OpenComRTOS

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OpenComRTOS
OpenComRTOS 1.jpg
OpenComRTOS application view
Developer
OS family
Working stateCurrent
Source modelSource code license
Initial release2008
Latest release1.6 / August, 2014
Marketing targetEmbedded systems
Package managerOpenComRTOS suite msi file
Platforms, , ARM, XMOS, MicroBlaze, LEON, , , Win32, Linux
Kernel typenetwork-centric real-time
Default
user interface
License
Official websitewww.altreonic.com

OpenComRTOS is a commercial network-centric, formally developed real-time operating system, aimed primarily at the embedded systems market.

Overview[]

OpenComRTOS is a network-centric RTOS (Real-time operating system) that was developed using Formal Methods. It has features like the capability to support heterogeneous multi-processor systems in a transparent way, independently of the processor type (16bit, 24bit, 32bit, 64bit) and the communication medium (shared memory, buses, point-to-point links or virtual links on top of existing communication mechanisms). Typical code size on a 32bit target processor is about 5 KiBytes. OpenComRTOS is based on the meta-modelling paradigm of Interacting Entities. In OpenComRTOS the unit of execution is a "Task" (a function with its local workspace or stack). Task entities synchronise and communicate using intermediate "Hubs" entities that are decoupled from the interacting Tasks. Hubs are formally modelled as "Guarded Actions". The current implementation provides the functionality of traditional RTOS services like Events, Semaphores, Ports, FIFOs, Resources, Packet Pools and Memory Pools. The user can also create his own Hub types. OpenComRTOS uses a uniform architecture with a Kernel Task, driver Tasks and application Tasks, each having a Task input Port. The same interface is used for the Interrupt Service Routines. The underlying architecture relies on the use of prioritised Packet switching with communication and routing being part of the underlying system services. One of the results is that the source code of the Tasks is independent of the mapping of Tasks and Hubs to the processing nodes in the target system.

History[]

The initial purpose for developing OpenComRTOS was to provide a software runtime environment supporting a coherent and unified systems engineering methodology based on Interacting Entities. This was originally developed by Open License Society since 2005, and since 2008 further developed and commercialised by Altreonic. A previously developed RTOS called Virtuoso[1][2][3][4][5] served as a guideline. Virtuoso was a distributed RTOS, developed by Eonic Systems until the technology was sold to Wind River Systems in 2001. Its overall functionality of transparent parallel processing (called the Virtual Single Processor runtime model) was a major driving force to redevelop it in a better way.[6][7] OpenComRTOS is conceptually a fourth generation of Virtuoso although it was a clean room development. The Virtuoso RTOS had its origin in the pioneering INMOS Transputer, a partial hardware implementation of C.A.R. Hoare's Communicating Sequential Processes (CSP) process algebra. Most challenging applications:[citation needed]

  1. Oil exploration system with 12000 processors featuring microcontrollers, fixed point and floating point DSPs and a Linux host in a single network.
  2. Sonar system with 1600 floating point DSPs.
  3. Rosetta and Giotto ESA space missions.
  4. Converting a 400000 lines application running on a POSIX style RTOS to OpenComRTOS.

Formal development approach[]

For the development of OpenComRTOS a systematic but iterative engineering process was followed. Requirements and specifications being defined, models were developed in Leslie Lamport's Temporal logic of actions (TLA+) and then model checked with the corresponding TLC model checker. Based on these models, the code was written and then a third person created new models in TLA+ to verify that the implementation was still isomorphic. The timer and associated time-out functionality for services were model checked using the Uppaal Model Checker. In 2011 Springer published the book on the OpenComRTOS project.[8]

OpenComRTOS Designer: development environment and tools[]

OpenComRTOS comes with a number of tools. Visual Designer is a visual modelling environment whereby the user specifies node topology and application topology in a graphical way. From these diagrams an application specific runtime model is generated. Application specific code is provided in ANSI-C for each task. Runtime execution, as well as inter-processor interactions, are visualised using the Event Tracer. A System Inspector allows reading out and modifying the data structures. Additional modules are hostserver modules (these allow any task access to the host node services) and a Safe Virtual Machine for C. The latter requires about 3 KiBytes (10 KiBytes for program and data) and allows dynamically downloading binary-compiled C code at runtime.

Portability[]

OpenComRTOS was developed for embedded systems and is written in portable , except the context switch and ISR interfaces. OpenComRTOS has been ported to the following targets: Freescale PowerPC, Texas Instruments C66xx DSP, Melexis MLX16, ARM Cortex M3/4, Xilinx MicroBlaze, LEON3, NXP CoolFlux DSP and to MS-Windows and Linux. The latter versions allow transparent integration of host nodes and serve as well cross development and simulation systems. As the RTOS kernel is identical for single or multi-processor nodes, supporting a multi-processor system requires only to write a small task level driver that can send and receives Packets.

OpenComRTOS is made available in binary, source code and Open Technology licenses. The latter provides formal models, design documents, source code and test suites.

References[]

  1. ^ E, Verhulst. "Beyond the von Neumann machine: communication as the driving design paradigm for MP-SOC from software to hardware". Kluwer Academic Publishers Hingham, MA, USA, Networks on chip, 1993, Pages: 217–238
  2. ^ E. Verhulst. "Virtuoso : providing sub-microsecond context switching on dsps with a dedicated nanokernel". International conference on signal processing applications and technology, Santa Clara, September, 1993.
  3. ^ E. Verhulst. "Beyond transputing : fully distributed semantics in Virtuoso’s Virtual Single Processor programming model and its implementation on of-the-shelf parallel DSPs". In Proceedings of WoTUG-20: Parallel Programming and Java, 1997, pages 77–86.
  4. ^ E. Verhulst. "Non-sequential processing: bridging the semantic gap left by the von Neumann architecture". In Signal Processing Systems SIPS’97, pages 35–49.
  5. ^ E. Verhulst. "The rationale for distributed semantics as a topology independent embedded systems design methodology and its implementation in the Virtuoso RTOS". Design Automation for Embedded Systems, 2002, 6:277–294. doi:10.1023/A:1014018820691.
  6. ^ E. Verhulst, G. de Jong. "OpenComRTOS: an ultra-small network centric embedded RTOS designed using formal modeling". In Proceedings of the 13th international SDL Forum conference on Design for dependable systems, SDL’07, pages 258–271, Berlin, Heidelberg. Springer-Verlag.
  7. ^ Eric Verhulst, Gjalt de Jong, Vitaliy Mezhuyev. "An industrial case: Pitfalls and benefits of applying formal methods to the development of a network-centric RTOS". In Cuellar, J., Maibaum, T., and Sere, K., editors, FM 2008: Formal Methods, volume 5014 of Lecture Notes in Computer Science, pages 411–418. Springer Berlin / Heidelberg.
  8. ^ Formal Development of a Network-Centric RTOS: Software Engineering for Reliable Embedded Systems by Eric Verhulst, Raymond T. Boute, José Miguel Sampaio Faria and Bernhard H.C. Sputh (ISBN 978-1-4419-9735-7) 1st Edition., 2011, XVII, 219 p. 54 illus

External links[]

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