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Message-ID: <20070810202646.GD8511@linux.vnet.ibm.com>
Date: Fri, 10 Aug 2007 13:26:46 -0700
From: "Paul E. McKenney" <paulmck@...ux.vnet.ibm.com>
To: Chris Snook <csnook@...hat.com>
Cc: linux-kernel@...r.kernel.org, linux-arch@...r.kernel.org,
torvalds@...ux-foundation.org, netdev@...r.kernel.org,
akpm@...ux-foundation.org, ak@...e.de, heiko.carstens@...ibm.com,
davem@...emloft.net, schwidefsky@...ibm.com, wensong@...ux-vs.org,
horms@...ge.net.au, wjiang@...ilience.com, cfriesen@...tel.com,
zlynx@....org, rpjday@...dspring.com, jesper.juhl@...il.com
Subject: Re: [PATCH 1/24] make atomic_read() behave consistently on alpha
On Fri, Aug 10, 2007 at 03:49:03PM -0400, Chris Snook wrote:
> Paul E. McKenney wrote:
> >On Thu, Aug 09, 2007 at 03:24:40PM -0400, Chris Snook wrote:
> >>Paul E. McKenney wrote:
> >>>On Thu, Aug 09, 2007 at 02:13:52PM -0400, Chris Snook wrote:
> >>>>Paul E. McKenney wrote:
> >>>>>On Thu, Aug 09, 2007 at 01:14:35PM -0400, Chris Snook wrote:
> >>>>>> If you're depending on volatile writes
> >>>>>>being visible to other CPUs, you're screwed either way, because the
> >>>>>>CPU can hold that data in cache as long as it wants before it writes
> >>>>>>it to memory. When this finally does happen, it will happen
> >>>>>>atomically, which is all that atomic_set guarantees. If you need to
> >>>>>>guarantee that the value is written to memory at a particular time in
> >>>>>>your execution sequence, you either have to read it from memory to
> >>>>>>force the compiler to store it first (and a volatile cast in
> >>>>>>atomic_read will suffice for this) or you have to use LOCK_PREFIX
> >>>>>>instructions which will invalidate remote cache lines containing the
> >>>>>>same variable. This patch doesn't change either of these cases.
> >>>>>The case that it -can- change is interactions with interrupt handlers.
> >>>>>And NMI/SMI handlers, for that matter.
> >>>>You have a point here, but only if you can guarantee that the interrupt
> >>>>handler is running on a processor sharing the cache that has the
> >>>>not-yet-written volatile value. That implies a strictly non-SMP
> >>>>architecture. At the moment, none of those have volatile in their
> >>>>declaration of atomic_t, so this patch can't break any of them.
> >>>This can also happen when using per-CPU variables. And there are a
> >>>number of per-CPU variables that are either atomic themselves or are
> >>>structures containing atomic fields.
> >>Accessing per-CPU variables in this fashion reliably already requires a
> >>suitable smp/non-smp read/write memory barrier. I maintain that if we
> >>break anything with this change, it was really already broken, if less
> >>obviously. Can you give a real or synthetic example of legitimate code
> >>that could break?
> >
> >My main concern is actually the lack of symmetry -- I would expect
> >that an atomic_set() would have the same properties as atomic_read().
> >It is easy and cheap to provide them with similar properties, so why not?
> >Debugging even a single problem would consume far more time than simply
> >giving them corresponding semantics.
> >
> >But you asked for examples. These are synthetic, and of course legitimacy
> >is in the eye of the beholder.
> >
> >1. Watchdog variable.
> >
> > atomic_t watchdog = ATOMIC_INIT(0);
> >
> > ...
> >
> > int i;
> > while (!done) {
> >
> > /* Do so stuff that doesn't take more than a few us. */
> > /* Could do atomic increment, but throughput penalty. */
> >
> > i++;
> > atomic_set(&watchdog, i);
> > }
> > do_something_with(&watchdog);
> >
> >
> > /* Every so often on some other CPU... */
> >
> > if ((new_watchdog = atomic_read(&watchdog)) == old_watchdog)
> > die_horribly();
> > old_watchdog = new_watchdog;
> >
> >
> > If atomic_set() did not have volatile semantics, the compiler
> > would be within its rights optimizing it to simply get the
> > final value of "i" after exit from the loop. This would cause
> > the watchdog check to fail spuriously. Memory barriers are
> > not required in this case, because the CPU cannot hang onto
> > the value for very long -- we don't care about the exact value,
> > or about exact synchronization, but rather about whether or
> > not the value is changing.
> >
> > In this (toy) example, one might replace the atomic_set() with
> > an atomic increment (though that might be too expensive in some
> > cases) or with something like:
> >
> > atomic_set(&watchdog, atomic_read(&watchdog) + 1);
> >
> > However, other cases might not permit this transformation,
> > for example, an existing heavily used API might take int rather
> > than atomic_t.
> >
> > Some will no doubt argue that this example should use a
> > macro or an asm similar to the "forget()" asm put forward
> > elsewhere in this thread.
> >
> >2. Communicating both with interrupt handler and with other CPUs.
> > For example, data elements that are built up in a location visible
> > to interrupts and NMIs, and then added as a unit to a data structure
> > visible to other CPUs. This more-realistic example is abbreviated
> > to the point of pointlessness as follows:
> >
> > struct foo {
> > atomic_t a;
> > atomic_t b;
> > };
> >
> > DEFINE_PER_CPU(struct foo *, staging) = NULL;
> >
> > /* Create element in staging area. */
> >
> > __get_cpu_var(staging) = kzalloc(sizeof(*p), GFP_WHATEVER);
> > if (__get_cpu_var(staging) == NULL)
> > die_horribly();
> > /* allocate an element of some per-CPU array, get the result in "i"
> > */
> > atomic_set(__get_cpu_var(staging).a, i);
> > /* allocate another element of a per-CPU array, with result in "i" */
> > atomic_set(__get_cpu_var(staging).b, i);
> > rcu_assign_pointer(some_global_place, __get_cpu_var(staging));
> >
> > If atomic_set() didn't have volatile semantics, then an interrupt
> > or NMI handler could see the atomic_set() to .a and .b out of
> > order due to compiler optimizations.
> >
> >Remember, you -did- ask for these!!! ;-)
>
> Ok, I'm convinced. Part of the motivation here is to avoid heisenbugs,
> so if people expect volatile atomic_set behavior, I'm inclined to give
> it to them. I don't really feel like indulging the compiler bug
> paranoiacs, but developer expectations are a legitimate motivation, and
> a major part of why I posted this in the first place. I'll resubmit the
> patchset with a volatile cast in atomic_set. Before I do, is there
> anything *else* that desperately needs such a cast? As far as I can
> tell, all the other functions are implemented with __asm__ __volatile__,
> or with spinlocks that use that under the hood.
Sounds good!!!
The only other API that I am aware of needing volatile semantics is
rcu_dereference(), but I already sent a patch in for it. So as far
as I know, atomic_read() and atomic_set() should cover it.
Thanx, Paul
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