Difference between pages "Code Generation Activity" and "Code Generation Tutorial"

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Tasking Event-B is the extension of Event-B for defining concurrent systems sharing data, for details see the [[Tasking Event-B Overview]] page. For more information contact Andy Edmunds - University of Southampton - mailto:ae2@ecs.soton.ac.uk, or Chris Lovell mailto:cjl3@ecs.soton.ac.uk
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'''This Page is Under Construction!!!!'''
  
 +
=== Tutorial Overview ===
  
 +
The aim of the tutorial is to allow users to explore the approach with a relatively simple example. The example uses a shared buffer with reader and writer processes. The tutorial is presented in three stages, making use of the example projects from the download site. There are two translations performed, one is to a common language model (IL1). The second is to an Event-B project which includes a model of the implementation. There is a PrettyPrinter for Ada source code, which uses the common language model. An overview of Tasking Event-B can be found at http://wiki.event-b.org/index.php/Tasking_Event-B_Overview.
  
== Code Generation Feature - Version 0.2.3 For Rodin 2.5==
+
A typical Event-B development may be refined to the point where it is ready for implementation, but the Event-B language is not expressive enough to fully describe the implementation. Tasking Event-B facilitates this final step to implementation, by extending Event-B with the necessary constructs. Event-B machines that are to be implemented (and their seen Contexts) are selected and added to a ''Tasking Development''; the Tasking Development files have the file extension ''.tasking''. The machines in the Tasking Development are then extended with implementation details.
A new release of the tool is imminent.
 
  
The main new features are:
+
The example/tutorial projects are,
  
* Code generation from [http://wiki.event-b.org/index.php/State-Machines_and_Code_Generation state-machine] diagrams.
+
{| border="1"
* Improved static checking.
+
|SharedBuffer20100819Demo
 +
|An example project with a completed Tasking Development and IL1 model (post IL1 translation, but before Event-B translation).
 +
|-
 +
|Sharedbuffer20100819Tasking
 +
|Same as the example project above, but with Event-B model translations. The difference being that this development includes a model of the implementation. These are refinements that include a program counter to describe flow of execution in each task.
 +
|-
 +
|SharedBuffer20100819Tutorial
 +
|A bare project for step 1 of the tutorial.
 +
|-
 +
|Sharedbuffer20100819Tutorial2
 +
|A partially completed tasking development for steps 2 and 3 of the tutorial.
 +
|}
  
We have also provided some details of the [http://wiki.event-b.org/index.php/The_Use_of_Theories_in_Code_Generation use of Theories in code generation], from the previous version.
+
== Preliminaries ==
 +
Before further discussion of the modelling aspects, we take a look at the PrettyPrint viewers. The PrettyPrinters make the viewing of IL1 and tasking models easier; it also provides a route to generate source code. The source code can easily be pasted from the IL1 Pretty Printer window into an the Ada source file .  
 +
==== The PrettyPrint View of a Tasking Development ====
 +
To open the Tasking PrettyPrint viewer,
 +
* from the top-menu select ''Window/Show View/Other/Tasking Pretty Printer''.
  
Updated Examples etc. are available:
+
Note that the Tasking PrettyPrinter may have to be closed when editing the Tasking Development, since it can give rise to exceptions. The PrettyPrinter would need further work to make it robust, however it is intended only as a short-term solution.
 
* Tutorial, and example, projects are available from the Examples directory: [https://codegenerationd.svn.sourceforge.net/svnroot/codegenerationd/Examples/v0.2.3/ SVN].
 
* Test projects are also available from the Examples directory [https://codegenerationd.svn.sourceforge.net/svnroot/codegenerationd/Examples/v0.2.3/Tests SVN].
 
* Sources (will be) available at: [https://rodin-b-sharp.svn.sourceforge.net/svnroot/rodin-b-sharp/trunk/CodeGeneration SVN]
 
* Example Theories at: [https://codegenerationd.svn.sourceforge.net/svnroot/codegenerationd/Examples/TheoriesForCG SVN]
 
  
== Code Generation Feature - Version 0.2.2 For Rodin 2.4==
+
* Open the ''SharedBuffer20100819Demo'' Project and switch to the Resource Perspective.
 +
* Open the ''.tasking'' model and inspect it. Clicking on the Main, Machine or Event nodes updates the pretty print window.
  
We released V0.2.2 on 22-03-2012. The main changes, to the interface, and translation from theories are described below:
+
==== Viewing Source Code ====
 +
aka. The PrettyPrint View of an IL1 Model.
  
* Tasking Event-B is now integrated with the Event-B Editors.
+
To view Ada source code,
* We have the ability to translate to C, Java, etc. in addition to Ada source code.
+
* from the top-menu select ''Window/Show View/Other/IL1 Pretty Printer''.
* We use theories to define translations of the Event-B mathematical language (Theories for Ada, Java and C are supplied).
+
* Open the ''SharedBuffer20100819Demo'' Project and switch to the Resource Perspective.
* We use the theory plug-in as a mechanism for defining new data types , and the translations to target data types.
+
* Open the ''.il1'' model and inspect it. Clicking on the Protected, Main Entry, or Task nodes updates the pretty print window.
* The translator is extensible.
 
* Minimal use is made of the EMF tree editor in Rose.
 
  
To install v0.2.2:
+
==== Cleaning the Tasking Development ====
 +
If the ''.tasking'' file has errors, then it may need cleaning. To do this right-click on the ''Main'' node, select ''Epsilon Translation/CleanUp''. If a model has errors it can still be viewed by clicking on the ''Selection'' tab at the bottom of the tasking editor window.
  
* Access the main Rodin Update Site. In Eclispe click on Help/Install new Software. Find the Rodin update site from the list. In Utilities add Code Generation.
+
== The Tutorial ==
The approach makes use of the following, which should be installed if the features are required by the user for editing:
+
The steps needed to generate code from an Event-B model, in this tutorial, are as follows,
*Model Decomposition: Download from the main Rodin Update Site, in the Decomposition section.
+
* Step 1 - [http://wiki.event-b.org/index.php/Code_Generation_Tutorial#Creating_The_Tasking_Development Create the tasking development].
*Shared Event Composition: Download from the main Rodin Update Site, in the Decomposition section.
+
* Step 2 - [http://wiki.event-b.org/index.php/Code_Generation_Tutorial#Providing_the_Annotations_for_Implementations Add annotations]
*Theory Plug-in: Download from the main Rodin Update Site, in the Modelling Extensions section.
+
* Step 3 - [http://wiki.event-b.org/index.php/Code_Generation_Tutorial#Invoking_the_Translation Invoke translators].
  
Examples available at:
+
==== Creating The Tasking Development ====
+
* Change to the Event-B Perspective.
* Tutorial, and example, projects are available from the Examples directory: [https://codegenerationd.svn.sourceforge.net/svnroot/codegenerationd/Examples/v0.2.2/ SVN].
+
* Open the ''SharedBuffer20100819Tutorial'' Project.  
* Test projects are also available from the Examples directory [https://codegenerationd.svn.sourceforge.net/svnroot/codegenerationd/Examples/v0.2.2/CG_v0.2.2_Tests SVN].
+
* Select the following Machines: Reader, Writer and Shared.
* Sources at: [https://rodin-b-sharp.svn.sourceforge.net/svnroot/rodin-b-sharp/trunk/CodeGeneration SVN]
+
* Right-click and select ''Make Tasking Development/Generate Tasking Development''.
* Example Theories at: [https://codegenerationd.svn.sourceforge.net/svnroot/codegenerationd/Examples/TheoriesForCG SVN]
 
  
== Code Generation Feature - Version 0.2.1 For Rodin 2.3==
+
The new Tasking Development will not be visible in the Event-B perspective, change to the resource perspective, open and inspect the new ''.tasking'' file. The Tasking Development contains (the EMF representation of) the machines that we wish to provide implementations for. In order to introduce the new concepts we have prepared a partially complete development.  
Contains Bug Fixes for previous release. 14-12-2011
 
  
== Code Generation Feature - Version 0.2.0 For Rodin 2.3==
+
Change to the Project ''SharedBuffer20100819Tutorial2'' to begin the next step.
We released a new version of the code generator on 30-11-2011, and updated documentation.
 
===== Changes to the Tooling and Approach =====
 
The main changes are:
 
* The code generators have been completely re-written. The translators are now implemented in Java, i.e. there is no longer a dependence on the Epsilon tool set. This was undertaken for code maintenance reasons.
 
* Tasking Event-B is now integrated with the Event-B explorer.
 
* The Rose Editor is used for editing the Tasking Event-B, and
 
* a text-based editor is provided, using the Rose extension, for editing the TaskBody. This feature has been added to address some of the usability concerns. It also overcomes the 'problem' experienced with duplicate event names in a development, since the parser-builder that has been implemented automatically selects the correct event.
 
* The EMF tree editor in Rose is only used minimally; we plan enhancements to further reduce its use.
 
* Composed machines are used to store event 'synchronizations'; these are generated automatically during the decomposition process. This reduces the amount of typing in the TaskBody editor, since we no longer need to specify both local and remote (synchronizing) events.
 
* The code generation approach is now extensible; new target language constructs can be added using the Eclipse extension mechanism.
 
* The translation of target's mathematical language is now specified in the theory plug-in. This improves clarity since the the translation from source to target is achieved by specifying pattern matching rules. Extensibility is also improved; the theory plug-in is used to specify new data-types, and how they are implemented.
 
* Translated code is deposited in a directory in the appropriate files. An Ada project file is generated for use with AdaCore's GPS workbench. Eventually this could be enabled/disabled in a preferences dialog box.
 
* The Tasking Event-B to Event-B translator is now properly integrated. Control variable updates to the Event-B model are made in a similar way to the equivalent updates in the state-machine plug-in. The additional elements are added to the Event-B model and marked as 'generated'. This prevents users from manually modifying them, and allows them to be removed through a menu choice.
 
  
===== Changes to the Documentation =====
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==== Providing the Annotations for Implementations ====
The following Pages have been updated:
+
* Close any Tasking Pretty Print Viewers that remain open. The incomplete model will give rise to exceptions.
* [http://wiki.event-b.org/index.php/Tasking_Event-B_Overview Tasking Event-B Overview]
+
* Go to the to the Resource Perspective.
* [http://wiki.event-b.org/index.php/Tasking_Event-B_Tutorial Tutorial]
+
* Open and inspect the ''.tasking'' machine.
  
TODO
+
The ''WriterTsk'' and ''SharedObj'' machines are incomplete. We will take the steps to necessary to provide implementation details.  
* Add addressed variables (for direct read/write access to memory)
 
* Flattening of composed machines/implementation machines.
 
* Interrupts
 
  
=== Sensing and Actuating for Tasking Event-B ===
+
===== The WriterTsk Machine =====
Version 0.1.5. Sensing and actuating events, and an Environ Machine have been added to allow simulation of the environment and implementation using memory mapped IO.
+
In the partially complete tutorial project we already identified the ''WriterTsk'' as an ''Auto Task'' Tasking Machine, by adding the ''Auto Task'' extension. ''Auto Tasks'' are tasks that will be declared and defined in the ''Main'' procedure of the implementation. The effect of this is that the ''Auto Tasks'' are created when the program first loads, and then activated (made ready to run) before the ''Main'' procedure body runs. We have added the ''Periodic Task'' extension to the ''Auto Task'', and set a period of 250 milliseconds. We will now complete the sequence that has been partially defined in the task body.
  
* The new v0.1.5 feature is available from the Rodin Update Site, it resides in the Utilities Category.
+
*'''Add Synchronisation between TWrite and SWrite'''.
 +
** Expand the ''Auto Task Machine'' node.
 +
** Expand the ''Seq'' sub-tree.
 +
** Right-click on the ''Seq'' node and select ''New Child/Left Branch EventWrapper''.
 +
** Provide the event label ''w1'' using the properties view.
 +
** Right-click on Event Wrapper and select ''New Child/ Synch Events''.
 +
** Select ''Synch Events'' and go to the drop-down menu of the ''Local Event'' property.
 +
** At this point the drop-down box displays a number of event names, select the ''TWrite'' event.
 +
** Go to the drop-down menu of the ''Remote Event'' property.
 +
** From the list of events select the ''SWrite'' event.
  
* As in previous releases, the code generation plug-in relies on the Epsilon tool suite. Add the following Epsilon interim update site to the list of available update sites in the Eclipse menu ''help/install new software'': http://download.eclipse.org/modeling/gmt/epsilon/interim/
+
The Synch Events construct is used to implement [http://wiki.event-b.org/index.php/Tasking_Event-B_Overview#Control_Constructs Event Synchronisation]. The next step wraps an event in an Event Wrapper in order to update the local state; there is no synchronisation as such but we will re-use the constructs that already exist.
  
* Select 'the Epsilon Core (Incubation)' component, this is the only component that is required for Tasking Event-B.
+
*'''Add the Wrapped Event TcalcWVal'''.
 +
** Expand the sub-tree of the second ''Seq'' node.
 +
** Right-click on the ''Seq'' node and select ''New Child/Left Branch EventWrapper''.
 +
** Provide the event label ''w2'' using the properties view.
 +
** Right-click on Event Wrapper and select ''New Child/ Synch Events''.
 +
** Select ''Synch Events'' and go to the drop-down menu of the ''Local Event'' property.
 +
** From the list of events select the ''TcalcWVal'' event.
  
A new [http://wiki.event-b.org/index.php?title=Tasking_Event-B_Tutorial Code Generation Tutorial] has been produced, that makes use of these new features. There is an explanation of the heating controller, upon which it is based, [http://wiki.event-b.org/index.php/Development_of_a_Heating_Controller_System here].
+
We have now completed the task body, and it just remains to complete provide details for the ''TWrite'' event. The ''TWrite'' event in ''WriterTsk'' is to be synchronized with the ''SWrite'' event in the ''SharedObj''.
 +
*'''Add Event Extensions'''.
 +
** Right-click on the ''TWrite'' Event node.
 +
** Select ''New Child/Extension''.
 +
** Right-click on the ''Extension'' node and select ''New Child/Implementation'' from the menu.
 +
** Go to the Implementation properties view and set the ''Implementation Type'' property to ''ProcedureSynch''.
  
The example/tutorial projects, and also and a Bundled Windows 7 version, are available in the [http://deploy-eprints.ecs.soton.ac.uk/304/ Deploy E-Prints archive] or [https://codegenerationd.svn.sourceforge.net/svnroot/codegenerationd/Examples/HeatingController_Tutorial_v0.1.4/ Examples SVN site].
+
*'''Identify Incoming and Outgoing parameters'''.
 +
** Right-click on the ''outAP'' node and add an ''Extension''.
 +
** Right-click on the ''Extension'' and select''New Child/Parameter Type''.
 +
** Go to the ''Parameter Type'' properties view and set the ''Parameter Type'' property to ''actualOut''.
 +
** Right-click on the ''inAP'' node and add an ''Extension''.
 +
** Right-click on the ''Extension'' and select''New Child/Parameter Type''.
 +
** Go to the ''Parameter Type'' properties view and set the ''Parameter Type'' property to ''actualIn''.
  
== The Code Generation Demonstrator for Rodin 2.1.x ==
+
===== The Shared Machine =====
  
Released 24 January 2011.
+
The next step is to identify the ''SharedObj'' machine as a ''Shared Machine''. The ''SharedObj'' Machine will be extended using the Event-B EMF extension mechanism.
 +
* Right-click on the ''SharedObj'' Machine node in the ''.tasking'' file.
 +
* Select ''New Child/Extension''.
 +
* Right-click on the ''Extension'' node and select ''New Child/Shared Machine'' from the menu.
  
The Rodin 2.1.x compatible code generation demonstrator plug-ins have been released into the Rodin Sourceforge repository at:
+
We now show how to extend the ''SWrite'' event of the Shared Machine with details about its implementation. The ''SWrite'' event in ''SharedObj'' is to be synchronized with the ''TWrite'' event in the ''WriterTsk''.
 +
* '''Identify SWrite as a Syncronisation'''.
 +
** Right-click on the ''SWrite'' Event node.
 +
** Select ''New Child/Extension''.
 +
** Right-click on the ''Extension'' node and select ''New Child/Implementation'' from the menu.
 +
** Go to the Implementation properties view and set the ''Implementation Type'' property to ''ProcedureSynch''.
  
  https://rodin-b-sharp.svn.sourceforge.net/svnroot/rodin-b-sharp/trunk/CodeGeneration
+
* '''Identify incoming and outgoing parameters'''.
 +
** Right-click on the ''inFP'' node and add an ''Extension''.
 +
** Right-click on the ''Extension'' and select''New Child/Parameter Type''.
 +
** Go to the ''Parameter Type'' properties view and set the ''Parameter Type'' property to ''formalIn''.
 +
** Right-click on the ''outFP'' node and add an ''Extension''.
 +
** Right-click on the ''Extension'' and select''New Child/Parameter Type''.
 +
** Go to the ''Parameter Type'' properties view and set the ''Parameter Type'' property to ''formalOut''.
  
The update-site is available through the Rodin update site in the ''Utilities'' category.
+
To summarise, for a Shared Machine definition:
 +
# Add the ''SharedMachine'' Machine type.
 +
# For each event, define the Event Type.
 +
# For each event parameter, define the Parameter Type.
  
The code generation tutorial examples are available for download at:
+
==== Invoking the Translation ====
 
 
  https://sourceforge.net/projects/codegenerationd/files/DemoFiles/
 
 
 
The code generation plug-in relies on the Epsilon tool suite. Install Epsilon manually, since the automatic install utility does not seem to work for this feature. We currently use the Epsilon interim update site available at:
 
 
 
  http://download.eclipse.org/modeling/gmt/epsilon/interim/
 
 
 
Select 'the Epsilon Core (Incubation)' component, this is the only component that is required for Tasking Event-B.
 
 
 
=== Latest Developments ===
 
* Demonstrator plug-in feature version 0.1.0
 
** for Rodin 2.1.x version is available.
 
 
 
* The Code Generation feature consists of,
 
** a tasking Development Generator.
 
** a tasking Development Editor (Based on an EMF Tree Editor).
 
** a translator, from Tasking Development to Common Language Model (IL1).
 
** a translator, from the Tasking Development to Event-B model of the implementation.
 
** a pretty-printer for the Tasking Development.
 
** a pretty-printer for Common Language Model, which generates Ada Source Code.
 
 
 
* A tutorial is available [[Code Generation Tutorial]]
 
** Step 1 - Create the tasking development.
 
** Step 2 - Add annotations.
 
** Step 3 - Invoke translators.
 
 
 
=== Ongoing Work ===
 
 
 
* Full Rodin Integration
 
* Sensed Variables
 
* Branching in Shared Machines
 
 
 
=== Future Work ===
 
* Support for Interrupts.
 
* Richer DataTypes.
 
* Accommodation of duplicate event names in tasking developments.
 
 
 
=== Metamodels ===
 
* In the plug-in we define several meta-models:
 
** CompositeControl: for the control flow (algorithmic) constructs such as branch, loop and sequence etc. These constructs may be used in the specification of either  sequential or concurrent systems.
 
** Tasking Meta-model: defines the tasking model where we attach tasking specific details, such as task priority, task type. The tasking structures provide the ability to define single tasking or multi-tasking (concurrent) systems. We make use of the composite control plug-in to specify the flow of control.
 
** Common Language (IL1) Meta-model: defines an abstraction of common programming language constructs for use in translations to implementations.
 
 
 
=== Translation Rules ===
 
* Tasking to IL1/Event-B translation rules [[http://wiki.event-b.org/images/Translation.pdf]]
 
 
 
== The Code Generation Demonstrator for Rodin 1.3.x ==
 
 
 
 
 
First release: 30 November 2010.
 
 
 
available from:
 
 
 
https://sourceforge.net/projects/codegenerationd/files/
 
 
 
The zip file contains a windows XP bundle, and a Windows V7 bundle. Alternatively, if you wish to build using an update-site, this is also included in the zip file, along with some notes on installation. However, note that the demonstrator tool is only compatible with Rodin 1.3.
 
 
 
A simple shared buffer example is provided. This will form the basis of a tutorial (which is work in progress). The WindowsBundles directory contains a Rodin 1.3.1 platform with the Code Generation plug-ins, together with a patch plug-in. The patch plug-in is required to correct an inconsistency in the org.eventb.emf.persistence plug-in. For the bundles, simply extract the appropriate zip file into a directory and run the rodin.exe. The plug-ins are pre-installed - the only configuration necessary may be to switch workspace to ''<installPath>\rodin1.3bWin7\workspace''. When using the update-site the example projects, and the project forming the basis of a simple tutorial, are provided in the accompanying zip file. These should be imported manually.
 
 
 
Mac users - no bundled version available at present, but use the update site in the 'advanced' folder.
 
 
 
'''A step-by-step [[Code Generation Tutorial]] is available'''
 
 
 
==== About the Initial Release ====
 
The Code Generation (CG) Feature in the initial release is a demonstration tool; a proof of concept, rather than a prototype. The tool has no static checker and, therefore, there will be a heavy reliance on docs and dialogue to facilitate exploration of the tools and concepts.
 
 
 
==== Source Code ====
 
 
 
The sources are available from,
 
 
 
https://codegenerationd.svn.sourceforge.net/svnroot/codegenerationd
 
 
 
Note - I used Eclipse 3.5 Galileo, and you will need to install (or have sources from) Epsilon's interim update site. There is also dependency on Camille v2.0.0
 
 
 
 
 
 
 
[[Category:Work in progress]]
 

Revision as of 16:35, 10 December 2010

This Page is Under Construction!!!!

Tutorial Overview

The aim of the tutorial is to allow users to explore the approach with a relatively simple example. The example uses a shared buffer with reader and writer processes. The tutorial is presented in three stages, making use of the example projects from the download site. There are two translations performed, one is to a common language model (IL1). The second is to an Event-B project which includes a model of the implementation. There is a PrettyPrinter for Ada source code, which uses the common language model. An overview of Tasking Event-B can be found at http://wiki.event-b.org/index.php/Tasking_Event-B_Overview.

A typical Event-B development may be refined to the point where it is ready for implementation, but the Event-B language is not expressive enough to fully describe the implementation. Tasking Event-B facilitates this final step to implementation, by extending Event-B with the necessary constructs. Event-B machines that are to be implemented (and their seen Contexts) are selected and added to a Tasking Development; the Tasking Development files have the file extension .tasking. The machines in the Tasking Development are then extended with implementation details.

The example/tutorial projects are,

SharedBuffer20100819Demo An example project with a completed Tasking Development and IL1 model (post IL1 translation, but before Event-B translation).
Sharedbuffer20100819Tasking Same as the example project above, but with Event-B model translations. The difference being that this development includes a model of the implementation. These are refinements that include a program counter to describe flow of execution in each task.
SharedBuffer20100819Tutorial A bare project for step 1 of the tutorial.
Sharedbuffer20100819Tutorial2 A partially completed tasking development for steps 2 and 3 of the tutorial.

Preliminaries

Before further discussion of the modelling aspects, we take a look at the PrettyPrint viewers. The PrettyPrinters make the viewing of IL1 and tasking models easier; it also provides a route to generate source code. The source code can easily be pasted from the IL1 Pretty Printer window into an the Ada source file .

The PrettyPrint View of a Tasking Development

To open the Tasking PrettyPrint viewer,

  • from the top-menu select Window/Show View/Other/Tasking Pretty Printer.

Note that the Tasking PrettyPrinter may have to be closed when editing the Tasking Development, since it can give rise to exceptions. The PrettyPrinter would need further work to make it robust, however it is intended only as a short-term solution.

  • Open the SharedBuffer20100819Demo Project and switch to the Resource Perspective.
  • Open the .tasking model and inspect it. Clicking on the Main, Machine or Event nodes updates the pretty print window.

Viewing Source Code

aka. The PrettyPrint View of an IL1 Model.

To view Ada source code,

  • from the top-menu select Window/Show View/Other/IL1 Pretty Printer.
  • Open the SharedBuffer20100819Demo Project and switch to the Resource Perspective.
  • Open the .il1 model and inspect it. Clicking on the Protected, Main Entry, or Task nodes updates the pretty print window.

Cleaning the Tasking Development

If the .tasking file has errors, then it may need cleaning. To do this right-click on the Main node, select Epsilon Translation/CleanUp. If a model has errors it can still be viewed by clicking on the Selection tab at the bottom of the tasking editor window.

The Tutorial

The steps needed to generate code from an Event-B model, in this tutorial, are as follows,

Creating The Tasking Development

  • Change to the Event-B Perspective.
  • Open the SharedBuffer20100819Tutorial Project.
  • Select the following Machines: Reader, Writer and Shared.
  • Right-click and select Make Tasking Development/Generate Tasking Development.

The new Tasking Development will not be visible in the Event-B perspective, change to the resource perspective, open and inspect the new .tasking file. The Tasking Development contains (the EMF representation of) the machines that we wish to provide implementations for. In order to introduce the new concepts we have prepared a partially complete development.

Change to the Project SharedBuffer20100819Tutorial2 to begin the next step.

Providing the Annotations for Implementations

  • Close any Tasking Pretty Print Viewers that remain open. The incomplete model will give rise to exceptions.
  • Go to the to the Resource Perspective.
  • Open and inspect the .tasking machine.

The WriterTsk and SharedObj machines are incomplete. We will take the steps to necessary to provide implementation details.

The WriterTsk Machine

In the partially complete tutorial project we already identified the WriterTsk as an Auto Task Tasking Machine, by adding the Auto Task extension. Auto Tasks are tasks that will be declared and defined in the Main procedure of the implementation. The effect of this is that the Auto Tasks are created when the program first loads, and then activated (made ready to run) before the Main procedure body runs. We have added the Periodic Task extension to the Auto Task, and set a period of 250 milliseconds. We will now complete the sequence that has been partially defined in the task body.

  • Add Synchronisation between TWrite and SWrite.
    • Expand the Auto Task Machine node.
    • Expand the Seq sub-tree.
    • Right-click on the Seq node and select New Child/Left Branch EventWrapper.
    • Provide the event label w1 using the properties view.
    • Right-click on Event Wrapper and select New Child/ Synch Events.
    • Select Synch Events and go to the drop-down menu of the Local Event property.
    • At this point the drop-down box displays a number of event names, select the TWrite event.
    • Go to the drop-down menu of the Remote Event property.
    • From the list of events select the SWrite event.

The Synch Events construct is used to implement Event Synchronisation. The next step wraps an event in an Event Wrapper in order to update the local state; there is no synchronisation as such but we will re-use the constructs that already exist.

  • Add the Wrapped Event TcalcWVal.
    • Expand the sub-tree of the second Seq node.
    • Right-click on the Seq node and select New Child/Left Branch EventWrapper.
    • Provide the event label w2 using the properties view.
    • Right-click on Event Wrapper and select New Child/ Synch Events.
    • Select Synch Events and go to the drop-down menu of the Local Event property.
    • From the list of events select the TcalcWVal event.

We have now completed the task body, and it just remains to complete provide details for the TWrite event. The TWrite event in WriterTsk is to be synchronized with the SWrite event in the SharedObj.

  • Add Event Extensions.
    • Right-click on the TWrite Event node.
    • Select New Child/Extension.
    • Right-click on the Extension node and select New Child/Implementation from the menu.
    • Go to the Implementation properties view and set the Implementation Type property to ProcedureSynch.
  • Identify Incoming and Outgoing parameters.
    • Right-click on the outAP node and add an Extension.
    • Right-click on the Extension and selectNew Child/Parameter Type.
    • Go to the Parameter Type properties view and set the Parameter Type property to actualOut.
    • Right-click on the inAP node and add an Extension.
    • Right-click on the Extension and selectNew Child/Parameter Type.
    • Go to the Parameter Type properties view and set the Parameter Type property to actualIn.
The Shared Machine

The next step is to identify the SharedObj machine as a Shared Machine. The SharedObj Machine will be extended using the Event-B EMF extension mechanism.

  • Right-click on the SharedObj Machine node in the .tasking file.
  • Select New Child/Extension.
  • Right-click on the Extension node and select New Child/Shared Machine from the menu.

We now show how to extend the SWrite event of the Shared Machine with details about its implementation. The SWrite event in SharedObj is to be synchronized with the TWrite event in the WriterTsk.

  • Identify SWrite as a Syncronisation.
    • Right-click on the SWrite Event node.
    • Select New Child/Extension.
    • Right-click on the Extension node and select New Child/Implementation from the menu.
    • Go to the Implementation properties view and set the Implementation Type property to ProcedureSynch.
  • Identify incoming and outgoing parameters.
    • Right-click on the inFP node and add an Extension.
    • Right-click on the Extension and selectNew Child/Parameter Type.
    • Go to the Parameter Type properties view and set the Parameter Type property to formalIn.
    • Right-click on the outFP node and add an Extension.
    • Right-click on the Extension and selectNew Child/Parameter Type.
    • Go to the Parameter Type properties view and set the Parameter Type property to formalOut.

To summarise, for a Shared Machine definition:

  1. Add the SharedMachine Machine type.
  2. For each event, define the Event Type.
  3. For each event parameter, define the Parameter Type.

Invoking the Translation

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