On Tue, Mar 26, 2019 at 1:04 AM Michal Hocko
> On Mon 25-03-19 13:03:47, Dan Williams wrote:
> > On Mon, Mar 25, 2019 at 3:20 AM Michal Hocko <mhocko(a)kernel.org> wrote:
> > > > User-defined memory namespaces have this problem, but 2MB is the
> > > > default alignment and is sufficient for most uses.
> > >
> > > What does prevent users to go and use a larger alignment?
> > Given that we are living with 64MB granularity on mainstream platforms
> > for the foreseeable future, the reason users can't rely on a larger
> > alignment to address the issue is that the physical alignment may
> > change from one boot to the next.
> I would love to learn more about this inter boot volatility. Could you
> expand on that some more? I though that the HW configuration presented
> to the OS would be more or less stable unless the underlying HW changes.
Even if the configuration is static there can be hardware failures
that prevent a DIMM, or a PCI device to be included in the memory map.
When that happens the BIOS needs to re-layout the map and the result
is not guaranteed to maintain the previous alignment.
> > No, you can't just wish hardware / platform firmware won't do this,
> > because there are not enough platform resources to give every hardware
> > device a guaranteed alignment.
> Guarantee is one part and I can see how nobody wants to give you
> something as strong but how often does that happen in the real life?
I expect a "rare" event to happen everyday in a data-center fleet.
Failure rates tend towards 100% daily occurrence at scale and in this
case the kernel has everything it needs to mitigate such an event.
Setting aside the success rate of a software-alignment mitigation, the
reason I am charging this hill again after a 2 year hiatus is the
realization that this problem is wider spread than the original
failing scenario. Back in 2017 the problem seemed limited to custom
memmap= configurations, and collisions between PMEM and System RAM.
Now it is clear that the collisions can happen between PMEM regions
and namespaces as well, and the problem spans platforms from multiple
vendors. Here is the most recent collision problem:
, from a third-party platform.
The fix for that issue uncovered a bug in the padding implementation,
and a fix for that bug would result in even more hacks in the nvdimm
code for what is a core kernel deficiency. Code review of those
changes resulted in changing direction to go after the core
This kind of information along with real world examples is exactly what
you should have added into the cover letter. A previous very vague
claims were not really convincing or something that can be considered a
proper justification. Please do realize that people who are not working
with the affected HW are unlikely to have an idea how serious/relevant
those problems really are.
People are asking for a smaller memory hotplug granularity for other
usecases (e.g. memory ballooning into VMs) which are quite dubious to
be honest and not really worth all the code rework. If we are talking
about something that can be worked around elsewhere then it is preferred
because the code base is not in an excellent shape and putting more on
top is just going to cause more headaches.
I will try to find some time to review this more deeply (no promises
though because time is hectic and this is not a simple feature). For the
future, please try harder to write up a proper justification and a
highlevel design description which tells a bit about all important parts
of the new scheme.