Re: [PATCH v5 02/11] mm/mempolicy: introduce MPOL_WEIGHTED_INTERLEAVE for weighted interleaving

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Gregory Price <gregory.price@xxxxxxxxxxxx> writes:

> On Thu, Jan 04, 2024 at 01:39:31PM +0800, Huang, Ying wrote:
>> Gregory Price <gregory.price@xxxxxxxxxxxx> writes:
>> 
>> > On Wed, Jan 03, 2024 at 01:46:56PM +0800, Huang, Ying wrote:
>> >> Gregory Price <gregory.price@xxxxxxxxxxxx> writes:
>> >> > I'm specifically concerned about:
>> >> > 	weighted_interleave_nid
>> >> > 	alloc_pages_bulk_array_weighted_interleave
>> >> >
>> >> > I'm unsure whether kmalloc/kfree is safe (and non-offensive) in those
>> >> > contexts. If kmalloc/kfree is safe fine, this problem is trivial.
>> >> >
>> >> > If not, there is no good solution to this without pre-allocating a
>> >> > scratch area per-task.
>> >> 
>> >> You need to audit whether it's safe for all callers.  I guess that you
>> >> need to allocate pages after calling, so you can use the same GFP flags
>> >> here.
>> >> 
>> >
>> > After picking away i realized that this code is usually going to get
>> > called during page fault handling - duh.  So kmalloc is almost never
>> > safe (or can fail), and we it's nasty to try to handle those errors.
>> 
>> Why not just OOM for allocation failure?
>>
>
> 2 notes:
>
> 1) callers of weighted_interleave_nid do not expect OOM conditions, they
>    expect a node selection.  On error, we would simply return the local
>    numa node without indication of failure.
>
> 2) callers of alloc_pages_bulk_array_weighted_interleave receive the
>    total number of pages allocated, and they are expected to detect
>    pages allocated != pages requested, and then handle whether to
>    OOM or simply retry (allocation may fail for a variety of reasons).
>
> By introducing an allocation into this area, if an allocation failure
> occurs, we would essentially need to silently squash it and return
> either local_node (interleave_nid) or return 0 (bulk allocator) and
> allow the allocation logic to handle any subsequent OOM condition.
>
> That felt less desirable than just allocating a scratch space up front
> in the mempolicy and avoiding the issue altogether.
>
>> > Instead of doing that, I simply chose to implement the scratch space
>> > in the mempolicy structure
>> >
>> > mempolicy->wil.scratch_weights[MAX_NUMNODES].
>> >
>> > We eat an extra 1kb of memory in the mempolicy, but it gives us a safe
>> > scratch space we can use any time the task is allocating memory, and
>> > prevents the need for any fancy error handling.  That seems like a
>> > perfectly reasonable tradeoff.
>> 
>> I don't think that this is a good idea.  The weight array is temporary.
>> 
>
> It's temporary, but it's also only used in the context of the task while
> the alloc lock is held.
>
> If you think it's fine to introduce another potential OOM generating
> spot, then I'll just go ahead and allocate the memory on the fly.
>
> I do want to point out, though, that weighted_interleave_nid is called
> per allocated page.  So now we're not just collecting weights to
> calculate the offset, we're doing an allocation (that can fail) per page
> allocated for that region.
>
> The bulk allocator amortizes the cost of this allocation by doing it
> once while allocating a chunk of pages - but the weighted_interleave_nid
> function is called per-page.
>
> By comparison, the memory cost to just allocate a static scratch area in
> the mempolicy struct is only incurred by tasks with a mempolicy.
>
>
> So we're talking ~1MB for 1024 threads with mempolicies to avoid error
> conditions mid-page-allocation and to reduce the cost associated with
> applying weighted interleave.

Think about this again.  Why do we need weights array on stack?  I think
this is used to keep weights consistent.  If so, we don't need weights
array on stack.  Just use RCU to access global weights array.

--
Best Regards,
Huang, Ying




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