# Business Objective
The Entando Process Driven Applications plugin is built to provide a rich and full featured user experience to allow for the management and completion of business processes and automation. The UX is delivered a general purpose UX layer built using micro frontends that can be utilized for any business process or task engine. Customers drive the UX layer by utilizing a pre-developed Entando integration or by implementing a set of interfaces on the server side. The backend is a Spring Boot microservice that provides a pluggable interface allowing for the injection of any underlying process or automation toolkit. The interfaces and steps for creating a new PDA backend implementation are provided below. This document provides an overview of the Entando Process Driven Apps (PDA) plugin. The initial section covers the business functionality and user facing micro frontends. The second section covers the architecture and the points of extension for the PDA plugin. The third provides a detailed technical overview for developers to add new functionality to a PDA implementation.
# Terminology
# Micro Frontend
A Micro frontend architecture is an approach to developing web application as a composition of small frontend apps. Instead of writing a large monolith frontend application, the application is broken down into domain specific micro frontends, which are self-contained and can be developed and deployed independently.
# Process Automation Manager (PAM)
A business process automation engine built and maintained by Red Hat
# Business Process Modeling Notation (bpmn)
Business Process Model and Notation (BPMN) is a graphical representation for specifying business processes in a business process model.
# Decision Model and Notation (dmn)
Decision Model and Notation is a standard published by the Object Management Group. It is a standard approach for describing and modeling repeatable decisions within organizations to ensure that decision models are interchangeable across organizations.
# Back End for Front End (BFF)
A microservice architecture allows teams to iterate quickly and to develop technology to scale rapidly. The Backend for Frontend (BFF) architecture is a type of pattern built with microservices. The key component of this pattern is an application that connects the front-end of your application with the backend. This BFF Code Pattern will help you build that component according to IBM’s best practices.
# PDA Micro Frontends
This section provides an overview of each of the micro frontends (MFE) that are available as part of the Entando PDA plugin. In cases below where there are details specific to the PAM implementation they are provided for that MFE. When extending the integration layer to other engines or custom implementations it will be up to the integrating team to define behavior and datasource for each MFE.
# Task List
The task list MFE provides a user with a list of visible tasks that are either assigned to that user or that are potentially ownable by that user. In the default implementation the visible tasks are limited to a single process instance. At configuration time the application designer is given the option to select a set of columns that will be visible in the task list for that page.
# PAM Implementation
The default PAM implementation makes the top level task fields available in the task list for selection. It is possible to fetch task and process variables for rendering in the task list but these values are excluded by default due to the additional API call overhead required.
# Task Details
The task details MFE renders detailed information about a given task. The task details widget is intended to give the final user processing a task the information necessary to complete the task at hand. The task details are rendered in a read only grid. See the styling section below for changing and customizing the layout.
# PAM Implementation
The PAM integration renders task variables in the task details widget.
# Task Comments
The task comments MFE gives the user the ability to view notes attached to a given task and to add new notes to a task.
# PAM Implementation
The PAM implementation reads and publishes notes to the comments endpoint
# Task Forms
The task form implementation renders a form specific to a task and gives the user the ability to complete that form. The form implementation is a wrapper around a JSON schema that describes the layout, style and content of the form. It is up to the backend implementation to transform to the schema and default ux layout needed to render the form. See the technical documentation below for more on the JSON schema based implementation.
# PAM Implementation
The PAM implementation of forms depends on the presence of a form definition being present on the PAM task. The Entando PAM engine implementation transforms from the PAM format to the JSON schema to render the form. And it transforms the API format back to the PAM format based on the form definition in PAM. There are some limitations on form customization due to the format required to return data to PAM. See the forms section in the technical documentation for more information.
# Attachments
The attachments MFE gives the user to view documents attached to a task/case/process and to add new documents to a task/case/process.
# PAM Implementation
The PAM implementation posts the documents to the PAM endpoints for storage. Future features will include using Entando document storage for storing documents and a pluggable document management interface.
# New Process Form
The new process form renders a form that allows the final user to provide the information necessary to instantiate a new business process instance. The technology for generating the process form is the same as the JSON schema definition used for task forms. === PAM Implementation The PAM implementation depends on a form definition being attached to the process definition. Entando transforms the PAM representation into a JSON schema form that can be rendered to the final user.
# Summary Card
The summary card MFE provides a view into aggregate data for the process implementation. The rendered information includes a total value, a trend value, and a selector for timeframe. The summary card allows the application developer to select a request for rendering the requested information which maps to a call in the underlying engine to provide the summarized data.
# PAM Implementation
The PAM implementation of the summary card widget relies on the PAM custom query functionality. The PAM PDA engine exposes configuration that allows users/developers to define a custom query in a config file that will be executed to render the summary card. This implementation allows the data rendered on the summary cards to be changed via configuration. In the application there is a properties file that allows the implementer to provide a custom query for each of the cards.
# Totals Over Time
The totals over time MFE provides a dual axis line/bar graph providing trend information about the process environment. The MFE also provides three summary values for comparison over the same time period.
# PAM Implementation
The PAM implementation of the totals over time MFE utilizes custom queries to fetch the summary data rendered in the chart. The queries used in the implementation are defined in configuration files in the MFE and can be updated to render data specific to a given implementation.
# Customizing the Process Driven Application
# Styling
The Entando PDA MFEs are styled via a material UI theme. That theme can be downloaded and updated here: https://github.com/entando/frontend-libraries/tree/master/packages/entando-ui (opens new window)
# Implementing a New Engine or Integrating a New Task Source
Implementing a new Engine for Process Driven Applications means to create a new Java Project and implement the interfaces defined in the pda-core-engine project. So, the new project should include the pda-core-engine as a dependency. To see an implementation in action, take a look at the pda-redhatpam-engine project, which implements the Red Hat PAM engine integration. After the engine is implemented, the JAR file resulting from the implementation should be available in the classpath for entando-process-driven-plugin, which is the project that is ultimately executed and exposes the Rest APIs for the frontend application. One way to do that is by publishing the engine implementation to a Maven repository and adding it as a dependency to the entando-process-driven-plugin project. Below are the descriptions of the key classes and interfaces in the pda-core-engine project that need to be inherited or implemented when creating a new engine implementation:
Engine: This class represents a BPM engine and exposes the services that are available for that specific implementation. It is intended to be inherited and the subclass should provide the real implementation for each service by calling the superclass constructor with the service implementations as arguments. If any service is not supported, a null value should be passed to the corresponding constructor argument. The engine can provide implementations for the the following service interfaces:
TaskService: defines service methods for task retrieval from the BPM engine.
TaskDefinitionService: defines service methods related to task definition. A task definition specifies which fields or columns are available for all task instances.
TaskCommentService: defines service methods related to task comment manipulation. It should be implemented if the task comment is supported by the engine.
TaskAttachmentService: defines service methods to operate on task attachments. It should be implemented if the engine supports file attachment on the task.
TaskFormService: defines service methods for task form operations, like retrieving the form definition and submitting a form. The Form object can be used to render a form dynamically.
TaskLifecycleService: defines service methods related to the task lifecycle. The lifecycle operations move the task from one state to another.
TaskLifecycleBulkService: defines methods for bulk lifecycle operations. Like the TaskLifecycleService, methods here move the task from one state to another, but this interface works with multiple tasks at a time.
ProcessService: defines service methods for process definitions operations.
ProcessFormService: defines service methods for process form operations, like retrieving the form definition and submitting a form. The Form object can be used to render a form dynamically.
GroupService: define service methods related to groups from the BPM engine.
# Creating a new PDA MFE
There are no limitations on the stack that could be used to create PDA
MFEs. Custom Elements are a great way to hide implementation details
while providing a neutral interface to others. To create a simple PDA
MFE, implement your solution using technologies you are familiar with
and wrap it in a custom element. Build your solution with a custom
element and upload the built files (Settings > File Browser) in
/public/ folder. Go to UX Pattern > Widget
section of the admin panel
and press “Add” to add a new widget. Enter widget code, titles, select
group (for free access to everybody, select “Free Access”), and fill the
Custom UI:
<#assign wp=JspTaglibs["/aps-core"]>
<script src="<@wp.resourceURL />path/from/static/bundle.js"></script>
<your-custom-element parameter=”value” />
<#assign wp=JspTaglibs["/aps-core"]>
- provides access to wp variable
that is used to get resource URL. After you add the widget, go to the
page tree, select a page where you would like to use the widget and
configure it. Drag and drop the widget into a frame and publish the
page.
# Communication between MFEs
Communication between MFEs can be achieved using Custom Events. Each widget can define events that it will emit and register to events that are important to it.
const createWidgetEvent = eventType => {
return payload => {
const widgetEvent = new CustomEvent(eventType, { payload });
window.dispatchEvent(widgetEvent);
};
};
const subscribeToWidgetEvent = (eventType, eventHandler) => {
window.addEventListener(eventType, eventHandler);
return () => {
window.removeEventListener(eventType, eventHandler);
};
};
Custom element then creates the events it emits and registers to the events that it wants to react to
constructor(props) {
super(props);
// other code
this.onClickSubmit = createWidgetEvent(‘myWidget.onSubmit’);
}
connectedCallback() {
// other code
this.unsubscribeFromWidgetEvents = subscribeToWidgetEvent(
‘otherWidget.onClickClear’,
() => {
// callback function when otherWidget fires the onClickClear custom event
}
}
}
# Technical Documentation
# Micro Frontend Overview
# Task forms
Widgets containing form (e.g., task completion form widget) use JSON schema to dynamically create forms. Widget implementation uses react-jsonshema-form library that converts forms’ JSON schemas into React components. Our initial implementation uses Material UI components via Material UI theme library rjsf-material-ui as baseline and has Entando specific templates, widgets and fields (which are react-jsonshema-form terms for parts of forms). In this section you will learn about basic setup of the form, but if you would like to learn more, please refer to react-jsonshema-form documentation. Themed JSON form is created using the withTheme() method from the react-jsonschema-form package
import { withTheme } from 'react-jsonschema-form';
import { Theme as MuiRJSForm } from 'rjsf-material-ui';
const JSONForm = props => {
const ThemedForm = withTheme(MuiRJSForm);
// ...
return (
<ThemedForm
schema={formSchema}
uiSchema={uiSchema}
{...customTemplates}
widgets={customWidgets}
formData={formData}
onSubmit={e => onSubmitForm(e)}
>
);
};
export default JSONForm;
For JSON Form to work, the form schema is mandatory. It’s a JSON definition of the form’s structure. Users can also provide form data via formData variable, which should follow the structure of JSON schema; and UI schema using uiSchema variable, which allows users to customise the form’s UI (components, rules, types, etc.) To test JSON schema, UI schema and form data, you can use react-jsonschema-form sandbox environment. Custom Entando templates, widgets, and fields provide a possibility to customise the layout of the form using Grid components. To specify what area a field or subform should fill, users can provide size parameter in UI schema’s ui:options object. Size refers to Material UI’s grid column widths (Material UI documentation) where the area the from can take up is divided into 12 columns and value 12 (a default value if size is not provided) means the field or subform should take up all 12 columns. That means that size should be a value from 1 to 12. If two fields that are next to each other have size values 8 and 4 respectively - they will fit into one row, first field being 2 times wider than the second field. User can also provide innerSize parameter to size the input inside the field. This helps with formatting - if user wants a two column layout and have smaller input fields inside these columns. Multicolumn layout can also be achieved using generateColumnedOFT(columnSize) functionality, basically providing the default columnSize to the created form. generateColumnedOFT returns an ObjectFieldTemplate that is used as a template for all object fields (fields that contain properties inside of them). To help us understand the mapping between JSON schema and UI schema lets define an example schema:
{
"$schema": "http://json-schema.org/draft-07/schema#",
"$id": "http://entando.org/schemas/pda-form.json",
"title": "Mortgage Application Form",
"type": "object",
"properties": {
"Application": {
"title": "Application",
"type": "object",
"required": [],
"properties": {
"mortgageamount": {
"type": "integer",
"title": "Mortgage amount",
"description": "Mortgage amount"
},
"downpayment": {
"type": "integer",
"title": "Down Payment",
"description": "Down Payment"
},
"applicant": {
"title": "Applicant",
"type": "object",
"required": [],
"properties": {
"name": {
"type": "string",
"title": "Name",
"description": "Name",
"maxLength": 100
},
"annualincome": {
"type": "integer",
"title": "Annual Income",
"description": "Annual Income"
}
}
},
"property": {
"title": "Property",
"type": "object",
"required": [],
"properties": {
"age": {
"type": "integer",
"title": "Age of property",
"description": "Age of property"
},
"address": {
"type": "string",
"title": "Address of property",
"description": "Address of property",
"maxLength": 100
}
}
}
}
},
"inlimit": {
"type": "boolean",
"title": "Is mortgage application in limit?"
}
}
}
From this JSON (you can copy & paste it into the react-jsonschema-form
sandbox) we can see that there is a main form with a title “Mortgage
Application Form”. Root “Mortgage Application Form” form has two
properties - one is a subform Application
and the second one is just a
checkbox field (field ID is inlimit). Application subform contains 2
fields: Mortgage amount (field ID is mortgageamount) and Down Payment
(field ID is downpayment); and two subforms - Applicant (field ID is
applicant) and Property (field ID is property). Applicant subform
contains 2 fields - Name (field ID is name) and Annual Income (field ID
is annualincome). Property subform contains 2 fields - Age of property
(field ID is age) and Address of property (field ID is address) By
default (without providing UI schema) they are all listed one field per
row. To use Entando’s implementation of Grid layout, users have to
provide UI schema with details about each field. For example, if we
would like to have a layout that looks like this (fields are marked
[ field name ]
):
+----------------------------------------------------------------------------+
| Mortgage Application Form |
+----------------------------------------------------------------------------+
| Application |
+----------------------------------+-----------------------------------------+
| [Mortgage amount] | [Down Payment] |
+----------------------------------+-----------------+-----------------------+
| Applicant | Property |
+----------------------------------+-----------------+-----------------------+
| [Name] | [Annual Income] | [Age of property] |
+----------------------------------+-----------------+-----------------------+
| | [Address of property] |
+----------------------------------------------------+-----------------------+
To set up the UI schema you have to define each field you want to customise by addressing using the field IDs - to add options to Applicant’s Name field, you will have to create an object tree going from root object through Application —> Applicant —> Name (using IDs it’s Application.applicant.name). UI schema for the table layout defined above would look like this:
{
Application: {
'ui:options': {
size: 12, // <-- this value is not mandatory as size is 12 columns-wide by default
},
mortgageamount: {
'ui:disabled': true, // <-- user can define fields disabled at UI schema level
'ui:options': {
size: 6, // <-- Mortgage amount field should take up half of the row
},
},
downpayment: {
'ui:options': {
size: 4, // <-- Down payment field should take up the other half of the row
},
},
applicant: {
'ui:options': {
size: 8, // <-- Applicant subform should take up 8 out of 12 columns
},
name: {
'ui:options': {
size: 8, // <-- Applicant name field should take up 8 columns in the 8 columns that Applicant subform occupies
},
},
annualincome: {
'ui:options': {
size: 4, // <-- Annual Income field taking up the remaining 4 columns
},
},
},
property: {
'ui:options': {
size: 4, // <-- Property subform should take up the remaining 4 out of 12 columns
},
// note that property's fields are not mentioned - defaulting them to 12 columns in are that is available to them
},
},
};
As Material UI components are used for field templates, there might be a need to pass some Material UI options into the field. You can do that by adding muiProps object to the ui:options.
For example, if you would like to make the Down payment field resizable, you can add multiline: true to muiProps option. If you want to make the field take up multiple rows by default, add rows and rowsMax fields. The latter limits how many rows should be added until the scroll bar is shown.
downpayment: {
'ui:options': {
size: 4,
muiProps: {
multiline: true,
rows: 2,
rowsMax: 4
}
}
}
# Widgets
Different types of widgets can be applied by passing the type via "ui:widget". Property tells the form which UI widget should be used to render a field. You can read about react-jsonschema-form supported widgets here.
# Building From source
Reference the component projects for instructions to build from source. https://github.com/entando/entando-process-driven-plugin (opens new window) https://github.com/entando/entando-process-driven-plugin/tree/master/widgets (opens new window) https://github.com/entando/pda-redhatpam-engine (opens new window) https://github.com/entando/pda-core-engine (opens new window)
# Code Style
See: https://github.com/entando/entando-code-style (opens new window)
# Sonar
https://sonarcloud.io/organizations/entando/projects (opens new window)