Hi Alex and Waiman, On Mon, Jan 27, 2020 at 4:02 PM Alex Kogan <alex.kogan@xxxxxxxxxx> wrote: > > Hi, Lihao. > > >>> > >>>> This is particularly relevant > >>>> in high contention situations when new threads keep arriving on the same > >>>> socket as the lock holder. > >>> In this case, the lock will stay on the same NUMA node/socket for > >>> 2^numa_spinlock_threshold times, which is the worst case scenario if we > >>> consider the long-term fairness. And if we have multiple nodes, it will take > >>> up to 2^numa_spinlock_threshold X (nr_nodes - 1) + nr_cpus_per_node > >>> lock transitions until any given thread will acquire the lock > >>> (assuming 2^numa_spinlock_threshold > nr_cpus_per_node). > >>> > >> > >> You're right that the latest version of the patch handles long-term fairness > >> deterministically. > >> > >> As I understand it, the n-th thread in the main queue is guaranteed to > >> acquire the lock after N lock handovers, where N is bounded by > >> > >> n - 1 + 2^numa_spinlock_threshold * (nr_nodes - 1) > >> > >> I'm not sure what role the variable nr_cpus_per_node plays in your analysis. > >> > >> Do I miss anything? > >> > > > > If I understand correctly, there are two phases in the algorithm: > > > > MCS phase: when the secondary queue is empty, as explained in your emails, > > the algorithm hands the lock to threads in the main queue in an FIFO order. > > When probably(SHUFFLE_REDUCTION_PROB_ARG) returns false (with default > > probability 1%), if the algorithm finds the first thread running on the same > > socket as the lock holder in cna_scan_main_queue(), it enters the following > > CNA phase > Yep. When probably() returns false, we scan the main queue. If as the result of > this scan the secondary queue becomes not empty, we enter what you call > the CNA phase. > As I understand it, the probability of making a transition from the MCS to CNA phase in less than N lock handovers is 1 - p^N, where p is the probability that probably() returns true (default 99%). So in high contention situations where N can become quite large in a relatively short period of time, the probability of getting into the CNA phase is high, e.g. 95% when N = 300. I was wondering whether it would be possible to detect contention and make a phase transition deterministically, maybe by reusing the intra_count variable to keep track of the processing rate in the MCS phase? As Will pointed out earlier, this would make formal analysis and verification of the CNA qspinlock much more feasible. > > . > > > > CNA phase: when the secondary queue is not empty, the algorithm keeps > > handing the lock to threads in the main queue that run on the same socket as > > the lock holder. When 2^numa_spinlock_threshold is reached, it splices > > the secondary queue to the front of the main queue. And we are back to the > > MCS phase above. > Correct. > > > For the n-th thread T in the main queue, the MCS phase handles threads that > > arrived in the main queue before T. In high contention situations, the CNA > > phase handles two kinds of threads: > > > > 1. Threads ahead of T that run on the same socket as the lock holder when > > a transition from the MCS to CNA phase was made. Assume there are m such > > threads. > > > > 2. Threads that keep arriving on the same socket as the lock holder. There > > are at most 2^numa_spinlock_threshold of them. > > > > Then the number of lock handovers in the CNA phase is max(m, > > 2^numa_spinlock_threshold). So the total number of lock handovers before T > > acquires the lock is at most > > > > n - 1 + 2^numa_spinlock_threshold * (nr_nodes - 1) > > > > Please let me know if I misunderstand anything. > I think you got it right (modulo nr_cpus_per_node instead of n, as mentioned in > my other response). > Make sense. Thanks a lot for the clarification :) Best, Lihao.