Re: [PATCH v3 3/3] xen/sched: fix cpu hotplug

[Juergen Gross <jgross@xxxxxxxx>]

On 01.09.22 14:01, Andrew Cooper wrote:
> On 01/09/2022 07:11, Juergen Gross wrote:
> > On 01.09.22 00:52, Andrew Cooper wrote:
> > > On 16/08/2022 11:13, Juergen Gross wrote:
> > > > Cpu cpu unplugging is calling schedule_cpu_rm() via stop_machine_run()
> > > Cpu cpu.
> > >
> > > > with interrupts disabled, thus any memory allocation or freeing must
> > > > be avoided.
> > > >
> > > > Since commit 5047cd1d5dea ("xen/common: Use enhanced
> > > > ASSERT_ALLOC_CONTEXT in xmalloc()") this restriction is being enforced
> > > > via an assertion, which will now fail.
> > > >
> > > > Before that commit cpu unplugging in normal configurations was working
> > > > just by chance as only the cpu performing schedule_cpu_rm() was doing
> > > > active work. With core scheduling enabled, however, failures could
> > > > result from memory allocations not being properly propagated to other
> > > > cpus' TLBs.
> > > This isn't accurate, is it?  The problem with initiating a TLB flush
> > > with IRQs disabled is that you can deadlock against a remote CPU which
> > > is waiting for you to enable IRQs first to take a TLB flush IPI.
> > As long as only one cpu is trying to allocate/free memory during the
> > stop_machine_run() action the deadlock won't happen.
> >
> > > How does a memory allocation out of the xenheap result in a TLB flush?
> > > Even with split heaps, you're only potentially allocating into a new
> > > slot which was unused...
> > Yeah, you are right. The main problem would occur only when a virtual
> > address is changed to point at another physical address, which should be
> > quite unlikely.
> >
> > I can drop that paragraph, as it doesn't really help.
> Yeah, I think that would be best.
>
> > > > diff --git a/xen/common/sched/cpupool.c b/xen/common/sched/cpupool.c
> > > > index 58e082eb4c..2506861e4f 100644
> > > > --- a/xen/common/sched/cpupool.c
> > > > +++ b/xen/common/sched/cpupool.c
> > > > @@ -411,22 +411,28 @@ int cpupool_move_domain(struct domain *d,
> > > > struct cpupool *c)
> > > >    }
> > > >      /* Update affinities of all domains in a cpupool. */
> > > > -static void cpupool_update_node_affinity(const struct cpupool *c)
> > > > +static void cpupool_update_node_affinity(const struct cpupool *c,
> > > > +                                         struct affinity_masks *masks)
> > > >    {
> > > > -    struct affinity_masks masks;
> > > > +    struct affinity_masks local_masks;
> > > >        struct domain *d;
> > > >    -    if ( !update_node_aff_alloc(&masks) )
> > > > -        return;
> > > > +    if ( !masks )
> > > > +    {
> > > > +        if ( !update_node_aff_alloc(&local_masks) )
> > > > +            return;
> > > > +        masks = &local_masks;
> > > > +    }
> > > >          rcu_read_lock(&domlist_read_lock);
> > > >          for_each_domain_in_cpupool(d, c)
> > > > -        domain_update_node_aff(d, &masks);
> > > > +        domain_update_node_aff(d, masks);
> > > >          rcu_read_unlock(&domlist_read_lock);
> > > >    -    update_node_aff_free(&masks);
> > > > +    if ( masks == &local_masks )
> > > > +        update_node_aff_free(masks);
> > > >    }
> > > >      /*
> > > Why do we need this at all?  domain_update_node_aff() already knows what
> > > to do when passed NULL, so this seems like an awfully complicated no-op.
> > You do realize that update_node_aff_free() will do something in case
> > masks
> > was initially NULL?
> By "this", I meant the entire hunk, not just the final if().
>
> What is wrong with passing the (possibly NULL) masks pointer straight
> down into domain_update_node_aff() and removing all the memory
> allocation in this function?
>
> But I've also answered that by looking more clearly.  It's about not
> repeating the memory allocations/freeing for each domain in the pool.
Correct.

> Which does make sense as this is a slow path already, but the complexity
> here of having conditionally allocated masks is far from simple.
>
> > > > @@ -1008,10 +1016,21 @@ static int cf_check cpu_callback(
> > > >    {
> > > >        unsigned int cpu = (unsigned long)hcpu;
> > > >        int rc = 0;
> > > > +    static struct cpu_rm_data *mem;
> > > >          switch ( action )
> > > >        {
> > > >        case CPU_DOWN_FAILED:
> > > > +        if ( system_state <= SYS_STATE_active )
> > > > +        {
> > > > +            if ( mem )
> > > > +            {
> > > So, this does compile (and indeed I've tested the result), but I can't
> > > see how it should.
> > >
> > > mem is guaranteed to be uninitialised at this point, and ...
> > ... it is defined as "static", so it is clearly NULL initially.
> Oh, so it is.  That is hiding particularly well in plain sight.
>
> Can it please be this:
>
> @@ -1014,9 +1014,10 @@ void cf_check dump_runq(unsigned char key)
>   static int cf_check cpu_callback(
>       struct notifier_block *nfb, unsigned long action, void *hcpu)
>   {
> +    static struct cpu_rm_data *mem; /* Protected by cpu_add_remove_lock */
> +
>       unsigned int cpu = (unsigned long)hcpu;
>       int rc = 0;
> -    static struct cpu_rm_data *mem;
>   
>       switch ( action )
>       {
>
> We already split static and non-static variable like this elsewhere for
> clarity, and identifying the lock which protects the data is useful for
> anyone coming to this in the future.
Fine with me.

> ~Andrew
>
> P.S. as an observation, this isn't safe for parallel AP booting, but I
> guarantee that this isn't the only example which would want fixing if we
> wanted to get parallel booting working.
You are aware that mem is used only when removing cpus?


Juergen

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