parMERASA Multi-Core Execution of Parallelised Hard Real-Time Applications Supporting Analysability

International audienceEngineers who design hard real-time embedded systems express a need for several times the performance available today while keeping safety as major criterion. A breakthrough in performance is expected by parallelizing hard real-time applications and running them on an embedded multi-core processor, which enables combining the requirements for high-performance with timing-predictable execution. parMERASA will provide a timing analyzable system of parallel hard real-time applications running on a scalable multicore processor. parMERASA goes one step beyond mixed criticality demands: It targets future complex control algorithms by parallelizing hard real-time programs to run on predictable multi-/many-core processors. We aim to achieve a breakthrough in techniques for parallelization of industrial hard real-time programs, provide hard real-time support in system software, WCET analysis and verification tools for multi-cores, and techniques for predictable multi-core designs with up to 64 cores

parMERASA – multicore execution of parallelised hard real-time applications supporting analysability

Abstract-Engineers who design hard real-time embedded systems express a need for several times the performance available today while keeping safety as major criterion. A breakthrough in performance is expected by parallelizing hard real-time applications and running them on an embedded multi-core processor, which enables combining the requirements for high-performance with timing-predictable execution. parMERASA will provide a timing analyzable system of parallel hard real-time applications running on a scalable multicore processor. parMERASA goes one step beyond mixed criticality demands: It targets future complex control algorithms by parallelizing hard real-time programs to run on predictable multi-/many-core processors. We aim to achieve a breakthrough in techniques for parallelization of industrial hard real-time programs, provide hard real-time support in system software, WCET analysis and verification tools for multi-cores, and techniques for predictable multi-core designs with up to 64 cores

A Benes Based NoC Switching Architecture for Mixed Criticality Embedded Systems

Multi-core, Mixed Criticality Embedded (MCE) real-time systems require high timing precision and predictability to guarantee there will be no interference between tasks. These guarantees are necessary in application areas such as avionics and automotive, where task interference or missed deadlines could be catastrophic, and safety requirements are strict. In modern multi-core systems, the interconnect becomes a potential point of uncertainty, introducing major challenges in proving behaviour is always within specified constraints, limiting the means of growing system performance to add more tasks, or provide more computational resources to existing tasks. We present MCENoC, a Network-on-Chip (NoC) switching architecture that provides innovations to overcome this with predictable, formally verifiable timing behaviour that is consistent across the whole NoC. We show how the fundamental properties of Benes networks benefit MCE applications and meet our architecture requirements. Using SystemVerilog Assertions (SVA), formal properties are defined that aid the refinement of the specification of the design as well as enabling the implementation to be exhaustively formally verified. We demonstrate the performance of the design in terms of size, throughput and predictability, and discuss the application level considerations needed to exploit this architecture

Predictable multi-processor system on chip design for multimedia applications

The design of multimedia systems has become increasingly complex due to consumer requirements. Consumers demand the functionalities offered by a huge desktop from these systems. Many of these systems are mobile. Therefore, power consumption and size of these devices should be small. These systems are increasingly becoming multi-processor based (MPSoCs) for the reasons of power and performance. Applications execute on these systems in different combinations also known as use-cases. Applications may have different performance requirements in each use-case. Currently, verification of all these use-cases takes bulk of the design effort. There is a need for analysis based techniques so that the platforms have a predictable behaviour and in turn provide guarantees on performance without expending precious man hours on verification. In this dissertation, techniques and architectures have been developed to design and manage these multi-processor based systems efficiently. The dissertation presents predictable architectural components for MPSoCs, a Predictable MPSoC design strategy, automatic platform synthesis tool, a run-time system and an MPSoC simulation technique. The introduction of predictability helps in rapid design of MPSoC platforms. Chapter 1 of the thesis studies the trends in modern multimedia applications and processor architectures. The chapter further highlights the problems in the design of MPSoC platforms and emphasizes the need of predictable design techniques. Predictable design techniques require predictable application and architectural components. The chapter further elaborates on Synchronous Data Flow Graphs which are used to model the applications throughout this thesis. The chapter presents the architecture template used in this thesis and enlists the contributions of the thesis. One of the contributions of this thesis is the design of a predictable component called communication assist. Chapter 2 of the thesis describes the architecture of this communication assist. The communication assist presented in this thesis not only decouples the communication from computation but also provides timing guarantees. Based on this communication assist, an MPSoC platform generation technique has been presented that can design MPSoC platforms capable of satisfying the throughput constraints of multiple applications in all use-cases. The technique is presented in Chapter 3. The design strategy uses three simple steps for platform design. In the first step it finds the required number of processors. The second step minimizes the communication interconnect between the processors and the third step minimizes the communication memory requirement of the platform. Further in Chapter 4, a tool has been developed to generate CA-based platforms for FPGAs. The output of this tool can be used to synthesize platforms on real hardware with the help of FPGA synthesis tools. The applications executing on these platforms often exhibit dynamism e.g. variation in task execution times and change in application throughput requirements. Further, new applications may often be added by consumers at run-time. Resource managers have been presented in literature to handle such dynamic situations. However, the scalability of these resource managers becomes an issue with the increase in number of processors and applications. Chapter 5 presents distributed run-time resource management techniques. Two versions of distributed resource managers have been presented which are scalable with the number of applications and processors. MPSoC platforms for real-time applications are designed assuming worst-case task execution times. It is known that the difference between average-case and worst-case behaviour can be quite large. Therefore, knowing the average case performance is also important for the system designer, and software simulation is often employed to estimate this. However, simulation in software is slow and does not scale with the number of applications and processing elements. In Chapter 6, a fast and scalable simulation methodology is introduced that can simulate the execution of multiple applications on an MPSoC platform. It is based on parallel execution of SDF (Synchronous Data Flow) models of applications. The simulation methodology uses Parallel Discrete Event Simulation (PDES) primitives and it is termed as "Smart Conservative PDES". The methodology generates a parallel simulator which is synthesizable on FPGAs. The framework can also be used to model dynamic arbitration policies which are difficult to analyse using models. The generated platform is also useful in carrying out Design Space Exploration as shown in the thesis. Finally, Chapter 7 summarizes the main findings and (practical) implications of the studies described in previous chapters of this dissertation. Using the contributions mentioned in the thesis, a designer can design and implement predictable multiprocessor based systems capable of satisfying throughput constraints of multiple applications in given set of use-cases, and employ resource management strategies to deal with dynamism in the applications. The chapter also describes the main limitations of this dissertation and makes suggestions for future research

Qduino: a cyber-physical programming platform for multicore Systems-on-Chip

Emerging multicore Systems-on-Chip are enabling new cyber-physical applications such as autonomous drones, driverless cars and smart manufacturing using web-connected 3D printers. Common to those applications is a communicating task pipeline, to acquire and process sensor data and produce outputs that control actuators. As a result, these applications usually have timing requirements for both individual tasks and task pipelines formed for sensor data processing and actuation. Current cyber-physical programming platforms, such as Arduino and embedded Linux with the POSIX interface do not allow application developers to specify those timing requirements. Moreover, none of them provide the programming interface to schedule tasks and map them to processor cores, while managing I/O in a predictable manner, on multicore hardware platforms. Hence, this thesis presents the Qduino programming platform. Qduino adopts the simplicity of the Arduino API, with additional support for real-time multithreaded sketches on multicore architectures. Qduino allows application developers to specify timing properties of individual tasks as well as task pipelines at the design stage. To this end, we propose a mathematical framework to derive each task’s budget and period from the specified end-to-end timing requirements. The second part of the thesis is motivated by the observation that at the center of these pipelines are tasks that typically require complex software support, such as sensor data fusion or image processing algorithms. These features are usually developed by many man-year engineering efforts and thus commonly seen on General-Purpose Operating Systems (GPOS). Therefore, in order to support modern, intelligent cyber-physical applications, we enhance the Qduino platform’s extensibility by taking advantage of the Quest-V virtualized partitioning kernel. The platform’s usability is demonstrated by building a novel web-connected 3D printer and a prototypical autonomous drone framework in Qduino

Overview of Swallow --- A Scalable 480-core System for Investigating the Performance and Energy Efficiency of Many-core Applications and Operating Systems

We present Swallow, a scalable many-core architecture, with a current configuration of 480 x 32-bit processors. Swallow is an open-source architecture, designed from the ground up to deliver scalable increases in usable computational power to allow experimentation with many-core applications and the operating systems that support them. Scalability is enabled by the creation of a tile-able system with a low-latency interconnect, featuring an attractive communication-to-computation ratio and the use of a distributed memory configuration. We analyse the energy and computational and communication performances of Swallow. The system provides 240GIPS with each core consuming 71--193mW, dependent on workload. Power consumption per instruction is lower than almost all systems of comparable scale. We also show how the use of a distributed operating system (nOS) allows the easy creation of scalable software to exploit Swallow's potential. Finally, we show two use case studies: modelling neurons and the overlay of shared memory on a distributed memory system.Comment: An open source release of the Swallow system design and code will follow and references to these will be added at a later dat

On the tailoring of CAST-32A certification guidance to real COTS multicore architectures

The use of Commercial Off-The-Shelf (COTS) multicores in real-time industry is on the rise due to multicores' potential performance increase and energy reduction. Yet, the unpredictable impact on timing of contention in shared hardware resources challenges certification. Furthermore, most safety certification standards target single-core architectures and do not provide explicit guidance for multicore processors. Recently, however, CAST-32A has been presented providing guidance for software planning, development and verification in multicores. In this paper, from a theoretical level, we provide a detailed review of CAST-32A objectives and the difficulty of reaching them under current COTS multicore design trends; at experimental level, we assess the difficulties of the application of CAST-32A to a real multicore processor, the NXP P4080.This work has been partially supported by the Spanish Ministry of Economy and Competitiveness (MINECO) under grant TIN2015-65316-P and the HiPEAC Network of Excellence. Jaume Abella has been partially supported by the MINECO under Ramon y Cajal grant RYC-2013-14717.Peer ReviewedPostprint (author's final draft