Re: [PATCH v2 01/13] mm: support madvise(MADV_FREE)
From: Andy Lutomirski
Date: Wed Nov 04 2015 - 13:23:39 EST
On Tue, Nov 3, 2015 at 9:50 PM, Daniel Micay <danielmicay@xxxxxxxxx> wrote:
>> Does this set the write protect bit?
>>
>> What happens on architectures without hardware dirty tracking?
>
> It's supposed to avoid needing page faults when the data is accessed
> again, but it can just be implemented via page faults on architectures
> without a way to check for access or writes. MADV_DONTNEED is also a
> valid implementation of MADV_FREE if it comes to that (which is what it
> does on swapless systems for now).
I wonder whether arches without the requisite tracking should just
turn it off. While it might be faster than MADV_DONTNEED or munmap on
those arches, it doesn't really deserve to be faster.
>
>> Using the dirty bit for these semantics scares me. This API creates a
>> page that can have visible nonzero contents and then can
>> asynchronously and magically zero itself thereafter. That makes me
>> nervous. Could we use the accessed bit instead? Then the observable
>> semantics would be equivalent to having MADV_FREE either zero the page
>> or do nothing, except that it doesn't make up its mind until the next
>> read.
>
> FWIW, those are already basically the semantics provided by GCC and LLVM
> for data the compiler considers uninitialized (they could be more
> aggressive since C just says it's undefined, but in practice they allow
> it but can produce inconsistent results even if it isn't touched).
>
> http://llvm.org/docs/LangRef.html#undefined-values
But C isn't the only thing in the world. Also, I think that a C
optimizer should be free to turn:
if ([complicated condition])
*ptr = 1;
into:
if (*ptr != 1 && [complicated condition])
*ptr = 1;
as long as [complicated condition] has no side effects. The MADV_FREE
semantics in this patch set break that.
>
> It doesn't seem like there would be an advantage to checking if the data
> was written to vs. whether it was accessed if checking for both of those
> is comparable in performance. I don't know enough about that.
I'd imagine that there would be no performance difference whatsoever
on hardware that has a real accessed bit. The only thing that changes
is the choice of which bit to use.
>
>>> + ptent = pte_mkold(ptent);
>>> + ptent = pte_mkclean(ptent);
>>> + set_pte_at(mm, addr, pte, ptent);
>>> + tlb_remove_tlb_entry(tlb, pte, addr);
>>
>> It looks like you are flushing the TLB. In a multithreaded program,
>> that's rather expensive. Potentially silly question: would it be
>> better to just zero the page immediately in a multithreaded program
>> and then, when swapping out, check the page is zeroed and, if so, skip
>> swapping it out? That could be done without forcing an IPI.
>
> In the common case it will be passed many pages by the allocator. There
> will still be a layer of purging logic on top of MADV_FREE but it can be
> much thinner than the current workarounds for MADV_DONTNEED. So the
> allocator would still be coalescing dirty ranges and only purging when
> the ratio of dirty:clean pages rises above some threshold. It would be
> able to weight the largest ranges for purging first rather than logic
> based on stuff like aging as is used for MADV_DONTNEED.
>
With enough pages at once, though, munmap would be fine, too.
Maybe what's really needed is a MADV_FREE variant that takes an iovec.
On an all-cores multithreaded mm, the TLB shootdown broadcast takes
thousands of cycles on each core more or less regardless of how much
of the TLB gets zapped.
--Andy
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