On Fri, Jul 13, 2018 at 04:07:29PM -0700, David Rientjes wrote: > One of the three significant concerns brought up about the cgroup aware > oom killer is that its decisionmaking is completely evaded by creating > subcontainers and attaching processes such that the ancestor's usage does > not exceed another cgroup on the system. > > Consider the example from the previous patch where "memory" is set in > each mem cgroup's cgroup.controllers: > > mem cgroup cgroup.procs > ========== ============ > /cg1 1 process consuming 250MB > /cg2 3 processes consuming 100MB each > /cg3/cg31 2 processes consuming 100MB each > /cg3/cg32 2 processes consuming 100MB each > > If memory.oom_policy is "cgroup", a process from /cg2 is chosen because it > is in the single indivisible memory consumer with the greatest usage. > > The true usage of /cg3 is actually 400MB, but a process from /cg2 is > chosen because cgroups are compared individually rather than > hierarchically. > > If a system is divided into two users, for example: > > mem cgroup memory.max > ========== ========== > /userA 250MB > /userB 250MB > > If /userA runs all processes attached to the local mem cgroup, whereas > /userB distributes their processes over a set of subcontainers under > /userB, /userA will be unfairly penalized. > > There is incentive with cgroup v2 to distribute processes over a set of > subcontainers if those processes shall be constrained by other cgroup > controllers; this is a direct result of mandating a single, unified > hierarchy for cgroups. A user may also reasonably do this for mem cgroup > control or statistics. And, a user may do this to evade the cgroup-aware > oom killer selection logic. > > This patch adds an oom policy, "tree", that accounts for hierarchical > usage when comparing cgroups and the cgroup aware oom killer is enabled by > an ancestor. This allows administrators, for example, to require users in > their own top-level mem cgroup subtree to be accounted for with > hierarchical usage. In other words, they can longer evade the oom killer > by using other controllers or subcontainers. > > If an oom policy of "tree" is in place for a subtree, such as /cg3 above, > the hierarchical usage is used for comparisons with other cgroups if > either "cgroup" or "tree" is the oom policy of the oom mem cgroup. Thus, > if /cg3/memory.oom_policy is "tree", one of the processes from /cg3's > subcontainers is chosen for oom kill. > > Signed-off-by: David Rientjes <rientjes@xxxxxxxxxx> > --- > Documentation/admin-guide/cgroup-v2.rst | 17 ++++++++++++++--- > include/linux/memcontrol.h | 5 +++++ > mm/memcontrol.c | 18 ++++++++++++------ > 3 files changed, 31 insertions(+), 9 deletions(-) > > diff --git a/Documentation/admin-guide/cgroup-v2.rst b/Documentation/admin-guide/cgroup-v2.rst > --- a/Documentation/admin-guide/cgroup-v2.rst > +++ b/Documentation/admin-guide/cgroup-v2.rst > @@ -1113,6 +1113,10 @@ PAGE_SIZE multiple when read back. > memory consumers; that is, they will compare mem cgroup usage rather > than process memory footprint. See the "OOM Killer" section below. > > + If "tree", the OOM killer will compare mem cgroups and its subtree > + as a single indivisible memory consumer. This policy cannot be set > + on the root mem cgroup. See the "OOM Killer" section below. > + > When an OOM condition occurs, the policy is dictated by the mem > cgroup that is OOM (the root mem cgroup for a system-wide OOM > condition). If a descendant mem cgroup has a policy of "none", for > @@ -1120,6 +1124,10 @@ PAGE_SIZE multiple when read back. > the heuristic will still compare mem cgroups as indivisible memory > consumers. > > + When an OOM condition occurs in a mem cgroup with an OOM policy of > + "cgroup" or "tree", the OOM killer will compare mem cgroups with > + "cgroup" policy individually with "tree" policy subtrees. > + > memory.events > A read-only flat-keyed file which exists on non-root cgroups. > The following entries are defined. Unless specified > @@ -1355,7 +1363,7 @@ out of memory, its memory.oom_policy will dictate how the OOM killer will > select a process, or cgroup, to kill. Likewise, when the system is OOM, > the policy is dictated by the root mem cgroup. > > -There are currently two available oom policies: > +There are currently three available oom policies: > > - "none": default, choose the largest single memory hogging process to > oom kill, as traditionally the OOM killer has always done. > @@ -1364,6 +1372,9 @@ There are currently two available oom policies: > subtree as an OOM victim and kill at least one process, depending on > memory.oom_group, from it. > > + - "tree": choose the cgroup with the largest memory footprint considering > + itself and its subtree and kill at least one process. > + > When selecting a cgroup as a victim, the OOM killer will kill the process > with the largest memory footprint. A user can control this behavior by > enabling the per-cgroup memory.oom_group option. If set, it causes the > @@ -1382,8 +1393,8 @@ Please, note that memory charges are not migrating if tasks > are moved between different memory cgroups. Moving tasks with > significant memory footprint may affect OOM victim selection logic. > If it's a case, please, consider creating a common ancestor for > -the source and destination memory cgroups and enabling oom_group > -on ancestor layer. > +the source and destination memory cgroups and setting a policy of "tree" > +and enabling oom_group on an ancestor layer. > > > IO > diff --git a/include/linux/memcontrol.h b/include/linux/memcontrol.h > --- a/include/linux/memcontrol.h > +++ b/include/linux/memcontrol.h > @@ -77,6 +77,11 @@ enum memcg_oom_policy { > * mem cgroup as an indivisible consumer > */ > MEMCG_OOM_POLICY_CGROUP, > + /* > + * Tree cgroup usage for all descendant memcg groups, treating each mem > + * cgroup and its subtree as an indivisible consumer > + */ > + MEMCG_OOM_POLICY_TREE, > }; > > struct mem_cgroup_reclaim_cookie { > diff --git a/mm/memcontrol.c b/mm/memcontrol.c > --- a/mm/memcontrol.c > +++ b/mm/memcontrol.c > @@ -2952,7 +2952,7 @@ static void select_victim_memcg(struct mem_cgroup *root, struct oom_control *oc) > /* > * The oom_score is calculated for leaf memory cgroups (including > * the root memcg). > - * Non-leaf oom_group cgroups accumulating score of descendant > + * Cgroups with oom policy of "tree" accumulate the score of descendant > * leaf memory cgroups. > */ > rcu_read_lock(); > @@ -2961,10 +2961,11 @@ static void select_victim_memcg(struct mem_cgroup *root, struct oom_control *oc) > > /* > * We don't consider non-leaf non-oom_group memory cgroups > - * as OOM victims. > + * without the oom policy of "tree" as OOM victims. > */ > if (memcg_has_children(iter) && iter != root_mem_cgroup && > - !mem_cgroup_oom_group(iter)) > + !mem_cgroup_oom_group(iter) && > + iter->oom_policy != MEMCG_OOM_POLICY_TREE) > continue; Hello, David! I think that there is an inconsistency in the memory.oom_policy definition. "none" and "cgroup" policies defining how the OOM scoped to this particular memory cgroup (or system, if set on root) is handled. And all sub-tree settings do not matter at all, right? Also, if a memory cgroup has no memory.max set, there is no meaning in setting memory.oom_policy. And "tree" is different. It actually changes how the selection algorithm works, and sub-tree settings do matter in this case. I find it very confusing. Thanks! -- To unsubscribe from this list: send the line "unsubscribe cgroups" in the body of a message to majordomo@xxxxxxxxxxxxxxx More majordomo info at http://vger.kernel.org/majordomo-info.html