[RFC PATCH RT v2 0/2] Add PINNED_HARD mode to hrtimers

From: Juri Lelli
Date: Wed Jun 16 2021 - 03:17:28 EST


Hi,

I rebased an RFC series I already proposed a while ago [1] and I'd like
people to consider it again for inclusion.

When running cyclictest on isolated CPUs with timer_migration enabled,
the following, where CPU0 is one of the housekeeping CPUs and CPU2 is
isolated, is (of course) happening:

<idle>-0 [000] ... hrtimer_cancel: hrtimer=0xffffb4a74be7fe70
<idle>-0 [000] ... hrtimer_expire_entry: hrtimer=0xffffb4a74be7fe70 now=144805770984 function=hrtimer_wakeup/0x0
<idle>-0 [000] ... sched_wakeup: cyclictest:1171 [4] success=1 CPU:002
<idle>-0 [000] ... hrtimer_expire_exit: hrtimer=0xffffb4a74be7fe70
<idle>-0 [002] ... sched_switch: swapper/2:0 [120] R ==> cyclictest:1171 [4]
cyclictest-1171 [002] ... hrtimer_init: hrtimer=0xffffb4a74be7fe70 clockid=CLOCK_MONOTONIC mode=0x8
cyclictest-1171 [002] ... hrtimer_start: hrtimer=0xffffb4a74be7fe70 function=hrtimer_wakeup/0x0 ...
cyclictest-1171 [002] ... sched_switch: cyclictest:1171 [4] S ==> swapper/2:0 [120]

While cyclitest is arming the hrtimer while running on isolated CPU2
(by means of clock_nanosleep), the hrtimer is then firing on CPU0. This
is due to the fact that switch_hrtimer_base(), called at hrtimer enqueue
time, will prefer to enqueue the timer on an housekeeping !idle CPU, if
the timer is not pinned, as per timer_migration feature.

The problem with this is that we are measuring wake up latencies across
isolated and !isolated domains, which is against the purpose of
configuring the latter, while having timer_migration enabled is required
for certain workloads that are not using timers and don't want to be
ever interrupted.

Since PREEMPT_RT already forces HARD mode for hrtimers armed by tasks
running with RT policies, it seems to make sense to also force PINNED
mode under the same conditions.

This set implements the behavior, achieving something like the
following:

<idle>-0 [002] ... hrtimer_cancel: hrtimer=0xffffafbacc19fe78
<idle>-0 [002] ... hrtimer_expire_entry: hrtimer=0xffffafbacc19fe78 now=104335855898 function=hrtimer_wakeup/0x0
<idle>-0 [002] ... sched_wakeup: cyclictest:1165 [4] success=1 CPU:002
<idle>-0 [002] ... hrtimer_expire_exit: hrtimer=0xffffafbacc19fe78
<idle>-0 [002] ... sched_switch: swapper/2:0 [120] R ==> cyclictest:1165 [4]
cyclictest-1165 [002] ... hrtimer_init: hrtimer=0xffffafbacc19fe78 clockid=CLOCK_MONOTONIC mode=0xa
cyclictest-1165 [002] ... hrtimer_start: hrtimer=0xffffafbacc19fe78 function=hrtimer_wakeup/0x0 ...
cyclictest-1165 [002] ... sched_switch: cyclictest:1165 [4] S ==> swapper/2:0 [120]

Sebastian didn't look against the proposed changes, but I didn't follow
up back then because it looked like we could meet workloads requirements
at that time w/o this set. Now things have changed, looks like the mix
of the two types of workloads - interrupt driven and always running - is
very relevant and we need to accommodate both types on the same system
setup.

Does this still make sense or do you suggest alternative approaches?

Thanks!

- Juri

1 - https://lore.kernel.org/lkml/20190214133716.10187-1-juri.lelli@xxxxxxxxxx/

Juri Lelli (2):
time/hrtimer: Add PINNED_HARD mode for realtime hrtimers
time/hrtimer: Embed hrtimer mode into hrtimer_sleeper

include/linux/hrtimer.h | 3 +++
kernel/time/hrtimer.c | 13 +++++++------
2 files changed, 10 insertions(+), 6 deletions(-)

--
2.31.1