WO2010060926A1 - Method and system for converting ccm software components into components that can be deployed in an sca standard-compatible environment - Google Patents

Abstract

The invention relates to a method for converting a software component defined by the "CORBA Component Model" standard, known by the abbreviation "CCM", said method comprising a container for providing the outer interface of the "Components :: CCMObject" component, an executer for providing the functional code of said component, and a software entity for managing the resources of the component and for making a "Components :: CCMHome" standard interface into a component compatible with the "Software Communication Architecture" standard, known by the abbreviation "SCA", comprising at least one "CF :: Resource" outer interface.

Description

 METHOD AND SYSTEM FOR PROCESSING

COMPONENTS CCM SOFTWARE IN DEPLOYABLE COMPONENTS

IN A COMPATIBLE ENVIRONMENT OF THE STANDARD SCA

The present invention provides a method and system for transforming a standardized software component by the CCM standard into a deployable component in a compatible software infrastructure of the SCA standard. It is used in the framework of infrastructure (embedded software component) real-time in particular for the field of software radio.

The Software Communication Architecture (SCA) is a reference standard for software-based applications and is essential in many industrial project contexts. This architecture defines a software infrastructure called the Core Framework SCA or CF-SCA that allows deploying and configuring waveform modules on a radio platform. For the sake of clarity, in the rest of the text, the term component SCA designates a deployable software component in an architecture complying with the SCA standard in its version as described in document [4] By analogy, any use of the acronym SCA will be made with reference to the standard described in document [4].

The Lightweight CORBA Component Model (LwCCM) standard of the Object Management Group (OMG) is a generic standard for many application areas. It represents the current state of the art of real-time and component-based software development approaches. In particular, it is based on the CORBA (Common Object Request Broker Architecture) and CCM (CORBA Component Model) standards.

For the sake of clarity, in the rest of the text, the term CCM component will designate a software component deployable in a CCM compatible infrastructure and LwCCM in their version as described in documents [1] and [2] The LwCCM standard is a subset of the CCM standard ("CORBA Component") which defines:

• the structure of a component as a design, implementation, deployment, and execution entity. • predefined interaction modes.

• deployment and execution mechanisms.

Two additional standards extend the LwCCM standard:

• Quality of Service Standard for the CCM Component Model, QoS for CCBA (Quality of Service for CORBA Component Model), allows for the definition of an integration interface for additional technical services, in the form of open containers for one more great component flexibility and better separation between business code and technical code. These containers contain all non-functional source code. "The data distribution service standard for the CORBA component model (currently being standardized); DDS for CCM (" Data Distribution Service for CORBA Component Model "), which allows you to define and implement generic connectors to implement in place specialized and high-level communication modes between components.

These three standards, representing the state of the art in computer systems based on real-time and embedded software components, can be used to complete the SCA standard ("Software Communication Architecture"). example:

• Through the software components of the LwCCM standard, design, implement, deploy, and execute radio waveform modules according to a standard approach shared by the software community and marketed solution providers. the general public. • Through the generic connectors specified by the DDS for CCM standard, define and implement specialized exchange mechanisms and interfaces for the software radio world.

• Through open containers (QoS for CCM), define and abstract the underlying execution platform (hardware and software) generically and be able to choose between an SCA compliant platform or not.

From the point of view of state-of-the-art and real-time software IT practice, the CF-SCA software infrastructure has limitations:

• The definition of the SCA component model is restricted in that: o There is no interaction semantics between the SCA components: it is not possible to generically define the semantics of the exchanges (data and behavior) between SCA components implementing, for example, algorithmic processing relating to a radio waveform. This description is left to the initiative of the developer and takes specific and proprietary forms. o There is no formal separation between functional code (eg source code implementing algorithm modules for a radio waveform) and non-functional code (eg activation, sequencing, flow management , communication ..). Integration of non-functional aspects

(use of the CORBA standard for example) is done in the component's business code.

• The SCA standard requires the use of a CORBA-type software bus for the deployment of radio applications developed on a software infrastructure compliant with the standard. This is a costly answer for hardware platforms that are limited in processing capacity and available memory.

By construction, the approach adopted by the LwCCM standard is not natively compatible with an SCA infrastructure. One of the aims of the invention is to make possible the porting of a software component CCM on an SCA architecture by implementing the operations necessary for the transformation of said CCM component into a new compatible component of the SCA standard.

To this end, the subject of the invention is a method of transforming a software component defined by the "CORBA Component Model" standard, known by the abbreviation "CCM", comprising a container (201) producing the external interface of the component "Components :: CCMObject", an executor realizing the functional code of this component and a software entity allowing the management of the resources of the component and realizing a standard "Components :: CCMHome" interface, into a compatible component of the "Software Communication Architecture" standard, known by the abbreviation "SCA", comprising at least one external interface "CF :: Resource", characterized in that said method comprises at least the following steps implemented by means of a suitable generator:

- Step 1: replace the container carrying out the "Components :: CCMObject" interface defined by the "CCM" standard by a container carrying out the "CF :: Resource" interface defined by the "SCA" standard - Step 2: delete the implementation of the "Components :: CCMHome" interface defined by the "CCM" standard

Step 3: Implement a software component executing the "SCA" component factory function for instantiating and managing the life cycle of said "SCA" compatible component resulting from the transformation of said compatible component of the standard

"CCM".

Step 4: implement means making it possible to redirect the connections between said compatible component of the "SCA" standard resulting from the transformation of said compatible component of the "CCM" standard. and its external environment to the executor of said software component defined by the "CCM" standard.

In an alternative embodiment, said adapted generator performs a transformation of the description of the interfaces of said compatible component of the standard "CCM" to the description of the interfaces of said component "SCA" standard compliant resulting from the transformation of said compatible component of the standard "CCM".

In an alternative embodiment, the description of the interfaces of said compatible component of the "CCM" standard is carried out in IDL3 language for "Interface Description Language 3".

The invention also relates to a system comprising at least one main processor, one or more secondary processors, a software infrastructure of "Core Framework" type defined by the "SCA" standard executed on the main processor, one or more compatible components of the standard "SCA" deployed on the secondary processor or processors using one or more files of description of the deployment plan of said components, characterized in that said compatible components of the "SCA" standard are obtained by transformation of a or several compatible components of the standard "CCM" using the steps of the method according to the invention.

In an alternative embodiment, the description file or files of the deployment plan are obtained by transforming the equivalent files describing the deployment plan of said compatible components of the standard "CCM".

In an alternative embodiment, the processor on which said compatible software component of the "CCM" standard is deployed is a generic GPP processor or a digital signal processor DSP or a reconfigurable FPGA processor. In an alternative embodiment, said compatible software component of the "CCM" standard executes a radio waveform module and the system under consideration is a software radio platform.

Another subject of the invention is a use of the method or system according to the invention, characterized in that the container carrying out the interface "CF :: Resource" and the executor of said compatible software component of the "CCM" standard are deployed. on two different processors.

In an alternative embodiment, the deployment of said compatible components of the "SCA" standard on secondary processors is obtained via a transformation of the description file (s) of the deployment plan of said compatible components of the "CCM" standard.

Other characteristics will become apparent on reading the detailed description given by way of nonlimiting example, which follows, with reference to appended drawings which represent:

- Figure 1, a block diagram describing a method according to the invention for the deployment of CCM software components in a compatible SCA standard environment from the deployment plan of these components in a non-compatible environment of the same standard.

- Figure 2; a block diagram describing the means implemented to carry out the transformation of a software component CCM into a standard component SCA via a method according to the invention. - Figure 3; a block diagram of a system implementing a method according to the invention.

FIG. 1 schematizes the deployment of one or more software components CCM 101 to 103, which may be radio waveform components, in a non-SCA compliant environment, for example a compatible infrastructure 100 of the deployment standard and configuration

(D & C) as well as the transformation carried out to bring these same software components 101 to 103 to an SCA compatible environment, for example a core framework software infrastructure 105. The deployment consists of defining the way in which the software components are distributed. on the physical infrastructure that hosts them as well as the relationships between these different components, such as a communication link or a dependency relationship between two components. The communication between different CCM components is done via the use of incoming ports 101a which may be for example facets, a standardized term which designates the services provided to the component, or outgoing ports 101b which may be for example receptacles, term standardized which designates the services required by the component. A software component CCM 101 contains an executor 106a on which a functional source code is developed, for example a source code implementing a radio waveform processing. An object of the method according to the invention is to allow to keep intact the functional code developed in this executor during porting in an SCA environment. The method includes the replacement of the standard "Components :: CCMObject" software interfaces required to deploy CCM software components on a D & C infrastructure through equivalent "CF :: Resource" equivalent interfaces of a standard SCA software infrastructure. The new "CF :: Resource" interfaces thus generated are represented in FIG. 1 by references 106 to 108, they encapsulate executors 106a, 107a and 108a originating from components CCM 101, 102 and 103.

The deployment of the CCM components in the infrastructure 100 is done via one or more description files 104 written for example, in XML description language (extensible markup language) respecting the semantics of a CDP deployment plan for "Component Deployment Plan" ". These description files 104 contain all the information enabling the components to be positioned in the physical infrastructure as well as defining the relationships between these components. In order to proceed with the deployment of the SCA components obtained after processing via the method according to the invention in the software infrastructure SCA 105, it is necessary to generate one or more necessary descriptor files, for example a descriptor file 109 SAD (Software Application Descriptor) to either from a Model Driven Engineering (MDE) approach, or generate them by transforming the CCM 104 deployment descriptors.

FIGS. 2a and 2b show a block diagram detailing the operations implemented during the transformation of a CCM component into an SCA component according to one embodiment. A CCM component 102 contains an executor 107a on which the functional code is developed, a container 201 which carries out the standard interface "Components :: CCMObject" and a context 203. The term context here refers to the term standardized by the LwCCM standard and corresponding to a software entity performing the Context interface, said interface making it possible to provide the executor CCM all the information of the external environment necessary for the communication with other components. A software entity 202 which makes the "Components :: CCMHome" interface enables the management of the life cycle of this component. After transformation by the method according to the invention, the resulting component always comprises the executor 107a, the context 203 and a container 107 which makes the interface "CF :: Resource" in the new environment. A software entity 204 which makes the interface "CF :: Resource Facto ry" offers a role similar to the entity 202 while being compatible with the SCA standard. In the remainder of the text, the acronym IDL3 will refer to the component description language used to describe a CCM component, and the IDL acronym to the interface description language to describe the equivalent interfaces of the CCM and SCA components. According to one embodiment, the transformation implemented by the method according to the invention is carried out according to several successive steps. A first step to achieve is to modify the transformation rules from IDL3 to IDL and the associated generator in order to:

- replace the inheritance of the "Components :: CCMObject" interface with the inheritance of the "CF :: Resource" interface in the equivalent definition of the CCM component.

- include SCA Core Framework definitions in these rules.

delete the software entity 202 implementing the "Components :: CCMHome" interface

A second step consists in generating a component factory 204 producing the "CF :: Resource Facto ry" interface that makes it possible to manage the life cycle of the SCA components and that replaces the software entity 202 that makes the "Components ::" interface. CCMHome ".

Then, from the IDL equivalent definition of the CCM component, the source code of the new SCA component can be generated. The first step to build this new component is to implement the container 107 implementing the new interface "CF :: Resource". Said container 107 must be able to communicate with other remote components, it is therefore necessary to redirect the requests received by the SCA component via its incoming or outgoing ports to the CCM component and vice versa according to the following steps: - Add an outgoing SCA 208 port (making the "CF :: Port" SCA standard interface) equivalent to the CCM 207 outgoing port used by the CCM component. This SCA port is used by the Core Framework infrastructure to make the connections specified in the generated SAD descriptor file (via a type operation).

CF :: Port :: connectPort ()) with the SCA input ports of the other SCA components.

- Add an incoming SCA 205 port equivalent of the existing CCM incoming port 206. This port must realize and record in the CORBA software bus the same IDL interface as that of the incoming port.

Associate CCM. It receives requests from remote client components and redirects them to the CCM executor's functional code.

Implementing a connection 209 between the SCA output port and the CCM context to transmit CCM requests made locally by the executor on the CCM context into SCA requests sent from the SCA output port to the component input SCA port SCA called.

- Change the CCM 203 context implementation used locally by the CCM component to interact with the SCA ports

205 and 208 of the SCA component.

- Implement an initialization operation of the LifeCycle :: initialize () container 107 by performing at least one SessionComponent :: set_session_context () context 203 initialization operation provided by the CCM component executor.

- Implement an initialization operation for each of the input and output ports 205 and 208 of type CF :: PortSupplier :: getPort (). This operation is parameterized by the name identifier and it returns the CORBA object reference of the SCA port registered in the CORBA software bus and corresponding to the name identifier passed as an argument.

- Implement a connection operation of the created SCA entry port 205 to the CORBA software bus, type CF r.Port :: connectPort (). This operation is parameterized by the connection identifier which corresponds to the CORBA object reference of the input port SCA 205 .It implements a transfer of said reference to the context CCM 203 in order to make this reference available to the executor CCM 107a. - Implement a configuration operation of the new component, of type PropertySet :: configure (), by redirecting the values of the configuration parameters from the SCA "Framework Framework" software infrastructure to the CCM component's executor using the associated accessors to each of the configuration parameters.

- Implement an operation of type Resource :: start () allowing the activation of the new SCA component, starting by calling an operation of type CCMObject :: configuration_complete () and then an operation of type SessionComponent :: ccm_activate () provided both by the executor of the CCM component.

- Implement a Resource :: stopQ operation, allowing the deactivation of the new SCA component by calling at least one SessionComponent :: ccm_passivate () operation provided by the CCM component executor.

- Implement an operation of type LifeCycle :: releaseObjectQ, allowing the removal of the SCA component, by calling at least one SessionComponent :: ccm_remove () operation provided by the CCM component executor. - Implement a PropertySet :: query () operation by redirecting the values of the configuration parameters from the CCM component's executor to the SCA 205 or 208 port to the client SCA component. This redirection can be done via calls to the accessors associated with each of the configuration parameters.

In order to eliminate the redundant elements between the two standards, the implementation of the software entity implementing the "Components :: CCMHome" interface and transfer the source code must also be removed. managing the life cycle of the CCM component in the entity 204 implementing the "CF :: Resource Facto ry" interface.

As each CCM container is transformed into an SCA container, so are the CCM connections declared in the original deployment plan that are transformed into SCA connections declared in the SCA component deployment description file. In the deployment phase of the SCA application formed by one or more SCA components obtained via the transformation method according to the invention, the binary code of each of the SCA components must be loaded and executed on each of the nodes of the target platform. Each of the SCA components initializes its CCM executor and creates the input and output ports it needs to communicate with the outside world. Input ports must also be registered with the software bus used to communicate with remote processors. Once the CF-SCA software infrastructure has knowledge of the different ports created by the SCA components, connections between these components can be made according to the deployment plan of the SCA application. Finally, the connection between the SCA ports and the CCM executor is provided by the CCM context which performs the operations necessary for the redirection of the SCA ports to the associated CCM ports.

Figure 3 illustrates the deployment of SCA components made by the method according to the invention on different types of processors. For example, a first SCA component comprising a CCM executor 402 and a container 403 is deployed on a generic processor (GPP) 401, a second SCA component comprising a CCM executor 406 and a container 407 is deployed on a digital signal processor (DSP). ) 405, said executor 406 performing for example a function associated with a radio waveform.

Another possible embodiment of the method according to the invention consists in deploying an executor 409 and its associated container 404 on two different processors. The communication of the executor 409 to its container 404 is via the introduction of local connector fragments that transform the request from the executor into a suitable request to the medium of communication existing between the two remote processors 401 and 408. This implementation of the method makes it possible, in particular, to bring a CCM executor to a non-compatible processor of the SCA standard, for example a reconfigurable FPGA processor, while using a compatible container of the SCA standard said container being executed on a remote generic processor 401.

The method according to the invention described above offers, in particular, the advantage of enabling the development of processing modules relating to a radio waveform by using a software infrastructure CCM. Component design can be done using the IDL3 standard interface description language to describe these same components or a UML modeler that automatically generates the equivalent component definition in IDL. The waveform component developer must only implement the functional code of its component in an LwCCM development environment. This implementation can remain as it is without any particular modification to be worn on different environments. Thus, the components can be deployed on a standard LwCCM infrastructure, this phase being of interest for the functional development of the waveform modules on host targets or if the deployment must be done in an infrastructure that does not support the standard. SCA. In a second step, the components can be adapted for deployment on an SCA infrastructure by generating the containers adapted to the target and the SCA personality envelope via the method according to the invention. An advantage of the method according to the invention is to overcome the limitations of the SCA standard by offering a richer design framework, another advantage residing in the portability to non-compatible environments of the SCA standard.

References

[1] Lightweight Corba Component Model (CCM) Object Management Group (OMG) Final Adopted Specification, November 2003 [2] CORBA Component Model Specification Version 4.0, OMG [3] OMG, v4.0 Deployment and Configuration of Component-Based Distributed Applications (D & C)

[4] Software Communications Architecture Specification V2.2, 2001

NOTES

Claims

1. A method of transforming a software component (102) defined by the "CORBA Component Model" standard, known by the abbreviation "CCM", comprising a container (201) providing the external interface of the "Components :: CCMObject" component, an executor (107a) realizing the functional code of said component and a software entity (202) making it possible to manage the resources of the component and producing a standard "Components :: CCMHome" interface, into a compatible component of the "Software Communication Architecture" standard, known under the abbreviation "SCA", comprising at least one external interface "CF :: Resource", characterized in that said method comprises at least the following steps implemented by means of a suitable generator: - Step 1: replace the container implementing the "Components :: CCMObject" interface (201) defined by the "CCM" standard by a container implementing the interface "CF :: Resource" (107) defined by the sta ndard "SCA"

- Step 2: Remove the implementation of the "Components :: CCMHome" interface (202) defined by the "CCM" standard

Step 3: Implement a software component executing the component factory function "SCA" (204) for instantiating and managing the life cycle of said compatible component of the "SCA" standard resulting from the transformation of said compatible component (102) of the "CCM" standard.

Step 4: implement means for redirecting the connections between said compatible component of the "SCA" standard resulting from the transformation of said component (102) compatible with the "CCM" standard. and its external environment to the executor (107a) of said software component (102) defined by the "CCM" standard.

2. Method according to claim 1, characterized in that said adapted generator performs a transformation of the description of the interfaces of said component (102) compatible standard "CCM" to the description of the interfaces of said compatible component of the standard "SCA" resulting from transforming said compatible component (102) of the "CCM" standard.

3. Method according to claim 2, characterized in that the description of the interfaces of said component (102) compatible standard "CCM" is performed in language IDL3 for "Interface Description Language 3".

4. System comprising at least one main processor, one or more secondary processors, a "Core Framework" software infrastructure defined by the "SCA" standard executed on the main processor, one or more components compatible with the "SCA" standard deployed on the secondary processor or processors using one or more files for describing the deployment plan of said components, characterized in that said compatible components of the "SCA" standard are obtained by transformation of one or more components (102) according to one of claims 1 to 3.

5. System according to claim 4, characterized in that the description file or files of the deployment plan are obtained by converting the equivalent files describing the deployment plan of said components (102) compatible standard "CCM".

6. System according to claims 4 or 5, characterized in that the processor on which is deployed said software component (102) compatible standard "CCM" GPP is a generic processor or a DSP digital signal processor or a reconfigurable processor FPGA.

7. System according to claims 4, 5 or 6, characterized in that said software component (102) compatible standard "CCM" executes a radio waveform module and the system is a radio platform software.

8. Use of the method according to one of claims 1 to 3 or the system according to one of claims 4 to 7, characterized in that the container carrying the interface "CF :: Resource" (107) and the executor (107a) of said compatible software component (102) of the "CCM" standard are deployed on two different processors.

9. Use of the method according to one of claims 1 to 3 or the system according to one of claims 4 to 7, characterized in that the deployment of said compatible components of the standard "SCA" on secondary processors is obtained via a transformation the deployment plan description file or files of said components (102) compatible with the standard "CCM".