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The memcg uncharging code that is involved towards the end of a page's lifetime - truncation, reclaim, swapout, migration - is impressively complicated and fragile. Because anonymous and file pages were always charged before they had their page->mapping established, uncharges had to happen when the page type could still be known from the context; as in unmap for anonymous, page cache removal for file and shmem pages, and swap cache truncation for swap pages. However, these operations happen well before the page is actually freed, and so a lot of synchronization is necessary: - Charging, uncharging, page migration, and charge migration all need to take a per-page bit spinlock as they could race with uncharging. - Swap cache truncation happens during both swap-in and swap-out, and possibly repeatedly before the page is actually freed. This means that the memcg swapout code is called from many contexts that make no sense and it has to figure out the direction from page state to make sure memory and memory+swap are always correctly charged. - On page migration, the old page might be unmapped but then reused, so memcg code has to prevent untimely uncharging in that case. Because this code - which should be a simple charge transfer - is so special-cased, it is not reusable for replace_page_cache(). But now that charged pages always have a page->mapping, introduce mem_cgroup_uncharge(), which is called after the final put_page(), when we know for sure that nobody is looking at the page anymore. For page migration, introduce mem_cgroup_migrate(), which is called after the migration is successful and the new page is fully rmapped. Because the old page is no longer uncharged after migration, prevent double charges by decoupling the page's memcg association (PCG_USED and pc->mem_cgroup) from the page holding an actual charge. The new bits PCG_MEM and PCG_MEMSW represent the respective charges and are transferred to the new page during migration. mem_cgroup_migrate() is suitable for replace_page_cache() as well, which gets rid of mem_cgroup_replace_page_cache(). However, care needs to be taken because both the source and the target page can already be charged and on the LRU when fuse is splicing: grab the page lock on the charge moving side to prevent changing pc->mem_cgroup of a page under migration. Also, the lruvecs of both pages change as we uncharge the old and charge the new during migration, and putback may race with us, so grab the lru lock and isolate the pages iff on LRU to prevent races and ensure the pages are on the right lruvec afterward. Swap accounting is massively simplified: because the page is no longer uncharged as early as swap cache deletion, a new mem_cgroup_swapout() can transfer the page's memory+swap charge (PCG_MEMSW) to the swap entry before the final put_page() in page reclaim. Finally, page_cgroup changes are now protected by whatever protection the page itself offers: anonymous pages are charged under the page table lock, whereas page cache insertions, swapin, and migration hold the page lock. Uncharging happens under full exclusion with no outstanding references. Charging and uncharging also ensure that the page is off-LRU, which serializes against charge migration. Remove the very costly page_cgroup lock and set pc->flags non-atomically. [mhocko@suse.cz: mem_cgroup_charge_statistics needs preempt_disable] [vdavydov@parallels.com: fix flags definition] Signed-off-by: Johannes Weiner <hannes@cmpxchg.org> Cc: Hugh Dickins <hughd@google.com> Cc: Tejun Heo <tj@kernel.org> Cc: Vladimir Davydov <vdavydov@parallels.com> Tested-by: Jet Chen <jet.chen@intel.com> Acked-by: Michal Hocko <mhocko@suse.cz> Tested-by: Felipe Balbi <balbi@ti.com> Signed-off-by: Vladimir Davydov <vdavydov@parallels.com> Signed-off-by: Andrew Morton <akpm@linux-foundation.org> Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
281 lines
8.3 KiB
Plaintext
281 lines
8.3 KiB
Plaintext
Memory Resource Controller(Memcg) Implementation Memo.
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Last Updated: 2010/2
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Base Kernel Version: based on 2.6.33-rc7-mm(candidate for 34).
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Because VM is getting complex (one of reasons is memcg...), memcg's behavior
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is complex. This is a document for memcg's internal behavior.
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Please note that implementation details can be changed.
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(*) Topics on API should be in Documentation/cgroups/memory.txt)
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0. How to record usage ?
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2 objects are used.
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page_cgroup ....an object per page.
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Allocated at boot or memory hotplug. Freed at memory hot removal.
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swap_cgroup ... an entry per swp_entry.
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Allocated at swapon(). Freed at swapoff().
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The page_cgroup has USED bit and double count against a page_cgroup never
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occurs. swap_cgroup is used only when a charged page is swapped-out.
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1. Charge
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a page/swp_entry may be charged (usage += PAGE_SIZE) at
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mem_cgroup_try_charge()
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2. Uncharge
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a page/swp_entry may be uncharged (usage -= PAGE_SIZE) by
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mem_cgroup_uncharge()
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Called when a page's refcount goes down to 0.
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mem_cgroup_uncharge_swap()
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Called when swp_entry's refcnt goes down to 0. A charge against swap
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disappears.
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3. charge-commit-cancel
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Memcg pages are charged in two steps:
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mem_cgroup_try_charge()
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mem_cgroup_commit_charge() or mem_cgroup_cancel_charge()
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At try_charge(), there are no flags to say "this page is charged".
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at this point, usage += PAGE_SIZE.
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At commit(), the page is associated with the memcg.
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At cancel(), simply usage -= PAGE_SIZE.
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Under below explanation, we assume CONFIG_MEM_RES_CTRL_SWAP=y.
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4. Anonymous
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Anonymous page is newly allocated at
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- page fault into MAP_ANONYMOUS mapping.
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- Copy-On-Write.
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4.1 Swap-in.
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At swap-in, the page is taken from swap-cache. There are 2 cases.
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(a) If the SwapCache is newly allocated and read, it has no charges.
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(b) If the SwapCache has been mapped by processes, it has been
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charged already.
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4.2 Swap-out.
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At swap-out, typical state transition is below.
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(a) add to swap cache. (marked as SwapCache)
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swp_entry's refcnt += 1.
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(b) fully unmapped.
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swp_entry's refcnt += # of ptes.
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(c) write back to swap.
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(d) delete from swap cache. (remove from SwapCache)
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swp_entry's refcnt -= 1.
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Finally, at task exit,
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(e) zap_pte() is called and swp_entry's refcnt -=1 -> 0.
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5. Page Cache
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Page Cache is charged at
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- add_to_page_cache_locked().
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The logic is very clear. (About migration, see below)
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Note: __remove_from_page_cache() is called by remove_from_page_cache()
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and __remove_mapping().
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6. Shmem(tmpfs) Page Cache
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The best way to understand shmem's page state transition is to read
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mm/shmem.c.
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But brief explanation of the behavior of memcg around shmem will be
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helpful to understand the logic.
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Shmem's page (just leaf page, not direct/indirect block) can be on
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- radix-tree of shmem's inode.
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- SwapCache.
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- Both on radix-tree and SwapCache. This happens at swap-in
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and swap-out,
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It's charged when...
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- A new page is added to shmem's radix-tree.
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- A swp page is read. (move a charge from swap_cgroup to page_cgroup)
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7. Page Migration
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mem_cgroup_migrate()
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8. LRU
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Each memcg has its own private LRU. Now, its handling is under global
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VM's control (means that it's handled under global zone->lru_lock).
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Almost all routines around memcg's LRU is called by global LRU's
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list management functions under zone->lru_lock().
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A special function is mem_cgroup_isolate_pages(). This scans
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memcg's private LRU and call __isolate_lru_page() to extract a page
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from LRU.
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(By __isolate_lru_page(), the page is removed from both of global and
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private LRU.)
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9. Typical Tests.
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Tests for racy cases.
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9.1 Small limit to memcg.
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When you do test to do racy case, it's good test to set memcg's limit
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to be very small rather than GB. Many races found in the test under
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xKB or xxMB limits.
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(Memory behavior under GB and Memory behavior under MB shows very
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different situation.)
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9.2 Shmem
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Historically, memcg's shmem handling was poor and we saw some amount
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of troubles here. This is because shmem is page-cache but can be
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SwapCache. Test with shmem/tmpfs is always good test.
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9.3 Migration
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For NUMA, migration is an another special case. To do easy test, cpuset
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is useful. Following is a sample script to do migration.
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mount -t cgroup -o cpuset none /opt/cpuset
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mkdir /opt/cpuset/01
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echo 1 > /opt/cpuset/01/cpuset.cpus
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echo 0 > /opt/cpuset/01/cpuset.mems
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echo 1 > /opt/cpuset/01/cpuset.memory_migrate
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mkdir /opt/cpuset/02
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echo 1 > /opt/cpuset/02/cpuset.cpus
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echo 1 > /opt/cpuset/02/cpuset.mems
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echo 1 > /opt/cpuset/02/cpuset.memory_migrate
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In above set, when you moves a task from 01 to 02, page migration to
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node 0 to node 1 will occur. Following is a script to migrate all
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under cpuset.
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--
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move_task()
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{
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for pid in $1
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do
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/bin/echo $pid >$2/tasks 2>/dev/null
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echo -n $pid
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echo -n " "
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done
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echo END
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}
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G1_TASK=`cat ${G1}/tasks`
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G2_TASK=`cat ${G2}/tasks`
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move_task "${G1_TASK}" ${G2} &
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--
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9.4 Memory hotplug.
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memory hotplug test is one of good test.
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to offline memory, do following.
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# echo offline > /sys/devices/system/memory/memoryXXX/state
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(XXX is the place of memory)
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This is an easy way to test page migration, too.
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9.5 mkdir/rmdir
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When using hierarchy, mkdir/rmdir test should be done.
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Use tests like the following.
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echo 1 >/opt/cgroup/01/memory/use_hierarchy
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mkdir /opt/cgroup/01/child_a
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mkdir /opt/cgroup/01/child_b
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set limit to 01.
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add limit to 01/child_b
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run jobs under child_a and child_b
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create/delete following groups at random while jobs are running.
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/opt/cgroup/01/child_a/child_aa
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/opt/cgroup/01/child_b/child_bb
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/opt/cgroup/01/child_c
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running new jobs in new group is also good.
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9.6 Mount with other subsystems.
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Mounting with other subsystems is a good test because there is a
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race and lock dependency with other cgroup subsystems.
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example)
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# mount -t cgroup none /cgroup -o cpuset,memory,cpu,devices
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and do task move, mkdir, rmdir etc...under this.
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9.7 swapoff.
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Besides management of swap is one of complicated parts of memcg,
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call path of swap-in at swapoff is not same as usual swap-in path..
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It's worth to be tested explicitly.
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For example, test like following is good.
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(Shell-A)
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# mount -t cgroup none /cgroup -o memory
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# mkdir /cgroup/test
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# echo 40M > /cgroup/test/memory.limit_in_bytes
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# echo 0 > /cgroup/test/tasks
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Run malloc(100M) program under this. You'll see 60M of swaps.
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(Shell-B)
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# move all tasks in /cgroup/test to /cgroup
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# /sbin/swapoff -a
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# rmdir /cgroup/test
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# kill malloc task.
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Of course, tmpfs v.s. swapoff test should be tested, too.
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9.8 OOM-Killer
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Out-of-memory caused by memcg's limit will kill tasks under
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the memcg. When hierarchy is used, a task under hierarchy
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will be killed by the kernel.
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In this case, panic_on_oom shouldn't be invoked and tasks
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in other groups shouldn't be killed.
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It's not difficult to cause OOM under memcg as following.
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Case A) when you can swapoff
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#swapoff -a
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#echo 50M > /memory.limit_in_bytes
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run 51M of malloc
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Case B) when you use mem+swap limitation.
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#echo 50M > memory.limit_in_bytes
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#echo 50M > memory.memsw.limit_in_bytes
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run 51M of malloc
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9.9 Move charges at task migration
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Charges associated with a task can be moved along with task migration.
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(Shell-A)
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#mkdir /cgroup/A
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#echo $$ >/cgroup/A/tasks
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run some programs which uses some amount of memory in /cgroup/A.
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(Shell-B)
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#mkdir /cgroup/B
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#echo 1 >/cgroup/B/memory.move_charge_at_immigrate
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#echo "pid of the program running in group A" >/cgroup/B/tasks
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You can see charges have been moved by reading *.usage_in_bytes or
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memory.stat of both A and B.
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See 8.2 of Documentation/cgroups/memory.txt to see what value should be
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written to move_charge_at_immigrate.
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9.10 Memory thresholds
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Memory controller implements memory thresholds using cgroups notification
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API. You can use tools/cgroup/cgroup_event_listener.c to test it.
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(Shell-A) Create cgroup and run event listener
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# mkdir /cgroup/A
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# ./cgroup_event_listener /cgroup/A/memory.usage_in_bytes 5M
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(Shell-B) Add task to cgroup and try to allocate and free memory
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# echo $$ >/cgroup/A/tasks
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# a="$(dd if=/dev/zero bs=1M count=10)"
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# a=
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You will see message from cgroup_event_listener every time you cross
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the thresholds.
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Use /cgroup/A/memory.memsw.usage_in_bytes to test memsw thresholds.
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It's good idea to test root cgroup as well.
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