Re: [PATCH resend v2 2/5] mm/madvise: introduce MADV_POPULATE_(READ|WRITE) to prefault page tables

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This means that you want to have two different uses depending on the
underlying mapping type. MADV_POPULATE_READ seems rather weak for
anonymous/private mappings. Memory backed by zero pages seems rather
unhelpful as the PF would need to do all the heavy lifting anyway.
Or is there any actual usecase when this is desirable?

Currently, userfaultfd-wp, which requires "some mapping" to be able to arm
successfully. In QEMU, we currently have to prefault the shared zeropage for
userfaultfd-wp to work as expected.

Just for clarification. The aim is to reduce the memory footprint at the
same time, right? If that is really the case then this is worth adding.

Yes. userfaultfd-wp is right now used in QEMU for background snapshotting of VMs. Just because you trigger a background snapshot doesn't mean that you want to COW all pages. (especially, if your VM previously inflated the balloon, was using free page reporting etc.)


I expect that use case might vanish over
time (eventually with new kernels and updated user space), but it might
stick for a bit.

Could you elaborate some more please?

After I raised that the current behavior of userfaultfd-wp is suboptimal, Peter started working on a userfaultfd-wp mode that doesn't require to prefault all pages just to have it working reliably -- getting notified when any page changes, including ones that haven't been populated yet and would have been populated with the shared zeropage on first access. Not sure what the state of that is and when we might see it.


Apart from that, populating the shared zeropage might be relevant in some
corner cases: I remember there are sparse matrix algorithms that operate
heavily on the shared zeropage.

I am not sure I see why this would be a useful interface for those? Zero
page read fault is really low cost. Or are you worried about cummulative
overhead by entering the kernel many times?

Yes, cumulative overhead when dealing with large, sparse matrices. Just an example where I think it could be applied in the future -- but not that I consider populating the shared zeropage a really important use case in general (besides for userfaultfd-wp right now).


So the split into these two modes seems more like gup interface
shortcomings bubbling up to the interface. I do expect userspace only
cares about pre-faulting the address range. No matter what the backing
storage is.

Or do I still misunderstand all the usecases?

Let me give you an example where we really cannot tell what would be best
from a kernel perspective.

a) Mapping a file into a VM to be used as RAM. We might expect the guest
writing all memory immediately (e.g., booting Windows). We would want
MADV_POPULATE_WRITE as we expect a write access immediately.

b) Mapping a file into a VM to be used as fake-NVDIMM, for example, ROOTFS
or just data storage. We expect mostly reading from this memory, thus, we
would want MADV_POPULATE_READ.

I am afraid I do not follow. Could you be more explicit about advantages
of using those two modes for those example usecases? Is that to share
resources (e.g. by not breaking CoW)?

I'm only talking about shared mappings "ordinary files" for now, because that's where MADV_POPULATE_READ vs MADV_POPULATE_WRITE differ in regards of "mark something dirty and write it back"; CoW doesn't apply to shared mappings, it's really just a difference in dirtying and having to write back. For things like PMEM/hugetlbfs/... we usually want MADV_POPULATE_WRITE because then we'd avoid a context switch when our VM actually writes to a page the first time -- and we don't care about dirtying, because we don't have writeback.

But again, that's just one use case I have in mind coming from the VM area. I consider MADV_POPULATE_READ really only useful when we are expecting mostly read access on a mapping. (I assume there are other use cases for databases etc. not explored yet where MADV_POPULATE_WRITE would not be desired for performance reasons)


Instead of trying to be smart in the kernel, I think for this case it makes
much more sense to provide user space the options. IMHO it doesn't really
hurt to let user space decide on what it thinks is best.

I am mostly worried that this will turn out to be more confusing than
helpful. People will need to grasp non trivial concepts and kernel
internal implementation details about how read/write faults are handled.

And that's the point: in the simplest case (without any additional considerations about the underlying mapping), if you end up mostly *reading* MADV_POPULATE_READ is the right thing. If you end up mostly *writing* MADV_POPULATE_WRITE is the right thing. Only care has to be taken when you really want a "prealloction" as in "allocate backend storage" or "don't ever use the shared zeropage". I agree that these details require more knowledge, but so does anything that messes with memory mappings on that level (VMs, databases, ...).

QEMU currently implements exactly these two cases manually in user space.

Anyhow, please suggest a way to handle it via a single flag in the kernel -- which would be some kind of heuristic as we know from MAP_POPULATE. Having an alternative at hand would make it easier to discuss this topic further. I certainly *don't* want MAP_POPULATE semantics when it comes to MADV_POPULATE, especially when it comes to shared mappings. Not useful in QEMU now and in the future.

We could make MADV_POPULATE act depending on the readability/writability of a mapping. Use MADV_POPULATE_WRITE on writable mappings, use MADV_POPULATE_READ on readable mappings. Certainly not perfect for use cases where you have writable mappings that are mostly read only (as in the example with fake-NVDIMMs I gave ...), but if it makes people happy, fine with me. I mostly care about MADV_POPULATE_WRITE.

--
Thanks,

David / dhildenb




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