On Fri, Jul 17, 2020 at 09:39:25AM -0400, Mathieu Desnoyers wrote: > ----- On Jul 16, 2020, at 5:24 PM, Alan Stern stern@xxxxxxxxxxxxxxxxxxx wrote: > > > On Thu, Jul 16, 2020 at 02:58:41PM -0400, Mathieu Desnoyers wrote: > >> ----- On Jul 16, 2020, at 12:03 PM, Mathieu Desnoyers > >> mathieu.desnoyers@xxxxxxxxxxxx wrote: > >> > >> > ----- On Jul 16, 2020, at 11:46 AM, Mathieu Desnoyers > >> > mathieu.desnoyers@xxxxxxxxxxxx wrote: > >> > > >> >> ----- On Jul 16, 2020, at 12:42 AM, Nicholas Piggin npiggin@xxxxxxxxx wrote: > >> >>> I should be more complete here, especially since I was complaining > >> >>> about unclear barrier comment :) > >> >>> > >> >>> > >> >>> CPU0 CPU1 > >> >>> a. user stuff 1. user stuff > >> >>> b. membarrier() 2. enter kernel > >> >>> c. smp_mb() 3. smp_mb__after_spinlock(); // in __schedule > >> >>> d. read rq->curr 4. rq->curr switched to kthread > >> >>> e. is kthread, skip IPI 5. switch_to kthread > >> >>> f. return to user 6. rq->curr switched to user thread > >> >>> g. user stuff 7. switch_to user thread > >> >>> 8. exit kernel > >> >>> 9. more user stuff ... > >> Requiring a memory barrier between update of rq->curr (back to current process's > >> thread) and following user-space memory accesses does not seem to guarantee > >> anything more than what the initial barrier at the beginning of __schedule > >> already > >> provides, because the guarantees are only about accesses to user-space memory. ... > > Is it correct to say that the switch_to operations in 5 and 7 include > > memory barriers? If they do, then skipping the IPI should be okay. > > > > The reason is as follows: The guarantee you need to enforce is that > > anything written by CPU0 before the membarrier() will be visible to CPU1 > > after it returns to user mode. Let's say that a writes to X and 9 > > reads from X. > > > > Then we have an instance of the Store Buffer pattern: > > > > CPU0 CPU1 > > a. Write X 6. Write rq->curr for user thread > > c. smp_mb() 7. switch_to memory barrier > > d. Read rq->curr 9. Read X > > > > In this pattern, the memory barriers make it impossible for both reads > > to miss their corresponding writes. Since d does fail to read 6 (it > > sees the earlier value stored by 4), 9 must read a. > > > > The other guarantee you need is that g on CPU0 will observe anything > > written by CPU1 in 1. This is easier to see, using the fact that 3 is a > > memory barrier and d reads from 4. > > Right, and Nick's reply involving pairs of loads/stores on each side > clarifies the situation even further. The key part of my reply was the question: "Is it correct to say that the switch_to operations in 5 and 7 include memory barriers?" From the text quoted above and from Nick's reply, it seems clear that they do not. I agree with Nick: A memory barrier is needed somewhere between the assignment at 6 and the return to user mode at 8. Otherwise you end up with the Store Buffer pattern having a memory barrier on only one side, and it is well known that this arrangement does not guarantee any ordering. One thing I don't understand about all this: Any context switch has to include a memory barrier somewhere, but both you and Nick seem to be saying that steps 6 and 7 don't include (or don't need) any memory barriers. What am I missing? Alan Stern