Am 24.03.21 um 13:01 schrieb Daniel Vetter:
On Wed, Mar 24, 2021 at 01:00:28PM +0100, Christian König wrote:
Am 24.03.21 um 12:55 schrieb Daniel Vetter:
On Wed, Mar 24, 2021 at 11:19:13AM +0100, Thomas Hellström (Intel) wrote:
On 3/23/21 4:45 PM, Christian König wrote:
Am 23.03.21 um 16:13 schrieb Michal Hocko:
On Tue 23-03-21 14:56:54, Christian König wrote:
Am 23.03.21 um 14:41 schrieb Michal Hocko:
[...]
Anyway, I am wondering whether the overall approach is
sound. Why don't
you simply use shmem as your backing storage from the
beginning and pin
those pages if they are used by the device?
Yeah, that is exactly what the Intel guys are doing for their
integrated
GPUs :)
Problem is for TTM I need to be able to handle dGPUs and those have all
kinds of funny allocation restrictions. In other words I need to
guarantee
that the allocated memory is coherent accessible to the GPU
without using
SWIOTLB.
The simple case is that the device can only do DMA32, but you also got
device which can only do 40bits or 48bits.
On top of that you also got AGP, CMA and stuff like CPU cache behavior
changes (write back vs. write through, vs. uncached).
OK, so the underlying problem seems to be that gfp mask (thus
mapping_gfp_mask) cannot really reflect your requirements, right? Would
it help if shmem would allow to provide an allocation callback to
override alloc_page_vma which is used currently? I am pretty sure there
will be more to handle but going through shmem for the whole life time
is just so much easier to reason about than some tricks to abuse shmem
just for the swapout path.
Well it's a start, but the pages can have special CPU cache settings. So
direct IO from/to them usually doesn't work as expected.
Additional to that for AGP and CMA I need to make sure that I give those
pages back to the relevant subsystems instead of just dropping the page
reference.
So I would need to block for the swapio to be completed.
Anyway I probably need to revert those patches for now since this isn't
working as we hoped it would.
Thanks for the explanation how stuff works here.
Another alternative here that I've tried before without being successful
would perhaps be to drop shmem completely and, if it's a normal page (no dma
or funny caching attributes) just use add_to_swap_cache()? If it's something
else, try alloc a page with relevant gfp attributes, copy and
add_to_swap_cache()? Or perhaps that doesn't work well from a shrinker
either?
So before we toss everything and go an a great rewrite-the-world tour,
what if we just try to split up big objects. So for objects which are
bigger than e.g. 10mb
- move them to a special "under eviction" list
- keep a note how far we evicted thus far
- interleave allocating shmem pages, copying data and releasing the ttm
backing store on a chunk basis (maybe 10mb or whatever, tuning tbh)
If that's not enough, occasionally break out of the shrinker entirely so
other parts of reclaim can reclaim the shmem stuff. But just releasing our
own pages as we go should help a lot I think.
Yeah, the later is exactly what I was currently prototyping.
I just didn't used a limit but rather a only partially evicted BOs list
which is used when we fail to allocate a page.
For the 5.12 cycle I think we should just go back to a hard 50% limit for
now and then resurrect this when we have solved the issues.
Can we do the 50% limit without tossing out all the code we've done thus
far? Just so this doesn't get too disruptive.
Yeah, I just need to get back to v1 of this patch. Before you convinced
me that the shrinker is the better approach .)
Cheers,
Christian.
-Daniel