On Fri, Feb 21, 2020 at 06:12:56PM +0100, Michal Koutný wrote: > On Thu, Dec 19, 2019 at 03:07:18PM -0500, Johannes Weiner <hannes@xxxxxxxxxxx> wrote: > > Unfortunately, this limitation makes it impossible to protect an > > entire subtree from another without forcing the user to make explicit > > protection allocations all the way to the leaf cgroups - something > > that is highly undesirable in real life scenarios. > I see that the jobs in descedant cgroups don't know (or care) what > protection is above them and hence the implicit distribution is sensible > here. > > However, the protection your case requires can already be reached thanks > to the the hierachical capping and overcommit normalization -- you can > set memory.low to "max" at all the non-caring descendants. > IIUC, that is the same as setting zeroes (after your patch) and relying > on the recursive distribution of unused protection -- or is there a > mistake in my reasonineg? That is correct, but it comes with major problems. We did in fact try exactly this as a workaround in our fleet, but had to revert and develop the patch we are discussing now instead. The reason is this: max isn't a "don't care" value. It's just a high number with actual meaning in the configuration, and that interferes when you try to compose it with other settings, such as limits. Here is a configuration we actually use in practice: workload.slice (memory.low=20G) / \ job (max=12G, low=10G) job2 (max=12G, low=10G) / \ task logger The idea is that we want to mostly protect the workload from other stuff running in the system (low=20G), but we also want to catch a job when it goes wild, to ensure reproducibility in testing regardless of how loaded the host otherwise is (max=12G). When you set task's and logger's memory.low to "max" or 10G or any bogus number like this, a limit reclaim in job treats this as origin protection and tries hard to avoid reclaiming anything in either of the two cgroups. memory.events::low skyrockets even though no intended protection was violated, we'll have reclaim latencies (especially when there are a few dying cgroups accumluated in subtree). So we had to undo this setting because of workload performance and problems with monitoring workload health (the bogus low events). The secondary problem with requiring explicit downward propagation is that you may want to protect all jobs on the host from system management software, as a very high-level host configuration. But a random job that gets scheduled on a host, that lives in a delegated cgroup and namespace, and creates its own nested tree of cgroups to manage stuff - that job can't possibly *know* about the top-level host protection that lies beyond the delegation point and outside its own namespace, and that it needs to propagate protection against rpm upgrades into its own leaf groups for each tasklet and component. Again, in practice we have found this to be totally unmanageable and routinely first forgot and then had trouble hacking the propagation into random jobs that create their own groups. [ And these job subgroups don't even use their *own* memory.low prioritization between siblings yet - god knows how you would integrate that with the values that you may inherit from higher level ancestors. ] And when you add new hardware configurations, you cannot just make a top-level change in the host config, you have to update all the job specs of workloads running in the fleet. My patch brings memory configuration in line with other cgroup2 controllers. You can make a high-level decision to prioritize one subtree over another, just like a top-level weight assignment in CPU or IO, and then you can delegate the subtree to a different entity that doesn't need to be aware of and reflect that decision all the way down the tree in its own settings. And of course can compose it properly with limits. > So in my view, the recursive distribution doesn't bring anything new, > however, its new semantics of memory.low doesn't allow turning the > protection off in a protected subtree (delegating the decision to > distribute protection within parent bounds is IMO a valid use case). I've made the case why it's not a supported usecase, and why it is a meaningless configuration in practice due to the way other controllers already behave. I think at this point in the discussion, the only thing I can do is remind you that the behavior I'm introducing is gated behind a mount option that nobody is forced to enable if they insist on disagreeing against all evidence to the contrary.