Hi David,
On Thu, Jun 20, 2024 at 04:14:23PM +0200, David Hildenbrand wrote:
On 20.06.24 15:08, Mostafa Saleh wrote:
Hi David,
On Wed, Jun 19, 2024 at 09:37:58AM +0200, David Hildenbrand wrote:
Hi,
On 19.06.24 04:44, John Hubbard wrote:
On 6/18/24 5:05 PM, Elliot Berman wrote:
In arm64 pKVM and QuIC's Gunyah protected VM model, we want to support grabbing shmem user pages instead of using KVM's guestmemfd. These hypervisors provide a different isolation model than the CoCo implementations from x86. KVM's guest_memfd is focused on providing memory that is more isolated than AVF requires. Some specific examples include ability to pre-load data onto guest-private pages, dynamically sharing/isolating guest pages without copy, and (future) migrating guest-private pages. In sum of those differences after a discussion in [1] and at PUCK, we want to try to stick with existing shmem and extend GUP to support the isolation needs for arm64 pKVM and Gunyah.
The main question really is, into which direction we want and can develop guest_memfd. At this point (after talking to Jason at LSF/MM), I wonder if guest_memfd should be our new target for guest memory, both shared and private. There are a bunch of issues to be sorted out though ...
As there is interest from Red Hat into supporting hugetlb-style huge pages in confidential VMs for real-time workloads, and wasting memory is not really desired, I'm going to think some more about some of the challenges (shared+private in guest_memfd, mmap support, migration of !shared folios, hugetlb-like support, in-place shared<->private conversion, interaction with page pinning). Tricky.
Ideally, we'd have one way to back guest memory for confidential VMs in the future.
Can you comment on the bigger design goal here? In particular:
Who would get the exclusive PIN and for which reason? When would we pin, when would we unpin?
What would happen if there is already another PIN? Can we deal with speculative short-term PINs from GUP-fast that could introduce errors?
How can we be sure we don't need other long-term pins (IOMMUs?) in the future?
Can you please clarify more about the IOMMU case?
pKVM has no merged upstream IOMMU support at the moment, although there was an RFC a while a go [1], also there would be a v2 soon.
In the patches KVM (running in EL2) will manage the IOMMUs including the page tables and all pages used in that are allocated from the kernel.
These patches don't support IOMMUs for guests. However, I don't see why would that be different from the CPU? as once the page is pinned it can be owned by a guest and that would be reflected in the hypervisor tracking, the CPU stage-2 and IOMMU page tables as well.
So this is my thinking, it might be flawed:
In the "normal" world (e.g., vfio), we FOLL_PIN|FOLL_LONGTERM the pages to be accessible by a dedicated device. We look them up in the page tables to pin them, then we can map them into the IOMMU.
Devices that cannot speak "private memory" should only access shared memory. So we must not have "private memory" mapped into their IOMMU.
Devices that can speak "private memory" may either access shared or private memory. So we may have"private memory" mapped into their IOMMU.
Private pages must not be accessible to devices owned by the host, and for that we have the same rules as the CPU: A) The hypervisor doesn’t trust the host, and must enforce that using the CPU stage-2 MMU. B) It’s preferable that userspace doesn’t, and hence these patches (or guest_memfd...)
We need the same rules for DMA, otherwise it is "simple" to instrument a DMA attack, so we need a protection by the IOMMU. pKVM at the moment provides 2 ways of establishing that (each has their own trade-off which are not relevant here):
1) pKVM manages the IOMMUs and provides a hypercall interface to map/unmap in the IOMMU, looking at the rules
For A), pKVM has its own per-page metadata which tracks page state, which can prevent mapping private pages in the IOMMU and transitioning pages to private if they are mapped in the IOMMU.
For B), userspace won’t be able to map private pages(through VFIO/IOMMUFD), as the hypercall interface would fail if the pages are private.
This proposal is the one on the list.
2) pKVM manages a second stage of the IOMMU (as SMMUv3), and let the kernel map what it wants in stage-1 and pKVM would use a mirrored page table of the CPU MMU stage-2.
For A) Similar to the CPU, stage-2 IOMMU will protect the private pages.
For B) userspace can map private pages in the first stage IOMMU, and that would result in stage-2 fault, AFAIK, SMMUv3 is the only Arm implementation that supports nesting in Linux, for that the driver would only print a page fault, and ideally the kernel wouldn’t crash, although that is really hardware dependant how it handle faults, and I guess assigning a device through VFIO to userspace comes with similar risks already (bogus MMIO access can crash the system).
This proposal only exists in Android at the moment(However I am working on getting an SMMUv3 compliant implementation that can be posted upstream).
What I see (again, I might be just wrong):
- How would the device be able to grab/access "private memory", if not via the user page tables?
I hope the above answers the question, but just to confirmn, a device owned by the host shouldn’t access the memory as the host kernel is not trusted and can instrument DMA attacks. Device assignment (passthrough) is another story.
- How would we be able to convert shared -> private, if there is a longterm pin from that IOMMU? We must dynamically unmap it from the IOMMU.
Depending on which solution from the above, for 1) The transition from shared -> private would fail 2) The private page would be unmapped from the stage-2 IOMMU (similar to the stage-2 CPU MMU)
I assume when you're saying "In the patches KVM (running in EL2) will manage the IOMMUs including the page tables", this is easily solved by not relying on pinning: KVM just knows what to update and where. (which is a very different model than what VFIO does)
Yes, that's is not required to protect private memory.
Thanks, Mostafa
Thanks!
-- Cheers,
David / dhildenb