BPMN 1.2 tutorial
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Introduction
This article provides a short overview of BPMN 1.2. BPMN is a so-called flowcharting notation language for defining a so-called business process in terms of connected activities, events and gateways.
See also: Business process modeling (for background information), BPMN (overview and links including software) and BPMN 2 tutorial
Overview of BPMN 1.1/1.2 (2008/9)
According to the BPMN 1.2 specification, “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. Thus, BPMN creates a standardized bridge for the gap between the business process design and process implementation. Another goal, but no less important, is to ensure that XML languages designed for the execution of business processes, such as BPEL4WS (Business Process Execution Language for Web Services), can be visualized with a business-oriented notation.”
BPMN 1.2 is a so-called notation language, i.e. it allows to "draw" the design of a business process, i.e. the coordination of human and computer workflows in an organization. In computer science, its closest kin is the UML activity diagram. Like some UML languages, BPMN is a kind of flow-charting language. However, the specification includes an informal annex that defines possible mapping to BPEL (more precisely the BPEL4WS version), a process execution language. In addition, vendors also could implement translators to any sort of execution environment. BPMN 2 (to be finalized by the end of 2010) defines its own serialization format.
BPMN core elements
BPMN is a fairly complex and rich language. According to the 1.2 specification, BPMN has 11 core elements for defining a business process and that can be grouped in four categories:
- (a) Flow Objects
- define the behavior of a business process and are the most important constituent elements of process diagrams.
- Types: (1) Event (start, intermediate, end), (2) Activity (task, sub-process and process), (3) Gateway (various)
- (b) Artifacts (Artefacts)
- are used to provide extra information about the process
- Types: (4) Data Object, (5) Group, (6) Annotation
- (c) Swimlanes
- group elements into processes performed by entities
- Types: (7) Pool, (8) Lane
- (d) Connecting Objects
- connect flow objects and artifacts (above) to each other
- Types: (9) Sequence Flow, (10) Message Flow, (11) Association.
With the help of these connecting objects, process diagrams can be structured in three ways:
- Sequence flows define an order of activities performed in a process. Each flow has a single source (a start event, activity or gateway) and a single target (a end event, activity of gateway). Elements of a sequence flow are connected with solid arrows.
- Message flows either connect two pools or flow objects within these pools. As opposed to sequence flows, they cannot connect objects within the same pool. Message flows are represented with dashed arrows.
- Associations associate flow objects with information and artifacts and are drawn with dotted lines.
Message and sequence flows are usually drawn orthogonally, i.e. sequence goes in one direction (either top->down or left->right) and messages in the other as the following picture shows.
The BPMN 1.2 extended set
Most of the eleven core elements can by typed, e.g. an event can be either "none" (default), start, intermediate or end event. These sub-types then can be further "augmented", e.g. events may have an associated trigger. As an example, the start event may be a message start event (the process is triggered (starts) after receiving a message from an other participant)
Below is a simple example of a pedagogical scenario. Tutor hands out a reading assignment, learner reads the book and then creates a summary with a online tool. The teacher will receive a message and then can provide some feedback. The student then has a revise it and the teacher will grade it after some deadline.
- Disclaimer: This is my first BPMN drawing, not sure that is correct - DKS/July 5/2010
As you can see in the figure, tasks also can be typed. In this simple scenario, we use "manual tasks" (user reading a book), computer-supported "user tasks" (using the hand symbol) and a message task.
Notice: I am not sure what can be done with data objects (in the model they are linked to more than one task, this may not work - Daniel K. Schneider 16:35, 20 July 2010 (UTC)
We will introduce some of these extended set further below.
BPMN process syntax and semantics
It is important to understand that there are many restrictions on how BPMN elements may be combined. The specification is easy enough to understand, but it is very difficult to get a global picture, i.e. what combinations of elements to use for a given process.
Overally speaking, the rules for connecting elements of a business process are fairly simple. Look at the previous figure for an example of a simple process that includes two participants (i.e. two sequence flows) and a message flow between these participants.
- Sequence flow rules
- Any flow object of start event, intermediate event, task, sub-process, gateway can connect to intermediate event, task, sub-process, gateway and end event. Or the other way round: no object can connect to start event, and end events cannot connect other events.
- Objects within subprocesses cannot connect to objects outside this process.
- Sequence flows cannot cross a pool boundary, use messages or signals for this purpose
- Message flow rules
- pools, subprocesses, tasks, intermediate message events and end message events can connect to pools, subprocesses, tasks, start message events and intermediate message events. Within this list, only start and event events behave differently: Start message events can only receive a message, but not send a message. End message events can only send messages but not receive messages. Let's recall that start events start a process and end events end a process.
There are no limitations with respect to drawing, exit and entry points of connecting lines can be anywhere on the border of an object. However, it is obvious that a flow diagram should be as simple as possible (mostly straight lines and little overlaps).
Data modeling and execution
BPMN 1.x does not specify any language that might be used as input for an workflow execution engine. Actually, it doesn't even specify a representation (serialization) language for the drawings.
In other words, your drawings are neither portable nor executable
Some vendors provide tools for exporting/importing their BPMN 1.x diagrams to their own workflow/web services framework. Some can import/export to XPDL, however many authors claim that BPEL is not the holy grail for BPM.
Another difficulty relate to the sometimes not very clear connecting objects semantics of BPMN 1.2 or maybe implementations we played with were incomplete. It seems that the question whether BPMN Semantics is "Vague" or Just Hard to Code? remains open.
Finally, it seems that a given problem can be modeled in many different ways and we wonder how this could affect potential execution models.
Below, as an example, we sketch out the whole process as it is implemented in Bizagi Studio and its built-in development runtime engine.
(1) We first did another take of the simple reading/summarizing assignment example shown above. We used a single pool, i.e. considered that this scenario was to be modeled as a single workflow. We then had to replicate the same data object representing the summary a learner had to write and which we meant to be a wiki page into three separate objects matching three versions.
This model then wasn't valid for the Bizagi Studio BPM Suite, since the latter expects data objects to be associated with a single task. We got 4 error messages complaining that "the data object must be associated with an activity". Actually they were, but with two for each .... Anyhow, we modified the model like this:
(2) In a next step (once a model is imported into a BPM(N) engine, one must model the data. The whole process is represented as one or more entities with attributes. This is IMHO the most difficult step (harder than modeling the process itself .... more later).
(3) After data is modeled, one can define user input forms, i.e. the user interface that will be used by the execution engine.
BPMN 1.2 event elements
An event is something that "happens" during a process and it will affect the flow of the process. It usually has either a cause or an impact or both. In more operational terms, events will affect the sequence of the timing of process activities.
There are three main types of events: start events, intermediate events and end events.
- Events are represented as small circles and fills must be either white (no color) or use a clear color.
- Start events have a fine stroke, intermediate events a double fine stroke, and end events a fat stroke.
- Inside the circle there can be shape that helps identifying a trigger. As you can see below, the various event types can be associated with various triggers, but not all triggers are available for each of the three start, intermediate and end event.
Start Events
Start events indicate the initiation of a process and are usually associated with a trigger. The five types of triggers defined by v. 1.1 are represented with graphical markers.
- Plain (generic) start events
- do not specify any trigger
- Message start events
- start when a message is received from an other participant
- Timer start event
- indicate a given time/date for starting
- Conditional start events
- a process is triggered when certain business conditions become true.
- Signal start events
- A signal arrives that has been broadcasted from another process
- Multiple start events
- Defines multiple ways of triggering a process.
Intermediate events
There are 10 types of intermediate events in BPMN 1.2. All of these can respond to (catch) a trigger and some can set off (throw) a trigger. Catching events (only) also can be directly attached to the boundary of an activity.
Events are drawn as double circle. Catching event markers are drawn with strokes and throwing events are drawn filled.
- Simple ("none") intermediate event
- Events in the main flow of the process that are not further specified.
- Message (catching and throwing) intermediate events
- When catching, a message arrives from a participant and triggers the Event. If the process was waiting for the message it then can continue. Messages also can be used for exception handling, i.e. the process will continue differently.
- When throwing in normal flow, a message is sent to another participant.
- Summarized, messages are used to receive/send between 2 participants A and B.
- Timer (catching) intermediate event
- A set time/date will trigger the event, i.e. also inserts a delay
- Error (catching) intermediate event
- Only can be used in the boundary of an object. Can either catch a named error or all errors if none is specified
- Cancel (catching) intermediate event
- This cancel event must be used in the boundary of a transaction subprocess. It can be triggered either by a message or by a cancel end event in the subprocess.
- Compensation (catching and throwing) intermediate events
- When catching, a compensation activity attached to this event will be triggered.
- In normal flow, when throwing an event is defined, this event will be triggered, else "compensation" is broadcasted to all activities in the process.
- Conditional (catching) intermediate event
- Event is triggered when a condition becomes true
- Link (catching and throwing) intermediate event
- Links connect two sections of a process (at the same level), e.g. to implement looping, goto or simply move to a "next page". There can be multiple source, but only one target link.
- Signal (catching and throwing) intermediate event
- Signals can be sent and received across process levels, pools and even diagrams. As opposed to messages, targets cannot be identified, i.e. there is always a specific source (throwing) but specific target. In other words, a signal is like a flare. Catching events must be attached to the boundary of an activity.
- Multiple (catching and throwing) intermediate event
- In normal flow, a multiple event can either catch or throw various events. When attached to an activity it can only catch.
End events
- Simple ("none") end event
- showing that and where a process ends
- Message end event
- indicates that a message is sent to a participant when the end of the process is reached
- Error end event
- an error code should be generated. This code then can be caught by an error catching intermediate event in the parent. If there is none, then the system also can handle this.
- Cancel end event
- is only used in transaction sub-processes and will signal that this transaction should be cancelled.
- Compensation end event
- can either compensate an activity that is identified. Otherwise all activities in the process can be subject to compensation if they have a compensation intermediate event attached.
- Signal end event
- a signal is generated. It will be broadcasted to any process (i.e. signal catching events) that can receive it. A signal is different from a message. The latter always has a source and a target.
- Terminate end event
- triggers an immediate end to the process and all its activities. The process is ended without compensation of event handling.
- Multiple end event
- multiple consequences of ending the Process.
Activities
An activity stand for the work that company performs. An activity can be atomic or non-atomic (compound). The types of activities that are a part of a Process Model are:
- Tasks, represented by rounded rectangles plus (optional) additional markers
- Sub-Processes, rounded rectangles (when collapsed with a + sign)
- Processes, represented with swimlanes (i.e. either pools with lanes or simple pools, both can be collapsed)
Simple task markers
An "atomic" (simple) task is a simple activity performed within an organization. A task correspond to an activity step in the process flow that cannot/should not be broken further down. Generally speaking, a task is either performed by a human, a computer application or both (i.e. a user using an application)
BPMN defines three basic kinds of tasks that are visually defined with markers which must adopt the form specified and be at the bottom of the rectangle. The compensation marker can be used together with loop or multiple instance.
- (1) Loop
Loops are repetitive tasks and include a test that defines if a task is to be repeated after each cycle of the loop (p. 54/p.65). May be used together with the compensation and multiple instance markers.
Standard loop attributes include:
- (a) LoopCondition - Expression
- Expressions are defined with respect to a scripting language, i.e. the modeler must both provide a string defining a scripting language and a valid expression.
- (b) LoopCounter - Integer
- Counts the cycles and may be used in the condition
- (c) LoopMaximum - Integer
- Defines maximum loops
- (d) TestTime - "Before"/"After"
- Defines either a while or until type of loop, i.e. the loop condition is tested before or after each cycle
- (2) Multiple instance loops
- Are a variant of loops and define for instance whether loop instances will perform in parallel or sequentially. Multiple instances also allow to define gateways after parallel path, i.e. where the "token" will go.
- (3) Compensation
- A compensation activity is special sicne it does not follow the normal sequence flow rules (p. 130). A compensation is one of the three types of "undo" activities: overwrite any changes (revert), do nothing, or invoke an activity that undoes the effects. The latter is called compensation. E.g. a student may turn in a late assignment and will get 10% off. If later, the student will show a medical certificate, then he will get the 10% reimbursed. However, and this is why it's not a simple undo, his assignment is still "done".
Simple task types
In addition to these task markers, BPMN defines so-called task types. There is no standard graphical representation for these. Implementors can choose their own and also are allowed to add additional types (something that we certainly would need for education).
- (1) Service task
A service task provides some sort of service like a web service or another automated application
- (2) Receive task
A Receive Task is designed to wait for a message to arrive from an external participant (relative to the Business Process). The receive task:
- can't have an incoming sequence flow
- the incoming sequence flow has a Start Event
- it is completed once the message is received
- (3) Send task
Send Task is designed to send a message to an external participant (in another pool, relative to the Business Process)
- The task is completed once the message is sent.
- (4) User task
The user task is a typical “workflow” task where a human performer performs the Task with the assistance of a software application.
- A user task is scheduled through a task list manager of some sort
- (5) Script task
A Script Task is executed by a business process engine. The modeler or implementer defines a script in a language that the engine can interpret.
- When the Task is ready to start, the engine will execute the script and the task is completed at the completion of the script.
- (6) Manual task
A Manual Task is expected to be performed without the aid of any software (like a business process execution engine, a web service or any other kind).
- (7) Reference task
When modeler may want to reference another task that has been defined (exactly the same behavior attributes)
As we already explained above, there exist some rules for both sequence flow connections and message flow connections. In addition:
- A task may have multiple sequence incoming flows although this is not recommended, i.e. one should use a gateway before the task to control flows in different paths
- ... (to do)
Sub-processes
A sub-process is a compound activity within a flow of other activities (p. 56). It has several purposes and comes two variants and serveral sub-variants.
An expanded sub-process can be used to (a) associate this compound activity with exception handling, (b) with compensation handling, and finally (c) implement parallel activites in a less cluttered way than using gateways.
A collapsed sub-process may be used to hide detail within a complex process. Collabsed (only) sub-processes then can then include a combination of up to three Loop Marker, Parallel Marker, Compensation Marker, and Ad Hoc Marker. Loop cannot be used with parallel (i.e. multiple instance).
Gateways
(to do)
Swimlanes
(to do)
Artifacts
Data objects
Data objects do not directly affect sequence or message flows. They provide information about what the process does, i.e. how data, documents and and sort of other objects are used and updated during the process.
PBMN doesn't model artifacts themselves, this task is left to vendors according to the specification (p 93.). We found the specification to very vague with respect to these objects and indeed various modeling tools we tried (Aris Express, Bizagi Process Modeler, Bizagi Studio) won't allow to use data objects in the same way - Daniel K. Schneider 17:58, 21 July 2010 (UTC).
Data objects are generally associated with flow objects (typically a task). In that case they can represent input or output with directional arrows.
They also can be attached to sequence and message flows in order to show what data are sent from one activity to another. In the case of a message flow, the data object represent the "content" (payload) of the message itself.
The data object includes a name, a state and various modeler-definable properties. The latter then can be mapped to a data model in an execution engine.
Some design patterns for connecting objects
(to do)
Examples
Model of a discussion
Email voting process
Model of surgery programming
The process model presented by Roja et al. (2008) shows at a high level abstraction the programmed surgical patient (PSP) process and the activities that are carried out when a patient is admitted into the hospital for the accomplishment of the surgical treatment of a disease that has been clinically diagnosed previously. This model is a result of a joint work between hospital and BPMN expert and it has been obtained through a reiterative and incremental method.
“The modelling of the programmed surgical patient process and its subprocesses has allowed to us to prepare an understandable model for the involved health professionals and make the communication of processes easier. Additionally, modelling allows early detection and correction of errors. This work is an essential previous step for further analysis and improvements in healthcare processes, including the adoption of information technology standards.” (Roja et al. (2008))
A BPMN 1 meta model
A more difficult to understand meta-model (i.e. an inofficial UML class diagram of BPMN was published by WSPER ("whisper").
Links and bibliography
See BPMN for more links and references
- Dive into BPMN
- Modeling Workflow Patterns through a Control-flow perspective using BPMN and the BPM Modeler BizAgi by Marcus Goetz, Institute of Applied Informatics and Formal Description Methods University Karlsruhe (TH).
- BPMN_Tutorial.pdf by Martin Owen and Jog Raj, Popkin Software