Re: [PATCH v6 2/3] CPU hotplug, stop-machine: Plug race-window that leads to "IPI-to-offline-CPU"
From: Frederic Weisbecker
Date: Fri May 23 2014 - 11:05:04 EST
On Fri, May 23, 2014 at 08:15:35PM +0530, Srivatsa S. Bhat wrote:
> On 05/23/2014 06:52 PM, Frederic Weisbecker wrote:
> > On Fri, May 23, 2014 at 03:42:20PM +0530, Srivatsa S. Bhat wrote:
> >> During CPU offline, stop-machine is used to take control over all the online
> >> CPUs (via the per-cpu stopper thread) and then run take_cpu_down() on the CPU
> >> that is to be taken offline.
> >>
> >> But stop-machine itself has several stages: _PREPARE, _DISABLE_IRQ, _RUN etc.
> >> The important thing to note here is that the _DISABLE_IRQ stage comes much
> >> later after starting stop-machine, and hence there is a large window where
> >> other CPUs can send IPIs to the CPU going offline. As a result, we can
> >> encounter a scenario as depicted below, which causes IPIs to be sent to the
> >> CPU going offline, and that CPU notices them *after* it has gone offline,
> >> triggering the "IPI-to-offline-CPU" warning from the smp-call-function code.
> >>
> >>
> >> CPU 1 CPU 2
> >> (Online CPU) (CPU going offline)
> >>
> >> Enter _PREPARE stage Enter _PREPARE stage
> >>
> >> Enter _DISABLE_IRQ stage
> >>
> >>
> >> =
> >> Got a device interrupt, | Didn't notice the IPI
> >> and the interrupt handler | since interrupts were
> >> called smp_call_function() | disabled on this CPU.
> >> and sent an IPI to CPU 2. |
> >> =
> >>
> >>
> >> Enter _DISABLE_IRQ stage
> >>
> >>
> >> Enter _RUN stage Enter _RUN stage
> >>
> >> =
> >> Busy loop with interrupts | Invoke take_cpu_down()
> >> disabled. | and take CPU 2 offline
> >> =
> >>
> >>
> >> Enter _EXIT stage Enter _EXIT stage
> >>
> >> Re-enable interrupts Re-enable interrupts
> >>
> >> The pending IPI is noted
> >> immediately, but alas,
> >> the CPU is offline at
> >> this point.
> >>
> >>
> >>
> >> So, as we can observe from this scenario, the IPI was sent when CPU 2 was
> >> still online, and hence it was perfectly legal. But unfortunately it was
> >> noted only after CPU 2 went offline, resulting in the warning from the
> >> IPI handling code. In other words, the fault was not at the sender, but
> >> at the receiver side - and if we look closely, the real bug is in the
> >> stop-machine sequence itself.
> >>
> >> The problem here is that the CPU going offline disabled its local interrupts
> >> (by entering _DISABLE_IRQ phase) *before* the other CPUs. And that's the
> >> reason why it was not able to respond to the IPI before going offline.
> >>
> >> A simple solution to this problem is to ensure that the CPU going offline
> >> disables its interrupts only *after* the other CPUs do the same thing.
> >> To achieve this, split the _DISABLE_IRQ state into 2 parts:
> >>
> >> 1st part: MULTI_STOP_DISABLE_IRQ_INACTIVE, where only the non-active CPUs
> >> (i.e., the "other" CPUs) disable their interrupts.
> >>
> >> 2nd part: MULTI_STOP_DISABLE_IRQ_ACTIVE, where the active CPU (i.e., the
> >> CPU going offline) disables its interrupts.
> >>
> >> With this in place, the CPU going offline will always be the last one to
> >> disable interrupts. After this step, no further IPIs can be sent to the
> >> outgoing CPU, since all the other CPUs would be executing the stop-machine
> >> code with interrupts disabled. And by the time stop-machine ends, the CPU
> >> would have gone offline and disappeared from the cpu_online_mask, and hence
> >> future invocations of smp_call_function() and friends will automatically
> >> prune that CPU out. Thus, we can guarantee that no CPU will end up
> >> *inadvertently* sending IPIs to an offline CPU.
> >>
> >> Signed-off-by: Srivatsa S. Bhat <srivatsa.bhat@xxxxxxxxxxxxxxxxxx>
> >> ---
> >>
> >> kernel/stop_machine.c | 39 ++++++++++++++++++++++++++++++++++-----
> >> 1 file changed, 34 insertions(+), 5 deletions(-)
> >>
> >> diff --git a/kernel/stop_machine.c b/kernel/stop_machine.c
> >> index 01fbae5..288f7fe 100644
> >> --- a/kernel/stop_machine.c
> >> +++ b/kernel/stop_machine.c
> >> @@ -130,8 +130,10 @@ enum multi_stop_state {
> >> MULTI_STOP_NONE,
> >> /* Awaiting everyone to be scheduled. */
> >> MULTI_STOP_PREPARE,
> >> - /* Disable interrupts. */
> >> - MULTI_STOP_DISABLE_IRQ,
> >> + /* Disable interrupts on CPUs not in ->active_cpus mask. */
> >> + MULTI_STOP_DISABLE_IRQ_INACTIVE,
> >> + /* Disable interrupts on CPUs in ->active_cpus mask. */
> >> + MULTI_STOP_DISABLE_IRQ_ACTIVE,
> >> /* Run the function */
> >> MULTI_STOP_RUN,
> >> /* Exit */
> >> @@ -189,12 +191,39 @@ static int multi_cpu_stop(void *data)
> >> do {
> >> /* Chill out and ensure we re-read multi_stop_state. */
> >> cpu_relax();
> >> +
> >> + /*
> >> + * We use 2 separate stages to disable interrupts, namely
> >> + * _INACTIVE and _ACTIVE, to ensure that the inactive CPUs
> >> + * disable their interrupts first, followed by the active CPUs.
> >> + *
> >> + * This is done to avoid a race in the CPU offline path, which
> >> + * can lead to receiving IPIs on the outgoing CPU *after* it
> >> + * has gone offline.
> >> + *
> >> + * During CPU offline, we don't want the other CPUs to send
> >> + * IPIs to the active_cpu (the outgoing CPU) *after* it has
> >> + * disabled interrupts (because, then it will notice the IPIs
> >> + * only after it has gone offline). We can prevent this by
> >> + * making the other CPUs disable their interrupts first - that
> >> + * way, they will run the stop-machine code with interrupts
> >> + * disabled, and hence won't send IPIs after that point.
> >> + */
> >> +
> >> if (msdata->state != curstate) {
> >> curstate = msdata->state;
> >> switch (curstate) {
> >> - case MULTI_STOP_DISABLE_IRQ:
> >> - local_irq_disable();
> >> - hard_irq_disable();
> >> + case MULTI_STOP_DISABLE_IRQ_INACTIVE:
> >> + if (!is_active) {
> >> + local_irq_disable();
> >> + hard_irq_disable();
> >> + }
> >> + break;
> >> + case MULTI_STOP_DISABLE_IRQ_ACTIVE:
> >> + if (is_active) {
> >> + local_irq_disable();
> >> + hard_irq_disable();
> >> + }
> >
> > Do we actually need that now that we are flushing the ipi queue on CPU dying?
> >
>
> Yes, we do. Flushing the IPI queue is one thing - it guarantees that a CPU
> doesn't go offline without finishing its work. Not receiving IPIs after going
> offline is a different thing - it helps avoid warnings from the IPI handling
> code (although it will be harmless if the queue had been flushed earlier).
I'm confused. Perhaps I don't understand well how things mix up. How does it avoid the warning.
Isn't there still a risk that some IPI don't fire due to hardware latency.
I mean either we do:
local_irq_enable()
wait_for_pending_ipi()
local_irq_disable()
Or we do
hotplug_cpu_down {
flush_ipi()
}
But something in between looks broken:
local_irq_disable()
local_irq_enable()
flush_ipi()
>
> So I think it is good to have both, so that we can keep CPU offline very
> clean - no pending work left around, as well as no possibility of (real or
> spurious) warnings.
Ah may be what you want to avoid is this:
CPU 0 CPU 1
-------------------------
send IPI to 1
flush_ipi()
set_cpu_offline()
get_ipi()
//get late IPI but queue is flushed already
smp_single_function_interrupt() {
WARN()
Yeah but still, your patch doesn't deal with late hardware IPI.
How about we move the warning to the IPI callback iterator:
- WARN_ON_ONCE(cpu_is_offline())
llist_for_each(...) {
+ WARN_ON_ONCE(cpu_is_offline())
csd->func()
}
Since what matters is that all functions are executed before going offline.
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