Re: [PATCH v2 2/7] sched/fair: Decay task PELT values during migration

From: Vincent Guittot
Date: Wed Jan 19 2022 - 08:22:51 EST


On Wed, 19 Jan 2022 at 12:59, Vincent Donnefort
<vincent.donnefort@xxxxxxx> wrote:
>
> [...]
>
> > > >
> > > > This has several shortfalls:
> > > > - have a look at cfs_rq_clock_pelt() and rq_clock_pelt(). What you
> > > > name clock_pelt in your commit message and is used to update PELT and
> > > > saved in se->avg.last_update_time is : rq->clock_pelt -
> > > > rq->lost_idle_time - cfs_rq->throttled_clock_task_time
> > >
> > > That's why, the PELT "lag" is added onto se->avg.last_update_time. (see the last
> > > paragraph of the commit message) The estimator is just a time delta, that is
> > > added on top of the entity's last_update_time. I don't see any problem with the
> > > lost_idle_time here.
> >
> > lost_idle_time is updated before entering idle and after your
> > clock_pelt_lag has been updated. This means that the delta that you
> > are computing can be wrong
> >
> > I haven't look in details but similar problem probably happens for
> > throttled_clock_task_time
> >
> > >
> > > > - you are doing this whatever the state of the cpu : idle or not. But
> > > > the clock cycles are not accounted for in the same way in both cases.
> > >
> > > If the CPU is idle and clock_pelt == clock_task, the component A of the
> > > estimator would be 0 and we only would account for how outdated is the rq's
> > > clock, i.e. component B.
> >
> > And if cpu is not idle, you can't apply the diff between clk_pelt and clock_task
> >
> > >
> > > > - (B) doesn't seem to be accurate as you skip irq and steal time
> > > > accounting and you don't apply any scale invariance if the cpu is not
> > > > idle
> > >
> > > The missing irq and paravirt time is the reason why it is called "estimator".
> > > But maybe there's a chance of improving this part with a lockless version of
> > > rq->prev_irq_time and rq->prev_steal_time_rq?
> > >
> > > > - IIUC your explanation in the commit message above, the (A) period
> > > > seems to be a problem only when idle but you apply it unconditionally.
> > >
> > > If the CPU is idle (and clock_pelt == clock_task), only the B part would be
> > > worth something:
> > >
> > > A + B = [clock_task - clock_pelt] + [sched_clock_cpu() - clock]
> > > A B
> > >
> > > > If cpu is idle you can assume that clock_pelt should be equal to
> > > > clock_task but you can't if cpu is not idle otherwise your sync will
> > > > be inaccurate and defeat the primary goal of this patch. If your
> > > > problem with clock_pelt is that the pending idle time is not accounted
> > > > for when entering idle but only at the next update (update blocked
> > > > load or wakeup of a thread). This patch below should fix this and
> > > > remove your A.
> > >
> > > That would help slightly the current situation, but this part is already
> > > covered by the estimator.
> >
> > But the estimator, as you name it, is wrong beaus ethe A part can't be
> > applied unconditionally
>
> Hum, it is used only in the !active migration. So we know the task was sleeping
> before that migration. As a consequence, the time we need to account is "sleeping"
> time from the task point of view, which is clock_pelt == clock_task (for
> __update_load_avg_blocked_se()). Otherwise, we would only decay with the
> "wallclock" idle time instead of the "scaled" one wouldn't we?

clock_pelt == clock_task only when cpu is idle and after updating
lost_idle_time but you have no idea of the state of the cpu when
migrating the task

>
>
> +-------------+--------------
> | Task A | Task B .....
> ^ ^ ^
> | | migrate A
> | | |
> | | |
> | | |
> | |<----------->|
> | Wallclock Task A idle time
> |<---------------->|
> "Scaled" Task A idle time
>
>
> [...]