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I am reading Linux Kernel Development recently, and I have a few questions related to disabling preemption.

  1. In the "Interrupt Control" section of chapter 7, it says:

    Moreover, disabling interrupts also disables kernel preemption.

    I also read from the book that kernel preemption can occur in the follow cases:

    When an interrupt handler exits, before returning to kernel-space.
    When kernel code becomes preemptible again.
    If a task in the kernel explicitly calls schedule()
    If a task in ther kernel blocks (which results in a call to schedule())

    But I can't relate disabling interrupts with these cases.

  2. As far as I know, a spinlock would disable preemption with the preempt_disable() function.

    The post What exactly are "spin-locks"? says:

    On a single core machine a spinlock is simply a "disable interrupts" or "raise IRQL" which prevents thread scheduling completely.

    Does preempt_disable() disable preemption by disabling interrupts?

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2 Answers 2

up vote 1 down vote accepted

I am not a scheduler guru, but I would like to explain how I see it. Here are several things.

  1. preempt_disable() doesn't disable IRQ. It just increases a thread_info->preempt_count variable
  2. Disabling interrupts also disables preemption because scheduler isn't working after that - but only on a single-CPU machine. On the SMP it isn't enough because when you close the interrupts on one CPU the other / others still does / do something asynchronously.
  3. The Big Lock (means - closing all interrupts on all CPUs) is slowing the system down dramatically - so it is why it not anymore in use. This is also the reason why preempt_disable() doesn't close the IRQ.

You can see what is preempt_disable(). Try this: 1. Get a spinlock. 2. Call schedule()

In the dmesg you will see something like "BUG: scheduling while atomic". This happens when scheduler detects that your process in atomic (not preemptive) context but it schedules itself.

Good luck.

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Thank you for your detailed answer. But I still don't understand why scheduler isn't working after disabling interrupts on a single-CPU machine. –  feirainy Dec 27 '13 at 2:37
    
No interrupts - no clock. No clock - no timers. –  Sebastian Mountaniol Dec 27 '13 at 7:02

In a test kernel module I wrote to monitor/profile a task, I've tried disabling interrupts by:

1 - Using local_irq_save()

2 - Using spin_lock_irqsave()

3 - Manually disable_irq() to all IRQs in /proc/interrupts

In all 3 cases I could still use the hrtimer to measure time even though IRQs were disabled (and a task I was monitoring got preempted as well).

I find this veeeeerrrryyyy strange... I personally was anticipating what Sebastian Mountaniol pointed out -> No interrupts - no clock. No clock - no timers...

Linux kernel 2.6.32 on a single core, single CPU... Can anyone have a better explanation ?

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I thought some of the Linux kernel timers use a trick of last timer interrupt plus the CPU cycle timer. So you'd get accurate time until the cycle counter overflow. –  Zan Lynx Feb 24 at 21:58
    
Ahhhh.... Very clever implementation :) –  user3297145 Feb 27 at 20:49

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