Thread (51 messages) 51 messages, 5 authors, 2020-09-25

Re: [PATCH v4 00/23] device-dax: Support sub-dividing soft-reserved ranges

From: Dan Williams <hidden>
Date: 2020-08-20 01:54:13
Also in: dri-devel, linux-acpi, lkml, nvdimm

On Mon, Aug 3, 2020 at 12:48 AM David Hildenbrand [off-list ref] wrote:
[...]
quoted
Well, no v5.8-rc8 to line this up for v5.9, so next best is early
integration into -mm before other collisions develop.

Chatted with Justin offline and it currently appears that the missing
numa information is the fault of the platform firmware to populate all
the necessary NUMA data in the NFIT.
I'm planning on looking at some bits of this series this week, but some
questions upfront ...
quoted
---
Cover:

The device-dax facility allows an address range to be directly mapped
through a chardev, or optionally hotplugged to the core kernel page
allocator as System-RAM. It is the mechanism for converting persistent
memory (pmem) to be used as another volatile memory pool i.e. the
current Memory Tiering hot topic on linux-mm.

In the case of pmem the nvdimm-namespace-label mechanism can sub-divide
it, but that labeling mechanism is not available / applicable to
soft-reserved ("EFI specific purpose") memory [3]. This series provides
a sysfs-mechanism for the daxctl utility to enable provisioning of
volatile-soft-reserved memory ranges.

The motivations for this facility are:

1/ Allow performance differentiated memory ranges to be split between
   kernel-managed and directly-accessed use cases.

2/ Allow physical memory to be provisioned along performance relevant
   address boundaries. For example, divide a memory-side cache [4] along
   cache-color boundaries.

3/ Parcel out soft-reserved memory to VMs using device-dax as a security
   / permissions boundary [5]. Specifically I have seen people (ab)using
   memmap=nn!ss (mark System-RAM as Persistent Memory) just to get the
   device-dax interface on custom address ranges. A follow-on for the VM
   use case is to teach device-dax to dynamically allocate 'struct page' at
   runtime to reduce the duplication of 'struct page' space in both the
   guest and the host kernel for the same physical pages.

I think I am missing some important pieces. Bear with me.
No worries, also bear with me, I'm going to be offline intermittently
until at least mid-September. Hopefully Joao and/or Vishal can jump in
on this discussion.
1. On x86-64, e820 indicates "soft-reserved" memory. This memory is not
automatically used in the buddy during boot, but remains untouched
(similar to pmem). But as it involves ACPI as well, it could also be
used on arm64 (-e820), correct?
Correct, arm64 also gets the EFI support for enumerating memory this
way. However, I would clarify that whether soft-reserved is given to
the buddy allocator by default or not is the kernel's policy choice,
"buddy-by-default" is ok and is what will happen anyways with older
kernels on platforms that enumerate a memory range this way.
2. Soft-reserved memory is volatile RAM with differing performance
characteristics ("performance differentiated memory"). What would be
examples of such memory?
Likely the most prominent one that drove the creation of the "EFI
Specific Purpose" attribute bit is high-bandwidth memory. One concrete
example of that was a platform called Knights Landing [1] that ended
up shipping firmware that lied to the OS about the latency
characteristics of the memory to try to reverse engineer OS behavior
to not allocate from that memory range by default. With the EFI
attribute firmware performance tables can tell the truth about the
performance characteristics of the memory range *and* indicate that
the OS not use it for general purpose allocations by default.

[1]: https://software.intel.com/content/www/us/en/develop/blogs/an-intro-to-mcdram-high-bandwidth-memory-on-knights-landing.html
Like, memory that is faster than RAM (scratch
pad), or slower (pmem)? Or both? :)
Both, but note that PMEM is already hard-reserved by default.
Soft-reserved is about a memory range that, for example, an
administrator may want to reserve 100% for a weather simulation where
if even a small amount of memory was stolen for the page cache the
application may not meet its performance targets. It could also be a
memory range that is so slow that only applications with higher
latency tolerances would be prepared to consume it.

In other words the soft-reserved memory can be used to indicate memory
that is either too precious, or too slow for general purpose OS
allocations.
Is it a valid use case to use pmem
in a hypervisor to back this memory?
Depends on the pmem. That performance capability is indicated by the
ACPI HMAT, not the EFI soft-reserved designation.
3. There seem to be use cases where "soft-reserved" memory is used via
DAX. What is an example use case? I assume it's *not* to treat it like
PMEM but instead e.g., use it as a fast buffer inside applications or
similar.
Right, in that weather-simulation example that application could just
mmap /dev/daxX.Y and never worry about contending for the "fast
memory" resource on the platform. Alternatively if that resource needs
to be shared and/or over-commited then kernel memory-management
services are needed and that dax-device can be assigned to kmem.
4. There seem to be use cases where some part of "soft-reserved" memory
is used via DAX, some other is given to the buddy. What is an example
use case? Is this really necessary or only some theoretical use case?
It's as necessary as pmem namespace partitioning, or the inclusion of
dax-kmem upstream in the first place. In that kmem case the motivation
was that some users want a portion of pmem provisioned for storage and
some for volatile usage. The motivation is similar here, platform
firmware can only identify memory attributes on coarse boundaries,
finer grained provisioning decisions are up to the administrator /
platform-owner and the kernel is a just a facilitator of that policy.
5. The "provisioned along performance relevant address boundaries." part
is unclear to me. Can you give an example of how this would look like
from user space? Like, split that memory in blocks of size X with
alignment Y and give them to separate applications?
One example of platform address boundaries are the memory address
ranges that alias in a direct-mapped memory-side-cache. In the
direct-map-cache aliasing may repeat every N GBs where N is the ratio
of far-to-near memory. ("Near memory" ==  cache "Far memory" ==
backing memory). Also refer back to the background in the page
allocator shuffling patches [2]. With this partitioning mechanism you
could, for one example use case, assign different VMs to exclusive
colors in the memory side cache.

[2]: https://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git/commit/?id=e900a918b098
6. If you add such memory to the buddy, is there any way the system can
differentiate it from other memory? E.g., via fake/other NUMA nodes?
Numa node numbers / are how performance differentiated memory ranges
are enumerated. The expectation is that all distinct performance
memory targets have unique ACPI proximity domains and Linux numa node
numbers as a result.
Also, can you give examples of how kmem-added memory is represented in
/proc/iomem for a) pmem and b) soft-resered memory after this series
(skimming over the patches, I think there is a change for pmem, right?)?
I don't expect a change. The only difference is the parent resource
will be marked "Soft Reserved" instead of "Persistent Memory".
I am really wondering if it's the right approach to squeeze this into
our pmem/nvdimm infrastructure just because it's easy to do. E.g., man
"ndctl" - "ndctl - Manage "libnvdimm" subsystem devices (Non-volatile
Memory)" speaks explicitly about non-volatile memory.
In fact it's not squeezed into PMEM infrastructure. dax-kmem and
device-dax are independent of PMEM. PMEM is one source of potential
device-dax instances, soft-reserved memory is another orthogonal
source. This is why device-dax needs its own userspace policy directed
partitioning mechanism because there is no PMEM to store the
configuration for partitioned higph-bandwidth memory. The userspace
tooling for this mechanism is targeted for a tool called daxctl that
has no PMEM dependencies. Look to Joao's use case that is using this
infrastructure independent of PMEM with manual soft-reservations
specified on the kernel command-line.
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