FR3053140B1 - DESIGN ARCHITECTURE, IN PARTICULAR FOR AN AERONAUTICAL AIRBORNE SYSTEM - Google Patents

Abstract

This computing architecture, in particular for an autonomous, federated or integrated modular avionics (IMA) aeronautical embedded system, comprising means (25) with an application execution processor, is characterized in that the execution processor means comprise a processor (25) multi-cores (26, 27, 28, 29) associated with a scheduler (30) for managing the operation of this processor, for executing the applications by the cores (26, 27, 28, 29 ) of the processor, in a sequential and segregated manner, respecting partitioning constraints determined by activating one and only one heart at a time.

Description

DESIGN ARCHITECTURE, IN PARTICULAR FOR AN AERONAUTICAL AIRBORNE SYSTEM

The present invention relates to a computation architecture in particular for an aeronautical embedded system.

Such aeronautical embedded systems can for example be so-called embedded autonomous systems, federated or integrated modular avionics (IMA). In general, such architectures include application or application execution processor means.

In the state of the art, these computing architectures can therefore be considered as so-called distributed architectures, in which a computing element is associated with one and only one application or application.

In current generations of architectures, we can summarize the situation that a function corresponds to an application that runs on a computer with a single-core processor.

Technological developments are leading processor manufacturers to use available silicon to integrate more and more functions within a single chip.

This integration was made necessary because the race to the power of these chips could no longer be performed by a simple increase in the operating frequency.

Technological evolutions linked in particular to the fineness of engraving of the components made it possible to replace the increase in frequency by an increase in the number of cores of computation, thus making the component more and more powerful while maintaining a controllable consumption.

But in the applications envisaged, then the problem of certification arises.

Indeed, the certification of a single or multi-core processor requires demonstrating that one is able to control the determinism of all the accesses made by one of the cores, whatever the applications that go run on each of the other available cores regardless of the internal architecture of the processor.

In a context of integrated IMA modular avionics, the lack of application control led to the conclusion that this determinism could not be demonstrated and that the calculation of a worst case execution time (WCET) such as it is currently requested, could not be performed without introducing strong constraints in the internal operation of the multi-core processor.

In addition, the complexity introduced by current architectures to processors leads to not being able to control the remanence that can be generated by a heart performing a transfer to the current execution and / or a transfer led by the other cores.

All this results in the fact that the certification of such structures is extremely difficult to obtain and that it is difficult or impossible to deploy these structures.

The object of the invention is to propose solutions of computational architectures to achieve this. For this purpose, the object of the invention is a computing architecture, in particular for an autonomous aeronautical system, federated or integrated modular avionics (IMA), comprising application execution processor means, characterized in that the execution processor means comprise a multi-core processor associated with a scheduler for managing the operation of this processor, making it possible to execute the applications by the cores of the processor, in a sequential and segregated manner, while respecting partitioning constraints determined by activating one and only one heart at a time.

According to other features of the architecture according to the invention, taken alone or in combination: the scheduler is adapted to define an activation cycle of the cores one after the other; the activation cycle of the cores is programmed by heart in a configuration file transmitted to the scheduler; the scheduler comprises means for storing information, for each core and each application to be executed, relating to: the start time of the execution of the application, and the execution time of the application application; the scheduler also comprises means for storing, for each heart and each application to be executed, information relating to a time of isolation of the cores relative to one another; the information is predetermined during the design of the architecture and is transmitted to the scheduler via the configuration file; the scheduler includes means for cleaning the processor and the core at the end of the execution of an application; - it includes an external control mechanism of the Dog Guard type; it includes an external control mechanism of the guard dog type by heart of the processor and initialized by the scheduler; the scheduler is hosted and clocked by one of the cores of the processor. The invention will be better understood on reading the description which follows, given solely by way of example and with reference to the appended drawings, in which: FIG. 1 illustrates the passage of a single-core segregated architecture of the state of the art, a multi-core architecture segregated according to the invention; FIG. 2 represents a block diagram illustrating a multi-core processor structure used in the constitution of a calculation architecture according to the invention; FIG. 3 represents the various information used by a scheduler used in the constitution of a calculation architecture according to the invention; and - Figure 4 illustrates a heart activation cycle.

As indicated above, the invention relates to a computing architecture, in particular for an aeronautical embedded system.

As also indicated above, such a system can be an autonomous, federated or integrated modular avionics (IMA) system.

In the state of the art, various equipment, such as, for example, the equipment designated by the references 1, 2, 3 and 4 in this FIG. 1, are associated with information input and output means, such as the means 5, 6, 7 and 8 respectively.

These equipments each comprise function execution processor means.

In the state of the art, each equipment then comprises a single-core processor, designated by the references 9, 10, 11 and 12 respectively, each implementing a corresponding function, designated by the references 13, 14, 15 and 16 respectively.

In the architecture according to the invention, it is proposed to use execution processor means which comprise a multi-core processor, associated with a scheduler for managing the operation of this processor.

This is illustrated in FIG. 1 also, where the equipment is designated by the general reference 20 in this figure and is connected to data input / output means 21.

The different functions are always designated by references 13, 14, 15 and 16.

These functions are implemented by a multi-core processor, designated by the general reference 25, comprising for example four cores 26, 27, 28 and 29.

This then makes it possible to execute the applications by the cores of the processor, in a sequential and segregated manner, while respecting partitioning constraints determined by activating one and only one core at a time. For this purpose, and as illustrated in FIG. 2, where the multi-core processor 25 and the cores 26, 27, 28 and 29 of the latter are recognized, it can be seen that this multi-core processor is associated with a scheduler for managing its operation.

This scheduler is designated by the general reference 30 in this FIG. 2 and is associated with a configuration file designated by the general reference 31.

In fact and to solve the various problems mentioned above, this configuration file 31 is established during the design of the architecture, to define the execution of the applications by the cores of the processor, in a sequential and segregated manner while respecting the constraints of fixed partitioning.

As illustrated in FIG. 3, the scheduler is then associated with means for storing this information file, which comprises, for each core and each application to be executed, information that is related to the start-up time of the information file. the execution of the application and the duration of execution of the application. Other information such as information relating to a time of isolation of the cores relative to each other, can also be envisaged.

Thus, in this FIG. 3, the file comprises, for each core, the start time, for example IDem1, the execution duration DE1 and the isolation time T1, for the application assigned.

It is then conceivable that from these different pieces of information, the scheduler is adapted to define an activation cycle of the cores one after the other, as illustrated in FIG. 4.

This activation cycle is programmed by heart, in a configuration file transmitted to the scheduler and which was for example determined during the design of the architecture. The scheduler also includes means for cleaning the processor and the core at the end of the execution of an application.

Thus, and as illustrated in FIG. 4, for each heart, the scheduler launches several steps consisting of: - initializing the heart, - starting the execution of the application, - cleaning the heart at the end of the application and - put the heart to sleep.

Of course, external control mechanisms can also be implemented, such as, for example, watchdog type mechanisms.

Such a watch dog type mechanism can also be implemented per processor core and initialized by the scheduler.

This scheduler can for example be hosted and clocked by one of the cores of the processor.

Of course other embodiments can be envisaged.

It is therefore conceivable that thanks to such an architecture, it is possible to use a multi-core processor in order to be able, thanks to its functionalities and thanks to its computing power, to bring together in a single component all the applications currently executed on several components. monohull independent.

This grouping is of course done in compliance with the requirements and constraints, particularly at the level of application segregations.

The development of the scheduler then allows operation of the multi-core processor in one of N, where N is the total number of available cores.

This approach makes it possible to consider that one can guarantee the independence of the applications between them and applications vis-à-vis the internal resources of the processor.

During the design, the entire execution graph is determined according to the needs of each application. All cores are synchronized around a single clock tree using a single reference clock or external synchronization.

Thus all the cores can be considered as being synchronous.

At launch, the set of cores will be synchronized around the mother clock of the architecture and each heart, during its initialization phase, will be programmed internally according to the preliminary analysis of isolation that has been made during the design phase of this architecture so that, at run time, each time period for one core is independent of that of the other cores.

This makes it possible to segregate the execution of the applications on each of the cores extremely securely.

Indeed, during a given period of time, one and only one heart is active and has the entire processor, that is to say that it then behaves as a single-core processor. The application is then found to be executed on an active processor then single-core.

Once the application is complete, the scheduler takes over and makes sure that the processor is cleaned and put to sleep. The use of control mechanisms by Chien de Garde for example makes it possible to control that the whole execution of the applications is correct.

It is then conceivable that this architecture makes it possible to group in a single component several applications that are currently executed or that are to be executed by several different equipments.

This approach makes it possible to offer a better ratio between performance, dissipated power and bulk because it favors a multi-processor approach, allowing full and complete independence between each application running on each of the cores.

Of course other embodiments can be envisaged.

Claims (9)

CLAIMS 1Architecture calculation including an autonomous aeronautical system, federated or integrated modular avionics (IMA), comprising means (25) application execution processor, characterized in that the execution processor means comprise a multi-core processor (25) (26, 27, 28, 29) associated with a scheduler (30) for managing the operation of this processor, for executing the applications by the cores of the processor, in a sequential manner and segregated, respecting partitioning constraints determined by activating one and only one heart at a time; and in that the scheduler (30) comprises means for cleaning the processor (25) and the core (26, 27, 28, 29) at the end of the execution of an application. 2, -Architecture of calculation according to claim 1, characterized in that the scheduler (30) is adapted to define an activation cycle of the cores (26, 27, 28, 29) one after the other. 3, - Computing architecture according to claim 2, characterized in that the activation cycle of the cores (26, 27, 28, 29) is programmed by heart in a configuration file (31) transmitted to the scheduler (30). ). 4, - computing architecture according to any one of the preceding claims, characterized in that the scheduler (30) comprises information storage means, for each core and each application to be executed, relating to: - the instant starting the execution of the application (IDem), and - the execution time of the application (DE). 5, -Architecture of calculation according to claim 4, characterized in that the scheduler (30) also comprises means for storing, for each heart and each application to be executed, information relating to an isolation time (Tl) hearts (26, 27, 28, 29) relative to one another. 6, - computing architecture according to claims 3 and 4 or 5, characterized in that the information is predetermined during the design of the architecture and are transmitted to the scheduler via the configuration file (31). 7, - computing architecture according to any one of the preceding claims, characterized in that it comprises an external control mechanism type Guard Dog. 8, -Architecture of calculation according to claim 7, characterized in that it comprises an external control mechanism type Guard Dog by heart (26, 27, 28, 29) of the processor (25) and initialized by the scheduler (30). 9, - computing architecture according to any one of the preceding claims, characterized in that the scheduler (30) is hosted and clocked by one of the cores (26, 27, 28, 29) of the processor.