{
"name":"wb-assets",
"description":"generic assets",
"userName":null,
"password":null,
"requestType":null,
"gitURL":"git://bpms-assets"
},
{
"name":"loanProject",
"description":"Loan processes and rules",
"userName":null,
"password":null,
"requestType":null,
"gitURL":"git://loansProject"
}
]
Creates a new empty repository or a new repository cloned from an existing (git) repository
Consumes a RepositoryRequest
instance
Returns a CreateOrCloneRepositoryRequest
instance
Example 10.3. An example (formatted) response body to the create repositories call
{
"name":"new-project-repo",
"description":"repo for my new project",
"userName":null,"password":null,
"requestType":"new",
"gitURL":null
}
Removes the repository from the Knowledge Store
Returns a RemoveRepositoryRequest
instance
Creates a project in the repository
Consumes an Entity
instance
Returns a CreateProjectRequest
instance
Example 10.4. An example (formatted) request body that defines the project to be created
{
"name":"myProject",
"description": "my project"
}
Organizational unit calls are calls to the Knowledge Store that allow you to manage its organizational units, so as to organize the connected Git repositories.
The following organizationalUnits
calls are provided:
Creates an organizational unit in the Knowledge Store
Consumes an OrganizationalUnit
instance
Returns a CreateOrganizationalUnitRequest
instance
Example 10.5. An example (formatted) request body defining a new organizational unit to be created
{
"name":"testgroup",
"description":"",
"owner":"tester",
"repositories":["testGroupRepository"]
}
Adds the repository to the organizational unit
Returns a AddRepositoryToOrganizationalUnitRequest
instance
Removes the repository from the organizational unit
Returns a RemoveRepositoryFromOrganizationalUnitRequest
instance
Maven calls are calls to a Project in the Knowledge Store that allow you compile and deploy the Project resources.
The following maven
calls are provided:
Compiles the project (equivalent to mvn compile
)
Consumes a BuildConfig
instance. While this must be supplied, it's not needed for the operation and may be left blank.
Returns a CompileProjectRequest
instance
Installs the project (equivalent to mvn install
)
Consumes a BuildConfig
instance. While this must be supplied, it's not needed for the operation and may be left blank.
Returns a InstallProjectRequest
instance
Compiles the project runs a test as part of compilation
Consumes a BuildConfig
instance
Returns a TestProjectRequest
instance
Deploys the project (equivalent to mvn deploy
)
Consumes a BuildConfig
instance. While this must be supplied, it's not needed for the operation and may be left blank.
Returns a DeployProjectRequest
instance
The URL templates in the table below are relative the following URL:
http://server:port/business-central/rest
Table 10.1. Knowledge Store REST calls
URL Template | Type | Description |
---|---|---|
/jobs/{jobID} | GET | return the job status |
/jobs/{jobID} | DELETE | remove the job |
/organizationalunits | GET | return a list of organizational units |
/organizationalunits | POST |
create an organizational unit in the Knowledge Store described by the JSON |
/organizationalunits/{organizationalUnitName}/repositories/{repositoryName} | POST | add a repository to an organizational unit |
/organizationalunits/{organizationalUnitName}/repositories/{repositoryName} | DELETE | remove a repository from an organizational unit |
/repositories/ | POST |
add the repository to the organizational unit described by the JSON |
/repositories | GET | return the repositories in the Knowledge Store |
/repositories/{repositoryName} | DELETE | remove the repository from the Knowledge Store |
/repositories/ | POST | create or clone the repository defined by the JSON RepositoryRequest entity |
/repositories/{repositoryName}/projects/ | POST | create the project defined by the JSON entity in the repository |
/repositories/{repositoryName}/projects/{projectName}/maven/compile/ | POST | compile the project |
/repositories/{repositoryName}/projects/{projectName}/maven/install | POST | install the project |
/repositories/{repositoryName}/projects/{projectName}/maven/test/ | POST |
compile the project and run tests as part of compilation |
/repositories/{repositoryName}/projects/{projectName}/maven/deploy/ | POST | deploy the project |
The VFS repositories (usually git repositories) stores all the assets (such as rules, decision tables, process definitions, forms, etc). If that VFS resides on each local server, then it must be kept in sync between all servers of a cluster.
Use Apache Zookeeper and Apache Helix to accomplish this. Zookeeper glues all the parts together. Helix is the cluster management component that registers all cluster details (nodes, resources and the cluster itself). Uberfire (on top of which Workbench is build) uses those 2 components to provide VFS clustering.
To create a VFS cluster:
Download Apache Zookeeper and Apache Helix.
Install both:
Unzip Zookeeper into a directory ($ZOOKEEPER_HOME
).
In $ZOOKEEPER_HOME
, copy zoo_sample.conf
to
zoo.conf
Edit zoo.conf
. Adjust the settings if needed. Usually only these 2 properties are
relevant:
# the directory where the snapshot is stored.
dataDir=/tmp/zookeeper
# the port at which the clients will connect
clientPort=2181
Unzip Helix into a directory ($HELIX_HOME
).
Configure the cluster in Zookeeper:
Go to its bin
directory:
$ cd $ZOOKEEPER_HOME/bin
Start the Zookeeper server:
$ sudo ./zkServer.sh start
If the server fails to start, verify that the dataDir
(as specified in
zoo.conf
) is accessible.
To review Zookeeper's activities, open zookeeper.out
:
$ cat $ZOOKEEPER_HOME/bin/zookeeper.out
Configure the cluster in Helix:
Go to its bin
directory:
$ cd $HELIX_HOME/bin
Create the cluster:
$ ./helix-admin.sh --zkSvr localhost:2181 --addCluster kie-cluster
The zkSvr
value must match the used Zookeeper server. The cluster name
(kie-cluster
) can be changed as needed.
Add nodes to the cluster:
# Node 1
$ ./helix-admin.sh --zkSvr localhost:2181 --addNode kie-cluster nodeOne:12345
# Node 2
$ ./helix-admin.sh --zkSvr localhost:2181 --addNode kie-cluster nodeTwo:12346
...
Usually the number of nodes a in cluster equal the number of application servers in the cluster. The
node names (nodeOne:12345
, ...) can be changed as needed.
nodeOne:12345
is the unique identifier of the node, which will be referenced
later on when configuring application servers. It is not a host and port number, but instead it is used to
uniquely identify the logical node.
Add resources to the cluster:
$ ./helix-admin.sh --zkSvr localhost:2181 --addResource kie-cluster vfs-repo 1 LeaderStandby AUTO_REBALANCE
The resource name (vfs-repo
) can be changed as needed.
Rebalance the cluster to initialize it:
$ ./helix-admin.sh --zkSvr localhost:2181 --rebalance kie-cluster vfs-repo 2
Start the Helix controller to manage the cluster:
$ ./run-helix-controller.sh --zkSvr localhost:2181 --cluster kie-cluster 2>&1 > /tmp/controller.log &
Configure the security domain correctly on the application server. For example on WildFly and JBoss EAP:
Edit the file $JBOSS_HOME/domain/configuration/domain.xml
.
For simplicity sake, presume we use the default domain configuration which uses the profile
full
that defines two server nodes as part of
main-server-group
.
Locate the profile full
and add a new security domain by copying the other security
domain already defined there by default:
<security-domain name="kie-ide" cache-type="default">
<authentication>
<login-module code="Remoting" flag="optional">
<module-option name="password-stacking" value="useFirstPass"/>
</login-module>
<login-module code="RealmDirect" flag="required">
<module-option name="password-stacking" value="useFirstPass"/>
</login-module>
</authentication>
</security-domain>
The security-domain name is a magic value.
Configure the system properties for the cluster on the application server. For example on WildFly and JBoss EAP:
Edit the file $JBOSS_HOME/domain/configuration/host.xml
.
Locate the XML elements server
that belong to the
main-server-group
and add the necessary system property.
For example for nodeOne:
<system-properties>
<property name="jboss.node.name" value="nodeOne" boot-time="false"/>
<property name="org.uberfire.nio.git.dir" value="/tmp/kie/nodeone" boot-time="false"/>
<property name="org.uberfire.metadata.index.dir" value="/tmp/kie/nodeone" boot-time="false"/>
<property name="org.uberfire.cluster.id" value="kie-cluster" boot-time="false"/>
<property name="org.uberfire.cluster.zk" value="localhost:2181" boot-time="false"/>
<property name="org.uberfire.cluster.local.id" value="nodeOne_12345" boot-time="false"/>
<property name="org.uberfire.cluster.vfs.lock" value="vfs-repo" boot-time="false"/>
<!-- If you're running both nodes on the same machine: -->
<property name="org.uberfire.nio.git.daemon.port" value="9418" boot-time="false"/>
</system-properties>
And for nodeTwo:
<system-properties>
<property name="jboss.node.name" value="nodeTwo" boot-time="false"/>
<property name="org.uberfire.nio.git.dir" value="/tmp/kie/nodetwo" boot-time="false"/>
<property name="org.uberfire.metadata.index.dir" value="/tmp/kie/nodetwo" boot-time="false"/>
<property name="org.uberfire.cluster.id" value="kie-cluster" boot-time="false"/>
<property name="org.uberfire.cluster.zk" value="localhost:2181" boot-time="false"/>
<property name="org.uberfire.cluster.local.id" value="nodeTwo_12346" boot-time="false"/>
<property name="org.uberfire.cluster.vfs.lock" value="vfs-repo" boot-time="false"/>
<!-- If you're running both nodes on the same machine: -->
<property name="org.uberfire.nio.git.daemon.port" value="9419" boot-time="false"/>
</system-properties>
Make sure the cluster, node and resource names match those configured in Helix.
In addition to the information above, jBPM clustering requires additional configuration. See this blog post to configure the database etc correctly.
Designer is a graphical web-based BPMN2 editor. It allows users to model and simulate executable BPMN2 processes. The main goal of Designe is to provide intuitive means to both technical and non-technical users to quickly create their executable business processes. This chapter intends to describe all feature Designer offers currently.
Designer targets the following business process modelling scenarios:
View and/or edit existing BPMN2 processes: Designer allows you to open existing BPMN2 processes (for example created using the BPMN2 Eclipse editor or any other tooling that exports BPMN2 XML).
Create fully executable BPMN2 processes: A user can create a new BPMN2 process in the Designer and use the editing capabilities (drag and drop and filling in properties in the properties panel) to fill in the details. This for example allows business users to create complete business processes all inside a a browser. The integration with Drools Guvnor allows for your business processes as wells as other business assets such as business rules, process forms/images, etc. to be stored and versioned inside a content repository.
View and/or edit Human Task forms during process modelling (using the in-line form editor or the Form Modeller).
Simulate your business process models. Busines Process Simulation is based on the BPSIM 1.0 specification.
Designer supports all BPMN2 elements that are also supported by jBPM as well as all jBPM-specific BPMN2 extension elements and attributes.
Designer UI is composed of a number of sections as shown below:
(1) Modelling Canvas - this is your process drawing board. After dropping different shapes onto the canvas, you can move them around, connect them, etc. Clicking on a shape on the canvas allows you to set its properties in the expandable Properties Window (3) (as well as create connecting shapes and morph the shape into other shapes).
(2) Toolbar - the toolbar contains a vast number of functions offered by Designer (described later). These includes operations that can be performed on shapes present on the Canvas. Individual operations are disabled or enabled depending on what is selected. For example, if no shapes are selected, the Cut/Paste/Delete operations are disabled, and become enabled once you select a shape. Hovering over the icons in the Toolbar displays the description text of the operation.
(3) Properties Panel - this expandable section on the right side of Designer allows you to set both process and shape properties. It is divided in four sections, namely "Core properties", and "Extra Properties, "Graphical Settings", and "Simulation Properties" are is expandable. When clicking on a shape in the Canvas, this panel is reloaded to show properties specific to the shape type. If you click on the canvas itself (not on a shape) the section shows your general process properties.
(4) Object Repository Panel - the expandable section on the left side of Designer shows the jBPM BPMN2 (default) shape repository tree. It includes all shapes of the jBPM BPMN2 stencil set which can be used to assemble your processes. If you expand each section sub-group you can see the BPMN2 elements that can be placed onto the Designer Canvas (1) by dragging and dropping the shape onto it.
(5) View Tabs - currently Designer offers functionality tabs for Process Modelling and Simulation. Process Modelling is the default tab. When users run process simulation, its results are presented in the Simulation tab.
(6) Info Tabls - On the bottom Designer shows two different Info tabs. The Business Process tab includes the process modeling while the Metadata tab displays the process metadata such as created by and last modified information.
The Object Repository panel provide means for users to select and drag/drop BPMN2 shapes onto the modelling canvas. Shapes are divided into sections as shown below:
Once a shape is dropped onto the canvas users have a much faster way of continuing modelling without having to go back to the Object Repository panel. This is realized through the shape morphing menu which is presented when a shape on the drawing canvas is clicked on. This menu allows users to either select a connecting shape (next shape) or morph the selected node into another node type. In addition this menu includes means to store the shape name as a dictionary item (explained later), view the specific BPMN2 code of the selected shape, as well as create/edit the task form (in the case of user tasks only).
When connecting shapes Designer applies connection rules that follow the BPMN2 specification. The connection shapes presented in the morphing menu only show shapes that are allowed to be connections. Similarly same rules are applied when dropping a shape from the Object Library from the canvas and trying to connect an existing shape to it. Additional connection rules for boundary events are also available (explained later) and applied when for example moving an intermediate event node onto the edge of a task node.
Users can give names to every shape on the drawing canvas. This is done by double-clicking onto the shape as shown below.
The name of a shape can be pulled from the Process Dictionary. If terms are set up in the dictionary, auto-complete can be used for the node names:
Designer also shows three buttons on top of a clicked shape as shown below.
These include:
(1) Add To Dictionary - this option allows users to add the name of the task to the Process Dictionary (explained in more details later)
(2) Edit Task Form - allows users to create/edit the Task Form. This option is only available for User Tasks
(3) View shape sources - shows the BPMN2 for this particular shape only.
The section should get you started with creating simple business process models by dragging/dropping BPMN2 shapes onto the drawing canvas. Next sections will dive deeper into many other aspects of Designer.
The Designer toolbar contains many different functions which can be used during process modelling.
We will now go through each of the buttons in the Designer Toolbar and give a brief overview of what it does.
(1) Save - allows users to save, copy, rename and delete the business process model. In addition users can turn on auto-save which will automatically save the business process within a defined time interval.
(2) Cut - enabled when a portion of the model is selected.
(3) Copy - enabled when a portion of the model is selected.
(4) Paste - paste the copied portion of the model onto the drawing board.
(5) Delete - enabled when there is a portion of the model is selected and removes it.
(6, 7) Undo/Redo - undo the last performed operation on the drawing canvas.
(8) Local History - local history allows continuous storage of your business process onto your browsers internal storage. Stored version of the business process can persist internet outages or browser crashes so your work will not be lost. This feature is disabled by default and must be enabled by users. Once local history has been enabled users are able to view all previously stored snapshots of their business model, clear local history, configure the snapshot interval, or disable local history. Note that local history will only take a snapshot of your business process on the set storing interval if there were some changes done in the model. If at the end of the snapshot interval Designer detects that there were no changes since the last local history save, no new snapshot will be created.
The Local History results screen allows users to select a stored snapshot of the model and
view its process image, and restore it back onto their drawing board.
(9) Object positioning - allows users to position one or more nodes in the business. Note that at last one shape must be selected first, otherwise these options are disable. Contains options "Bring to Front", "Bring to back", "Bring forward", and "Bring Backward"
(10) Alignment: enabled when a portion of the model is selected. Includes options "Align Bottom", "Align Middle", "Align Top", "Align Left", "Align Center", "Align Right", and "Align Same Size".
(11, 12) Group and Ungroup - allows grouping and ungrouping of selected shapes on the drawing board.
(13, 14) Locking and Unlocking - allows parts of the business model to be locked and unlocked. Locked parts of the model cannot be edited (visual display and properties are both locked). Locked nodes are displayed in a light blue color. This feature fosters collaboration of process modelling by allowing users to set parts of their model as "completed" and preventing any further changes to that portion. Other parts of the model can continue to be edited.
(15, 16) Add/Remove Docker - this allows users to add or remove Dockers, or edge points, to sequence flows in the model. Enables when a sequence flow (connector) is selected. It allows users to create very customized connection points from one shape to another. Users can add and remove as many dockers as they would like on a single sequence flow.
(17) Color Themes - Colors are a big part or process modelling as they help with expressing intent as well as help allowing visually impaired users to better view the model. Designer provides two default color themes out of the box named "jBPM" and "High Contrast". The jBPM theme is the default theme used for all new business processes created. Users can switch color themes and the changes will be applied to all nodes that are currently on the model, as well as any new shapes added. Users have the ability to add new custom color themes by adding their own definitions in the Designer themes.json file. Color theme selection is persisted over browser close or possible crash/internet loss.
(18) Process and Task forms - here users have the ability to generate/edit process and task forms. When no user task is selected the default enabled options are "Edit Process Form" and "Generate all Forms". Generate all forms will apply the current model information such as process variables, data objects, and the user tasks data input/output parameters and associations to generate default executable input forms. Upon editing a process and task form, users have the choice between two form editors, the jBPM Form Modeler, and the Designer in-line meta editor. The Designer meta editor is targeted more to technical users as it is text based with the ability for live preview. When the user selects an user task in the model, the "Edit Task Form" and "Generate Task Form" options are enabled which allow users to edit the particular task form, or choose to apply the same generation logic to create a task form for the selected task only. Users have the ability to extend the default form generation templates in designer to create fully customized templates. Node that in the case of the Designer meta editor for forms, generating forms will overwrite existing forms for the process and user tasks. In the case of Form Modeler form generation, a merging algorithm is applied when generating.
When selecting a task, users have the ability to edit the selected tasks form via the form button shown above the user task node.
When editing forms, users are asked to choose between the Form Modeler and the Designer in-line meta editor. If the user selects Form Modeler the form is shown in a new asset tab separately from Designer. Designer meta editor is in-line and part of the Designer application.
The Designer in-line meta form editor is a powerful text-based editor with a live preview feature as well as auto-completion on process variables and user task data inputs/outputs.
(19) Process Information Sharing - this section includes many functions that help with sharing information of your model. These include:
Share process image - generates a stand-alone HTML image tag which contains a Base64 encoded image source of the current model on the canvas. This link can be shared to team members or other parties and embedded in any HTML content or email that allows HTML content embedding.
Share process PDF - generates a stand-alone HTML object tag which contains a Base64 encoded PDF source of the current model on the canvas. This can similarly be shared and embedded in any HTML content.
Download process PNG - generates a PNG image of the current process on the drawing board which users can download and share.
Download process PDF - generates a PDF of the current process on the drawing board which can be downloaded and shared.
View Process Sources - displays the current process sources in various formats, namely BPMN2, JSON, SVG, and ERDF. Also has the option to download the BPMN2 sources.
(20) Extra tooling - this section allows users to import their existing BPMN2 processes into designer as well as be able to migrate their old jPDL based processes to BPMN2. For BPMN2 or JSON imports users can choose to add the import ontop of the existing model on the drawing board or choose to replace the current one with the import.
(21) Visual Validation - Designer includes over 100 validation checks and this list is growing. It allows users to view validation issues in real-time as they are modelling their business process. Users can enable visual validation, disable it, as well as view all validation issues at once. If Visual Validation is turned on, Designer with set the shape border of shapes that do not pass validation to red color. Users can then click on that particular shape to view the validation issues for that particular shape only. Alternatively "View All Issues" present a combined list of all validation errors currently found. Note that you do not have to periodically save your business process in order for validation to update. It will do so on its own short intervals during modelling. Users can extend the list of validation issues to include their own types of validation on certain elements of their business model.
(22) Process Simulation - Business Process Simulation deals with statistical analysis of process models over time. It's main goals include
Pre-execution and post-execution optimization
Reducing the risk of change in business processes
Predict business process performance
Foster continuous improvements of performance, quality and resource utilization of business processes
Designer includes a powerful simulation engine which is based on jBPM and Drools and a graphical user interface to view and interpret simulation results. In addition users are able to view all process paths included in their current model on the drawing board. Designer Process Simulation is based on the BPSim 1.0 specification. Details of Process Simulation capabilities in Designer are can be found in its Simulation documentation chapter. Here we just give a brief overview of all features it contains.
When selecting Process Paths, the simulation engine find all possible paths in the business model. Users can choose certain found paths and choose to display them. The chosen path is marked with given colors as shown below.
When selecting "Run Simulation", users have to enter in simulation runtime properties. These include the number of instances of this business process to simulate and the interval time and units. This interval is the time in-between consecutive simulation.
Each shape on the drawing board includes Simulation properties (properties panel) where users can set numerous simulation properties for that particular shape. More info on each of these properties can be found in the Simulation chapter of the documentation.
Designer pre-sets some defaults for new processes, which allows business processes to be simulated by default without any modifications of these properties. Note however that the results of the default settings
may not be optimal or targeted for the users particular needs.
Once the simulation runtime has completed, users are shown the simulation results in the "Simulation Results" tab of Designer. The results default to the process results. Users can switch to results for each particular shape in their business process to see more specific detauls. In addition,
the results contain process paths simulation results for each path in the business process.
Designer simulation presents the users with many different chart types. These include:
Process results: Execution times, Activity instances, Total cost
Human Task results: Execution times, Resource Utilization, Resource Cost
All other nodes: Execution times
Process Paths: Path Execution
The below image shows a number of possible chart types users can view after process simulation has completed.
In addition to the chart results, Designer simulation also offers a full timeline display that includes all details of what happened during simulation. This timeline allows users to navigate through each
event that happened during process simulation and select a particular node to display results at that particular point in time.
The simulation timeline can be switched to the Model view. This view displays the process model with the currently selected node in the timeline highlighted. The highlighted node displays the simulation results at that particular point in time of the simulation.
Path execution results shows a chart displaying the chosen path as well as path instance execution details.
(23) Service Repository - this feature allows users to connect to an existing service tasks repository to install service tasks into their list of available shapes. Mode default of this can be found in the Service Repository chapter of the documentation. Users have to enter the URL to the existing service repository and then can install the available service nodes by double-clicking on a particular results row.
(24) Full screen Modev - allows users to place the drawing board of Designer into full-screen mode. This can help with better visualizing larger business processes without having to scroll. Note that this feature is possible only if your browser has full screen mode capabilities. If it does not designer will show a message stating this to the user.
(25) Process Dictionary - Designer Dictionary Editor allows users to create their own dictionary entries or harvest from process documentation or business requirement documents. Process Dictionary entries can be used as auto-completion for shape names. This will be expanded in the future versions to allow mapping of node patters to specific dictionary entries as well. Users can add entries to the dictionary in the Dictioanry Editor or from the selected shapes directly.
(26, 27, 28, 29) Zooming - zooming allows users to zoom in/out of the model, zoom in/out back to the original setting as well as zoom the process model on the drawing board to fit the currently dimensions of the drawing board.
This chapter intends to describe in a simple ways all the steps required to create a process with human tasks, generate and modify the forms for these tasks and execute them. It will provide initial guidance to perform all initial steps, but it will not provide a full description of all available features.
Given that forms are going to be used in tasks, it's possible to generate forms automatically from process variables and task definitions. These forms can be later be modified by using the form editor. In runtime, forms will receive data from process variables, display it to the user and capture his input, and then finally updating process variables again with the new values.
The following example will show all the steps to follow to create a form for the 'Create order' task in the process below.
This form must look like the following in execution:
To hold values capture by forms, process variables can be created. These variables can be of a simple type like 'String' or a complex type. These complex types can be defined by using the Data Modeler tool, or be just regular POJOs (Plain Java Objects) created with any Java IDE.
In this example, we define a variable 'po' of type 'org.jbpm.examples.purchases.PurchaseOrder', defined with the Data Modeler tool.
This variable is declared in the 'variables definition' property for the process.
After that, we must configure which variables are set as input parameters to the task, which ones will receive the response back from the form and establish the mappings. This is done by setting the 'DataInputSet', 'DataOutputSet' and 'Assignments' properties for any human task. See screenshots below for details.
The Process Designer module provides some functionality to generate the forms automatically from task and variable definitions, as well as easily open the right form from the modeler.
This is done with the following menu option.
You can also click on the icon on top of task to open the form directly.
Forms are related to tasks by following a naming convention. If a form with a name formName-taskform is defined in the same package as the process, then this form is used by the human task engine to display and capture information from user.
Also, if a form named ProcessId-task form is created, it will be used as the initial form when starting this process.
For example, for our process the following forms would be generated.
Once the forms have been generated, you can start editing them. There are several artifacts that are generated in the previous process, but also can be created manually.
When the form has been generated automatically, this tab contain the process variables as data origins. This allow bind form fields with them, this relation it’s linked creating data bindings.
A data binding define how task inputs will be mapped to form variables, and when the form is validated and submitted, how the values will update the task outputs.
For example, for this process, the following bindings are generated. Notice that the identifiers are automatically generated. You can have as many data origins as required, and can use a different colour to identify it.
In automatic form generation, a data origin is created for each process variable. The generated form have a field for each data origin bindable item (view FieldTypes) and this automatic fields have the binding defined too.
When these fields are displayed in editor the color of the data origin is shown over the field to make easy view if the field is correctly bound and the data origin implied.
We can change the way the form is displayed to the user in the task list. Next, we will show different levels of customization that will allow change it
The fields may be placed in different regions of the form. To move a field the user can access the contextual menu of the field and select 'Move field'.
This will display the different regions of the form where you can place it.
A field can be moved to the first or the last region with the contextual icons for that purpose.
You can add fields to forms either by its origin or by selecting one type of form field.
Let's see what has been created automatically for this purchase order form.
Add fields by origin: this tab allows you to add fields to the form based on the data origins defined. These fields will have the correct configuration on the "Input binding expression" and "Output binding expression" properties, so when the form is submitted, the fields values will be stored in the corresponding Data Origin.
Add fields by type: this tab allows you to freely add fields to the form from the Field Types palette on the Form Modeler. These fields won't be storing their values on any Data Origin until they have a correct configuration on the "Input binding expression" and "Output binding expression" properties.
To see a complete list of the available field types go to
Field types section.
Notice the data model 'po' of type 'org.jbpm.examples.purchases.PurchaseOrder' is composed of three properties.
Simple: property of type text (description). We will adjust the view settings.
Complex: property of type object (header).
Complex: property of type array of objects (lines)
Now all these properties had to be configured.
Each field can be configured to enhance performance in the form. There are a group of common properties, that we call ‘Generic field properties’ and a group of specific properties that depends on the field type.
There are a group of properties that are common to all field types. We will detail them below:
Table 13.1.
Field type | Can change the field type to other compatible field types |
Field Name | Will be used as identifier in formulas calculation |
Label | The text that will be shown as field label |
Error message | When something goes wrong with the field, like validations,.. this message will be displayed |
Label ccs class | Allows enter a class css to apply in label visualization |
Label css style | to enter directly the style to apply to the label. |
Help text | The text introduced is displayed as alt attribute to help to the user in data introduction |
Style class | Allows enter a class css to apply in field visualization |
Css style | to enter directly the style to apply to the label. |
Read Only | When this check is on, the field will be used only for read |
Input binding expression | This expression defines the link between field and process task input variable. It will be used in runtime to set the field value with that task input variable data. |
Output binding expression | This expression defines the link between field and process task output variable. It will be used in runtime to set that task output variable. |
Let's explain the specific properties of each field type:
Short Text (java.lang.String)
Compatible field type: Long text, E-mail, Rich text
Specific properties
Size: input text length.
MaxLength: Maximum number of characters allowed.
Required: Indicates if it’s mandatory to fill this field.
Show HTML: indicates whether the contents of the field is interpreted as HTML in show mode.
Formula. to enter expressions that will be evaluated to set the field value. These expressions are described in Formula & expression section .
Range value. A range formula allows you to let you specify the values that the user can select from an specific field. These expressions are described in Formula & expression section
Pattern. Allow introduce an expression to specify the validation of the field. In case that the field value introduced hasn’t match the expression, and error is thrown and the error message has to be shown.
Default Value formula. Expression to set the field default value.
Long Text (java.lang.String)
Compatible field type: Long text, E-mail, Rich text
Specific properties
Size: input text length.
MaxLength: Maximum number of characters allowed.
Required: Indicates if it’s mandatory to fill this field.
Height: The number or rows to show at text area.
Formula. to enter expressions that will be evaluated to set the field value. These expressions are described in Formula & expression section .
Range value. A range formula allows you to let you specify the values that the user can select from an specific field. These expressions are described in Formula & expression section
Pattern. Allow introduce an expression to specify the validation of the field. In case that the field value introduced hasn’t match the expression, and error is thrown and the error message has to be shown.
Default Value formula. Expression to set the field default value.
Float (java.lang.Float)
Specific properties
Size: input text length.
MaxLength: Maximum number of characters allowed.
Required: Indicates if it’s mandatory to fill this field.
Formula. to enter expressions that will be evaluated to set the field value. These expressions are described in Formula & expression section .
Range value. A range formula allows you to let you specify the values that the user can select from an specific field. These expressions are described in Formula & expression section
Pattern. Allow introduce an expression to specify how the Float value has to be displayed. The pattern allowed is show in section pattern in http://docs.oracle.com/javase/6/docs/api/java/text/DecimalFormat.html
Default Value formula. Expression to set the field default value.
Decimal (java.lang.Double)
Specific properties
Size: input text length.
MaxLength: Maximum number of characters allowed.
Required: Indicates if it’s mandatory to fill this field.
Formula. Used to enter expressions that will be evaluated to set the field value. These expressions are described in Formula & expression section.
Range value. A range formula allows you to let you specify the values that the user can select from an specific field. These expressions are described in Formula & expression section .
Pattern. Allow introduce an expression to specify how the Double value has to be displayed. The pattern allowed is show in section pattern in http://docs.oracle.com/javase/6/docs/api/java/text/DecimalFormat.html
Default Value formula. Expression to set the field default value.
BigDecimal (java.math.BigDecimal)
Specific properties
Size: input text length.
MaxLength: Maximum number of characters allowed.
Required: Indicates if it’s mandatory to fill this field.
Formula. Used to enter expressions that will be evaluated to set the field value. These expressions are described in Formula & expression section.
Range value. A range formula allows you to let you specify the values that the user can select from an specific field. These expressions are described in Formula & expression section .
Pattern. Allow introduce an expression to specify how the BigDecimal value has to be displayed. The pattern allowed is show in section pattern in http://docs.oracle.com/javase/6/docs/api/java/text/DecimalFormat.html
Default Value formula. Expression to set the field default value.
Big integer (java.math.BigInteger)
Specific properties
Size: input text length.
MaxLength: Maximum number of characters allowed.
Required: Indicates if it’s mandatory to fill this field.
Formula. Used to enter expressions that will be evaluated to set the field value. These expressions are described in Formula & expression section.
Range value. A range formula allows you to let you specify the values that the user can select from an specific field. These expressions are described in Formula & expression section .
Default Value formula. Expression to set the field default value.
Short (java.lang.Short)
Specific properties
Size: input text length.
MaxLength: Maximum number of characters allowed.
Required: Indicates if it’s mandatory to fill this field.
Formula. Used to enter expressions that will be evaluated to set the field value. These expressions are described in Formula & expression section.
Range value. A range formula allows you to let you specify the values that the user can select from an specific field. These expressions are described in Formula & expression section .
Default Value formula. Expression to set the field default value.
Integer (java.lang.Integer)
Specific properties
Size: input text length.
MaxLength: Maximum number of characters allowed.
Required: Indicates if it’s mandatory to fill this field.
Formula. Used to enter expressions that will be evaluated to set the field value. These expressions are described in Formula & expression section.
Range value. A range formula allows you to let you specify the values that the user can select from an specific field. These expressions are described in Formula & expression section .
Default Value formula. Expression to set the field default value.
Long Integer (java.lang.Long)
Specific properties
Size: input text length.
MaxLength: Maximum number of characters allowed.
Required: Indicates if it’s mandatory to fill this field.
Formula. Used to enter expressions that will be evaluated to set the field value. These expressions are described in Formula & expression section.
Range value. A range formula allows you to let you specify the values that the user can select from an specific field. These expressions are described in Formula & expression section .
Default Value formula. Expression to set the field default value.
E-mail (java.lang.String)
Compatible field type: Short text, Long text, Rich text
Specific properties
Size: input text length.
MaxLength: Maximum number of characters allowed.
Required: Indicates if it’s mandatory to fill this field.
Default Value formula. Expression to set the field default value.
Checkbox (java.lang.Boolean)
Specific properties
Required: Indicates if it’s mandatory to fill this field.
Default Value formula. Expression to set the field default value.
Rich text: (java.lang.String)
Compatible field type: Short text, Long text, E-mail
Specific properties
Size: input text length.
MaxLength: Maximum number of characters allowed.
Required: Indicates if it’s mandatory to fill this field.
Height: The number or rows to show at text area.
Default Value formula. Expression to set the field default value.
Timestamp (java.util.Date)
Compatible field type: Short date
Specific properties
Size: input text length.
Required: Indicates if it’s mandatory to fill this field.
Formula. to enter expressions that will be evaluated to set the field value. These expressions are described in Formula & expression section .
Default Value formula. Expression to set the field default value.
Short date (java.util.Date)
Compatible field type: Timestamp
Specific properties
Size: input text length.
Required: Indicates if it’s mandatory to fill this field.
Formula. to enter expressions that will be evaluated to set the field value. These expressions are described in Formula & expression section .
Default Value formula. Expression to set the field default value.
Document (org.jbpm.document.Document)
Specific properties
Required: Indicates if it’s mandatory to fill this field.
Simple subform (Object)
For more details see sectionSimple Object (Subform field Type).
Specific properties
Default form. Show the list of available forms to select what one will be displayed to show the object.
Multiple subform (Multiple Object)
For more details see sectionArrays of objects.( Multiple subform field Type).
Specific properties
Default form. Show the list of available forms to select what one will be displayed to show the object when no other form is configured with an specific purpose.
Preview form. If a form is specified, it will be used to show the item details
Table form. If a form is specified, it will be used to show the table columns when the item list is showed
New item text. Text to show at New Item button
Add item text. Text to show at Add Item button
Cancel text. Text to show at Cancel button
Allow remove Items. If this check is selected, the form allow remove items in table view.
Allow edit items. If this check is selected, the form allow edit items in table view.
Allow preview items. If this check is selected, the form allow preview items in table view.
Hide creation button. Check to not show the creation button
Expanded. If is checked, when a new item is being added, the field display the table with the existing items and the creation form at same time
Allow data enter in table mode. Allow modify data in table view directly.
There are two types of complex fields: fields representing an object, and fields representing an object array.
Once the field is added to the form, either automatically or manually, it must be configured so that the form had to know how to display the objects that will contain in execution time.
Next we describe how can be the configuration process:
The first thing to do is define how the contained object will be displayed. This is done creating a form that represents the object.
In case of the object array, you can define a form to show in preview(edition), or to show when table is shown
Once the form to represent the object, the parent form has to be configured to use them in the parent Subform or Multiple subform.
Below we will describe how the setup would be:
One possible way of setting the value for an object property is by using an existing form, and embedding this form into the parent. This is called subform.
In this example, the Purchase Order header data is held in an object. Therefore, we must create a form to enter all the purchase order header data and link it from the parent task form.
We will follow the steps:
Create new form.
Create new data origin, selecting the type of the purchase order header.
Add fields by origin. All the properties are shown, and can be added to the form, either one by one or all of them at once.
All the properties have been added to the form, and now we can edit each of them and move them around.
Configure the fields and customize form.
Once the form has been saved, open the initial parent form and set the field property 'Default form'.
This will insert the subform inside the parent form, and will be shown as below:
Now, we want to be able to create, edit and remove purchase order lines, by displaying a table with all the values and being able to capture information through a form. This will be done as follows:
Create a form that will hold and capture the information for each line's value (description, amount, unitPrice and total), following the same steps as above. This will be done as follows:
Create new form.
Create new data origin.
Add fields by origin. All the properties are shown, and can be added to the form, either one by one or all of them at once.
Customize form. Change display options to improve the form visualization
Configure the fields. After creating the basic form structure, we can use a formula to calculate automatically the total field. This formulas and expressions are described in Formula & expression section.
Finally, we save the lines form and go back to the parent form and configure all the lines properties.
Form Modeler provides a Formula Engine that you can use to automatically calculate field values. That Formula engine supports Java and XPATH expressions to access the form fields values. Let’s see some examples.
Setting a Default value formula
Imagine that you have a form that contains a date field “Creation date” that has to be set by default with the current date. To do that you should edit the field properties and set a Default value formula like:
=new java.util.Date();
After setting a Default formula value on a field properties, when the form is rendered by the first time the field will have the specified value.
As you can see, you can use a default formula any expression that return a value supported for the field.
Setting a Formula
The formula engine allows you to calculate formulas that depend on other Field values using XPATH expressions to refer to fields values like {a_field_nane}, standard operators (+, -, *, /, %...) to operate with them or calls to Java Functions for more complex operations.
To start let’s see how you can create a formula to calculate the line_total of a Purchase Order Line. Look at the image below and look at the formula on the line_total properties.
With this expression:
={line_unitPrice}*{line_amount}
we’re forcing the Total of the line value to be the result of the the Unit price multiplied by the Amount, so when the user fills the Amount and Unit Price fields automatically the Total Amount field value is going to be calculated and filled with the operation result:
Is possible to create formulas to operate with values stored in subforms using expressions like
={a_field/a_subform_field}
Look at the next image to see how it works:
This form has a subform field called po_header that is showing a form with the fields header_creationDate, header_customer and header_project. We want the Description field on our parent form to show some information from the header. Look at the Description field properties formula.
="Customer: " + {po_header/header_customer} + " Project: " + {po_header/header_project}
This formula returns a text when the fields header_customer and header_projects are filled on the child form, so from now the parent form will be filled like this:
Ok, you’ve seen how to create formulas that access to a subform fields values, now we are going to see how to work with values stored in Multiple Subforms. Imagine that we have a Purchase Order Line form that contains a multiple subform of Purchase Order Lines, and we want to calculate the total amount of the lines created. Look at the image below and how the TOTAL field is configured.
On the formula expression: ={sum(po_lines/line_total)} we are using the XPATH function sum() that is going to summarize the totals of all the lines. So after creating some Lines the form will look like this:
Note that the line_total child field corresponds with the field line_total field on then form selected as a Default Form selected on the Lines field configuration.
On this sample we are using the sum() XPATH function to calculate the total of the Purchase Order, but XPATH provides a lot of possibilities to select values from a set of children and also a lot functions to summarize values (sum, count, avg...). For more information about XPATH you can take a look at http://www.w3schools.com/xpath/
Setting a Range Formula
A range formula allows you to let you specify the values that the user can select from an specific field, showing it like a select box. It can be used on all simple types except Dates and Checkboxes.
To see how it works look the next image and look at the Review Status field configuration.
As you can see that field is being shown as a select box and it has a range formula that specifies the values like this:
{approve,Approve order;reject,Reject order;modifications,Request Modifications}
This expression is defining 3 duos of value/”text to show” separated with the character ‘,’ and each of this duos is separated from each other other with the ‘;’ character. So due this formula the resulting select box will show:
Table 13.2.
Value stored in input | Text shown on Select Box |
---|---|
approve | Approve order |
reject | Reject order |
modifications | Request Modifications |
When you need an extra customization level and have more control over the HTML that is displayed. The form modeler provides the ability to edit the HTML directly.
To use this functionality, the user have to specify that in the ‘Form properties’ tab, 'Custom form layout' option and save.
Now the form is displayed with the custom HTML. To access this HTML editing, we click on the icon 'Edit'
The HTML editor is displayed; the HTML code will define how the form has to be shown. In this editor the user can directly create the HTML i locate the fields and labels with the syntax described below:
$field{fieldName} for field identified fieldName
$label{fieldName} for field identified fieldName label
These expressions will be replaced by the field or label rendering when the form will be shown.
Form modeler also provides two ways to help in the form HTML creation.
'Insert form elements'
Two select: one for the fields and another for the labels. Clicking on that, the field or label text is added to HTML. These selects only show the form fields haven’t been added yet.
'Generate template based on'
This functionality generates the HTML using all fields (default, alignment fields or Not aligned) depending on the selected value and overwrite the HTML.
There are three types of field types that you can use to model your form:
Simple types
These field types are used to represent simple properties like texts, numeric, dates, etc. The supported Field types are:
Table 13.3. Field types
Name | Description | Java Type | Default on generated forms |
---|---|---|---|
Short Text | Simple input to enter short texts. | java.lang.String | yes |
Long Text | Text area to enter long text. | java.lang.String | no |
Rich Text | HTMLEditor to enter formatted texts . | java.lang.String | no |
Simple input to enter short text with email pattern. | java.lang.String | no | |
Float | Input to enter short decimals. | java.lang.Float | yes |
Decimal | Input to enter number with decimals. | java.lang.Double | yes |
BigDecimal | Input to enter big decimal numbers. | java.math.BigDecimal | yes |
BigInteger | Input to enter big integers. | java.math.BigInteger | yes |
Short | Input to enter short integers | java.lang.Short | yes |
Integer | Input to enter integers. | java.lang.Integer | yes |
Long Integer | Input to enter long integers | java.lang.Long | yes |
Checkbox | Checkbox to enter true/false values | java.lang.Boolean | yes |
Timestamp | Input to enter date & time values | java.util.Date | yes |
Short Date | Input to enter date values. | java.util.Date | no |
Document | File input to upload documents. | org.jbpm.document.Document | yes |
Complex types
These field types are made to deal with properties that are Java Objects instead of basic types. These field types need extra forms to be created in order to show and write values onto the specified Java Object/s
Table 13.4. Complex types
Name | Description | Java Type | Default on generated forms |
---|---|---|---|
Simple subform | Renders the a form, it is used to deal with 1:1 relationships. | java.lang.Object | yes |
Multiple subform | This field type is used to deal with 1:N relationships. It allows to create, edit and delete a set child Objects.Text area to enter long text. | java.util.List | yes |
Decorators
Decorators are a type of field types that don’t store data in the Object shown on the form. They can be used with aesthetic purpose
Table 13.5. Decorators
Name | Description |
---|---|
HTML label | Allows the user to create HTML code that will be rendered in the form |
Separator | Renders an HTML separator |
Is possible to extend the platform to add Custom Field Types that make a specific field (of any type) on the form to look and behave totally different than the standard platform fields. On this section we will take a look on how to create them and how to configure them.
Basically a Custom Field Type is a Java class that implements the org.jbpm.formModeler.core.fieldTypes.CustomFieldType interface and is packaged inside inside a JAR file that is placed on the Application Server classpath or inside the application WAR.
Lets take a look atorg.jbpm.formModeler.core.fieldTypes.CustomFieldType:
package org.jbpm.formModeler.core.fieldTypes;
import java.util.Locale;
import java.util.Map;
/**
* Definition interface for custom fields
*/
public interface CustomFieldType {
/**
* This method returns a text definition for the custom type. This text will be shown
* on the UI to identify the CustomFieldType
* @param locale The current user locale
* @return A String that describes the field type on the specified locale.
*/
public String getDescription(Locale locale);
/**
* This method returns a string that contains the HTML code that will be used to show
* the field value on screen
* @param value The current field value
* @param fieldName The field name
* @param namespace The unique id for the rendered form, it should be used to generate
* identifiers inside the HTML code.
* @param required Determines if the field is required or not
* @param readonly Determines if the field must be shown on read only mode
* @param params A list of configuration params that can be set on the field
* configuration screen
* @return The HTML that will be used to show the field value
*/
public String getShowHTML(Object value, String fieldName, String namespace,
boolean required, boolean readonly, String... params);
/**
* This method returns a String that contains the HTML code that will show the input
* view of the field. That will be used to set the field value.
* @param value The current field value
* @param fieldName The field name
* @param namespace The unique id for the rendered form, it should be used to
* generate identifiers inside the HTML code.
* @param required Determines if the field is required or not
* @param readonly Determines if the field must be shown on read only mode
* @param params A list of configuration params that can be set on the field
* configuration screen
* @return The HTML code that will be used to show the input view of the field.
*/
public String getInputHTML(Object value, String fieldName, String namespace,
boolean required, boolean readonly, String... params);
/**
* This method is used to obtain the field value from the submitted values.
* @param requestParameters A Map containing the request parameters for the
* submitted form
* @param requestFiles A Map containing the java.io.Files uploaded on the request
* @param fieldName The field name
* @param namespace The unique id for the rendered form, it should be used to generate
* identifiers inside the HTML code.
* @param previousValue The previous value of the current field
* @param required Determines if the field is required or not
* @param readonly Determines if the field must be shown on read only mode
* @param params A list of configuration params that can be set on the field
* configuration screen
* @return The value of the field based on the submitted form values.
*/
public Object getValue(Map requestParameters, Map requestFiles, String fieldName,
String namespace, Object previousValue, boolean required, boolean readonly,
String... params);
}
As you can see this Interface defines the methods that determines how the field has to be shown on the screen for when the form is shown on insert(getInputHTML(...)) or readonly (getShowHTML(...)) mode. It also provides the method (getValue(...)) that reads the needed parameters from the request and to obtain the correct field value. Te returned value type must match with the type of the field added on the form.
Now let's see how to use and configure and use a Custom Field type. Following the example on the previous chapter, we have created a File Input type and we have it already installed on our application. So now we are going to create a new form and add a Short Text property and turn it into a File Input and edit the field properties changing the Field Type from Short text toCustom field.
After changing the field type a new set of properties will appear:
Table 13.6. Custom field properties
Property | Description |
---|---|
Field type | Can change the field type to other compatible field types |
Field Name | Will be used as identifier in formulas calculation |
Label | The text that will be shown as field label |
Custom field | A list containing all the Custom Field Types available on the platform |
First parameter | A String parameter that can be user to pass custom configuration needed by the Custom Field Type implementation |
Second parameter | A String parameter that can be user to pass custom configuration needed by the Custom Field Type implementation |
Third parameter | A String parameter that can be user to pass custom configuration needed by the Custom Field Type implementation |
Fourth parameter | A String parameter that can be user to pass custom configuration needed by the Custom Field Type implementation |
Fifth parameter | A String parameter that can be user to pass custom configuration needed by the Custom Field Type implementation |
Required | Indicates if it’s mandatory to fill this field. |
Read Only | When this check is on, the field will be used only for read |
Input binding expression | This expression defines the link between field and process task input variable. It will be used in runtime to set the field value with that task input variable data. |
Output binding expression | This expression defines the link between field and process task output variable. It will be used in runtime to set that task output variable. |
So opening the Custom field select box we'll be able to select the File Input from the available custom types:
After selecting the File Input type on the list and saving the field properties the form will look like:
If we build a simple process and configure a Short text to be shown as the sampleFile Input, if we build the project on runtime the field will behave uploading the chosen files to the server and allowing the user to download it like this:
If we take a look at what's the process variable value, we'll see that is storing a String with the file path stored in server.
On this section we are going to describe step by step how to attach documents to your process variables from your forms and how you can configure to store the uploaded documents anywhere (File System, Data Base, Alfresco...) using the Pluggable Variable Persistence.
To make your process manage documents you have to define your process variables as usual using
the Custom Type org.jbpm.document.Document
. Each variable defined as Document
will be shown on the form as a FILE input.
When the process forms are genereated and a org.jbpm.document.Document
variable si found
a File input will be placed on the form.
Each time a document is uploaded using a form the Form Engine will generate an instance of
org.jbpm.document.Document
to be stored on the process variable.
In order to store the document using the Pluggable Variable Persistence you'll have to define your Marshalling Strategy to manage the uploaded Documents. To start create a Maven project with your favourite IDE and add the following dependencies:
<dependency>
<groupId>org.kie</groupId>
<artifactId>kie-api</artifactId>
<version>{version}</version>
</dependency>
<dependency>
<groupId>org.jbpm</groupId>
<artifactId>jbpm-document</artifactId>
<version>{version}</version>
</dependency>
Once you did that is time to create your Marshalling Strategy, to do so you just have to create a class implementing:
package org.kie.api.marshalling;
public interface ObjectMarshallingStrategy {
public boolean accept(Object object);
public void write(ObjectOutputStream os, Object object)
throws IOException;
public Object read(ObjectInputStream os)
throws IOException, ClassNotFoundException;
public byte[] marshal( Context context, ObjectOutputStream os, Object object )
throws IOException;
public Object unmarshal( Context context, ObjectInputStream is, byte[] object,
ClassLoader classloader ) throws IOException, ClassNotFoundException;
public Context createContext();
The methods to implement are:
public boolean accept(Object object): Determines if the given object can be marshalled by the strategy
byte[] marshal( Context context, ObjectOutputStream os, Object object ): Marshals the given object and returns the marshalled object as byte[]
Object unmarshal( Context context, ObjectInputStream is, byte[] object, ClassLoader classloader ): Reads the object received as byte[] and returns the unmarshalled object
void write(ObjectOutputStream os, Object object): Implement for backguards compatibility, it should do the same functionallity than byte[] marshal( Context context, ObjectOutputStream os, Object object )
Object read(ObjectInputStream os): Implement for backguards compatibility, it should do the same functionallity than Object unmarshal( Context context, ObjectInputStream is, byte[] object, ClassLoader classloader )
You can see how the default DocumentMarshallingStrategy is implemented looking at this link.
After creating your Marshalling Strategy and add it to your server classpath the only thing
remaining is to configure your project deployment descriptor add it to the marshalling strategies list.
To do it you just have to open the Kie-Workbench on your browser, open your project on the Authoring view and
edit the kie-deployment-descriptor.xml file located on <yourproject>/src/main/resources/META-INF
and add your Marshalling Strategy to the <marshalling-strategies>
list
like this:
<?xml version="1.0" encoding="UTF-8" standalone="yes"?>
<deployment-descriptor
xsi:schemaLocation="http://www.jboss.org/jbpm deployment-descriptor.xsd"
xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance">
<persistence-unit>org.jbpm.domain</persistence-unit>
<audit-persistence-unit>org.jbpm.domain</audit-persistence-unit>
<audit-mode>JPA</audit-mode>
<persistence-mode>JPA</persistence-mode>
<runtime-strategy>SINGLETON</runtime-strategy>
<marshalling-strategies>
<marshalling-strategy>
<resolver>reflection</resolver>
<identifier>
org.jbpm.document.marshalling.DocumentMarshallingStrategy
</identifier>
</marshalling-strategy>
</marshalling-strategies>
<event-listeners/>
<task-event-listeners/>
<globals/>
<work-item-handlers/>
<environment-entries/>
<configurations/>
<required-roles/>
</deployment-descriptor>
Since this is done you're able to build your project and upload your documents on your process.
On this example we are configuring the default DocumentMarshallingStrategy
, please use it for test and
demo purposes.
This chapter intends to describe how you can embed process forms and interact with them on another webapp including the new Javascript API provided by the platform.
You can find the library inside the kie-wb-*.war
on the js file located on
js/jbpm-forms-rest-integration.js
.
This JavaScript API tries to be a simple mechanism to use forms on remote applications allowing to load the forms from different KIE Workbench instances, submit them, launch processes/tasks and execute callback functions when the actions are done.
The basic methods are:
hostURL: the URL of the KIE Workbench instance that holds the deployments.
deploymentId: the deployment identifier that contains the process to run.
processId: the identifier of the process to run.
divId: the identifier of the div that has to contain the form.
onsuccessCallback (optional): a javascript function that will be executed if the form is going to be rendered. This function will receive the server response as a parameter
onerrorCallback (optional): a javascript function that will be executed if any error occurs and it is impossible to render the form. This function will receive the server response as a parameter
divId: the identifier of the div that to contains the form.
onsuccessCallback (optional): a javascript function that will be executed after the process is started. This function will receive the server response as a parameter
onerrorCallback (optional): a javascript function that will be executed if any error occurs and it is impossible to start the process. This function will receive the server response as a parameter
hostURL: the URL of the KIE Workbench instance that holds the deployments.
taskId: the identifier of the task to show the form.
divId: the identifier of the div that has to contain the form.
onsuccessCallback (optional): a javascript function that will be executed if the form is going to be rendered. This function will receive the server response as a parameter
onerrorCallback (optional): a javascript function that will be executed if any error occurs and it is impossible to render the form. This function will receive the server response as a parameter
divId: the identifier of the div that contains the form.
onsuccessCallback (optional): a javascript function that will be executed after the task is claimed. This function will receive the server response as a parameter
onerrorCallback (optional): a javascript function that will be executed if any error occurs and it is impossible to claim the task. This function will receive the server response as a parameter
divId: the identifier of the div that contains the form.
onsuccessCallback (optional): a javascript function that will be executed after the task is started. This function will receive the server response as a parameter
onerrorCallback (optional): a javascript function that will be executed if any error occurs and it is impossible to start the task. This function will receive the server response as a parameter
divId: the identifier of the div that contains the form.
onsuccessCallback (optional): a javascript function that will be executed after the task is released. This function will receive the server response as a parameter
onerrorCallback (optional): a javascript function that will be executed if any error occurs and it is impossible to release the task. This function will receive the server response as a parameter
divId: the identifier of the div that contains the form.
onsuccessCallback (optional): a javascript function that will be executed after the task is saved. This function will receive the server response as a parameter
onerrorCallback (optional): a javascript function that will be executed if any error occurs and it is impossible to save the task. This function will receive the server response as a parameter
divId: the identifier of the div that contains the form.
onsuccessCallback (optional): a javascript function that will be executed after the task is completed. This function will receive the server response as a parameter
onerrorCallback (optional): a javascript function that will be executed if any error occurs and it is impossible to complete the task. This function will receive the server response as a parameter
divId: the identifier of the div that contains the form.
Now let's see an example how you can use the library to load the HR process form and start a new process instance. We are going to define a HTML page that will contain very simple components:
"Show Process Form" BUTTON: The button that is going to make a call to a showProcessForm() function to embedd the process form.
"myform" DIV: the div that will containt the form
"Start Process" BUTTON: the button that will call the startProcess() function that submits the form and start a new process instance. At the begining it will be hidden and only will be displayed when the form is going to be rendered.
First we are look at the HTML code:
<head>
<script src="js/jbpm-forms-rest-integration.js"></script>
<script>
var formsAPI = new jBPMFormsAPI();
</script>
</head>
<body>
<input type="button" id="showformButton"
value="Show Process Form" onclick="showProcessForm()">
<p/>
<div id="myform" style="border: solid black 1px; width: 500px; height: 200px;">
</div>
<p/>
<input type="button" id="startprocessButton"
style="display: none;" value="Start Process" onclick="startProcess()">
</body>
Notice that in first place we have added the js library and created an instance of the jBPMFormsAPI object that will manage the form rendering.
Now let's see how the showProcessForm() function looks like:
function showProcessForm() {
var onsuccessCallback = function(response) {
document.getElementById("showformButton").style.display = "none";
document.getElementById("startprocessButton").style.display = "block";
}
var onerrorCallback = function(errorMessage) {
alert("Unable to load the form, something wrong happened: " + errorMessage);
formsAPI.clearContainer("myform");
}
formsAPI.showStartProcessForm("http://localhost:8080/kie-wb/", "org.jbpm:HR:1.0", "hiring", "myform", onsuccessCallback, onerrorCallback);
}
As you can see, first we are defining the callback functions:
Once we defined the callback function we proceed to call the formsAPI.showStartProcessForm(...) that is going make the REST call and embedd the form inside the specified div. Notice that we are providing a bunch of information in order to load the form, the URL where the KIE-Workbench is running (in this example "http://localhost:8080/kie-wb/"), the deployment where the process is located ("org.jbpm:HR:1.0"), the process id ("hiring"), the DIV id that is going to contain the form ("myform") and the callback functions (onsuccessCallback and onerrorCallback).
Now let's take a look at the startProcess() that is the one that is going to submit the form and start the process:
function startProcess() {
var onsuccessCallback = function(response) {
document.getElementById("showformButton").style.display = "block";
document.getElementById("startprocessButton").style.display = "none";
formsAPI.clearContainer("myform");
alert(response);
}
var onerrorCallback = function(response) {
document.getElementById("showformButton").style.display = "block";
document.getElementById("startprocessButton").style.display = "none";
formsAPI.clearContainer("myform");
alert("Unable to start the process, something wrong happened: " + response);
}
formsAPI.startProcess("myform", onsuccessCallback, onerrorCallback);
}
As showProcessForm(), first we are defining the callback functions. Both are doing basically the same:
Show the "Show Process Form" button and hide the "Start Process" button to allow start another process instance.
Clear the "myform" DIV status
Show an alert with the response notifying that the process has started well or if an error occured
Once that is done we just do the call to the formsAPI.startProcess(...) that will send a message to the component that renders the form inside the "myform" DIV and will exectue the callback functions when the action is done. Notice that we don't need the provide any other information than the DIV that contains the form and optionally the callback functions.
With a simple code like this you'll be able to run process/task forms that are located on different Kie-Workbench instances from any other application.
In version 5.x processes were stored in so called packages produced by Guvnor and next downloaded by jbpm console for execution using KnowledgeAgent. Alternatively one could drop their process files (bpmn2 files) into a predefined directory that was scanned on the jbpm console start. That was it. That enforces users to always use Guvnor when dynamic deployment was needed. Although there is nothing wrong with it, actually that was recommended approach but not everytime it was desired.
Version 6, on the other hand moves away from proprietary packages in favor of, well known and mature, Apache Maven based packaging - known as knowledge archives - kjar. Processes, rules etc (aka business assets) are now part of a simple jar file built and managed by Maven. Along the business assets, java classes and other file types are stored in the jar file too. Moreover, as any other maven artifact, kjar can have defined dependencies on other artifacts including other kjars. What makes the kjar special when compared with regular jars is a single descriptor file kept inside META-INF directory of the kjar - kmodule.xml. That descriptor allows to define:
knowledge bases and their properties
knowledge sessions and their properties
work item handlers
event listeners
By default, this descriptor is empty (just kmodule root element) and is considered as marker file. Whenever a runtime component (such as jbpm console) is about to process kjar it looks up kmodule.xml to build its runtime representation. In addition to kmodule.xml a deployment descriptor (that provides fine graind control over deployment) is available (since 6.1).
While kmodule is mainly targeting on knowledge base and knowledge session basic configuration, deployment descriptors are considered more technical configuration. Following are the items available for configuration via deployment descriptors:
persistence unit name for runtime data
persistence unit for audit data
persistence mode (JPA or NONE)
audit mode (JPA, JMS, NONE)
runtime strategy (SINGLETON, PER_REQUEST, PER_PROCESS_INSTANCE)
list of event listeners to be registered
list of task event listeners to be registered
list of work item handlers to be registered
list of globals to be registered
marshalling strategies to be registered (for pluggable variable persistence)
required roles to be granted access to resources of the kjar
additional configuration options of knowledge session
additional environment entries for knowledge session
list of fully qualified class names that shall be added to remote services support - JAXBContent for marshal and unmarshal operations for custom types
Deployment descriptor is an xml file that is placed inside META-INF folder of the kjar, although it is an optional file and deployments will succeed even when such descriptor is missing.
<deployment-descriptor xsi:schemaLocation="http://www.jboss.org/jbpm deployment-descriptor.xsd" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance">
<persistence-unit>org.jbpm.domain</persistence-unit>
<audit-persistence-unit>org.jbpm.domain</audit-persistence-unit>
<audit-mode>JPA</audit-mode>
<persistence-mode>JPA</persistence-mode>
<runtime-strategy>PER_PROCESS_INSTANCE</runtime-strategy>
<marshalling-strategies/>
<event-listeners/>
<task-event-listeners/>
<globals/>
<work-item-handlers/>
<environment-entries/>
<configurations/>
<required-roles/>
<remoteable-classes/>
</deployment-descriptor>
It provides more configuration options then the standard deployment has. Deployment descriptors are used in hierarchical way meaning they can be placed on various levels of the system and merged on runtime. jBPM supports following levels of deployment descriptors:
server level - this is the main and considered default deployment descriptos that apply to all deployments on given server
kjar level - this is dedicated deployment descriptor to given kjar
deploy time level - this is deployment descriptor that is given at the time of deployment
Deployment descriptors on different levels are merged on deployment time where the master is considered descriptor lower in the hierarchy and slave one that is higher in hierarchy. To give an example, when a kjar is deployed and it contains deployment descriptor kjar's deployment descriptor is considered slave and server level descriptor is considered master. With default merge mode it will override all master entries with slave ones as long as they are not empty and combine all collections.
Since kjar can have dependencies to other kjars, and in turn that dependencies might have deployment descriptors as well, they will be placed in deployment descriptors hierarchy lower than the actual kjar that is being deployed. With that said, this is how it will look like from hierarchy point of view, starting with master (server level):
server level
dependency kjar level
kjar level
That in default merging mode will result in deployment descriptor where with non empty values from kjar's deployment descriptors and merged collection from all levels.
So far all merging was done with default mode, which is MERGE_COLLECTIONS but that's not the only mode that is available:
KEEP_ALL - meaning that the master wins - all configuration defined in master will be retained
OVERRIDE_ALL - meaning that slave wins - all configuration defined in master will be retained
OVERRIDE_EMPTY - meaning all non empty configuration items from slave will replace those in master, including collections
MERGE_COLLECTIONS - meaning all non empty configuration items from slave will replace those in master but collections will me merged (combined)
Deployment descriptos can be given as partial xml documents, meaning they do not need to be complete set of all configuration items, e.g. if user would like to override only the audit mode in kjar, it's enough to have following deployment descriptor:
<?xml version="1.0" encoding="UTF-8" standalone="yes"?>
<deployment-descriptor xsi:schemaLocation="http://www.jboss.org/jbpm deployment-descriptor.xsd" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance">
<audit-mode>JPA</audit-mode>
</deployment-descriptor>
Although it's worth noting that when using OVERRIDE_ALL merge mode all configuration items should be specified since it will always use them and do not merge with any other deployment descriptor in the hierarchy.
Default deployment descriptor
There is always default deployment descriptor available, even if it was not explicitly configured, when running in jbpm-console (kie-workbench) the default values are as follows:
persistence-unit is set to org.jbpm.domain
audit-persistence-unit is set to org.jbpm.domain
persistence-mode is set to JPA
audit-mode is set to JPA
runtime-strategy is set to SINGLETON
all collection based configuration items are left empty
Regardless of collection elements in default deployment descriptor are empty there will be some work item handlers/listeners registered that are required to support functionality of the jbpm console such as BAM listeners or human task work item handler.
Default deployment descriptor can be altered by specifying valid URL location to an xml file that will provide fully defined deployment descriptor. By fully defined we mean that all elements should be specified as this deployment descriptor will become server level deployment descriptor.
-Dorg.kie.deployment.desc.location=file:/my/custom/location/deployment-descriptor.xml
Collection configuration items
Deployment descriptor consists of collection based items (event listeners, work item handlers, globals, etc) that usually require definition of an object that should be created on runtime. There are two types of collection based configuration items:
object model - that is clear definition of the object to be built or looked up in available registry
named object model - that is an extension to object model and allows to provide name of the object which will be used to register object
Object model consits of:
identifier - defines main information about the object, such as fully qualified class name, spring bean id, mvel expression
parameters - optional parameters that should be used while creating object instance from the model
resolver - identifier of the resolver that will be used to create object instances from the model - (reflection, mvel, spring)
Table 14.1. Object models
Configuration item | Type of collection items |
---|---|
event-listeners | ObjectModel |
task-event-listeners | ObjectModel |
marshalling-strategies | ObjectModel |
work-item-handlers | NamedObjectModel |
globals | NamedObjectModel |
environment-entries | NamedObjectModel |
configurations | NamedObjectModel |
required-roles | String |
Depending on resolver type, creation or look up of the object will be performed. The default (and easiest) is reflection that will use both parameters and identifier (in this case is FQCN) to construct the object. Parameters in this case can be String or another object model for representing other types than String. Following is an example of an object model that will create an instance of org.jbpm.test.CustomStrategy using reflection resolver that will use constructor of that class with two String parameters. Note that String paramaters are created with different ways (using object model - first param, directly by giving String - second param).
Example 14.1.
...
<marshalling-strategy>
<resolver>reflection</resolver>
<identifier>org.jbpm.test.CustomStrategy</identifier>
<parameters>
<parameter xsi:type="objectModel">
<resolver>reflection</resolver>
<identifier>java.lang.String</identifier>
<parameters>
<parameter xsi:type="xs:string" xmlns:xs="http://www.w3.org/2001/XMLSchema">param1</parameter>
</parameters>
</parameter>
<parameter xsi:type="xs:string" xmlns:xs="http://www.w3.org/2001/XMLSchema">param2</parameter>
</parameters>
</marshalling-strategy>
...
Same can be done by using DeploymentDescriptor fluent API:
// create instance of DeploymentDescriptor with default persistence unit name
DeploymentDescriptor descriptor = new DeploymentDescriptorImpl("org.jbpm.domain");
// get builder and modify the descriptor
descriptor.getBuilder()
.addMarshalingStrategy(new ObjectModel("org.jbpm.testCustomStrategy",
new Object[]{
new ObjectModel("java.lang.String", new Object[]{"param1"}),
"param2"}));
Reflection based object model resolver is the most verbose in case there are parameters involved but there are few parameters that are available out of the box and do not need to be created, they are simply referenced by name:
entityManagerFactory (type of this parameter is javax.persistence.EntityManagerFactory)
runtimeManager (type of this parameter is org.kie.api.runtime.manager.RuntimeManager)
kieSession (type of this parameter is org.kie.api.KieServices)
taskService (type of this parameter is org.kie.api.task.TaskService)
executorService (type of this parameter is org.kie.internal.executor.api.ExecutorService)
So to be able to use one of these it's enough to reference them by name and make sure that proper object type is used within your class:
...
<marshalling-strategy>
<resolver>reflection</resolver>
<identifier>org.jbpm.test.CustomStrategy</identifier>
<parameters>
<parameter xsi:type="xs:string" xmlns:xs="http://www.w3.org/2001/XMLSchema">runtimeManager</parameter>
</parameters>
</marshalling-strategy>
...
In case reflection based resolver is not enough, more advanced resolver can be used that utilizes power of MVEL language. It's much easier in the configuration as it expects mvel expression as identifier of the object model. It will provide the out of the box parameters (listed above: runtime manager, kie session, etc) into the mvel context while evaluating expression. To define object model with mvel resolver use following xml (that will be equivalent to replection based above):
...
<marshalling-strategy>
<resolver>mvel</resolver>
<identifier>new org.jbpm.test.CustomStrategy(runtimeManager)</identifier>
</marshalling-strategy>
...
Last but not least, there is Spring based resolver available as well that allows to simply look up a bean by its identifier from spring application context. This resolver is not used in jbpm console (kie-workbench) as it does not use spring but whenever jBPM is used together with Spring it might become handy when deploying kjars into the runtime. It's very simple definition in xml, again equivalent to the other one assuming org.jbpm.test.CustomStrategy is registered in spring application context under customStrategy id.
...
<marshalling-strategy>
<resolver>spring</resolver>
<identifier>customStrategy</identifier>
</marshalling-strategy>
...
Manage deployment descriptor
Deployment descriptor is created as soon as project is created. It does contins the most basic deployment descriptor that is based on the default one. Meaning all settings present in default deployment descriptor will be copied into the one placed in the project. Further changes can be done directly in the xml content (in next versions more user friendly editor will most likely be provided). It is accessible from Administration perspecitve as this is considered technical administration task rather than business related activity.
Restrict access to runtime engine
jbpm console (kie-workbench) provides access restriction to repositories that can be configured with supplementary tool called kie-config-cli. This protects repositories in the authoring perspsective based on roles membership. Deployment descriptors moves this capability to the runtime engine by ensuring that access to processes will be granted only to users that belong to groups defined in the deployment descriptor as required roles. By default when project is created (at the same time deployment descriptor is created as well) required roles are automatically filled in based on repository restrictions. These roles can be still altered by editing deployment descriptor via Administration perspective as presented in Manage deployment descriptor section.
Security is enforced on two levels:
user interface - user will see only process definitions that are available for his/her roles
runtime manager - each access to get RuntimeEngine out of RuntimeManager is pretected based on the role membership, in case unauthorized access it attempted SecurityException will be thrown
Required roles are defined as simple strings that should match actual roles defined in security realm. Following is a xml snippet that shows definition of required roles in deployment descriptor:
<deployment-descriptor>
...
<required-roles>
<required-role>experts</required-role>
</required-roles>
...
</deployment-descriptor>
In case fine grained control is required defined roles can be prefixed with one of the following to control it on further level:
view:
to restrict access to be able to see given process definitions/instances on UI
executre:
to restrict access to be able to execute given process definitions
all:
applies to both view and execute restrictions and this is the default when no prefix is given.
For example to restrict access to show process from given kjar only to group 'management' but still allow them to be executed by anyone (sort of system processes) one could define it as follows:
<deployment-descriptor>
...
<required-roles>
<required-role>view:management</required-role>
</required-roles>
...
</deployment-descriptor>
Remote services support
When processes make use of custom types (or in general non promitive types) and there is a use case to include remote api invocations (REST, SOAP, JMS) such types must be available to the remote services marshalling mechanism that is based on JAXB for XML type. By default all types defined in kjar will be automatically included in JAXB context and therefore will be avialble for remote interaction. Though there might be more classes (like from dependent model) that shall be included there too.
Upon deployment, jbpm will scan classpath of given kjar to automatically register classes that might be needed for remote interaction. This is done based on following rules:
all classes included in kjar project itself
all classes included as dependency of projects type kjar
classes that are annotated with @XmlRootElement (JAXB annotation) and included as regular dependency of the kjar
classes that are annotated with @Remotable (kie annotation) and included as regular dependency of the kjar
If that is not enough deployment descriptor allows to manually specify classes that shall be added to the JAXB context via remoteable-classes element:
<remoteable-classes>
...
<remotable-class>org.jbpm.test.CustomClass</remotable-class>
<remotable-class>org.jbpm.test.AnotherCustomClass</remotable-class>
...
</remoteable-classes>
With this all classes can be added to the JAXB context to properly marshal and unmarshal data types when interacting with jBPM remotely.
You can access to the Deployment Units List under the Runtime menu (TODO: fix image and menu name)
The Deployment Unit list shows all the Deployment Units deployed into the platform that are already enabled to be used. Each deployment unit can contain multiple business processes and business rules. By default the list is populated by Building and Deploying a KIE Module using the Project Editor Screen. When you Build and Deploy a
You also have the option to deploy custom Deployment Units with other options different from the defaults. When a KIE Project is deployed, by default the "DEFAULT" KIE Base and KIE Sessions are used and the SINGLETON Strategy is used. You can select a different KIE Base and KIE Session using the New Deployment Unit.
You can access to the Process Deployments List under the Deploy top level menu of the KIE Workbench
The Deployed Unit list shows all the Process Deployed Units into the platform that are already enabled to be used. Each deployment unit can contain multiple business processes and business rules. In order to have your process and rules deployed and listed in this list, you need ot Build and Deploy your KIE projects from the Authoring Perspective or via the Remote Endpoints. If your processes and rules are in a KIE Project listed in this list and you have correspondent the rights you should be able to see the process definitions in the Process Definitions Perspective.
From the Authoring Perspective (Build and Deploy), a default deployment will be performed, for a more advanced deployments you can trigger a custom deployment with other options from this screen.
By clicking the New Deployment Unit (+) button you will be able to select a different KIE Base, KIE Session, Strategy and Merge Mode for your deployment. By default the "DEFAULT" KIE Base and KIE Sessions are used, the SINGLETON Strategy is selected and the Merge Mode is set to "Merge Collection".
This chapter describes the screens related with the creation and management of process definitions and process instances.
Once you have modelled and configured all the technical details to run a process definition your process definition will appear in the Process Definitions List. Once you have the process in the Process Definition List, you can start new instances of it. The following sections describes the features provided by each of these screens. You can find these screens under the Process Management Menu, in the jBPM Console NG or in KIE Workbench.
You can find the source code for this module here: https://github.com/droolsjbpm/jbpm-console-ng/tree/master/jbpm-console-ng-process-runtime
The process definition section is composed by two main screens: the Process Definition Lists and the Process Definition Details.
The process definition list shows all the available process definitions that were deployed into the platform. Look at the Deployments section for more information about how to check all the deployment units available.
You can click in the list rows to access to the details of the process definition.
The process definition details shows all the available information about the process definition. You can consider this screen as a brief about the process model. You can quickly see if there is a Sub Process associated with it, or how many users and groups are participating in the selected definition.
Notice that you can View the Process Model (Read Only mode) using the Options Menu in the top bar. You can also look at all the process instances for the selected process definition by going to Options -> View Process Instances.
You can create new Process Instances from the Process Definition List or from the Process Definition Detail view.
When you want to create a Process Instance usually a Form will be presented to introduce the information required by the process to be started. Once you complete the form and click into the Start Process button, the instance will be created and the details of the Process Instance will be displayed on top of the Process Definition Details.
This chapter introduces the Task Management screens and the its integration with the Form Modeller component to allow users to work on their assigned tasks. You can find the source code of these screens here: https://github.com/droolsjbpm/jbpm-console-ng/tree/master/jbpm-console-ng-human-tasks . At the end of this section you will find a technical description about how to customize these views.
Every user with access to the platform will have access to its personal task list where tasks assigned to him/her will be displayed. Each user will be able to create its own personal tasks or work on tasks that were create as a result of a business process execution.
You can access to the Task List under the Work main menu:
Pending tasks can be displayed using different metaphors depending on what the user is interested on. We are currently providing two different views explained in the sections below: Grid and Calendar View.
If you are interested in having a tabular view of all the pending tasks for a specific person or group you can use the Grid View. The list will show all the pending tasks ordered by the columns presented. You can change the default ordering clicking on the column header. In future version more advanced filters will be provided and the search mechanism will be improved to look for task internal data. This view offer a more traditional BPM Task List view.
With this current version you can filter based on the tasks status:
Active: all the Active tasks that user can work on. That means Personal and Group Tasks.
Personal: all the personal tasks that already belong to the user.
Group: all the group tasks that needs to be claimed by the user in order to start working on them.
All: show all the tasks no matter the status. It will show completed tasks as well with the exception of completed tasks that belongs to a process that is already finished. In such cases the tasks are cleaned up after the process is completed and for that reason they will not be displayed.
If you want a more time oriented view of your pending tasks you can use the Calendar View. This view arrange the tasks based on the Task Due Date. You can switch between three different ranges: Day, Week or Month.
The Day view shows all the tasks that Due Today. Notice that you can change the selected date using the calendar or using the Next and Previous button. The Today button will be enabled when you are in a different day than today, and when you click it it will return the selection to the current date.
The Week view shows all the tasks pending for the current week. You can change the selected week using the calendar or the Next and Previous button. If you click on the Today button, you will be moved to the week the current week.
The Month view shows all the tasks that due on the selected month. You can change the month using the calendar or the Next and Previous button. If you click on the Today button the calendar will show all the tasks that due in the current month.
You can access to the Task Details by clicking in a task row (in both Grid and Calendar Views). The details associated with a task can be changed, like for example the Due Date, the Priority or the task description.
You can also view the Process Context for a specific task. If the task was created by a Business Process, you will have access to see the Process Instance status that has created it.
Finally you can see the Task Log, which allows you to see all the operations that has been executed on the task since its creation.
Tasks can have associated a Form to store data. If tasks are part of a Business Process, usually some data needs to be collected and propagated to the business process for further usage. For that reason, tasks has to provide a way to gather and store data. Forms can be created for specific tasks using the Form Modeller. If no form is provided a dynamic form will be created based on the information that the task needs to handle. If a task is created as an ad-hoc task (not related with any process) there will be no such information to generate a form and only basic actions will be provided.
You can Delegate tasks to different people when you are not able to work on them.
As mentioned in the introduction a User can create their own tasks, which will not be associated with any Business Process. These tasks can be used to keep track of your personal list of TO DOs. You can also create tasks and assign them to different people in your team or group.
Imagine you are developing a BPM solution which mixes process with business data. Imagine also you need some forms to be used within processes in order to let the users enter data. Moreover, you'll likely want to have some kind of dashboards to display metrics and key performance indicators in order to quickly assess how your processes are doing. So far so good.
jBPM brings you all the ingredients you need to develop end-to-end business process solutions. The jBPM's BAM module (also known as Dashboard Builder or just Dashbuilder) allows for composing custom business dashboards mixing data coming from heterogeneous sources of information. The module is now fully integrated into KIE workbench. A new specific section for dealing with dashboards has been added and it can be accessed either from the home page or from the menu bar, as shown in the next figure.
In the figure, within the highlighted sections, there exists two options:
Business Dashboards: This option is intended to give users access to the generic dashboard tooling either to compose new dashboards or just to consume existing ones.
Process & Task Dashboard: It opens up the Process Dashboard perspective which contains several performance indicators related to the jBPM execution engine.
BPM solutions are not only made up with processes, rules or forms but also with data belonging to the customer business domain. Such data is handled in the forms, the rules and, of course, the dashboards that are part of the solution. Usually, dashboards feed with data coming from several sources of information, from business domain entities persisted into relational databases to data hold in legacy systems. In order to cope with this kind of scenarios a generic highly customizable dashboard tooling is needed.
It's obviously expected that a customer building a BPM solution want to track how its processes are performing. To do so the customer need a monitoring and reporting tool. This is the main reason why the Dashbuilder project has been included as a core module of the jBPM ecosystem. Notice also that Dashbuilder, as an independent project, is not only used by jBPM but also by many other projects like, for example, JBoss Teiid a data virtualization system that allows applications to use data from multiple, heterogeneous data stores.
An example of dashboard is the Sales Dashboard which comes built-in any installation of Dashbuilder. Two screenshots below:
The jBPM Process Dashboard is an specific use case of a dashboard feed from data coming from a relational database via SQL queries. In this case, the database tables consumed are: processinstancelog and bamtasksummary both belonging to the jBPM engine.
From the data provider perspective there exists 14 data providers in charge of retrieving the data needed by all the key performance indicators of the jBPM Process Dashboard. These data provides are all defined in the Dashbuilder tooling data provider management screen.
Below are the details of all the data providers used in the jBPM dashboard.
jBPM Count Processes: Retrieves the total number of process instances per process and per process status.
select processname,
ifnull(instances,0) total,
ifnull(instances_act,0) active,
ifnull(instances_compl,0) completed,
ifnull(instances_pend,0) pending,
ifnull(instances_susp,0) suspended,
ifnull(instances_abrt,0) aborted
from
(select processinstanceid, processname, count(*) as instances
from processinstancelog
where {sql_condition, optional, processname, processname}
and {sql_condition, optional, user_identity, userid}
and {sql_condition, optional, start_date, start_date}
and {sql_condition, optional, end_date, end_date}
and {sql_condition, optional, processversion, processversion}
group by processinstanceid,processname) as total
left outer join
(select processinstanceid, count(*) as instances_act
from processinstancelog
where status=1
and {sql_condition, optional, processname, processname}
and {sql_condition, optional, user_identity, userid}
and {sql_condition, optional, start_date, start_date}
and {sql_condition, optional, end_date, end_date}
and {sql_condition, optional, processversion, processversion}
group by processinstanceid) as active
on (total.processinstanceid=active.processinstanceid)
left outer join
(select processinstanceid, count(*) as instances_compl
from processinstancelog
where status=2
and {sql_condition, optional, processname, processname}
and {sql_condition, optional, user_identity, userid}
and {sql_condition, optional, start_date, start_date}
and {sql_condition, optional, end_date, end_date}
and {sql_condition, optional, processversion, processversion}
group by processinstanceid) as completed
on (total.processinstanceid=completed.processinstanceid)
left outer join
(select processinstanceid, count(*) as instances_pend
from processinstancelog
where status=0
and {sql_condition, optional, processname, processname}
and {sql_condition, optional, user_identity, userid}
and {sql_condition, optional, start_date, start_date}
and {sql_condition, optional, end_date, end_date}
and {sql_condition, optional, processversion, processversion}
group by processinstanceid) as pending
on (total.processinstanceid=pending.processinstanceid)
left outer join
(select processinstanceid, count(*) as instances_susp
from processinstancelog
where status=4
and {sql_condition, optional, processname, processname}
and {sql_condition, optional, user_identity, userid}
and {sql_condition, optional, start_date, start_date}
and {sql_condition, optional, end_date, end_date}
and {sql_condition, optional, processversion, processversion}
group by processinstanceid) as suspended
on (total.processinstanceid=suspended.processinstanceid)
left outer join
(select processinstanceid, count(*) as instances_abrt
from processinstancelog
where status=3
and {sql_condition, optional, processname, processname}
and {sql_condition, optional, user_identity, userid}
and {sql_condition, optional, start_date, start_date}
and {sql_condition, optional, end_date, end_date}
and {sql_condition, optional, processversion, processversion}
group by processinstanceid) as aborted
on (total.processinstanceid=aborted.processinstanceid)
order by processname
jBPM Process By Status: Retrieves the number of process instances grouped by status.
select status, count(processinstanceid)
from processinstancelog
where status is not null and {sql_condition, optional, processname, processname}
and {sql_condition, optional, user_identity, userid}
and {sql_condition, optional, status, status}
and {sql_condition, optional, start_date, start_date}
and {sql_condition, optional, end_date, end_date}
and {sql_condition, optional, processversion, processversion}
group by status
jBPM Process By Version: Retrieves the number of process instances grouped by version.
select processVersion, count(processinstanceid)
from processinstancelog
where processVersion is not null
and {sql_condition, optional, processname, processname}
and {sql_condition, optional, user_identity, userid}
and {sql_condition, optional, status, status}
and {sql_condition, optional, start_date, start_date}
and {sql_condition, optional, end_date, end_date}
and {sql_condition, optional, processversion, processversion}
group by processVersion
jBPM Process Completed By Date: Retrieves the number of process instances completed grouped by date.
select end_date, count(processinstanceid)
from processinstancelog
where end_date is not null
and {sql_condition, optional, processname, processname}
and {sql_condition, optional, user_identity, userid}
and {sql_condition, optional, status, status}
and {sql_condition, optional, start_date, start_date}
and {sql_condition, optional, end_date, end_date}
and {sql_condition, optional, processversion, processversion}
group by end_date
order by end_date asc
jBPM Process Duration: Retrieves the number of instances and duration stats per process.
select processname, count(processinstanceid), min(duration), avg(duration), max(duration)
from processinstancelog
where {sql_condition, optional, processname, processname}
and {sql_condition, optional, user_identity, userid}
and {sql_condition, optional, status, status}
and {sql_condition, optional, start_date, start_date}
and {sql_condition, optional, end_date, end_date}
and {sql_condition, optional, processversion, processversion}
group by processname
order by processname asc
jBPM Process Instances: Retrieves the number of instances per process.
select processname, count(processinstanceid)
from processinstancelog
where {sql_condition, optional, processname, processname}
and {sql_condition, optional, user_identity, userid}
and {sql_condition, optional, status, status}
and {sql_condition, optional, start_date, start_date}
and {sql_condition, optional, end_date, end_date}
and {sql_condition, optional, processversion, processversion}
group by processname
order by processname asc
jBPM Process Instances By User: Retrieves the number of process instances grouped by the user who initiates.
select user_identity userid, count(processinstanceid)
from processinstancelog
where user_identity is not null
and {sql_condition, optional, processname, processname}
and {sql_condition, optional, user_identity, userid}
and {sql_condition, optional, status, status}
and {sql_condition, optional, start_date, start_date}
and {sql_condition, optional, end_date, end_date}
and {sql_condition, optional, processversion, processversion}
group by user_identity
jBPM Process Started By Date: Retrieves the number of process instances started on given date periods.
select start_date, count(processinstanceid)
from processinstancelog
where start_date is not null
and {sql_condition, optional, processname, processname}
and {sql_condition, optional, user_identity, userid}
and {sql_condition, optional, status, status}
and {sql_condition, optional, start_date, start_date}
and {sql_condition, optional, end_date, end_date}
and {sql_condition, optional, processversion, processversion}
group by start_date
order by start_date asc
jBPM Task Instances: Retrieves the number of task instances per process.
select ts.taskname, count(ts.taskid) taskid
from bamtasksummary ts left join processinstancelog ps on (ts.processinstanceid=ps.processinstanceid)
where {sql_condition, optional, ps.processname, processname}
and {sql_condition, optional, ps.status, status}
and {sql_condition, optional, ps.start_date, start_date}
and {sql_condition, optional, ps.end_date, end_date}
and {sql_condition, optional, ps.processversion, processversion}
and {sql_condition, optional, ts.userid, userid}
and {sql_condition, optional, ts.taskname, taskname}
and {sql_condition, optional, ts.createddate, createddate}
and {sql_condition, optional, ts.enddate, enddate}
and {sql_condition, optional, ts.status, status}
group by ts.taskname
jBPM Tasks By Status: Retrieves the number of task instances grouped by status.
select ts.status as taskstatus, count(ts.taskid)
from bamtasksummary ts left join processinstancelog ps on (ts.processinstanceid=ps.processinstanceid)
where {sql_condition, optional, ps.processname, processname}
and {sql_condition, optional, ps.status, status}
and {sql_condition, optional, ps.start_date, start_date}
and {sql_condition, optional, ps.end_date, end_date}
and {sql_condition, optional, ps.processversion, processversion}
and {sql_condition, optional, ts.userid, userid}
and {sql_condition, optional, ts.taskname, taskname}
and {sql_condition, optional, ts.createddate, createddate}
and {sql_condition, optional, ts.enddate, enddate}
and {sql_condition, optional, ts.status, taskstatus}
group by ts.status
jBPM Tasks By User: Retrieves the number of task instances grouped by the user who holds it.
select ts.userid, count(ts.taskid)
from bamtasksummary ts left join processinstancelog ps on (ts.processinstanceid=ps.processinstanceid)
where ts.userid is not null
and {sql_condition, optional, ps.processname, processname}
and {sql_condition, optional, ps.status, status}
and {sql_condition, optional, ps.start_date, start_date}
and {sql_condition, optional, ps.end_date, end_date}
and {sql_condition, optional, ps.processversion, processversion}
and {sql_condition, optional, ts.userid, userid}
and {sql_condition, optional, ts.taskname, taskname}
and {sql_condition, optional, ts.createddate, createddate}
and {sql_condition, optional, ts.enddate, enddate}
and {sql_condition, optional, ts.status, taskstatus}
group by ts.userid
jBPM Tasks Completed By Date: Retrieves the number of task instances completed grouped by date.
select ts.enddate, count(ts.taskid)
from bamtasksummary ts left join processinstancelog ps on (ts.processinstanceid=ps.processinstanceid)
where ts.enddate is not null
and {sql_condition, optional, ps.processname, processname}
and {sql_condition, optional, ps.status, status}
and {sql_condition, optional, ps.start_date, start_date}
and {sql_condition, optional, ps.end_date, end_date}
and {sql_condition, optional, ps.processversion, processversion}
and {sql_condition, optional, ts.userid, userid}
and {sql_condition, optional, ts.taskname, taskname}
and {sql_condition, optional, ts.createddate, createddate}
and {sql_condition, optional, ts.enddate, enddate}
and {sql_condition, optional, ts.status, taskstatus}
group by ts.enddate
order by ts.enddate asc
jBPM Tasks Duration: Retrieves the number of instances and duration stats per task.
select ts.taskname, count(ts.taskid), min(ts.duration), avg(ts.duration), max(ts.duration)
from bamtasksummary ts left join processinstancelog ps on (ts.processinstanceid=ps.processinstanceid)
where ts.duration is not null
and {sql_condition, optional, ps.processname, processname}
and {sql_condition, optional, ps.status, status}
and {sql_condition, optional, ps.start_date, start_date}
and {sql_condition, optional, ps.end_date, end_date}
and {sql_condition, optional, ps.processversion, processversion}
and {sql_condition, optional, ts.userid, userid}
and {sql_condition, optional, ts.taskname, taskname}
and {sql_condition, optional, ts.createddate, createddate}
and {sql_condition, optional, ts.enddate, enddate}
and {sql_condition, optional, ts.status, taskstatus}
group by ts.taskname
order by ts.taskname asc
jBPM Tasks Started By Date: Retrieves the number of task instances started on given date periods.
select ts.createddate, count(ts.taskid)
from bamtasksummary ts left join processinstancelog ps on (ts.processinstanceid=ps.processinstanceid)
where ts.createddate is not null
and {sql_condition, optional, ps.processname, processname}
and {sql_condition, optional, ts.userid, userid}
and {sql_condition, optional, ps.status, status}
and {sql_condition, optional, ps.start_date, start_date}
and {sql_condition, optional, ps.end_date, end_date}
and {sql_condition, optional, ps.processversion, processversion}
and {sql_condition, optional, ts.userid, userid}
and {sql_condition, optional, ts.taskname, taskname}
and {sql_condition, optional, ts.createddate, createddate}
and {sql_condition, optional, ts.enddate, enddate}
and {sql_condition, optional, ts.status, taskstatus}
group by ts.createddate
order by ts.createddate asc
As shown above, every SQL contains several {sql_condition} clauses. These are needed in order to support filtering on the data displayed by the dashboard. Every time the user issues a filter request, the data providers feeding the KPIs react by re-executing their SQL with the proper filter criteria. The {sql_condition} clauses not satisfied are just ignored.
From the end user perspective, the jBPM Process Dashboard has been designed to consume the data from the data providers defined above. It has been also designed has a panel fully integrated into the KIE Workbench environment as shown in the next figure:
The dashboard itself is composed by two views or pages:
Global main view: containing metrics about all the processes.
Table 16.1. jBPM Process Dashboard: Global KPIs
Key Performance Indicator | Data provider |
---|---|
Instances by process | jBPM Process Instances |
Instances started by user | jBPM Process Instances By User |
Number of tasks per user | jBPM Tasks By User |
Tasks started by date | jBPM Tasks Started By Date |
Tasks completed by date | jBPM Tasks Completed By Date |
Tasks duration (average, min. and max.) | jBPM Tasks Duration |
Tasks by status | jBPM Tasks By Status |
Process instances by status | jBPM Process Count |
Process initiated by date | jBPM Process Started By Date |
Process completed by date | jBPM Process Completed By DateSummary |
Process duration (average, min. and max.) | jBPM Process Duration |
Process detailed view: containing metrics about an specific process. To get into this view a process must be selected from the global view. Once a process is selected, a drill-down request is carried out by the system and the process specific view is set as the current screen.
Table 16.2. jBPM Process Dashboard: Process specific KPIs
Key Performance Indicator | Data provider |
---|---|
Instances by status | jBPM Process By Status |
By version | jBPM Process By Version |
Users with tasks | jBPM Tasks By User |
Number of task instances | jBPM Task Instances |
Tasks started by date | jBPM Task Started By Date |
Tasks completed by date | jBPM Tasks Completed By Date |
Tasks duration (average, min. and max.) | jBPM Tasks Duration |
Process instances by status | jBPM Process Count |
Process initiated by date | jBPM Process Started By Date |
Process completed by date | jBPM Process Completed By DateSummary |
Process duration (average, min. and max.) | jBPM Process Duration |
The workbench contains an execution server (for executing processes and tasks), which also allows you to invoke various process and task related operations through a remote API. As a result, you can setup your process engine "as a service" and integrate this into your applications easily by doing remote requests and/or sending the necessary triggers to the execution server whenever necessary (without the need to embed or manage this as part of your application).
Both a REST and JMS based service are available (which you can use directly), and a Java remote client allows you to invoke these operations using the existing KieSession and TaskService interfaces (you also use for local interaction), making remote integration as easy as if you were interacting with a local process engine.
The Remote Java API provides KieSession
, TaskService
and
AuditService
interfaces to the JMS and REST APIs.
The interface implementations provided by the Remote Java API take care of the underlying
logic needed to communicate with the JMS or REST APIs. In other words, these implementations
will allow you to interact with a remote workbench instance (i.e. KIE workbench or the jBPM
Console) via known interfaces such as the KieSession
or TaskService
interface,
without having to deal with the underlying transport and serialization details.
While the KieSession
, TaskSerivce
and
AuditService
instances provided by the Remote Java API may "look" and "feel"
like local instances of the same interfaces, please make sure to remember that these instances
are only wrappers around a REST or jMS client that interacts with a remote REST or JMS
API.
This means that if a requested operation fails on the server, the
Remote Java API client instance on the client side will throw a
RuntimeException
indicating that the REST call failed. This is different from
the behaviour of a "real" (or local) instance of a KieSession
,
TaskSerivce
and AuditService
instance because the exception the
local instances will throw will relate to how the operation failed. Also, while local
instances require different handling (such as having to dispose of a KieSession
),
client instances provided by the Remote Java API hold no state and thus do not require any
special handling.
Lastly, operations on a Remote Java API client instance that would normally throw other
exceptions (such as the TaskService.claim(taskId, userId)
operation when called
by a user who is not a potential owner), will now throw a RuntimeException
instead when the requested operation fails on the server.
The first step in interacting with the remote runtime is to create either the
RemoteRestRuntimeFactory
or RemoteJmsRuntimeEngineFactory
, both of
which are instances of the RemoteRuntimeEngineFactory
interface.
The configuration for the Remote Java API is done when creating the
RemoteRuntimeEngineFactory
instance: there are a number of different constructors
for both the JMS and REST impelementations that allow the configuration of such things as the
base URL of the REST API, JMS queue location or timeout while waiting for responses.
Once the factory instances have been created, there are a couple of methods that can then be used to instantiate the client instance that you want to use:
Remote Java API Methods
This method instantiates a new RemoteRuntimeEngine (client) instance.
This method adds extra classes to the classpath available to the serialization mechanisms.
When passing instances of user-defined classes in a Remote Java API call, it's important to have added the classes via this method first so that the class instances can be serialized correctly.
This method instantiates a new (client) KieSession instance.
This method instantiates a new (client) TaskService instance.
This method instantiates a new (client) AuditService instance.
The RemoteRestRuntimeFactory
should indeed have been called the
RemoteRestRuntimeEngineFactory
! Sometimes it's the
easiest mistakes which are the hardest to catch. This will be corrected in future
releases.
The RemoteRestRuntimeFactory
has 4 constructor methods available. Besides
an "everything" constructor method which provides all of the options provided below, there are
also the following 3 constructors:
RemoteRestRuntimeFactory constructor method parameters
Table 17.1. Simple RemoteRestRuntimeFactory constructor parameters
Name | Type | Description |
---|---|---|
|
|
This is the name (id) of the deployment the |
|
|
This is the URL of the deployed jbpm-console, kie-wb or BPMS instance. For example: |
|
|
This is the user name needed to access the JMS queues. |
|
|
This is the password needed to access the JMS queues. |
Table 17.2. RemoteRestRuntimeFactory constructor parameters with (response message) timeout parameter
Name | Type | Description |
---|---|---|
|
|
This is the name (id) of the deployment the |
|
|
This is the URL of the deployed jbpm-console, kie-wb or BPMS instance. For example: |
|
|
This is the user name needed to access the REST API. |
|
|
This is the password needed to access the REST API. |
|
|
This maximum number of seconds to wait when waiting for a response from the server. |
Table 17.3. RemoteRestRuntimeFactory constructor parameters with form-based authorization parameter
Name | Type | Description |
---|---|---|
|
|
This is the name (id) of the deployment the |
|
|
This is the URL of the deployed jbpm-console, kie-wb or BPMS instance. For example: |
|
|
This is the user name needed to access the REST API. |
|
|
This is the password needed to access the REST API. |
|
|
Whether or not to use form-based authentication when making a REST call. Form-based authentication will be necessary on tomcat instances. |
The following example illustrates how the Remote Java API can be used with the REST API.
public void startProcessAndHandleTaskViaRestRemoteJavaAPI(URL instanceUrl, String deploymentId, String user, String password) {
// the serverRestUrl should contain a URL similar to "http://localhost:8080/jbpm-console/"
// Setup the factory class with the necessarry information to communicate with the REST services
RemoteRuntimeEngineFactory restSessionFactory
= new RemoteRestRuntimeFactory(deploymentId, instanceUrl, user, password);
// Create KieSession and TaskService instances and use them
RemoteRuntimeEngine engine = restSessionFactory.newRuntimeEngine();
KieSession ksession = engine.getKieSession();
TaskService taskService = engine.getTaskService();
// Each opertion on a KieSession, TaskService or AuditService (client) instance
// sends a request for the operation to the server side and waits for the response
// If something goes wrong on the server side, the client will throw an exception.
ProcessInstance processInstance
= ksession.startProcess("com.burns.reactor.maintenance.cycle");
long procId = processInstance.getId();
String taskUserId = user;
taskService = engine.getTaskService();
List<TaskSummary> tasks = taskService.getTasksAssignedAsPotentialOwner(user, "en-UK");
long taskId = -1;
for (TaskSummary task : tasks) {
if (task.getProcessInstanceId() == procId) {
taskId = task.getId();
}
}
if (taskId == -1) {
throw new IllegalStateException("Unable to find task for " + user + " in process instance " + procId);
}
taskService.start(taskId, taskUserId);
}
The Remote JMS Java RuntimeEngine works precisely the same as the REST variant, except that it has different constructors.
The RemoteJmsRuntimeEngineFactory
constructors can be grouped into 3 types.
The list below specifies the main arguments to each group type.
The URL of the execution server instance is given
The JMS remote access objects (such as the ConnectionFactory
and
Queue
) are given.
A remote InitialContext
instance (created using JNDI) from the server
is given.
Configuration using the server URL
. Configuration using only the URL of the server where the jBPM Console or KIE Workbench
instance is running, is the most straightforward. However, this is only possible when the
jBPM console or KIE Workbench instance is running on Wildfly or JBoss AS, or JBoss EAP.
The following table describes the parameters used when using an
InitialContext
to configure a RemoteJmsRuntimeEngineFactory
instance:
Table 17.4. RemoteJmsRuntimeFactory constructor arguments
Name | Type | Description |
---|---|---|
|
|
This is the name (id) of the deployment the |
|
|
This is the URL of the (JBoss) server instance.. |
|
|
This is the user name needed to access the JMS queues and JNDI InitialContext instance. |
|
|
This is the password needed to access the JMS queues and JNDI InitialContext instance. |
Configuration using an InitialContext
instance. When configuring the RemoteJmsRuntimeEngineFactory
with an
InitialContext
instance as a parameter, it's necessary to retrieve the
(remote) InitialContext
instance first from the remote server. The following
code illustrates how to do this.
The code below illustrates how this can be done with a JBoss AS 7 or EAP 6 server instance. Similar code is used in the constructor above.
However, regardless of which application server you use, it is necessary to
include in your classpath the class specified as the INITIAL_CONTEXT_FACTORY
(see below). For JBoss AS 7 and EAP 6, the artifact (jar) containing this class is the
org.jboss:jboss-remote-naming
artifact (jar), version
1.0.5.Final
or higher. Depending on the version of AS 7 or EAP 6 that you
use, this version may vary.
If you are using a different application server, please see your specific
application server documentation for the parameters and artifacts necessary to create an
InitialContextFactory
instance or otherwise get a remote
InitialContext
instance (via JNDI) from the application server instance.
public void startProcessAndTaskViaJmsRemoteJavaAPI(String serverHostName, String deploymentId, String user, String password) {
// Setup remote JMS runtime engine factory
InitialContext remoteInitialContext
= getRemoteInitialContext(serverHostName, user, password);
int maxTimeoutSecs = 5;
RemoteJmsRuntimeEngineFactory remoteJmsFactory
= new RemoteJmsRuntimeEngineFactory(deploymentId, remoteInitialContext, user, password, maxTimeoutSecs);
// Interface with JMS api
RuntimeEngine engine = remoteJmsFactory.newRuntimeEngine();
KieSession ksession = engine.getKieSession();
ProcessInstance processInstance = ksession.startProcess("com.burns.reactor.maintenance.cycle");
long procId = processInstance.getId();
TaskService taskService = engine.getTaskService();
List<Long> tasks = taskService.getTasksByProcessInstanceId(procId);
taskService.start(tasks.get(0), user);
}
private static InitialContext getRemoteInitialContext(String jbossServerHostName, String user, String password) {
// Configure the (JBoss AS 7/EAP 6) InitialContextFactory
Properties initialProps = new Properties();
initialProps.setProperty(InitialContext.INITIAL_CONTEXT_FACTORY, "org.jboss.naming.remote.client.InitialContextFactory");
initialProps.setProperty(InitialContext.PROVIDER_URL, "remote://"+ jbossServerHostName + ":4447");
initialProps.setProperty(InitialContext.SECURITY_PRINCIPAL, user);
initialProps.setProperty(InitialContext.SECURITY_CREDENTIALS, password);
for (Object keyObj : initialProps.keySet()) {
String key = (String) keyObj;
System.setProperty(key, (String) initialProps.get(key));
}
// Create the remote InitialContext instance
try {
return new InitialContext(initialProps);
} catch (NamingException e) {
throw new RuntimeException("Unable to create " + InitialContext.class.getSimpleName(), e);
}
}
The following table describes the parameters used when using an
InitialContext
to configure a RemoteJmsRuntimeEngineFactory
instance:
Table 17.5. RemoteJmsRuntimeFactory constructor arguments
Name | Type | Description |
---|---|---|
|
|
This is the name (id) of the deployment the |
|
|
This is a remote |
|
|
This is the user name needed to access the JMS queues. |
|
|
This is the password needed to access the JMS queues. |
|
|
This maximum number of seconds to wait when waiting for a response from the server. |
Configuration using ConnectionFactory
and Queue
instance parameters. Some users may have direct access to a ConnectionFactory
and the
Queue
instances needed to interact with the JMS API. In this case, they can
use the RemoteJmsRuntimeEngineFactory
constructor that uses the following
arguments:
Table 17.6. RemoteJmsRuntimeEngineFactory constructor arguments
Name | Type | Description |
---|---|---|
|
|
This is the name (id) of the deployment the |
|
|
This is a |
|
|
This is an instance of the |
|
|
This is an instance of the |
|
|
This is an instance of the |
|
|
This is the user name needed to access the JMS queues (in your application server configuration). |
|
|
This is the password needed to access the JMS queues (in your application server configuration). |
|
|
This maximum number of seconds to wait when waiting for a response from the server. |
As mentioned above, the Remote Java API provides client-like instances of the RuntimeEngine
, KieSession
,
TaskService
and AuditService
interfaces.
This means that while many of the methods in those interfaces are available, some are not. The following tables lists the methods
which are available. Methods not listed in the below, will throw an UnsupportedOperationException
explaining that the
called method is not available.
Table 17.7. Available process-related KieSession
methods
Returns | Method signature | Description |
---|---|---|
|
| Abort the process instance |
|
| Return the process instance |
|
| Return the process instance |
|
| Return all (active) process instances |
|
| Signal all (active) process instances |
|
| Signal the process instance |
|
| Start a new process and return the process instance (if the process instance has not immediately completed) |
|
| Start a new process and return the process instance (if the process instance has not immediately completed) |
Table 17.8. Available rules-related KieSession
methods
Returns | Method signature | Description |
---|---|---|
|
| Return the total fact count |
|
| Return a global fact |
|
| Return the id of the |
|
| Set a global fact |
|
| Fire all rules |
Table 17.9. Available WorkItemManager
methods
Returns | Method signature | Description |
---|---|---|
|
| Abort the work item |
|
| Complete the work item |
|
| Return the work item |
Table 17.10. Available task operation TaskService
methods
Returns | Method signature | Description |
---|---|---|
|
| Add a new task |
|
| Activate a task |
|
| Claim a task |
|
| Claim a task |
|
| Claim the next available task for a user |
|
| Claim the next available task for a user |
|
| Complete a task |
|
| Delegate a task |
|
| Exit a task |
|
| Fail a task |
|
| Forward a task |
|
| Nominate a task |
|
| Release a task |
|
| Remove a task |
|
| Resume a task |
|
| Skip a task |
|
| Start a task |
|
| Stop a task |
|
| Suspend a task |
Table 17.11. Available task retrieval and query TaskService
methods
Returns | Method signature |
---|---|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Table 17.12. Available AuditService
methods
Returns | Method signature |
---|---|
|
|
|
|
|
|
ProcessInstanceLog |
|
List<ProcessInstanceLog> |
|
List<NodeInstanceLog> |
|
List<NodeInstanceLog> |
|
List<VariableInstanceLog> |
|
List<VariableInstanceLog> |
|
List<VariableInstanceLog> |
|
List<VariableInstanceLog> |
|
void |
|
REST API calls to the execution server allow you to remotely manage processes and tasks and retrieve various dynamic
information from the execution server. The majority of the calls are synchronous, which means that the call will only
finish once the requested operation has completed on the server. The exceptions to this are the deployment
POST
calls, which will return the status of the request while the actual operation requested will
asynchronously execute.
When using Java code to interface with the REST API, the classes used in POST operations or otherwise returned by
various operations can be found in the (org.kie.remote:)kie-services-client
JAR.
This section lists REST calls that interface with
The deploymentId component of the REST calls below must conform to the following regular expression:
[\w\.-]+(:[\w\.-]+){2,2}(:[\w\.-]*){0,2}
For information, see the Deployment calls section.
Starts a process.
Returns a JaxbProcessInstanceResponse
instance, that contains basic information about the process instance.
The prodessDefIdcomponent of the URL must conform to the following regex: [_a-zA-Z0-9-:\.]+
This operation takes map query parameters (see above), which will be used as parameters for the process instance.
Checks that exists the process idetified by prodessDefId on the given deployment and generates an URL to show the start form on a remote application.
Returns a JaxbProcessInstanceFormResponse
instance, that contains the URL to the start process form.
The prodessDefIdcomponent of the URL must conform to the following regex: [_a-zA-Z0-9-:\.]+
Does a (read only) retrieval of the process instance. This operation will fail (code 400) if the process instance has been completed.
Returns a JaxbProcessInstanceResponse
instance.
The procInstId component of the URL must conform to the following regex: [0-9]+
Aborts the process instance.
Returns a JaxbGenericResponse
indicating whether or not the operation has succeeded.
The procInstId component of the URL must conform to the following regex: [0-9]+
Signals the process instance.
Returns a JaxbGenericResponse
indicating whether or not the operation has succeeded.
The procInstId component of the URL must conform to the following regex: [0-9]+
This operation takes a signal
and a event
query parameter.
The signal
parameter value is used as the name of the signal. This parameter
is required.
The event
parameter value is used as the value of the event. This value may use the
number query parameter syntax described above.
Gets the list of process variables in a process instance.
Returns a JaxbVariablesResponse
The procInstId component of the URL must conform to the following regex: [0-9]+
Signals the KieSession
Returns a JaxbGenericResponse
indicating whether or not the operation has succeeded.
The procInstId component of the URL must conform to the following regex: [0-9]+
This operation takes a signal
and a event
query parameter.
The signal
parameter value is used as the name of the signal. This parameter is required.
The event
parameter value is used as the value of the event. This value may use the
number query parameter syntax described above.
Gets a WorkItem
instance
Returns a JaxbWorkItem
instance
The workItemId component of the URL must conform to the following regex:
[0-9]+
Completes a WorkItem
Returns a JaxbGenericResponse
indicating whether or not the operation has succeeded
The workItemId component of the URL must conform to the following regex:
[0-9]+
This operation takes map query parameters, which are used as input to signify the results for completion of the work item.
Aborts a WorkItem
Returns a JaxbGenericResponse
indicating whether or not the operation has succeeded
The workItemId component of the URL must conform to the following regex:
[0-9]+
Starts a process and retrieves the list of variables associated with the process instance
Returns a JaxbProcessInstanceWithVariablesResponse
that contains:
Information about the process instance (with the same fields and behaviour as the
JaxbProcessInstanceResponse
A key-value list of the variables available in the process instance.
The processDefId component of the URL must conform to the following regex:
[_a-zA-Z0-9-:\.]+
Starts a process and retrieves the list of variables associated with the process instance
Returns a JaxbProcessInstanceWithVariablesResponse
(see the above REST call)
The processInstId component of the URL must conform to the following regex:
[0-9]+
Signals a process instance and retrieves the list of variables associated it
Returns a JaxbProcessInstanceWithVariablesResponse
(see above)
The processInstId component of the URL must conform to the following regex:
[0-9]+
This operation takes a signal
and a event
query parameter.
The signal
parameter value is used as the name of the signal. This parameter is required.
The event
parameter value is used as the value of the event. This value may use the
number query parameter syntax described above.
Between the 6.0.0.Final and 6.0.1.Final releases, the History REST calls were udpated and fixed in order to make them both more robust and accessible. While the REST calls that were provided with 6.0.0.Final are still available in 6.0.1.Final, they will be removed in a future release.
Cleans (deletes) all history logs
Gets a list of ProcessInstanceLog
instances
Returns a JaxbHistoryLogList
instance that contains a list of JaxbProcessInstanceLog
instances
This operation responds to pagination parameters
Gets the ProcessInstanceLog
instance associated with the specified process instance
Returns a JaxbHistoryLogList
instance that contains a JaxbProcessInstanceLog
instance
The processInstId component of the URL must conform to the following regex:
[0-9]+
This operation responds to pagination parameters
Gets a list of ProcessInstanceLog
instances associated with any child/sub-processes
associated with the specified process instance
Returns a JaxbHistoryLogList
instance that contains a list of JaxbProcessInstanceLog
instances
The processInstId component of the URL must conform to the following regex:
[0-9]+
This operation responds to pagination parameters
Gets a list of NodeInstanceLog
instances associated with the specified process instance
Returns a JaxbHistoryLogList
instance that contains a list of JaxbNodeInstanceLog
instances
The processInstId component of the URL must conform to the following regex:
[0-9]+
This operation responds to pagination parameters
Gets a list of VariableInstanceLog
instances associated with the specified process instance
Returns a JaxbHistoryLogList
instance that contains a list of JaxbVariableInstanceLog
instances
The processInstId component of the URL must conform to the following regex:
[0-9]+
This operation responds to pagination parameters
Gets a list of NodeInstanceLog
instances associated with the specified process instance
that have the given (node) id
Returns a JaxbHistoryLogList
instance that contains a list of JaxbNodeInstanceLog
instances
The processInstId component of the URL must conform to the following regex:
[0-9]+
The nodeId component of the URL must conform to the following regex:
[a-zA-Z0-9-:\.]+
This operation responds to pagination parameters
Gets a list of VariableInstanceLog
instances associated with the specified process instance
that have the given (variable) id
Returns a JaxbHistoryLogList
instance that contains a list of
JaxbVariableInstanceLog
instances
The processInstId component of the URL must conform to the following regex:
[0-9]+
The varId component of the URL must conform to the following regex:
[a-zA-Z0-9-:\.]+
This operation responds to pagination parameters
Gets a list of ProcessInstanceLog
instances associated with the specified process definition
Returns a JaxbHistoryLogList
instance that contains a list of JaxbProcessInstanceLog
instances
The processDefId component of the URL must conform to the following regex:
[_a-zA-Z0-9-:\.]+
This operation responds to pagination parameters
Gets a list of VariableInstanceLog
instances associated with the specified variable id
Returns a JaxbHistoryLogList
instance that contains a list of JaxbVariableInstanceLog
instances
The varId component of the URL must conform to the following regex:
[a-zA-Z0-9-:\.]+
This operation responds to pagination parameters
Gets a list of VariableInstanceLog
instances associated with the specified variable id
that contain the value specified
Returns a JaxbHistoryLogList
instance that contains a list of
JaxbVariableInstanceLog
instances
Both the varId and value components of the URL must conform
to the following regex:
[a-zA-Z0-9-:\.]+
This operation responds to pagination parameters
Gets a list of ProcessInstance
instances that contain the variable specified by the
given variable id.
Returns a JaxbProcessInstanceListResponse
instance that contains a list of
JaxbProcessInstanceResponse
instances
The varId component of the URL must conform to the following regex:
[a-zA-Z0-9-:\.]+
This operation responds to pagination parameters
Gets a list of ProcessInstance
instances that contain the variable specified by
the given variable id which contains the (variable) value specified
Returns a JaxbProcessInstanceListResponse
instance that contains a list of
JaxbProcessInstanceResponse
instances
Both the varId and value components of the URL must conform
to the following regex: [a-zA-Z0-9-:\.]+
This operation responds to pagination parameters
Rest calls that contain
"rest/runtime/{deploymentId}/history
" have been
deprecated: the same functionality provided by these calls can be found in the history REST
calls described in the previous sections.
If you're using the 6.0.0.Final release, the following applies to the History REST calls:
The history calls in 6.0.0.Final are dependent on a deployment being available to call them. This is because
the History REST calls in 6.0.0.Final needed the persistence framework of a deployment in order to be executed.
This means that history REST calls listed below may sometimes fail when used with a deployment unit
that uses a PER_REQUEST
or PER_PROCESS_INSTANCE
strategy
(i.e. when the deployment is no longer available).
Cleans (deletes) all history logs
Gets a list of ProcessInstanceLog
instances
Returns a JaxbHistoryLogList
instance that contains a list of JaxbProcessInstanceLog
instances
This operation responds to pagination parameters
Gets the ProcessInstanceLog
instance associated with the specified process instance
Returns a JaxbHistoryLogList
instance that contains a JaxbProcessInstanceLog
instance
The processInstId component of the URL must conform to the following regex: [0-9]+
This operation responds to pagination parameters
Gets a list of ProcessInstanceLog
instances associated with any child/sub-processes associated with the specified process instance
Returns a JaxbHistoryLogList
instance that contains a list of JaxbProcessInstanceLog
instances
The processInstId component of the URL must conform to the following regex: [0-9]+
This operation responds to pagination parameters
Gets a list of NodeInstanceLog
instances associated with the specified process instance
Returns a JaxbHistoryLogList
instance that contains a list of JaxbNodeInstanceLog
instances
The processInstId component of the URL must conform to the following regex: [0-9]+
This operation responds to pagination parameters
Gets a list of VariableInstanceLog
instances associated with the specified process instance
Returns a JaxbHistoryLogList
instance that contains a list of JaxbVariableInstanceLog
instances
The processInstId component of the URL must conform to the following regex: [0-9]+
This operation responds to pagination parameters
Gets a list of NodeInstanceLog
instances associated with the specified process instance that have the given (node) id
Returns a JaxbHistoryLogList
instance that contains a list of JaxbNodeInstanceLog
instances
The processInstId component of the URL must conform to the following regex:[0-9]+
The nodeId component of the URL must conform to the following regex: [a-zA-Z0-9-:\.]+
This operation responds to pagination parameters
Gets a list of VariableInstanceLog
instances associated with the specified process instance that have the given (variable) id
Returns a JaxbHistoryLogList
instance that contains a list of JaxbVariableInstanceLog
instances
The processInstId component of the URL must conform to the following regex: [0-9]+
The varId component of the URL must conform to the following regex: [a-zA-Z0-9-:\.]+
This operation responds to pagination parameters
Gets a list of ProcessInstanceLog
instances associated with the specified process definition
Returns a JaxbHistoryLogList
instance that contains a list of JaxbProcessInstanceLog
instances
The processDefId component of the URL must conform to the following regex: [_a-zA-Z0-9-:\.]+
This operation responds to pagination parameters
Gets a list of VariableInstanceLog
instances associated with the specified variable id
Returns a JaxbHistoryLogList
instance that contains a list of JaxbVariableInstanceLog
instances
The varId component of the URL must conform to the following regex: [a-zA-Z0-9-:\.]+
This operation responds to pagination parameters
Gets a list of VariableInstanceLog
instances associated with the specified variable id that contain the value specified
Returns a JaxbHistoryLogList
instance that contains a list of JaxbVariableInstanceLog
instances
Both the varId and value components of the URL must conform to the following regex: [a-zA-Z0-9-:\.]+
This operation responds to pagination parameters
Gets a list of ProcessInstance
instances that contain the variable specified by the given variable id.
Returns a JaxbProcessInstanceListResponse
instance that contains a list of JaxbProcessInstanceResponse
instances
The varId component of the URL must conform to the following regex: [a-zA-Z0-9-:\.]+
This operation responds to pagination parameters
Gets a list of ProcessInstance
instances that contain the variable specified by the given variable id which contains the (variable) value specified
Returns a JaxbProcessInstanceListResponse
instance that contains a list of JaxbProcessInstanceResponse
instances
Both the varId and value components of the URL must conform to the following regex: [a-zA-Z0-9-:\.]+
This operation responds to pagination parameters
The following section describes the three different types of task calls:
Task REST operations that mirror the TaskService
interface, allowing the user to interact
with the remote TaskService
instance
The Task query REST operation, that allows users to query for Task
instances
Other Task REST operations that retrieve information
Task operation authorizations. Task REST operations use the user information (used to authorize and authenticate the HTTP call) to check whether or not the requested operations can happen. This also applies to REST calls that retrieve information, such as the task query operation. REST calls that request information will only return information about tasks that the user is allowed to see.
With regards to retrieving information, only users associated with a task may retrieve information about the task. However, the authorizations of progress and other modifications of task information are more complex. See the Task Permissions section in the Task Service documentation for more infomration.
Given that many users have expressed the wish for a "super-task-user" that can execute task REST operations on all tasks, regardless of the users associated with the task, there are now plans to implement that feature. However, for the 6.0.x releases, this feature is not available.
All of the task operation calls described in this section use the user (id) used in the REST basic authorization as input for the user parameter in the specific call.
Some of the operations take an optional lanaguage
query parameter. If this parameter is not given
as a element of the URL itself, the default value of "en-UK
" is used.
The taskId component of the REST calls below must conform to the following regex:
[0-9]+
Activates a task
Returns a JaxbGenericResponse
with the status of the operation
Claims a task
Returns a JaxbGenericResponse
with the status of the operation
Claims the next available task
Returns a JaxbGenericResponse
with the status of the operation
Takes an optional language
query parameter.
Completes a task
Returns a JaxbGenericResponse
with the status of the operation
Takes map query parameters, which are the "results" input for the complete operation
Delegates a task
Returns a JaxbGenericResponse
with the status of the operation
Requires a targetId
query parameter, which identifies the user or group
to which the task is delegated
Exits a task
Returns a JaxbGenericResponse
with the status of the operation
Fails a task
Returns a JaxbGenericResponse
with the status of the operation
Delegates a task
Returns a JaxbGenericResponse
with the status of the operation
Requires a targetId
query parameter, which identifies the user or group
to which the task is forwarded
Nominates a task
Returns a JaxbGenericResponse
with the status of the operation
Requires at least one of either the user
or group
query parameter,
which identify the user(s) or group(s) that are nominated for the task
Releases a task
Returns a JaxbGenericResponse
with the status of the operation
Resumes a task
Returns a JaxbGenericResponse
with the status of the operation
Skips a task
Returns a JaxbGenericResponse
with the status of the operation
Starts a task
Returns a JaxbGenericResponse
with the status of the operation
Stops a task
Returns a JaxbGenericResponse
with the status of the operation
Suspends a task
Returns a JaxbGenericResponse
with the status of the operation
Checks that the task idetified by taskId exists and generates an URL to show the task form on a remote application.
Returns a JaxbTaskFormResponse
instance, that contains the URL to the task form.
The /task/query
operation queries all non-archived tasks based on the parameters given.
Queries the available non-archived tasks
Returns a JaxbTaskSummaryListResponse
with a list of TaskSummaryImpl
instances.
Takes the following (case-insensitive) query parameters listed below:
businessAdministrator
Specifies that the returned tasks should have the business administrator identified by this parameter
This parameter may be repeated
potentialOwner
Specifies that the returned tasks should have the potential owner identified by this parameter
This parameter may be repeated
processInstanceId
Specifies that the returned tasks should be associated with the process instance identified by this parameter
This parameter may be repeated
status
Specifies that the returned tasks should have the status identified by this parameter
This parameter may be repeated
taskId
Specifies that the returned tasks should have the (task) id identified by this parameter
This parameter may be repeated
taskOwner
Specifies that the returned tasks should have the task owner (initiator) identified by this parameter
This parameter may be repeated
workItemId
Specifies that the returned tasks should be associated with the work item identified by this parameter
This parameter may be repeated
language
Specifies the language that the returned tasks should be associated with
This parameter may be repeated
union
This specifies whether the query should query the union or intersection of the parameters. See below for more info.
This parameter must only be passed once
Example 17.1. Query usage
This call retrieves the task summaries of all tasks that have a work item id of 3, 4, or 5. If you specify the same parameter multiple times, the query will select tasks that match any of that parameter.
http://server:port/rest/task/query?workItemId=3&workItemId=4&workItemId=5
The next call will retrieve any task summaries for which the task id is 27 and for which the work item id is 11. Specifying different parameters will result in a set of tasks that match both (all) parameters.
http://server:port/rest/task/query?workItemId=11&taskId=27
The next call will retrieve any task summaries for which the task id is 27 or the
work item id is 11. While these are different parameters, the union
parameter is being used
here so that the union of the two queries (the work item id query and the task id query) is returned.
http://server:port/rest/task/query?workItemId=11&taskId=27&union=true
The next call will retrieve any task summaries for which the status is `Created
`
and the potential owner of the task is `Bob`. Note that the letter case for the status
parameter value is case-insensitve.
http://server:port/rest/task/query?status=creAted&potentialOwner=Bob
The next call will return any task summaries for which the status is `Created
`
and the potential owner of the task is `bob`. Note that the potential owner parameter is
case-sensitive. `bob` is not the same user id as `Bob`!
http://server:port/rest/task/query?status=created&potentialOwner=bob
The next call will return the intersection of the set of task summaries for which the
process instance is 201, the potential owner is `bob` and for which the status is `Created
`
or `Ready
`.
http://server:port/rest/task/query?status=created&status=ready&potentialOwner=bob&processInstanceId=201
That means that the task summaries that have the following characteristics would be included:
process instance id 201, potential owner `bob`, status `Ready`
process instance id 201, potential owner `bob`, status `Created`
And that following task summaries will not be included:
process instance id 183, potential owner `bob`, status `Created`
process instance id 201, potential owner `mary`, status `Ready`
process instance id 201, potential owner `bob`, status `Complete`
Gets the task content from a task identified by the given task id
Returns a JaxbContent
with the content of the task
The taskId component of the URL must conform to the following regex:
[0-9]+
Gets the task content from a task identified by the given content id
Returns a JaxbContent
with the content of the task
The contentId component of the URL must conform to the following regex:
[0-9]+
The calls described in this section allow users to manage deployments. Deployments are in fact
KieModule
JARs which can be deployed or undeployed, either via the UI or via the REST calls described
below. Configuration options, such as the runtime strategy, should be specified when deploying the deployment:
the configuration of a deployment can not be changed after it has already been deployed.
The above deploymentId regular expression describes an expression that contains the following elements, separated from eachother by a :
character:
The group id
The artifact id
The version
The (optional) kbase id
The (optional) ksession id
In a more formal sense, the deploymentId component of the REST calls below must conform to the following regex:
[\w\.-]+(:[\w\.-]+){2,2}(:[\w\.-]*){0,2}
This regular expression is explained as follows:
The [\w\.-]
element, which occurs 3 times in the above regex, refers to a character set that
can contain the following character sets:
[A-Z] | [0-9] | . | ||
[a-z] | _ | - |
This [\w\.-]
element occurs at least 3 times and at most 5 times, separated by a ':
' character
each time.
Example 17.2. Accepted deploymentId
's
com.wonka:choco-maker:67.190
These example deploymentId
's contain the optional kbase and
ksession id groups.
com.wonka:choco-maker:67.190:oompaBase
com.wonka:choco-maker:67.190:oompaLoompaBase:gloopSession
There are 2 operations that can be used to modify the status of a deployment:
/deployments/{deploymentId}/deploy
/deployments/{deploymentId}/undeploy
These POST
deployment calls are both asynchronous, which
means that the information returned by the POST
request does not reflect the
eventual final status of the operation itself.
As noted above, both the /deploy
and /undeploy
operations are
asynchronous REST operations. Successfull requests to these URLs will return the
status 202
upon the request completion. RFC 2616 defines the 202
status
as meaning that
“the request has been accepted for processing, but the processing has not been completed.”
This means the following:
While the request may have been accepted "successfully", the operation itself (deploying or undeploying the deployment unit) may actually fail.
Furthermore, information about deployments, such as that retrieved by calling the
GET
operations described below, are snapshots and the information
(including the status of the deployment unit) may have changed by the time the user client receives
the answer to the GET
request.
Returns a list of all the available deployed instances in a
JaxbDeploymentUnitList
instance
Returns a JaxbDeploymentUnit
instance containing th e information
(including the configuration) of the deployment unit.
This operation will fail when the URL uses a deployementId that refers to a deployment unit that does not exist or for which the deployment has not yet been completed.
This operation may succeed for deployment units for which an undeploy operation request has not yet completed.
Deploys the deployment unit referenced by the deploymentId
Returns a JaxbDeploymentJobResult
instance with the status of the
request
Takes a strategy
query parameter:
This parameter describes the runtime strategy used for the deployment.
This parameter takes the following (case- in sensitive) values:
SINGLETON
PER_REQUEST
PER_PROCESS_INSTANCE
The default runtime strategy used for a deployment is
SINGLETON
.
The deploy operation is an asynchronous operation. The
status of the deployment can be retrieved using the GET
calls described
above.
The request can fail for the reasons described
It is possible to post a deployment descriptor (or a fragment of it) while submitting deploy request. That allows to override other deployment descriptors in the hierarchy. To do so the content type of the request must be set to application/xml and the request body should be a a valid deployment descriptor content.
For example to change the audit logging mode from default JPA to JMS submit following partial deployment descriptor:
<deployment-descriptor xsi:schemaLocation="http://www.jboss.org/jbpm deployment-descriptor.xsd" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance">
<audit-mode>JMS</audit-mode>
</deployment-descriptor>
Since deployment descriptors can be merged differently, there is a possibility to provide the merge mode as part of deploy request by adding query parameter:
mergemode where values should be one of the following - KEEP_ALL, OVERRIDE_ALL, OVERRIDE_EMPTY, MERGE_COLLECTIONS
Undeploys the deployment unit referenced by the deploymentId
Returns a JaxbDeploymentJobResult
instance with the status of the
request
The undeploy operation is an asynchronous operation. The
status of the deployment can be retrieved using the GET
calls described
above.
While there is a /runtime/{id}/execute
and a task/execute
method, both will take all types
of commands. This is possible because execute takes a JaxbCommandsRequest object, which contains a list of
(org.kie.api.command.)Command
objects. The JaxbCommandsRequest
has fields to store the proper
deploymentId
and processInstanceId
information.
Of course, if you send a request with a command that needs this information (deploymentId
, for example)
and don't fill the deploymentId
in, the request will fail.
Executes a
Command
, assumed to be related to tasks.
Returns a
JaxbCommandResponse
implementation with the result of the operation
Executes a
Command
, assumed to be related to business processes or the knowledge session.
Returns a
JaxbCommandResponse
implementation with the result of the operation
Runtime commands.
AbortWorkItemCommand | GetProcessInstancesCommand | GetGlobalCommand |
CompleteWorkItemCommand | SetProcessInstanceVariablesCommand | GetIdCommand |
GetWorkItemCommand | SignalEventCommand | SetGlobalCommand |
AbortProcessInstanceCommand | StartCorrelatedProcessCommand | DeleteCommand |
GetProcessIdsCommand | StartProcessCommand | FireAllRulesCommand |
GetProcessInstanceByCorrelationKeyCommand | GetVariableCommand | InsertObjectCommand |
GetProcessInstanceCommand | GetFactCountCommand | UpdateCommand |
Task commands.
ActivateTaskCommand | FailTaskCommand | GetTasksOwnedCommand |
AddTaskCommand | ForwardTaskCommand | NominateTaskCommand |
CancelDeadlineCommand | GetAttachmentCommand | ProcessSubTaskCommand |
ClaimNextAvailableTaskCommand | GetContentCommand | ReleaseTaskCommand |
ClaimTaskCommand | GetTaskAssignedAsBusinessAdminCommand | ResumeTaskCommand |
CompleteTaskCommand | GetTaskAssignedAsPotentialOwnerCommand | SkipTaskCommand |
CompositeCommand | GetTaskByWorkItemIdCommand | StartTaskCommand |
DelegateTaskCommand | GetTaskCommand | StopTaskCommand |
ExecuteTaskRulesCommand | GetTasksByProcessInstanceIdCommand | SuspendTaskCommand |
ExitTaskCommand | GetTasksByStatusByProcessInstanceIdCommand |
Task commands.
ClearHistoryLogsCommand | FindProcessInstanceCommand | FindSubProcessInstancesCommand |
FindActiveProcessInstancesCommand | FindProcessInstancesCommand | FindVariableInstancesByNameCommand |
FindNodeInstancesCommand | FindSubProcessInstancesCommand | FindVariableInstancesCommand |
Except for the Execute calls, all other REST calls described below can use either JAXB or JSON.
All REST calls, unless otherwise specified, will use JAXB serialization.
When using JSON, make sure to add the JSON media type ("application/json"
) to the
ACCEPT
header of your REST call.
Sometimes, users may wish to pass instances of their own classes as parameters to commands sent in a REST request or JMS message. In order to do this, there are a number of requirements.
The user-defined class satisfy the following in order to be property serialized and deserialized by the JMS API:
The user-defined class must be correctly annotated with JAXB annotations, including the following:
The user-defined class must be annotated with a
javax.xml.bind.annotation.XmlRootElement
annotation with a
non-empty name
value
All fields or getter/setter methods must be annotated with a
javax.xml.bind.annotation.XmlElement
or
javax.xml.bind.annotation.XmlAttribute
annotations.
Furthermore, the following usage of JAXB annotations is recommended:
Annotate the user-defined class with a
javax.xml.bind.annotation.XmlAccessorType
annotation
specifying that fields should be used,
(javax.xml.bind.annotation.XmlAccessType.FIELD
). This also
means that you should annotate the fields (instead of the getter or setter
methods) with @XmlElement
or @XmlAttribute
annotations.
Fields annotated with @XmlElement
or
@XmlAttribute
annotations should also be annotated with
javax.xml.bind.annotation.XmlSchemaType
annotations
specifying the type of the field, even if the fields contain primitive
values.
Use objects to store primitive values. For example, use the
java.lang.Integer
class for storing an integer value, and
not the int
class. This way it will always be obvious if the
field is storing a value.
The user-defined class definition must implement a no-arg constructor.
Any fields in the user-defined class must either be object primitives (such
as a Long
or String
) or otherwise be objects that
satisfy the first 2 requiremends in this list (correct usage of JAXB annotations
and a no-arg constructor).
The class definition must be included in the deployment jar of the deployment that the JMS message content is meant for.
The sender must set a “deploymentId” string property on the JMS bytes message to the name of the deploymentId. This property is necessary in order to be able to load the proper classes from the deployment itself before deserializing the message on the server side.
While submitting an instance of a user-defined class is possible via both the JMS and REST API's, retrieving an instance of the process variable is only possible via the REST API.
When interacting with the Remote API, users may want to pass instances of their own classes as parameters to certain operations. As mThis will only be possible if the KJar for a deployment includes these classes.
REST calls that involve the TaskService
(e.g. that start with /task
..), often do not
contain any information about the associated deployment. In that case, an extra query parameter will have to be
added to the REST call so that the server can find the appropriate deployment with the class (definition) and
correctly deserialize the information passed with the call.
For these REST calls which do not contain the deployment id, you'll need to add the following parameter:
Table 17.13. Deployment id query parameter
Parameter name | Description |
---|---|
deploymentId
|
Value (must match the regex |
Some of the REST calls below return lists of information. The results of these operations can be paginated , which means that the lists can be split up and returned according to the parameters sent by the user.
For example, if the REST call parameters indicate that page 2 with page size 10 should be returned for the results, then results 10 to (and including) 19 will be returned.
The first page is always page 1 (as opposed to page "0").
Table 17.14. Pagination query parameter syntax
Parameter name | Description |
---|---|
page
|
The page number requested. The default value is 1. |
p
|
Synonym for the above
|
pageSize
|
The number of elements per page to return. The default value is 10. |
s
|
Synonym for the above
|
If both a "long" pagination parameter and its synonym are used, then only the value from the "long" variant is used. For
example, if
the
page
is given with a value of 11 and the
p
parameter is given with a value of 37, then the value of the
page
parameter,
11
, will be used and the
p
parameter will be ignored.
For the following operations, pagination is always used. See above for the default values used.
Table 17.15. REST operations using pagination
REST call URL | Short Description |
---|---|
|
Returns a list of
|
|
Returns a list of
|
|
Returns a list of
|
|
Returns a list of
|
|
Returns a list of
|
|
Returns a list of
|
|
Returns a list of
|
|
Returns a list of
|
|
Returns a list of
|
|
Returns a list of
|
|
Returns a list of
|
|
Returns a list of
|
|
Returns a list of
|
If you're triggering an operation with a REST API call that would normally (e.g. when interacting the same operation on a
local
KieSession
or
TaskService
instance) take an instance of a
java.util.Map
as one of its parameters,
you can submit key-value pairs to the operation to simulate this behaviour by passing a query parameter whose name starts with
map_
.
Example 17.3.
If you pass the query parameter
map_kEy=vAlue
in a REST call, then the
Map
that's passed to the
actual underlying
KieSession
or
TaskService
operation will contain this (
String, String
) key value pair:
"kEy" => "vAlue"
.You could pass this parameter like so:
http://localhost:8080/kie-wb/rest/runtime/myproject/process/wonka.factory.loompa.hire/start?map_kEy=vAlue
Map query parameters also use the object query parameter syntax described below, so the following query parameter,
map_total=5000
will be translated into a key-value pair in a map where the key is the String "total" and the value is a Long with the
value of 5000. For example:
http://localhost:8080/kie-wb/rest/runtime/myproject/process/wonka.factory.oompa.chocolate/start?map_total=5000
The following operations take query map parameters:
/runtime/{deploymentId}/process/{processDefId}/start
/runtime/{deploymentId}/workitem/{processItemId}/complete
/runtime/{deploymentId}/withvars/process/{processDefId}/start
/task/{taskId}/complete
/task/{taskId}/fail
While REST calls obviously only take strings as query parameters, using the following notation for query parameters will mean that the string is translated into a different type of object when the value of the string is used in the actual operation:
The REST calls allow access to the underlying deployments, regardless of whether these deployments use the
Singleton
,
Per-Process-Instance
or
Per-Request
strategies.
While there's enough information in the URL in order to access deployments that use the
Singleton
, or
Per-Request
strategies, that's not always the case with the
Per-Process-Instance
runtimes because the REST operation will obviously
need the process instance id in order to identify the deployment.
Therefore, for REST calls for which the URL does not contain the process instance id, you'll need to add the following parameter:
Table 17.17. Per-Process-Instance runtime query parameter
Parameter name | Description |
---|---|
runtimeProcInstId
|
Value (must match the regex
Will have no effect if the underlying deployment uses the
|
The URL templates in the table below are relative the following URL:
http://server:port/business-central/rest
Table 17.18. runtime REST calls
URL Template | Type | Description |
---|---|---|
/runtime/{deploymentId}/process/{procDefID}/start | POST | start a process instance based on the Process definition (accepts query map parameters) |
/runtime/{deploymentId}/process/{procDefID}/startform | POST | returns a valid URL to the start process form to be shown on a client aplication. |
/runtime/{deploymentId}/process/instance/{procInstanceID} | GET | return a process instance details |
/runtime/{deploymentId}/process/instance/{procInstanceID}/abort | POST | abort the process instance |
/runtime/{deploymentId}/process/instance/{procInstanceID}/signal | POST | send a signal event to process instance (accepts query map parameters) |
/runtime/{deploymentId}/process/instance/{procInstanceID}/variable/{varId} | GET | return a variable from a process instance |
/runtime/{deploymentId}/signal/{signalCode} | POST | send a signal event to deployment |
/runtime/{deploymentId}/workitem/{workItemID}/complete | POST | complete a work item (accepts query map parameters) |
/runtime/{deploymentId}/workitem/{workItemID}/abort | POST | abort a work item |
/runtime/{deploymentId}/withvars/process/{procDefinitionID}/start | POST |
start a process instance and return the process instance with its variables Note that even if a passed variable is not defined in the underlying process definition, it is created and initialized with the passed value. |
/runtime/{deploymentId}/withvars/process/instance/{procInstanceID}/ | GET |
return a process instance with its variables |
/runtime/{deploymentId}/withvars/process/instance/{procInstanceID}/signal | POST |
send a signal event to the process instance (accepts query map parameters) The following query parameters are accepted:
|
Table 17.19. task REST calls
URL Template | Type | Description |
---|---|---|
/task/query | GET |
return a TaskSummary list |
/task/content/{contentID} | GET |
returns the content of a task |
/task/{taskID} | GET |
return the task |
/task/{taskID}/activate | POST |
activate the task |
/task/{taskID}/claim | POST |
claim the task |
/task/{taskID}/claimnextavailable | POST |
claim the next available task |
/task/{taskID}/complete | POST |
complete the task (accepts query map paramaters) |
/task/{taskID}/delegate | POST |
delegate the task |
/task/{taskID}/exit | POST |
exit the task |
/task/{taskID}/fail | POST |
fail the task |
/task/{taskID}/forward | POST |
forward the task |
/task/{taskID}/nominate | POST |
nominate the task |
/task/{taskID}/release | POST |
release the task |
/task/{taskID}/resume | POST |
resume the task (after suspending) |
/task/{taskID}/skip | POST |
skip the task |
/task/{taskID}/start | POST |
start the task |
/task/{taskID}/stop | POST |
stop the task |
/task/{taskID}/suspend | POST |
suspend the task |
/task/{taskID}/content | GET |
returns the content of a task |
/task/{taskID}/showTaskForm | GET |
returns a valid URL to the task form to be shown on a client aplication. |
Table 17.20. history REST calls
URL Template | Type | Description |
---|---|---|
/history/clear/ | POST | delete all process, node and history records |
/history/instances | GET | return the list of all process instance history records |
/history/instance/{procInstId} | GET | return a list of process instance history records for a process instance |
/history/instance/{procInstId}/child | GET | return a list of process instance history records for the subprocesses of the process instance |
/history/instance/{procInstId}/node | GET | return a list of node history records for a process instance |
/history/instance/{procInstId}/node/{nodeId} | GET | return a list of node history records for a node in a process instance |
/history/instance/{procInstId}/variable | GET | return a list of variable history records for a process instance |
/history/instance/{procInstId}/variable/{variableId} | GET | return a list of variable history records for a variable in a process instance |
/history/process/{procDefId} | GET | return a list of process instance history records for process instances using a given process definition |
/history/variable/{varId} | GET | return a list of variable history records for a variable |
/history/variable/{varId}/instances | GET | return a list of process instance history records for process instances that contain a variable with the given variable id |
/history/variable/{varId}/value/{value} | GET | return a list of variable history records for variable(s) with the given variable id and given value |
/history/variable/{varId}/value/{value}/instances | GET | return a list of process instance history records for process instances with the specified variable that contains the specified variable value |
Table 17.21. deployment REST calls
URL Template | Type | Description |
---|---|---|
/deployments | GET | return a list of (deployed) deployments |
/deployment/{deploymentId} | GET | return the status and information about the deployment |
/deployment/{deploymentId}/deploy | POST |
submit a request to deploy a deployment |
/deployment/{deploymentId}/undeploy | POST |
submit a request to undeploy a deployment |
The Java Message Service (JMS) is an API that allows Java Enterprise components to communicate with each other asynchronously and reliably.
Operations on the runtime engine and tasks can be done via the JMS API exposed by the jBPM console and KIE workbench. However, it's not possible to manage deployments or the knowledge base via this JMS API.
Unlike the REST API, it is possible to send a batch of commands to the JMS API that will all be processed in one request after which the responses to the commands will be collected and return in one response message.
When the Workbench is deployed on the JBoss AS or EAP server, it automatically creates 3 queues:
jms/queue/KIE.SESSION
jms/queue/KIE.TASK
jms/queue/KIE.RESPONSE
The KIE.SESSION
and KIE.TASK
queues should be used
to send request messages to the JMS API. Command response messages will be then placed on the
KIE.RESPONSE
queues. Command request messages that involve starting and
managing business processes should be sent to the KIE.SESSION
and command request
messages that involve managing human tasks, should be sent to the KIE.TASK
queue.
Although there are 2 different input queues, KIE.SESSION
and KIE.TASK
, this is only in order to provide multiple
input queues so as to optimize processing: command request messages will be processed in the same manner regardless of which queue they're sent to.
However, in some cases, users may send many more requests involving human tasks than requests involving business processes, but then not want the
processing of business process-related request messages to be delayed by the human task messages. By sending the appropriate command request
messages to the appropriate queues, this problem can be avoided.
The term "command request message" used above refers to a JMS byte message that contains a serialized
JaxbCommandsRequest
object. At the moment, only XML serialization (as opposed to, JSON or protobuf, for example) is supported.
While it is possible to interact with a BPMS or KIE workbench server instance by sending and processing JMS messages that you create yourself,
it will always be easier to use the remote Java API that's supplied by the kie-services-client
jar.
For more information about how to use the remote Java API to interact with the JMS API of a server instance, see the Remote Java API section.
The JMS API accepts ByteMessage
instances that contain serialized
JaxbCommandsRequest
objects. These JaxbCommandsRequest
instances
can be filled with multiple command objects. In this way, it's possible to send a batch of
commands for processing to the JMS API.
When users wish to include their own classes with requests, there a number of requirements that must be met for the user-defined classes. For more information about these requirements, see the Sending and receiving user class instances section in the REST API documentation.
The following is a rather long example that shows how to use the JMS API. The numbers ("callouts") along the side of the example refer to notes below that explain particular parts of the example. It's supplied for those advanced users that do not wish to use the jBPM Remote Java API.
The jBPM Remote Java API, described here, will otherwise take care of all of the logic shown below.
// normal java imports skipped import org.drools.core.command.runtime.process.StartProcessCommand; import org.jbpm.services.task.commands.GetTaskAssignedAsPotentialOwnerCommand; import org.kie.api.command.Command; import org.kie.api.runtime.process.ProcessInstance; import org.kie.api.task.model.TaskSummary; import org.kie.services.client.api.command.exception.Remote
CommunicationException; import org.kie.services.client.serialization.JaxbSerializationProvider; import org.kie.services.client.serialization.SerializationConstants; import org.kie.services.client.serialization.SerializationException; import org.kie.services.client.serialization.jaxb.impl.JaxbCommandResponse; import org.kie.services.client.serialization.jaxb.impl.JaxbCommandsRequest; import org.kie.services.client.serialization.jaxb.impl.JaxbCommandsResponse; import org.kie.services.client.serialization.jaxb.rest.JaxbExceptionResponse; import org.slf4j.Logger; import org.slf4j.LoggerFactory; public class DocumentationJmsExamples { protected static final Logger logger = LoggerFactory.getLogger(DocumentationJmsExamples.class); public void sendAndReceiveJmsMessage() { String USER = "charlie"; String PASSWORD = "ch0c0licious"; String DEPLOYMENT_ID = "test-project"; String PROCESS_ID_1 = "oompa-processing"; URL serverUrl; try { serverUrl = new URL("http://localhost:8080/jbpm-console/"); } catch (MalformedURLException murle) { logger.error("Malformed URL for the server instance!", murle); return; } // Create JaxbCommandsRequest instance and add commands Command<?> cmd = new StartProcessCommand(PROCESS_ID_1); int oompaProcessingResultIndex = 0;
JaxbCommandsRequest req = new JaxbCommandsRequest(DEPLO
YMENT_ID, cmd); req.getCommands().add(new GetTaskAssignedAsPotentialOwnerCommand(USER, "en-UK")); int loompaMonitoringResultIndex = 1;
// Get JNDI context from server InitialContext context = getRemoteJbossInitialContext(serverUrl, USER, PASSWORD); // Create JMS connection ConnectionFactory connectionFactory; try { connectionFactory = (ConnectionFactory) context.lookup("jms/RemoteConnectionFactory"); } catch (NamingException ne) { throw new RuntimeException("Unable to lookup JMS connection factory.", ne); } // Setup queues Queue sendQueue, responseQueue; try { sendQueue = (Queue) context.lookup("jms/queue/KIE.SESSION"); responseQueue = (Queue) context.lookup("jms/queue/KIE.RESPONSE"); } catch (NamingException ne) { throw new RuntimeException("Unable to lookup send or response queue", ne); } // Send command request Long processInstanceId = null; // needed if you're doing an operation on a PER_PROCESS_INSTANCE deployment String humanTaskUser = USER; JaxbCommandsResponse cmdResponse = sendJmsCommands( DEPLOYMENT_ID, processInstanceId, humanTaskUser, req, connectionFactory, sendQueue, responseQueue, USER, PASSWORD, 5); // Retrieve results ProcessInstance oompaProcInst = null; List<TaskSummary> charliesTasks = null; for (JaxbCommandResponse<?> response : cmdResponse.getR
esponses()) { if (response instanceof JaxbExceptionResponse) { // something went wrong on the server side JaxbExceptionResponse exceptionResponse = (JaxbExceptionResponse) response; throw new RuntimeException(exceptionResponse.getMessage()); } if (response.getIndex() == oompaProcessingResultIndex
) { oompaProcInst = (ProcessInstance) response.getResul
t(); } else if (response.getIndex() == loompaMonitoringRes
ultIndex) { charliesTasks = (List<TaskSummary>) response.getRes
ult(); } } } private JaxbCommandsResponse sendJmsCommands(String deploymentId, Long processInstanceId, String user, JaxbCommandsRequest req, ConnectionFactory factory, Queue sendQueue, Queue responseQueue, String jmsUser, String jmsPassword, int timeout) { req.setProcessInstanceId(processInstanceId); req.setUser(user); Connection connection = null; Session session = null; String corrId = UUID.randomUUID().toString(); String selector = "JMSCorrelationID = '" + corrId + "'"; JaxbCommandsResponse cmdResponses = null; try { // setup MessageProducer producer; MessageConsumer consumer; try { if (jmsPassword != null) { connection = factory.createConnection(jmsUser, jmsPassword); } else { connection = factory.createConnection(); } session = connection.createSession(false, Session.AUTO_ACKNOWLEDGE); producer = session.createProducer(sendQueue); consumer = session.createConsumer(responseQueue, selector); connection.start(); } catch (JMSException jmse) { throw new RemoteCommunicationException("Unable to setup a JMS connection.", jmse); } JaxbSerializationProvider serializationProvider = new JaxbSerializationProvider(); // if necessary, add user-created classes here: // xmlSerializer.addJaxbClasses(MyType.class, AnotherJaxbAnnotatedType.class); // Create msg BytesMessage msg; try { msg = session.createBytesMessage();
// set properties msg.setJMSCorrelationID(corrId);
msg.setIntProperty(SerializationConstants.SERIALIZA
TION_TYPE_PROPERTY_NAME, JaxbSerializationProvider.JMS_SERIALIZATION_TYPE); Collection<Class<?>> extraJaxbClasses = serializationProvider.getExtraJaxbClasses(); if (!extraJaxbClasses.isEmpty()) { String extraJaxbClassesPropertyValue = JaxbSerializationProvider .classSetToCommaSeperatedString(extraJaxbClasses); msg.setStringProperty(SerializationConstants.EXTRA_JAXB_CLASSES_PROPERTY_NAME, extraJaxbClassesPropertyValue); msg.setStringProperty(SerializationConstants.DEPLOYMENT_ID_PROPERTY_NAME, deploymentId); } // serialize request String xmlStr = serializationProvider.serialize(req
); msg.writeUTF(xmlStr); } catch (JMSException jmse) { throw new RemoteCommunicationException("Unable to create and fill a JMS message.", jmse); } catch (SerializationException se) { throw new RemoteCommunicationException("Unable to deserialze JMS message.", se.getCause()); } // send try { producer.send(msg); } catch (JMSException jmse) { throw new RemoteCommunicationException("Unable to send a JMS message.", jmse); } // receive Message response; try { response = consumer.receive(timeout); } catch (JMSException jmse) { throw new RemoteCommunicationException("Unable to receive or retrieve the JMS response.", jmse); } if (response == null) { logger.warn("Response is empty, leaving"); return null; } // extract response assert response != null : "Response is empty."; try { String xmlStr = ((BytesMessage) response).readUTF(); cmdResponses = (JaxbCommandsResponse) serialization
Provider.deserialize(xmlStr); } catch (JMSException jmse) { throw new RemoteCommunicationException("Unable to extract " + JaxbCommandsResponse.class.getSimpleName() + " instance from JMS response.", jmse); } catch (SerializationException se) { throw new RemoteCommunicationException("Unable to extract " + JaxbCommandsResponse.class.getSimpleName() + " instance from JMS response.", se.getCause()); } assert cmdResponses != null : "Jaxb Cmd Response was null!"; } finally { if (connection != null) { try { connection.close(); session.close(); } catch (JMSException jmse) { logger.warn("Unable to close connection or session!", jmse); } } } return cmdResponses; } private InitialContext getRemoteJbossInitialContext(URL url, String user, String password) { Properties initialProps = new Properties(); initialProps.setProperty(InitialContext.INITIAL_CONTEXT_FACTORY, "org.jboss.naming.remote.client.InitialContextFactory"); String jbossServerHostName = url.getHost(); initialProps.setProperty(InitialContext.PROVIDER_URL, "remote://"+ jbossServerHostName + ":4447"); initialProps.setProperty(InitialContext.SECURITY_PRINCIPAL, user); initialProps.setProperty(InitialContext.SECURITY_CREDENTIALS, password); for (Object keyObj : initialProps.keySet()) { String key = (String) keyObj; System.setProperty(key, (String) initialProps.get(key)); } try { return new InitialContext(initialProps); } catch (NamingException e) { throw new RemoteCommunicationException("Unable to create " + InitialContext.class.getSimpleName(), e); } } }
These classes can all be found in the | |
The A deployment id is required for command request messages that deal with business processes. Command request messages that only contain human task-related commands do not require a deployment id. | |
Note that the JMS message sent to the remote JMS API must be constructed as follows:
| |
The same serialization mechanism used to serialize the request message will be used to serialize the response message. | |
In order to match the response to a command, to the initial command, use the | |
Since many of the results returned by various commands are not serializable, the jBPM JMS Remote API converts these results
into JAXB equivalents, all of which implement the For example, in the code above, the However, not all methods that can be called on a normal |
How to use the Eclipse-based tooling
The jBPM Eclipse plugin provides developers (and very technical users) with an environment to edit and test processes, and integrate it deeply with their applications. It provides the following features (on top of the Eclipse IDE):
Wizards for creation of
a jBPM project
a BPMN2 process
jBPM Perspective (showing the most commonly used views in a predefined layout)
The jBPM installer is capable of downloading and installing an Eclipse installation, including the Drools and jBPM Eclipse plugin (with a full jBPM runtime preconfigured) and the Eclipse BPMN2 Modeler.
Using the jBPM installer is definitely the recommended starting point for most users.
You can however also download and install the jBPM Eclipse Plugin manually. To do so, you need to:
Download Eclipse (Kepler recommended, but older versions like Indigo or Juno should also still work)
Start Eclipse
Select "Install New Software ..." from the Help menu. Add the Drools and jBPM update site http://downloads.jboss.org/jbpm/release/6.0.1.Final/updatesite/. You should see the plugins as shown below. Note that you can also download and unzip the Drools and jBPM update site to your local file system and use that as local update site instead.
Select the JBoss jBPM Core and JBoss Drools Core plugins and click "Next >". Click "Next >" again after reviewing your selecting, accept the terms of the license agreement and click "Finish" to download and install the plugins. If you get a warning about installing software that contains unsigned content, click OK. After successful installation, Eclipse should ask you to restart, click Yes.
The plugin should now be installed. To check, check if you can for example see the new jBPM Project wizard: under the "File" menu, select "New Project ..." and there you should be able to see "New jBPM Project" under the jBPM category.
Register a jBPM runtime to get started, see the section on jBPM runtimes in this chapter for more information.
Note that, when doing a manual install, you still need to manually install the Eclipse BPMN 2.0 Modeler plugin as well. Check out the chapter on the Eclipse BPMN 2.0 Modeler on how to do that.
The aim of the new project wizard is to set up an executable sample project to start using processes immediately. This will set up a basic structure, the classpath, sample process and a test case to get you started. To create a new jBPM project, in the "File" menu select "New" and then "Project ..." and under the jBPM category, select "jBPM Project". A dialog as shown below should pop up.
Fill in a name for your project and if necessary change the location where this project should be located (by default Eclipse will generate it inside your Eclipse workspace folder) and click "Next >".
Now you can optionally include a sample process in your project to get started. You can select to either use a simple "Hello World" process, a slightly more advanced process including human tasks and persistence or simply an empty project. You can also select to include a JUnit test class that you can use to test your process. These can serve as a starting point, and will give you something executable almost immediately, which you can then modify to your needs.
Finally, the last page in the wizard allows you select a jBPM runtime, as shown below. You can either use the default runtime (as configured for you workspace, in your workspace preferences), or you can select a specific runtime for this project. For more information about runtimes and how to create them, see the section on jBPM runtimes in this chapter.
You can also select which version of jBPM you want to generate sample code for. By default it will generate an example using the latest jBPM 6.x API, but you could also generate examples using the old jBPM 5.x API. Note that you yourself are responsible for making sure that the code you generate can be understood by the runtime (for example, if you create an example using jBPM6 API but select a jBPM5 runtime, your sample will not compile). Also note that, if you want to execute a jBPM5 example on jBPM6, you will need to have the knowledge-api JAR inside your jBPM6 runtime, as this is responsible for the backwards compatibility of the jBPM5 API in jBPM6.
When you selected the simple 'hello world' example, the result is shown below. Feel free to experiment with the plug-in at this point.
The newly created project contains an example process file (sample.bpmn) in the src/main/resources directory and an example Java file (ProcessTest.java) that can be used to test the process in a jBPM engine. You'll find this in the folder src/main/java, in the com.sample package. All the other JARs that are necessary during execution are also added to the classpath in a custom classpath container called jBPM Library.
You can also convert an existing Java project to a jBPM project by selecting the "Convert to jBPM Project" action. Right-click the project you want to convert and under the "Configure" category (at the bottom) select "Convert to jBPM Project". This will add the jBPM Library to your project's classpath.
You can create a new process simply as an empty text file with extension ".bpmn", or use the "New BPMN2 Process" wizard to do so. To create a new process, in the "File" menu select "New" and then "Other ..." and under the jBPM category, select "BPMN2 Process" and click "Next >". In the next dialog, you should select the folder where the process should be created (for example the src/main/resources folder of your project) and a name for the process. Clicking "Finish" should create your new process (by default it should only contain one start node) and open it so you can start editing it.
A jBPM runtime is a collection of JAR files that represent one specific release of the jBPM project JARs. To create a runtime, download the binary distribution of the version of jBPM you want to use and unzip on your local file system. You must then point the IDE to the release of your choice by selecting the folder where these JARs are located. If you want to create a new runtime based on the latest jBPM project JARs included in the plugin itself, you can also easily do that. You are required to specify a default jBPM runtime for your Eclipse workspace, but each individual project can override the default and select the appropriate runtime for that project specifically.
To define one or more jBPM runtimes using the Eclipse preferences view you open up your Preferences, by selecting the "Preferences" menu item in the menu "Window". A "Preferences" dialog should show all your settings. On the left side of this dialog, under the jBPM category, select "Installed jBPM runtimes". The panel on the right should then show the currently defined jBPM runtimes. For example, if you used the jBPM Installer, it should look like the figure below.
To define a new jBPM runtime, click on the "Add" button. A dialog such as the one shown below should pop up, asking for the name of your runtime and the location on your file system where it can be found.
In general, you have two options:
If you simply want to use the default JAR files as included in the jBPM Eclipse plugin, you can create a new jBPM runtime automatically by clicking the "Create a new jBPM Runtime ..." button. A file browser will show up, asking you to select the folder on your file system where you want this runtime to be created. The plugin will then automatically copy all required dependencies to the specified folder. Make sure to select a unique name for the newly created runtime and click "OK" to register this runtime.
Note that creating a jBPM runtime from the default JAR files as included in the jBPM Eclipse plugin is only recommended to get you started the first time and for very simple use cases. The runtime that is created this way only contains the minimal set of JARs, and therefore doesn't support a significant set of features, including for example persistence. Make sure to create a full runtime (using the second approach) for real development.
If you want to use one specific release of the jBPM project, you should create a folder on your file system that contains all the necessary jBPM libraries and dependencies (for example by downloading the binary distribution and unzipping it on your local file system). Instead of creating a new jBPM runtime as explained above, give your runtime a unique name and click the "Browse ..." button to select the location of this folder containing all the required JARs. Click "OK" to register this runtime.
After clicking the OK button, the runtime should show up in your table of installed jBPM runtimes, as shown below. Click on the checkbox in front of one of the installed runtimes to make it the default jBPM runtime. The default jBPM runtime will be used as the runtime of all your new jBPM projects (in case you didn't select a project-specific runtime).
You can add as many jBPM runtimes as you need. Note that you will need to restart Eclipse if you changed the default runtime and you want to make sure that all the projects that are using the default runtime update their classpath accordingly.
Whenever you create a jBPM project (using the New jBPM Project wizard or by converting an existing Java project to a jBPM project), the plugin will automatically add all the required JARs to the classpath of your project.
When creating a new jBPM project, the plugin will automatically use the default Drools runtime for that project, unless you specify a project-specific one. You can do this in the final step of the New jBPM Project wizard, as shown below, by deselecting the "Use default Drools runtime" checkbox and selecting the appropriate runtime in the drop-down box. If you click the "Configure workspace settings ..." link, the workspace preferences showing the currently installed jBPM runtimes will be opened, so you can add new runtimes there.
You can change the runtime of a jBPM project at any time by opening the project properties and selecting the jBPM category, as shown below. Mark the "Enable project specific settings" checkbox and select the appropriate runtime from the drop-down box. If you click the "Configure workspace settings ..." link, the workspace preferences showing the currently installed jBPM runtimes will be opened, so you can add new runtimes there. If you deselect the "Enable project specific settings" checkbox, it will use the default runtime as defined in your global workspace preferences.
The aim of the new Maven project wizard is to set up an executable sample project to start using processes immediately (but not as normal Java project with all jBPM dependencies added using a jBPM library but by using Maven (and thus a pom.xml) to define your project's properties and dependencies. This wizard will set up a Maven project using a pom.xml, and include a sample process and Java class to execute it. To create a new jBPM Maven project, in the "File" menu select "New" and then "Project ..." and under the jBPM category, select "jBPM Project (Maven)". Give your project a name and click finish. The result should be as shown below.
The pom.xml that is generated for your project contains the following:
<?xml version="1.0" encoding="UTF-8"?>
<project xmlns="http://maven.apache.org/POM/4.0.0"
xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
xsi:schemaLocation="http://maven.apache.org/POM/4.0.0 http://maven.apache.org/xsd/maven-4.0.0.xsd">
<modelVersion>4.0.0</modelVersion>
<groupId>com.sample</groupId>
<artifactId>jbpm-example</artifactId>
<version>1.0.0-SNAPSHOT</version>
<name>jBPM :: Sample Maven Project</name>
<description>A sample jBPM Maven project</description>
<properties>
<version.org.jbpm>6.0.0.Final</version.org.jbpm>
</properties>
<repositories>
<repository>
<id>jboss-public-repository-group</id>
<name>JBoss Public Repository Group</name>
<url>http://repository.jboss.org/nexus/content/groups/public/</url>
<releases>
<enabled>true</enabled>
<updatePolicy>never</updatePolicy>
</releases>
<snapshots>
<enabled>true</enabled>
<updatePolicy>daily</updatePolicy>
</snapshots>
</repository>
</repositories>
<dependencies>
<dependency>
<groupId>org.jbpm</groupId>
<artifactId>jbpm-test</artifactId>
<version>${version.org.jbpm}</version>
</dependency>
</dependencies>
</project>
In the properties section, you can specify which version of jBPM you would like to use (by default it uses 6.0.0.Final). It adds the JBoss Nexus Maven repository (where all the jBPM JARs and their dependencies are located) to your project and configures the dependencies.
By default, only the jbpm-test JAR is specified as a dependency, as this has transitive dependencies to almost all of the core dependencies you will need. You are free to update the dependencies section however to include only the dependencies you need.
The project also contains a sample process, under src/main/resources, in the com.sample package, and a kmodule.xml configuration file under the META-INF folder. The kmodule.xml defines which resources (processes, rules, etc.) are to be loaded as part of your project. In this case, it is defining a kbase called "kbase" that will load all the resources in the com.sample folder:
<kmodule xmlns="http://jboss.org/kie/6.0.0/kmodule">
<kbase name="kbase" packages="com.sample"/>
</kmodule>
Finally, it also contains a Java class that can be used to execute the sample process.
It will first create a kbase called "kbase" (by inspecting the kmodule.xml file and thus
loading the sample.bpmn
process) and then use a RuntimeManager
to
get access to a KieSession
and TaskService
. In this case, it is used
to start a process and then complete the tasks created by this process one by one.
The Drools Eclipse Plugin, which is bundled as part of the same Eclipse Update Site as the jBPM Eclipse Plugin, provides similar features for creating and editing business rules, and execute them using the Drools engine. This for example allows you to create and edit .drl files containing business rules. You can combine your processes and rules inside one project and execute them together on the same KieSession.
This section describes how to debug processes using the jBPM Eclipse plugin. This means that the current state of your running processes can be inspected and visualized during the execution. Note that we currently don't allow you to put breakpoints on the nodes within a process directly. You can however put breakpoints inside any Java code you might have (i.e. your application code that is invoking the engine or invoked by the engine, listeners, etc.) or inside rules (that could be evaluated in the context of a process). At these breakpoints, you can then inspect the internal state of all your process instances.
When debugging the application, you can use the following debug views to track the execution of the process:
The process instances view, showing all running process instances (and their state). When double-clicking a process instance, the process instance view visually shows the current state of that process instance at that point in time.
The audit view, showing the audit log (note that you should probably use a threaded file logger if you want to session to save the audit event to the file system on regular intervals, so the audit view can be update to show the latest state).
The global data view, showing the globals.
Other views related to rule execution like the working memory view (showing the contents (data) in the working memory related to rule execution), the agenda view (showing all activated rules), etc.
The process instances view shows the process instances currently running in the selected ksession. To be able to use the process instances view, first open the Process Instances view (Window - Show View - Other ... and under the Drools category select Process Instances and Process Instance). Tip: it might be useful to drag the Process Instance view to the Outline View and slightly enlarge it, as shown in the screenshot below, so you can see both the Process Instances and Process Instance views at the same time.
Next, use a (regular) Java breakpoint to stop your application at a specific point (for example right after starting a new process instance). In the Debug perspective, select the ksession you would like to inspect, and the Process Instances view should show the process instances that are currently active inside that ksession. For example, the screenshot below shows one running process instance (with id "1"). When double-clicking a process instance, the process instance viewer will graphically show the progress of that process instance. An example where the process instance is waiting for a human actor to perform "Task 1" is shown below.
The process instances view shows the process instances currently active inside the selected ksession. Note that, when using persistence, process instances are not kept in memory inside the ksession, as they are stored in the database as soon as the command completes. Therefore, you will not be able to use the Process Instances view when using persistence. For example, when executing a JUnit test using the JbpmJUnitBaseTestCase, make sure to call "super(true, false);" in the constructor to create a runtime manager that is not using persistence.
When you double-click a process instance in the process instances view and the process instance view complains that it cannot find the process, this means that the plugin wasn't able to find the process definition of the selected process instance in the cache of parsed process definitions. To solve this, simply change the process definition in question and save again (so it will be parsed) or rebuild the project that contains the process definition in question.
The audit view can be used to show the all the events inside an audit log in a tree-based manner. An audit log is an XML-based log file which contains a log of all the events that occurred while executing a specific ksession. To create a logger, use KieServices to create a new logger and attach it to a ksession. Be sure to close the logger after usage.
KieRuntimeLogger logger = KieServices.Factory.get().getLoggers()
.newThreadedFileLogger(ksession, "mylogfile", 1000);
// do something with the ksession here
logger.close();
To be able to use the Audit View, first open it (Window - Show View - Other ... and under the Drools category select Audit). To open up a log file in the audit view, open the selected log file in the audit view (using the "Open Log" action in the top right corner), or simply drag and drop the log file from the Package Explorer or Navigator into the audit view. A tree-based view is generated based on the data inside the audit log. An event is shown as a subnode of another event if the child event is caused by (a direct consequence of) the parent event. An example is shown below.
Note that the file-based logger will only save the events on close (or when a certain threshold is reached). If you want to make sure the events are saved on a regular interval (for example during debugging), make sure to use a threaded file logger, so the audit view can be update to show the latest state. When creating a threaded file logger, you can specify the interval after which events should be saved to the file (in milliseconds).
From Eclipse, you can synchronize your local workspace with one or more repositories that are managed inside the workbench application. This enables collaboration between developers using Eclipse and users of the web-based workbench (business analysts or end users for example). Synchronization between the workbench repositories and your local version of these projects is done using Git (a popular distributed source code version control system).
When creating and executing processes inside Eclipse, you are creating them on your local file system. You can however also import an existing repository from the Workbench, apply changes and push these changes back into the Workbench repositories. We are using existing Git tools for this. Note that this section will describe how to do this using the EGit tooling (Eclipse Tooling for Git which comes by default with most versions of Eclipse), but feel free to use your preferred Git tool instead.
This section is not intended to explain what Git is, or how to use EGit, in detail. If you don't have any experience with Git and/or EGit, it might be recommended to read up on them first if necessary.
To import an existing repository from the workbench, you can use the EGit import wizard. In the File menu, select "Import ..." and in the Git category, select "Projects from Git" and click "Next >". This should open a new dialog where you should select the location of the repository you would like to import. Since we are connecting to a repository that is managed by the workbench application, select "URI" and click "Next >" once more.
Use the following URI to connect to your workbench repositories:
ssh://<hostname>:8001/<repository_name>
For example, if you are running the workbench application on your local host (for example by using the jbpm-installer), and you want to import the jbpm-playground repo, use the following URI:
ssh://localhost:8001/jbpm-playground
Note that you can change the port that is used by the server to provide ssh access
to the git repository if necessary, using the system property org.uberfire.nio.git.ssh.port
Fill in the URI of the repository you would like to import, as for example shown below, and click "Next >".
You will be asked to select which branch you would like to import. Select the master branch and click "Next >" again.
Finally, you need to specify where on your local file system you would like this repository to be created. Fill in the directory (you can use the Browse button to select the folder in question, and if necessary you can create a new folder there as well) and click "Next >". This will now download the repository to the folder you just selected.
You still need to import the repository you just downloaded as a project in your Eclipse workspace. Select "Import as general project" and after clicking "Next >", give it a name and click "Finish". After doing so, your workspace should now contain your repository, and you should be able to browse, open and edit the various assets inside.
You can commit and push changes (you do locally) back to the workbench repositories. To commit changes, right-click on your repository project and select "Team -> Commit ...". A new dialog pops up, showing all the changes you have on your local file system. Select the files you want to commit (if you double-click them, you can get an overview of the changes you did for that file), provide an appropriate commit message and click "Commit".
Once you've committed your change to your local git, you still need to push it to the workbench repository. Right-click your project again, and select "Team -> Push to Upstream".
You are only allowed to push changes upstream if your local version includes all recent changes (otherwise you might be overriding someone else's changes). You might be forced to update (and if necessary resolve conflicts) before you are allowed to commit any changes.
To retrieve the latest changes from the workbench repository, right-click your repository project and select "Team -> Fetch from Upstream". This will fetch all changes from the workbench repository, but not yet apply them to your local version. Now right-click your project again and select "Team -> Merge ...". In the dialog that pops up next, you need to select "origin/master" branch (under Remote Tracking) to indicate that you want to merge in all changes from the original repository in the workbench, and click "Merge".
It is possible that you have committed and/or conflicting changes in your local version, you might have to resolve these conflicts and commit the merge results before you will be able to complete the merge successfully. It is recommended to update regularly, before you start updating a file locally, to avoid merge conflicts being detected when trying to commit changes.
When you import a repository, it will download all the projects that are inside that repository. It is however useful to mount one specific project as a separate Java project in Eclipse. When you do this, Eclipse will be able to interpret the information in the project pom.xml file (that you created in the workbench), download and include any dependencies you specified, compile any Java classes you have in your project (that you for example created with the data modeler), etc.
To do so, right-click on one of the projects in your repository project and select "Import ..." and under the Maven category, select "Existing Maven Projects" (as shown below) and click Next.
In the next page, you should see the pom.xml of the project you selected. Click Finish.
If your project requires some of the jBPM libraries to correctly compile and/or execute any Java classes in your project (for example if you have test classes in your project that start up a jBPM engine and execute some tests for your project, or if you are using the data modeler, which will add some annotations to the generated Java classes), you still need to add the jBPM libraries to the classpath of your project. To do so, simply convert your project into a jBPM project, which will add the jBPM library to your project's classpath. Right-click your project and select "Configure -> Convert to jBPM Project". Your project should now have a jBPM Library added to its classpath (it might be necessary to clean your project to pick up this change and recompile all Java classes).
The Eclipse BPMN 2.0 Modeler allows you to specify business processes, choreographies, etc. using the BPMN 2.0 XML syntax (including BPMNDI for the graphical information). The editor itself is based on the Eclipse Graphiti framework and the Eclipse BPMN 2.0 EMF meta-model.
Features:
It supports almost all BPMN 2.0 process constructs and attributes (including lanes and pools, annotations and all the BPMN2 node types).
Added additional support for the few custom attributes that jBPM introduces using a special jBPM Target Runtime.
Allows you to configure which elements and attributes you want use when modeling processes (so we can limit the constructs for example to the subset currently supported by jBPM, which is a profile supported by default, or even more if you like).
The BPMN2 Modeler project is being developed at eclipse.org, sponsored by Red Hat/JBoss. Red Hat understan