On 19.03.24 06:06, zhukeqian wrote:
Hi David,
Thanks for reviewing.
On 17.03.24 09:37, Keqian Zhu via wrote:
Both main loop thread and vCPU thread are allowed to call
pause_all_vcpus(), and in general resume_all_vcpus() is called after
it. Two issues live in pause_all_vcpus():
In general, calling pause_all_vcpus() from VCPU threads is quite dangerous.
Do we have reproducers for the cases below?
I produce the issues by testing ARM vCPU hotplug feature:
QEMU changes for vCPU hotplug could be cloned from below site,
https://github.com/salil-mehta/qemu.git virt-cpuhp-armv8/rfc-v2
Guest Kernel changes (by James Morse, ARM) are available here:
https://git.kernel.org/pub/scm/linux/kernel/git/morse/linux.git
virtual_cpu_hotplug/rfc/v2
Thanks for these infos (would be reasonable to include that in the cover
letter).
Okay, so likely this is not actually a "fix" for upstream as it is. Understood.
The procedure to produce problems:
1. Startup a Linux VM (e.g., called OS-vcpuhotplug) with 32 possible vCPUs and
16 current vCPUs.
2. Log in guestOS and run script[1] to continuously online/offline CPU.
3. At host side, run script[2] to continuously hotplug/unhotplug vCPU.
After several minutes, we can hit these problems.
Script[1] to online/offline CPU:
for ((time=1;time<10000000;time++));
do
for ((cpu=16;cpu<32;cpu++));
do
echo 1 > /sys/devices/system/cpu/cpu$cpu/online
done
for ((cpu=16;cpu<32;cpu++));
do
echo 0 > /sys/devices/system/cpu/cpu$cpu/online
done
done
Script[2] to hotplug/unhotplug vCPU:
for ((time=1;time<1000000;time++));
do
echo $time
for ((cpu=16;cpu<=32;cpu++));
do
echo "virsh setvcpus OS-vcpuhotplug --count $cpu --live"
virsh setvcpus OS-vcpuhotplug --count $cpu --live
sleep 2
done
for ((cpu=32;cpu>=16;cpu--));
do
echo "virsh setvcpus OS-vcpuhotplug --count $cpu --live"
virsh setvcpus OS-vcpuhotplug --count $cpu --live
sleep 2
done
for ((cpu=16;cpu<=32;cpu+=2));
do
echo "virsh setvcpus OS-vcpuhotplug --count $cpu --live"
virsh setvcpus OS-vcpuhotplug --count $cpu --live
sleep 2
done
for ((cpu=32;cpu>=16;cpu-=2));
do
echo "virsh setvcpus OS-vcpuhotplug --count $cpu --live"
virsh setvcpus OS-vcpuhotplug --count $cpu --live
sleep 2
done
done
The script[1] will call PSCI CPU_ON which emulated by QEMU, which result in
calling cpu_reset() on vCPU thread.
I spotted new pause_all_vcpus() / resume_all_vcpus() calls in
hw/intc/arm_gicv3_kvm.c and
thought they would be the problematic bit.
Yeah, that's going to be problematic. Further note that a lot of code does not
expect
that the BQL is suddenly dropped.
We had issues with that in different context where we ended up wanting to use
pause/resume from VCPU context:
https://lore.kernel.org/all/294a987d-b0ef-1b58-98ac-0d4d43075d6e@redhat.com/
This sounds like a bad idea. Read below.
For ARM architecture, it needs to reset GICC registers, which is only possible
when all vcpus paused. So script[1]
will call pause_all_vcpus() in vCPU thread.
The script[2] also calls cpu_reset() for newly hotplugged vCPU, which is done
in main loop thread.
So this scenario causes problems as I state in commit message.
1. There is possibility that during thread T1 waits on qemu_pause_cond
with bql unlocked, other thread has called
pause_all_vcpus() and resume_all_vcpus(), then thread T1 will stuck,
because the condition all_vcpus_paused() is always false.
How can this happen?
Two threads calling pause_all_vcpus() is borderline broken, as you note.
IIRC, we should call pause_all_vcpus() only if some other mechanism prevents
these races. For example, based on runstate changes.
We already has bql to prevent concurrent calling of pause_all_vcpus() and
resume_all_vcpus(). But pause_all_vcpus() will
unlock bql in the half way, which gives change for other thread to call pause
and resume. In the past, code does not consider
this problem, now I add retry mechanism to fix it.
Note that BQL did not prevent concurrent calling of pause_all_vcpus(). There
had to be something else. Likely that was runstate transitions.
Just imagine one thread calling pause_all_vcpus() while another one
calls resume_all_vcpus(). It cannot possibly work.
With bql, we can make sure all vcpus are paused after pause_all_vcpus() finish,
and all vcpus are resumed after resume_all_vcpus() finish.
For example, the following situation may occur:
Thread T1: lock bql -> pause_all_vcpus -> wait on cond and unlock bql -> wait T2
unlock bql to lock bql -> lock bql &&
all_vcpu_paused -> success and do other work -> unlock bql
Thread T2: wait T1 unlock bql to lock bql ->
lock bql -> resume_all_vcpus -> success and do other work -> unlock
bql
Now trow in another thread and it all gets really complicated :)
Finding ways to avoid pause_all_vcpus() on the ARM reset code would be
preferable.
I guess you simply want to do something similar to what KVM does to avoid
messing
with pause_all_vcpus(): inhibiting certain IOCTLs.
commit f39b7d2b96e3e73c01bb678cd096f7baf0b9ab39
Author: David Hildenbrand <david@redhat.com>
Date: Fri Nov 11 10:47:58 2022 -0500
kvm: Atomic memslot updates
If we update an existing memslot (e.g., resize, split), we temporarily
remove the memslot to re-add it immediately afterwards. These updates
are not atomic, especially not for KVM VCPU threads, such that we can
get spurious faults.
Let's inhibit most KVM ioctls while performing relevant updates, such
that we can perform the update just as if it would happen atomically
without additional kernel support.
We capture the add/del changes and apply them in the notifier commit
stage instead. There, we can check for overlaps and perform the ioctl
inhibiting only if really required (-> overlap).
To keep things simple we don't perform additional checks that wouldn't
actually result in an overlap -- such as !RAM memory regions in some
cases (see kvm_set_phys_mem()).
To minimize cache-line bouncing, use a separate indicator
(in_ioctl_lock) per CPU. Also, make sure to hold the kvm_slots_lock
while performing both actions (removing+re-adding).
We have to wait until all IOCTLs were exited and block new ones from
getting executed.
This approach cannot result in a deadlock as long as the inhibitor does
not hold any locks that might hinder an IOCTL from getting finished and
exited - something fairly unusual. The inhibitor will always hold the BQL.
AFAIKs, one possible candidate would be userfaultfd. If a page cannot be
placed (e.g., during postcopy), because we're waiting for a lock, or if
the
userfaultfd thread cannot process a fault, because it is waiting for a
lock, there could be a deadlock. However, the BQL is not applicable here,
because any other guest memory access while holding the BQL would already
result in a deadlock.
Nothing else in the kernel should block forever and wait for userspace
intervention.
Note: pause_all_vcpus()/resume_all_vcpus() or
start_exclusive()/end_exclusive() cannot be used, as they either drop
the BQL or require to be called without the BQL - something inhibitors
cannot handle. We need a low-level locking mechanism that is
deadlock-free even when not releasing the BQL.