On Thu, Nov 02, 2017 at 01:08:52PM -0400, Alan Stern wrote:
> On Thu, 2 Nov 2017, Peter Zijlstra wrote:
>
> > On Thu, Nov 02, 2017 at 11:40:35AM -0400, Alan Stern wrote:
> > > On Thu, 2 Nov 2017, Peter Zijlstra wrote:
> > >
> > > > > Lock functions such as refcount_dec_and_lock() &
> > > > > refcount_dec_and_mutex_lock() Provide exactly the same guarantees as
> > > > > they atomic counterparts.
> > > >
> > > > Nope. The atomic_dec_and_lock() provides smp_mb() while
> > > > refcount_dec_and_lock() merely orders all prior load/store's against all
> > > > later load/store's.
> > >
> > > In fact there is no guaranteed ordering when refcount_dec_and_lock()
> > > returns false;
> >
> > It should provide a release:
> >
> > - if !=1, dec_not_one will provide release
> > - if ==1, dec_not_one will no-op, but then we'll acquire the lock and
> > dec_and_test will provide the release, even if the test fails and we
> > unlock again it should still dec.
> >
> > The one exception is when the counter is saturated, but in that case
> > we'll never free the object and the ordering is moot in any case.
>
> Also if the counter is 0, but that will never happen if the
> refcounting is correct.
>
> > > it provides ordering only if the return value is true.
> > > In which case it provides acquire ordering (thanks to the spin_lock),
> > > and both release ordering and a control dependency (thanks to the
> > > refcount_dec_and_test).
> > >
> > > > The difference is subtle and involves at least 3 CPUs. I can't seem to
> > > > write up anything simple, keeps turning into monsters :/ Will, Paul,
> > > > have you got anything simple around?
> > >
> > > The combination of acquire + release is not the same as smp_mb, because
> >
> > acquire+release is nothing, its release+acquire that I meant which
> > should order things locally, but now that you've got me looking at it
> > again, we don't in fact do that.
> >
> > So refcount_dec_and_lock() will provide a release, irrespective of the
> > return value (assuming we're not saturated). If it returns true, it also
> > does an acquire for the lock.
> >
> > But combined they're acquire+release, which is unfortunate.. it means
> > the lock section and the refcount stuff overlaps, but I don't suppose
> > that's actually a problem. Need to consider more.
>
> Right. To address your point: release + acquire isn't the same as a
> full barrier either. The SB pattern illustrates the difference:
>
> P0 P1
> Write x=1 Write y=1
> Release a smp_mb
> Acquire b Read x=0
> Read y=0
>
> This would not be allowed if the release + acquire sequence was
> replaced by smp_mb. But as it stands, this is allowed because nothing
> prevents the CPU from interchanging the order of the release and the
> acquire -- and then you're back to the acquire + release case.
>
> However, there is one circumstance where this interchange isn't
> allowed: when the release and acquire access the same memory
> location. Thus:
>
> P0(int *x, int *y, int *a)
> {
> int r0;
>
> WRITE_ONCE(*x, 1);
> smp_store_release(a, 1);
> smp_load_acquire(a);
> r0 = READ_ONCE(*y);
> }
>
> P1(int *x, int *y)
> {
> int r1;
>
> WRITE_ONCE(*y, 1);
> smp_mb();
> r1 = READ_ONCE(*x);
> }
>
> exists (0:r0=0 /\ 1:r1=0)
>
> This is forbidden. It would remain forbidden even if the smp_mb in P1
> were replaced by a similar release/acquire pair for the same memory
> location.
Isn't this allowed on x86 mapping smp_mb() to mfence, store-release to plain
store and load-acquire to plain load? All we're saying is that you can forward
from a release to an acquire, which is fine for RCpc semantics.
e.g.
X86 SB+mfence+po-rfi-po
"MFencedWR Fre PodWW Rfi PodRR Fre"
Generator=diyone7 (version 7.46+3)
Prefetch=0:x=F,0:y=T,1:y=F,1:x=T
Com=Fr Fr
Orig=MFencedWR Fre PodWW Rfi PodRR Fre
{
}
P0 | P1 ;
MOV [x],$1 | MOV [y],$1 ;
MFENCE | MOV [z],$1 ;
MOV EAX,[y] | MOV EAX,[z] ;
| MOV EBX,[x] ;
exists
(0:EAX=0 /\ 1:EAX=1 /\ 1:EBX=0)
which herd says is allowed:
Test SB+mfence+po-rfi-po Allowed
States 4
0:EAX=0; 1:EAX=1; 1:EBX=0;
0:EAX=0; 1:EAX=1; 1:EBX=1;
0:EAX=1; 1:EAX=1; 1:EBX=0;
0:EAX=1; 1:EAX=1; 1:EBX=1;
Ok
Witnesses
Positive: 1 Negative: 3
Condition exists (0:EAX=0 /\ 1:EAX=1 /\ 1:EBX=0)
Observation SB+mfence+po-rfi-po Sometimes 1 3
Time SB+mfence+po-rfi-po 0.00
Hash=0f983e2d7579e5c04c332f9ac620c31f
and I can reproduce using litmus to actually run it on my x86 box:
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% Results for SB+mfence+po-rfi-po.litmus %
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
X86 SB+mfence+po-rfi-po
"MFencedWR Fre PodWW Rfi PodRR Fre"
{}
P0 | P1 ;
MOV [x],$1 | MOV [y],$1 ;
MFENCE | MOV [z],$1 ;
MOV EAX,[y] | MOV EAX,[z] ;
| MOV EBX,[x] ;
exists (0:EAX=0 /\ 1:EAX=1 /\ 1:EBX=0)
Generated assembler
#START _litmus_P1
movl $1,(%r8,%rcx)
movl $1,(%r9,%rcx)
movl (%r9,%rcx),%eax
movl (%rdi,%rcx),%edx
#START _litmus_P0
movl $1,(%rdx,%rcx)
mfence
movl (%rdi,%rcx),%eax
Test SB+mfence+po-rfi-po Allowed
Histogram (4 states)
8 *>0:EAX=0; 1:EAX=1; 1:EBX=0;
1999851:>0:EAX=1; 1:EAX=1; 1:EBX=0;
1999549:>0:EAX=0; 1:EAX=1; 1:EBX=1;
592 :>0:EAX=1; 1:EAX=1; 1:EBX=1;
Ok
Witnesses
Positive: 8, Negative: 3999992
Condition exists (0:EAX=0 /\ 1:EAX=1 /\ 1:EBX=0) is validated
Hash=0f983e2d7579e5c04c332f9ac620c31f
Generator=diyone7 (version 7.46+3)
Com=Fr Fr
Orig=MFencedWR Fre PodWW Rfi PodRR Fre
Observation SB+mfence+po-rfi-po Sometimes 8 3999992
Time SB+mfence+po-rfi-po 0.17
Will
