Revision as of 09:12, 19 February 2022 edit Ipr1 (talk \| contribs) Extended confirmed users 1,003 edits let's not add soft/hard here (in between "softness" and "hardness" there is sometimes called "firm" real-time) ← Previous edit		Revision as of 19:28, 26 February 2022 edit undo Jerryobject (talk \| contribs) Extended confirmed users 16,305 edits WP:LINKs: update, adds. WP:REFerence WP:CITations: repeats cut; parameters: updates, corrects, reorders, adds, fills. MOS:FIRSTABBReviation [[WP:AB. Nonacronym proper noun WP:ALLCAPS > sentence case. WP:BADEMPHASIS WP:QUOTE marks > WP:ITALICs. Small WP:EoS WP:TERSE WP:COPYEDITs. Cut needless carriage return whitespace characters in sections: standardize, aid edits via mobile devices. WP:NAVBOXs: add, reorder more germane to top. Next edit →
Line 11: \| language = [[English language\|English]] \| operating system = [[Linux]] \| genre = [[Kernel (~~computer~~operating ~~science~~system)\|Kernel]] \| license = [[GNU General Public License#Version 2\|GPL2]] }} '''RTLinux''' is a [[hard realtime]] [[real-time operating system]] (RTOS) [[microkernel]] that runs the entire [[Linux]] [[operating system]] as a fully [[preemption (computing)\|preemptive]] process. The hard real-time property makes it possible to control robots, data acquisition systems, manufacturing plants, and other time-sensitive instruments and machines from RTLinux applications. The design was patented.<ref name="RTLinux Patent">{{cite web \|last1=yodaiken \|first1=victor \|title=Adding real-time support to general purpose operating systems \|url=https://patft.uspto.gov/netacgi/nph-Parser?Sect1=PTO2&Sect2=HITOFF&p=1&u=%2Fnetahtml%2FPTO%2Fsearch-bool.html&r=1&f=G&l=50&co1=AND&d=PTXT&s1=5,995,745.PN.&OS=PN/5,995,745&RS=PN/5,995,745 \|website=USPTO \|publisher=USPTO \|access-date=19 January 2022 \|ref=RTLPATENT}}</ref> Despite the similar name, it is not related to the [[Real-Time Linux]] project of the [[Linux Foundation]].<ref>{{cite web\|url=https://wiki.linuxfoundation.org/realtime/start\|title=realtime:start [Linux Foundation Wiki]\|website=wiki.linuxfoundation.org}}</ref> which is for soft real-time. Line 22 ⟶ 20: == Background == The key RTLinux design objective<ref name="Barabanov">{{cite ~~web~~report \|~~last1~~last=Barabanov \|~~first1~~first=Michael \|title=Introducing RTLinux \|url=https://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.302.3221 \|website=Citeseer \|publisher=Linux Journal \|access-date=19 January 2022 \|ref=RTLINUX}}</ref> was to add hard real-time capabilities to a commodity operating system to facilitate the development of complex control programs with both capabilities.<ref name="manifesto">~~"The~~{{cite ~~RTLinux~~report ~~Manifesto",~~\|last=Yodaiken \|first=Victor ~~Yodaiken,~~\|date=1999 \|title=The RTLinux Manifesto \|publisher=5th Linux Conference Proceedings, ~~1999, [~~\|url=http://www.yodaiken.com/papers/rtlmanifesto.pdf]}}</ref><ref name="redist">~~"Cheap~~{{cite ~~Operating~~report ~~systems Research",~~\|last=Yodaiken \|first=Victor ~~Yodaiken.~~\|date=1996 ~~Published~~\|title=Cheap inOperating ~~the~~systems Research \|publisher=Proceedings of the First Conference on Freely Redistributable Systems, \|place=Cambridge, MAMassachusetts, ~~1996~~ [\|url=http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.39.9505 ]}}</ref> For example, one might want to develop a real-time motor controller that used a commodity database and exported a web operator interface. Instead of attempting to build a single operating system that could support real-time and non-real-time capabilities, RTLinux was designed to share a computing device between a real-time and non-real-time operating system so that (1) the real-time operating system could never be blocked from execution by the non-real-time operating system and (2) components running in the two different environments could easily share data. As the name implies RTLinux was originally designed to use Linux as the non-real-time system<ref name="barabanov">{{cite ~~web~~thesis \|last=Barabanov \|first=Michael \|date=1996 \|type=M.S. \|url=http://www.yodaiken.com/papers/BarabanovThesis.pdf \|title=~~Barabanov, Michael (1996). "~~A Linux Based Real-Time Operating System"}}</ref> but it eventually evolved so that the RTCore real-time kernel could run with either Linux or [[Berkeley Software Distribution]] (BSD) ~~UNIX~~[[Unix]]. [[Multi-Environment Real-Time]] (MERT) was the first example of a real-time operating system coexisting with a ~~UNIX~~Unix system. MERT relied on traditional virtualization techniques: the real-time kernel was the ''host'' operating system (or [[hypervisor]]) and Bell Systems ~~UNIX~~Unix was the ''guest''. RTLinux was an attempt to update the MERT concept to the PC era and commodity hardware. It was also an attempt to also overcome the performance limits of MERT, particularly the overhead introduced by virtualization. Instead of encapsulating the guest OS in a virtual machine, RTLinux virtualized only the guest interrupt control. This method allowed the real-time kernel to convert the guest operating system into a system that was completely preemptible but that could still directly control, for example, storage devices. In particular, standard drivers for the guest worked without source modification although they needed to be recompiled to use the virtualization "hooks". See also [[paravirtualization]]. The ~~UNIX~~Unix "''[[Pipeline (Unix)\|pipe"]]'' was adapted to permit real-time and non-real-time programs to communicate, although other methods such as shared memory were also added. From the programmer's point of view, RTLinux originally looked like a small threaded environment for real-time tasks plus the standard Linux environment for everything else. The real-time operating system was implemented as a [[loadable kernel module]] which began by virtualizing guest interrupt control and then started a real-time scheduler. Tasks were assigned static priorities and scheduling was originally purely priority driven. The guest operating system was incorporated as the lowest priority task and essentially acted as the idle task for the real-time system. Real-time tasks ran in kernel mode. Later development of RTLinux adopted the Portable Operating System Interface ([[POSIX]]) [[POSIX threads]] application programming interface ([[API]]) and then permitted creation of threads in user mode with real-time threads running inside guest processes. In multiprocessor environments threads were locked to processor cores and it was possible to prevent the guest thread from running on designated core (effectively reserving cores for only real-time processing). == Implementation == RTLinux provides the ~~capability~~ability ofto ~~running~~run special real-time tasks and interrupt handlers on the same machine as standard Linux. These tasks and handlers execute when they need to execute no matter what Linux is doing. The worst case time between the moment a hardware interrupt is detected by the processor and the moment an interrupt handler starts to execute is under 15 microseconds on RTLinux running on a generic x86 (circa 2000). A RTLinux periodic task runs within 35 microseconds of its scheduled time on the same hardware. These times are hardware limited, and as hardware improves RTLinux will also improve. Standard Linux has excellent average performance and can even provide millisecond level scheduling precision for tasks using the POSIX soft real-time capabilities. Standard Linux is not, however, designed to provide sub-millisecond precision and reliable timing guarantees. RTLinux was based on a lightweight virtual machine where the Linux "guest" was given a virtualized interrupt controller and timer, and all other hardware access was direct. From the point of view of the real-time "host", the Linux kernel is a thread. Interrupts needed for deterministic processing are processed by the real-time core, while other interrupts are forwarded to Linux, which runs at a lower priority than real-time threads. Linux drivers handled almost all [[I/O]]. First-In-First-Out pipes ([[FIFO (computing and electronics)\|FIFO]]) or shared memory can be used to share data between the operating system and RTLinux. == Objective == The key RTLinux design objective is that the system should be transparent, modular, and extensible {{citation needed\|date=August 2021}}. Transparency means that there are no unopenable black boxes and the cost of any operation should be determinable. Modularity means that it is possible to omit functionality and the expense of that functionality if it is not needed. And extensibility means that programmers should be able to add modules and tailor the system to their requirements. The base RTLinux system supports high speed interrupt handling and no more. It has simple priority scheduler that can be easily replaced by schedulers more suited to the needs of some specific application. When developing RTLinux, it was designed to maximize the advantage we get from having Linux and its powerful capabilities available. == Core components == RTLinux is structured as a small core component and a set of optional components. The core component permits installation of very low latency interrupt handlers that cannot be delayed or preempted by Linux itself and some low level synchronization and interrupt control routines. This core component has been extended to support SMP and at the same time it has been simplified by removing some functionality that can be provided outside the core. == ~~Functionality~~Functions == ~~The majority of~~Most RTLinux ~~functionality~~functions isare in a ~~collection~~set of loadable kernel modules that provide optional services and levels of abstraction. These modules include:▼ ▲The majority of RTLinux functionality is in a collection of loadable kernel modules that provide optional services and levels of abstraction. These modules include: # rtl sched - a priority scheduler that supports both a "lite POSIX" interface described below and the original V1 RTLinux API. Line 54 ⟶ 49: == Realtime tasks == RTLinux realtime tasks get implemented as [[kernel module]]s similar to the type of module that Linux uses for drivers, file systems, and so on. Realtime tasks have direct access to the hardware and do not use virtual memory. On initialization, a realtime task (module) informs the RTLinux kernel of its deadline, period, and release-time constraints. == Threads == RT-Linux implements a POSIX API for a thread's manipulation. A thread is created by calling the <code>pthread_create</code> function. The third parameter of <code>pthread_create</code> is a function which contains the code executed by the thread. Line 104 ⟶ 97: * [[Xenomai]] * [[Preemption (computing)]] * [[Linux on embedded systems]] * [[Real-time testing]] == References == {{~~reflist~~Reflist}} ==Sources== {{refbegin}} * [http://www.yodaiken.com/papers/rtlmanifesto.pdf Yodaiken, Victor (1999). "The RTLinux Manifesto". Published in the 5th Linux Conference Proceedings] * [http://www.yodaiken.com/papers/BarabanovThesis.pdf Barabanov, Michael (1996). "A Linux Based Real-Time Operating System"] * [http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.39.9505 Yodaiken, Victor (1996). "Cheap Operating systems Research" Published in the Proceedings of the First Conference on Freely Redistributable Systems, Cambridge MA, 1996] * [http://www.ddj.com/cpp/184401758 Dougan, Cort (2004), "Precision and predictability for Linux and RTLinuxPro", Dr. Dobbs Journal, February 1, 2004] * [https://patentimages.storage.googleapis.com/99/da/90/31f19019130256/US5995745.pdf Yodaiken,Victor (1997), US Patent 5,995,745] Line 124 ⟶ 114: * {{webarchive \|date=2013-01-28 \|url=https://archive.today/20130128073427/http://www.linuxdevices.com/articles/AT3694406595.html \|title=Article about RT concept}} {{Real-time operating systems}}▼ {{Linux}} ▲{{Real-time operating systems}} {{Microkernels}} [[Category:Linux kernel variant]]

RTLinux: Difference between revisions