On 2018-01-19 09:39 AM, Christian König wrote:
Am 19.01.2018 um 09:20 schrieb Michal Hocko:
On Thu 18-01-18 12:01:32, Eric Anholt wrote:
Michal Hocko mhocko@kernel.org writes:
On Thu 18-01-18 18:00:06, Michal Hocko wrote:
On Thu 18-01-18 11:47:48, Andrey Grodzovsky wrote:
Hi, this series is a revised version of an RFC sent by Christian König a few years ago. The original RFC can be found at https://lists.freedesktop.org/archives/dri-devel/2015-September/089778.html
This is the same idea and I've just adressed his concern from the original RFC and switched to a callback into file_ops instead of a new member in struct file.
Please add the full description to the cover letter and do not make people hunt links.
Here is the origin cover letter text : I'm currently working on the issue that when device drivers allocate memory on : behalf of an application the OOM killer usually doesn't knew about that unless : the application also get this memory mapped into their address space. : : This is especially annoying for graphics drivers where a lot of the VRAM : usually isn't CPU accessible and so doesn't make sense to map into the : address space of the process using it. : : The problem now is that when an application starts to use a lot of VRAM those : buffers objects sooner or later get swapped out to system memory, but when we : now run into an out of memory situation the OOM killer obviously doesn't knew : anything about that memory and so usually kills the wrong process.
OK, but how do you attribute that memory to a particular OOM killable entity? And how do you actually enforce that those resources get freed on the oom killer action?
: The following set of patches tries to address this problem by introducing a per : file OOM badness score, which device drivers can use to give the OOM killer a : hint how many resources are bound to a file descriptor so that it can make : better decisions which process to kill.
But files are not killable, they can be shared... In other words this doesn't help the oom killer to make an educated guess at all.
Maybe some more context would help the discussion?
The struct file in patch 3 is the DRM fd. That's effectively "my process's interface to talking to the GPU" not "a single GPU resource". Once that file is closed, all of the process's private, idle GPU buffers will be immediately freed (this will be most of their allocations), and some will be freed once the GPU completes some work (this will be most of the rest of their allocations).
Some GEM BOs won't be freed just by closing the fd, if they've been shared between processes. Those are usually about 8-24MB total in a process, rather than the GBs that modern apps use (or that our testcases like to allocate and thus trigger oomkilling of the test harness instead of the offending testcase...)
Even if we just had the private+idle buffers being accounted in OOM badness, that would be a huge step forward in system reliability.
OK, in that case I would propose a different approach. We already have rss_stat. So why do not we simply add a new counter there MM_KERNELPAGES and consider those in oom_badness? The rule would be that such a memory is bound to the process life time. I guess we will find more users for this later.
I already tried that and the problem with that approach is that some buffers are not created by the application which actually uses them.
For example X/Wayland is creating and handing out render buffers to application which want to use OpenGL.
So the result is when you always account the application who created the buffer the OOM killer will certainly reap X/Wayland first. And that is exactly what we want to avoid here.
FWIW, what you describe is true with DRI2, but not with DRI3 or Wayland anymore. With DRI3 and Wayland, buffers are allocated by the clients and then shared with the X / Wayland server.
Also, in all cases, the amount of memory allocated for buffers shared between DRI/Wayland clients and the server should be relatively small compared to the amount of memory allocated for buffers used only locally in the client, particularly for clients which create significant memory pressure.