On 1/9/22 16:36, Halil Pasic wrote:
On Thu, 21 Oct 2021 11:23:26 -0400
Tony Krowiak <akrowiak@xxxxxxxxxxxxx> wrote:
Keep in mind that the kvm->lock must be taken outside of the
matrix_mdev->lock to avoid circular lock dependencies (i.e., a lockdep
splat). This will necessitate taking the matrix_dev->guests_lock in order
to find the guest(s) in the matrix_dev->guests list to which the affected
APQN(s) may be assigned. The kvm->lock can then be taken prior to the
matrix_dev->lock and the APCB plugged into the guest without any problem.
IMHO correct and sane locking is one of the key points we have to
resolve. Frankly, I'm having trouble understanding the why behind some
of your changes, compared to v16, and I suspect that looking for a good
locking scheme might have played a role.
The locking scheme introduced with this patch series was
precipitated by the fact that the queue probe/remove
callbacks require access to both the matrix_dev->lock
and matrix_mdev->kvm->lock. When those callbacks are
invoked, the only information we have is the queue device
being removed. In order to retrieve the mdev to which
the APQN of the queue is assigned, we have to take the
matrix_dev->lock. We also need the matrix_mdev->kvm->lock
because we are hot plugging/unplugging the queue (i.e.,
kvm_arch_crypto_set_masks).
Given we need to take the kvm->lock prior to the
matrix_dev->lock in order to avoid potential lockdep
splats, this design was created.
In the beginning, I was not very keen on taking the kvm->lock first
and the matrix_dev->lock, but the more I think about it the more I
become convinced that this is probably the simplest way to resolve the
problem in a satisfactory manner. I don't like the idea of
hogging the kvm->lock and potentially stalling out some core kvm code
because there is contention on matrix_dev->lock. And it is kind of up to
the user-space and the guests, how much pressure is put on the
matrix_dev->lock. And I'm still worried about that, but when I went
through the alternatives, my mood turned form bad to worse. Because of
that, I'm fine with this solution, provided some of the KVM/s390
maintainers ack it as well. I don't feel comfortable making a call on
this alone.
You are feeling the very same frustrations I felt when trying to
come up with a viable solution. I share your concerns, but I
was simply not able to come up with anything better that
wouldn't require redesigning the secure execution ioctls as well
as the instruction interception ioctls.
That said, let me also sum up my thoughts on alternatives and
non-alternatives, hopefully for the benefit of other reviewers.
1) I deeply regret that I used to argue against handling PQAP in
userspace with an ioctl as Pierre originally proposed. I was unaware of
the kvm->lock vcpu->lock locking order. Back then we didn't use to
have that sequence, but the rule was already there. I guess we could
still go back to that scheme of handling PQAP if QEMU were to support
it, and thus break the circle, but that would result in a very ugly
dependency (we would need QEMU support for dynamic, and we would have
to handle the case of an old QEMU). Technically it is still possible, but
very ugly.
Note that this didn't rear its ugly head until secure execution guests
were introduced.
2) I've contemplated if it is possible to simulate the userspace exit
and re-entry via ioctl in KVM. But looking at the code, it does not
look like a sane option to me.
3) I also considered using a read-write lock for matrix_dev->lock. In
theory a read-write lock that favors reads in a sense that a steady
stream of readers can starve the writers would work. But rwsem can't be
used in this situation because rwsem is fair, in a sense that a waiting
writers may effectively block readers that try to acquire the lock while
the lock is held as a read lock. So while rwsem in practice does allow
for more parallelism regarding lock dependency circles it does not
provide any benefits over a mutex.
Note: I went down this road already and was not able to resolve
lockdep splats with rwsem. That is not to say I exhausted
all permutations, but I ended up pulling what little hair I
have left out.
4) I considered srcu as well. But rcu is a very different beast and does
not seem to be a great fit for what we are trying to do here. We are
not not fine with working with a stale copy of the matrix in most of the
situations.
5) I also contemplated, if relaxing the mutual exclusion is possible.
PQAP only needs the CRYCB matrix to check whether the queue is in the
config or not. So maybe we could get away without taking the
matrix_dev->lock and doing separate locking for the queue in question,
and instead of delaying any updates to the CRYCB while processing AQIC,
we could just work with whatever we see in the CRYCB. Since the setting
up of the interrupts is asynchronous with respect to the instruction
requesting it (PQAP/AQIC) and the CRYCB masks are relevant in the
instruction context... So I was thinking: if we were to introduce a
separate lock for the AQIC state, and find the queue without taking
the matrix_dev->lock, we could actually process the PQAP/AQIC without
the matrix_dev->lock. But then because we would have vcpu->lock -->
vfio_ap_queue->lock, we would have to avoid ending up with a circle
on the cleanup path, and also avoid races on the cleanup path. I'm not
sure how tricky that would end up being, if at all possible.
Note: I too considered this, but again failed to make it work.
I don't recall why, but I ended up with lockdep splats.
Maybe I just didn't design it properly.
6) We could practically implement that unfair read-write lock with
a mutex and condition variables (and a waitqueue), but that wouldn't
simplify things either. Still if we want to avoid taking kvm->lock
before taking the vfio_ap lock, it may be the most straight forward
alternative.
Note: The original lockdep splat was resolved with a wait queue,
but as you may recall, that was objected to on the grounds
that it circumvented lockdep. That is what precipitated this
mess in the first place.
At the end let me also state, that my understanding of some of the
details is still incomplete.
Given the difficulty of keeping the mental thread needed to
implement this, I can certainly understand:)
Regards,
Halil