Re: [RESEND][PATCH v2] mm: don't call lru draining in the nested lru_cache_disable
From: David Hildenbrand
Date: Thu Jan 20 2022 - 03:42:32 EST
On 19.01.22 01:12, Minchan Kim wrote:
> On Mon, Jan 17, 2022 at 02:47:06PM +0100, Michal Hocko wrote:
>> On Thu 30-12-21 11:36:27, Minchan Kim wrote:
>>> lru_cache_disable involves IPIs to drain pagevec of each core,
>>> which sometimes takes quite long time to complete depending
>>> on cpu's business, which makes allocation too slow up to
>>> sveral hundredth milliseconds. Furthermore, the repeated draining
>>> in the alloc_contig_range makes thing worse considering caller
>>> of alloc_contig_range usually tries multiple times in the loop.
>>>
>>> This patch makes the lru_cache_disable aware of the fact the
>>> pagevec was already disabled. With that, user of alloc_contig_range
>>> can disable the lru cache in advance in their context during the
>>> repeated trial so they can avoid the multiple costly draining
>>> in cma allocation.
>>
>> Do you have any numbers on any improvements?
>
> The LRU draining consumed above 50% overhead for the 20M CMA alloc.
>
>>
>> Now to the change. I do not like this much to be honest. LRU cache
>> disabling is a complex synchronization scheme implemented in
>> __lru_add_drain_all now you are stacking another level on top of that.
>>
>> More fundamentally though. I am not sure I understand the problem TBH.
>
> The problem is that kinds of IPI using normal prority workqueue to drain
> takes much time depending on the system CPU business.
>
>> What prevents you from calling lru_cache_disable at the cma level in the
>> first place?
>
> You meant moving the call from alloc_contig_range to caller layer?
> So, virtio_mem_fake_online, too? It could and make sense from
> performance perspective since upper layer usually calls the
> alloc_contig_range multiple times on retrial loop.
>
^ I actually do have something like that on my TODO list.
The issue is that we have demanding requirements for
alloc_contig_range(), discussed in the past for CMA bulk allocations:
(1) Fast, unreliable allocations
Fail fast and let caller continue with next allocation instead of
retrying. Try to not degrade system performance.
(2) Slow, reliable allocations
Retry as good as possible. Degrading system performance (e.g., disabling
lru) is acceptable.
virtio-mem is usually (2), although there could be some use cases where
we first want to try (1) -- unplug as much memory as we can fast -- to
then fallback to (2) -- unplug what remains.
CMA bulk allocations are (1). "Ordinary" CMA is mostly (2) I'd assume.
--
Thanks,
David / dhildenb