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I was reading this article, but my question is on a generic level, I was thinking along the following lines:

  1. Can a kernel be called real time just because it has a real time scheduler? Or in other words, say I have a linux kernel, and if I change the default scheduler from O(1) or CFS to a real time scheduler, will it become an RTOS?
  2. Does it require any support from the hardware? Generally I have seen embedded devices having an RTOS (eg VxWorks, QNX), do these have any special provisions/hw to support them? I know RTOS process's running time is deterministic, but then one can use longjump/setjump to get the output in determined time.

I'd really appreciate some input/insight on it, if I am wrong about something, please correct me.

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All "real-time" means is that interrupt latency (time during which interrupts are disabled) is guaranteed to be less than some specified number of microseconds. In other words, the kernel guarantees that it can respond to incoming external events up to some maximum frequency (1/maxlatency). It takes a lot of careful programming and testing of all interrupt-handling paths to make this guarantee. The actual details of how this is accomplished will depend on the kernel architecture. – Jim Garrison Mar 7 '14 at 4:16
    
@Jim: So, does it requires any support from the hardware? – brokenfoot Mar 7 '14 at 4:21
    
@JimGarrison: Can you please copy your comment into an answer ? – brokenfoot Mar 13 '14 at 20:14
up vote 5 down vote accepted

After doing some research, talking to poeple (Jamie Hanrahan, Juha Aaltonen @linkedIn Group - Device Driver Experts) and ofcourse the input from @Jim Garrison, this what I can conclude:

In Jamie Hanrahan's words-

What makes a kernel real time?
The sine qua non of a real time OS -

  • The ability to guarantee a maximum latency between an external interrupt and the start of the interrupt handler.

    Note that the maximum latency need not be particularly short (e.g. microseconds), you could have a real time OS that guaranteed an absolute maximum latency of 137 milliseconds.

  • A real time scheduler is one that offers completely predictable (to the developer) behavior of thread scheduling - "which thread runs next".

    This is generally separate from the issue of a guaranteed maximum latency to responding to an interrupt (since interrupt handlers are not necessarily scheduled like ordinary threads) but it is often necessary to implement a real-time application. Schedulers in real-time OSs generally implement a large number of priority levels. And they almost always implement priority inheritance, to avoid priority inversion situations.

So, it is good to have a guaranteed latency for an interrupt and predictability of thread scheduling, then why not make every OS real time?

  • Because an OS suited for general purpose use (servers and/or desktops) needs to have characteristics that are generally at odds with real-time latency guarantees.

    For example, a real-time scheduler should have completely predictable behavior. That means, among other things, that whatever priorities have been assigned to the various tasks by the developer should be left alone by the OS. This might mean that some low-priority tasks end up being starved for long periods of time. But the RT OS has to shrug and say "that's what the dev wanted." Note that to get the correct behavior, the RT system developer has to worry a lot about things like task priorities and CPU affinities.

    A general-purpose OS is just the opposite. You want to be able to just throw apps and services on it, almost always things written by many different vendors (instead of being one tightly integrated system as in most R-T systems), and get good performance. Perhaps not the absolute best possible performance, but good.

    Note that "good performance" is not just measured in interrupt latency. In particular, you want CPU and other resource allocations that are often described as "fair", without the user or admin or even the app developers having to worry much if at all about things like thread priorities and CPU affinities and NUMA nodes. One job might be more important than another, but in a general-purpose OS, that doesn't mean that the second job should get no resources at all.

    So the general purpose OS will usually implement time-slicing among threads of equal priority, and it may adjust the priorities of threads according to their past behavior (e.g. a CPU hog might have its priority reduced; an I/O bound thread might have its priority increased, so it can keep the I/O devices working; a CPU-starved thread might have its priority boosted so it can get a little bit of CPU time now and then).

Can a kernel be called real time just because it has a real time scheduler?

  • No, an RT scheduler is a necessary component of an RT OS, but you also need predictable behavior in other parts of the OS.

Does it require any support from the hardware?

  • In general, the simpler the hardware the more predictable its behavior is. So PCI-E is less predictable than PCI, and PCI is less predictable than ISA, etc. There are specific I/O buses that were designed for (among other things) easy predictability of e.g. interrupt latency, but a lot of R-T requirements can be met these days with commodity hardware.
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