Re: [PATCH] mm: skip current when memcg reclaim

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On Tue, Oct 19, 2021 at 9:24 PM Michal Hocko <mhocko@xxxxxxxx> wrote:
>
> On Tue 19-10-21 20:17:16, Zhaoyang Huang wrote:
> > On Tue, Oct 19, 2021 at 5:09 PM Michal Hocko <mhocko@xxxxxxxx> wrote:
> > >
> > > On Tue 19-10-21 15:11:30, Zhaoyang Huang wrote:
> > > > On Mon, Oct 18, 2021 at 8:41 PM Michal Hocko <mhocko@xxxxxxxx> wrote:
> > > > >
> > > > > On Mon 18-10-21 17:25:23, Zhaoyang Huang wrote:
> > > > > > On Mon, Oct 18, 2021 at 4:23 PM Michal Hocko <mhocko@xxxxxxxx> wrote:
> > > [...]
> > > > > > > I would be really curious about more specifics of the used hierarchy.
> > > > > > What I am facing is a typical scenario on Android, that is a big
> > > > > > memory consuming APP(camera etc) launched while background filled by
> > > > > > other processes. The hierarchy is like what you describe above where B
> > > > > > represents the APP and memory.low is set to help warm restart. Both of
> > > > > > kswapd and direct reclaim work together to reclaim pages under this
> > > > > > scenario, which can cause 20MB file page delete from LRU in several
> > > > > > second. This change could help to have current process's page escape
> > > > > > from being reclaimed and cause page thrashing. We observed the result
> > > > > > via systrace which shows that the Uninterruptible sleep(block on page
> > > > > > bit) and iowait get smaller than usual.
> > > > >
> > > > > I still have hard time to understand the exact setup and why the patch
> > > > > helps you. If you want to protect B more than the low limit would allow
> > > > > for by stealiong from C then the same thing can happen from anybody
> > > > > reclaiming from C so in the end there is no protection. The same would
> > > > > apply for any global direct memory reclaim done by a 3rd party. So I
> > > > > suspect that your patch just happens to work by a luck.
> > > > B and C compete fairly and superior than others. The idea based on
> > > > assuming NOT all groups will trap into direct reclaim concurrently, so
> > > > we want to have the groups steal pages from the processes under
> > > > root(Non-memory sensitive) or other groups with lower thresholds(high
> > > > memory tolerance) or the one totally sleeping(not busy for the time
> > > > being, borrow some pages).
> > >
> > > I am really confused now. The memcg reclaim cannot really reclaim
> > > anything from outside of the reclaimed hierarchy. Protected memcgs are
> > > only considered if the reclaim was not able to reclaim anything during
> > > the first hierarchy walk. That would imply that the reclaimed hierarchy
> > > has either all memcgs with memory protected or non-protected memcgs do
> > > not have any memory to reclaim.
> > >
> > > I think it would really help to provide much details about what is going
> > > on here before we can move forward.
> > >
> > > > > Why both B and C have low limit setup and they both cannot be reclaimed?
> > > > > Isn't that a weird setup where A hard limit is too close to sum of low
> > > > > limits of B and C?
> > > > >
> > > > > In other words could you share a more detailed configuration you are
> > > > > using and some more details why both B and C have been skipped during
> > > > > the first pass of the reclaim?
> > > > My practical scenario is that important processes(vip APP etc) are
> > > > placed into protected memcg and keep other processes just under root.
> > > > Current introduces direct reclaim because of alloc_pages(DMA_ALLOC
> > > > etc), in which the number of allocation would be much larger than low
> > > > but would NOT be charged to LRU. Whereas, current also wants to keep
> > > > the pages(.so files to exec) on LRU.
> > >
> > > I am sorry but this description makes even less sense to me. If your
> > > important process runs under a protected memcg and everything else is
> > > running under root memcg then your memcg will get protected as long as
> > > there is a reclaimable memory. There should ever be only global memory
> > > reclaim happening, unless you specify a hard/high limit on your
> > > important memcg. If you do so then there is no way to reclaim from
> > > outside of that specific memcg.
> > >
> > > I really fail how your patch can help with either of those situations.
> >
> > please find cgv2 hierarchy on my sys[1], where uid_2000 is a cgroup
> > under root and trace_printk info[3] from trace_printk embedded in
> > shrink_node[2]. I don't why you say there should be no reclaim from
> > groups under root which opposite to[3]
>
> That is not what I am saying. I am saying the protected (by low limit)
> memcgs only get reclaimed if there is no reclaim progress from the
> reclaimed hierarchy. In your case that would mean that there is no
> reclaim from the root cgroup.
Do you mean that direct reclaim should succeed for the first round
reclaim within which memcg get protected by memory.low and would NOT
retry by setting memcg_low_reclaim to true? It is not true in android
like system, where reclaim always failed and introduce lmk and even
OOM.
>
> > [1]
> > /sys/fs/cgroup # ls uid_2000
> > cgroup.controllers  cgroup.max.depth        cgroup.stat
> > cgroup.type   io.pressure     memory.events.local  memory.max
> > memory.pressure      memory.swap.events
> > cgroup.events       cgroup.max.descendants  cgroup.subtree_control
> > cpu.pressure  memory.current  memory.high          memory.min
> > memory.stat          memory.swap.max
> > cgroup.freeze       cgroup.procs            cgroup.threads
> > cpu.stat      memory.events   memory.low           memory.oom.group
> > memory.swap.current  pid_275
>
> This doesn't really help to make a better picture because it doesn't
> tell the configuration. It would help to print all cgroups with memory
> controller enabled and print memory.* values.
>
> > [2]
> > @@ -2962,6 +2962,7 @@ static bool shrink_node(pg_data_t *pgdat, struct
> > scan_control *sc)
> >
> >                         reclaimed = sc->nr_reclaimed;
> >                         scanned = sc->nr_scanned;
> > +                     trace_printk("root %x memcg %x reclaimed
> > %ld\n",root_mem_cgroup,memcg,sc->nr_reclaimed);
> >                         shrink_node_memcg(pgdat, memcg, sc, &lru_pages);
> >                         node_lru_pages += lru_pages;
> >
> > [3]
> >  allocator@4.0-s-1034    [005] ....   442.077013: shrink_node: root
> > ef022800 memcg ef027800 reclaimed 41
> >    kworker/u16:3-931     [002] ....   442.077019: shrink_node: root
> > ef022800 memcg c7e54000 reclaimed 17
> >  allocator@4.0-s-1034    [005] ....   442.077019: shrink_node: root
> > ef022800 memcg ef025000 reclaimed 41
> >  allocator@4.0-s-1034    [005] ....   442.077024: shrink_node: root
> > ef022800 memcg ef023000 reclaimed 41
> >    kworker/u16:3-931     [002] ....   442.077026: shrink_node: root
> > ef022800 memcg c7e57800 reclaimed 17
> >  allocator@4.0-s-1034    [005] ....   442.077028: shrink_node: root
> > ef022800 memcg ef026800 reclaimed 41
>
> It is impossible to tell which memcgs those are. It also doesn't tell
> anything whether low limit has been broken due to lack of progress.
> --
> Michal Hocko
> SUSE Labs




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