On 13.06.23 10:26, Kasireddy, Vivek wrote:
Hi David,
On 12.06.23 09:10, Kasireddy, Vivek wrote:
Hi Mike,
Hi Vivek,
Sorry for the late reply; I just got back from vacation.
If it is unsafe to directly use the subpages of a hugetlb page, then reverting
this patch seems like the only option for addressing this issue immediately.
So, this patch is
Acked-by: Vivek Kasireddy <vivek.kasire...@intel.com>
As far as the use-case is concerned, there are two main users of the
udmabuf
driver: Qemu and CrosVM VMMs. However, it appears Qemu is the only
one
that uses hugetlb pages (when hugetlb=on is set) as the backing store for
Guest (Linux, Android and Windows) system memory. The main goal is to
share the pages associated with the Guest allocated framebuffer (FB) with
the Host GPU driver and other components in a zero-copy way. To that
end,
the guest GPU driver (virtio-gpu) allocates 4k size pages (associated with
the FB) and pins them before sharing the (guest) physical (or dma)
addresses
(and lengths) with Qemu. Qemu then translates the addresses into file
offsets and shares these offsets with udmabuf.
Is my understanding correct, that we can effectively long-term pin
(worse than mlock) 64 MiB per UDMABUF_CREATE, allowing eventually !root
The 64 MiB limit is the theoretical upper bound that we have not seen hit in
practice. Typically, for a 1920x1080 resolution (commonly used in Guests),
the size of the FB is ~8 MB (1920x1080x4). And, most modern Graphics
compositors flip between two FBs.
Okay, but users with privileges to open that file can just create as
many as they want? I think I'll have to play with it.
users
ll /dev/udmabuf
crw-rw---- 1 root kvm 10, 125 12. Jun 08:12 /dev/udmabuf
to bypass there effective MEMLOCK limit, fragmenting physical memory and
breaking swap?
Right, it does not look like the mlock limits are honored.
That should be added.
Regarding the udmabuf_vm_fault(), I assume we're mapping pages we
obtained from the memfd ourselves into a special VMA (mmap() of the
mmap operation is really needed only if any component on the Host needs
CPU access to the buffer. But in most scenarios, we try to ensure direct GPU
access (h/w acceleration via gl) to these pages.
udmabuf). I'm not sure how well shmem pages are prepared for getting
mapped by someone else into an arbitrary VMA (page->index?).
Most drm/gpu drivers use shmem pages as the backing store for FBs and
other buffers and also provide mmap capability. What concerns do you see
with this approach?
Are these mmaping the pages the way udmabuf maps these pages (IOW,
on-demand fault where we core-mm will adjust the mapcount etc)?
Skimming over at shmem_read_mapping_page() users, I assume most of them
use a VM_PFNMAP mapping (or don't mmap them at all), where we won't be
messing with the struct page at all.
(That might even allow you to mmap hugetlb sub-pages, because the struct
page -- and mapcount -- will be ignored completely and not touched.)
... also, just imagine someone doing FALLOC_FL_PUNCH_HOLE / ftruncate()
on the memfd. What's mapped into the memfd no longer corresponds to
what's pinned / mapped into the VMA.
IIUC, making use of the DMA_BUF_IOCTL_SYNC ioctl would help with any
coherency issues:
https://www.kernel.org/doc/html/v6.2/driver-api/dma-buf.html#c.dma_buf_sync
Would it as of now? udmabuf_create() pulls the shmem pages out of the
memfd, not sure how DMA_BUF_IOCTL_SYNC would help to update that
whenever the pages inside the memfd would change (e.g.,
FALLOC_FL_PUNCH_HOLE + realloc).
But that's most probably simply "not supported".
Was linux-mm (and especially shmem maintainers, ccing Hugh) involved in
the upstreaming of udmabuf?
It does not appear so from the link below although other key lists were cc'd:
https://patchwork.freedesktop.org/patch/246100/?series=39879&rev=7
That's unfortunate :(
--
Cheers,
David / dhildenb