Memory Resource Controller NOTE: The Memory Resource Controller has been generically been referred to as the memory controller in this document. Do not confuse memory controller used here with the memory controller that is used in hardware. (For editors) In this document: When we mention a cgroup (cgroupfs's directory) with memory controller, we call it "memory cgroup". When you see git-log and source code, you'll see patch's title and function names tend to use "memcg". In this document, we avoid using it. Benefits and Purpose of the memory controller The memory controller isolates the memory behaviour of a group of tasks from the rest of the system. The article on LWN [12] mentions some probable uses of the memory controller. The memory controller can be used to a. Isolate an application or a group of applications Memory hungry applications can be isolated and limited to a smaller amount of memory. b. Create a cgroup with limited amount of memory, this can be used as a good alternative to booting with mem=XXXX. c. Virtualization solutions can control the amount of memory they want to assign to a virtual machine instance. d. A CD/DVD burner could control the amount of memory used by the rest of the system to ensure that burning does not fail due to lack of available memory. e. There are several other use cases, find one or use the controller just for fun (to learn and hack on the VM subsystem). Current Status: linux-2.6.34-mmotm(development version of 2010/April) Features: - accounting anonymous pages, file caches, swap caches usage and limiting them. - private LRU and reclaim routine. (system's global LRU and private LRU work independently from each other) - optionally, memory+swap usage can be accounted and limited. - hierarchical accounting - soft limit - moving(recharging) account at moving a task is selectable. - usage threshold notifier - oom-killer disable knob and oom-notifier - Root cgroup has no limit controls. Kernel memory and Hugepages are not under control yet. We just manage pages on LRU. To add more controls, we have to take care of performance. Brief summary of control files. tasks # attach a task(thread) and show list of threads cgroup.procs # show list of processes cgroup.event_control # an interface for event_fd() memory.usage_in_bytes # show current memory(RSS+Cache) usage. memory.memsw.usage_in_bytes # show current memory+Swap usage memory.limit_in_bytes # set/show limit of memory usage memory.memsw.limit_in_bytes # set/show limit of memory+Swap usage memory.failcnt # show the number of memory usage hits limits memory.memsw.failcnt # show the number of memory+Swap hits limits memory.max_usage_in_bytes # show max memory usage recorded memory.memsw.usage_in_bytes # show max memory+Swap usage recorded memory.soft_limit_in_bytes # set/show soft limit of memory usage memory.stat # show various statistics memory.use_hierarchy # set/show hierarchical account enabled memory.force_empty # trigger forced move charge to parent memory.swappiness # set/show swappiness parameter of vmscan (See sysctl's vm.swappiness) memory.move_charge_at_immigrate # set/show controls of moving charges memory.oom_control # set/show oom controls. 1. History The memory controller has a long history. A request for comments for the memory controller was posted by Balbir Singh [1]. At the time the RFC was posted there were several implementations for memory control. The goal of the RFC was to build consensus and agreement for the minimal features required for memory control. The first RSS controller was posted by Balbir Singh[2] in Feb 2007. Pavel Emelianov [3][4][5] has since posted three versions of the RSS controller. At OLS, at the resource management BoF, everyone suggested that we handle both page cache and RSS together. Another request was raised to allow user space handling of OOM. The current memory controller is at version 6; it combines both mapped (RSS) and unmapped Page Cache Control [11]. 2. Memory Control Memory is a unique resource in the sense that it is present in a limited amount. If a task requires a lot of CPU processing, the task can spread its processing over a period of hours, days, months or years, but with memory, the same physical memory needs to be reused to accomplish the task. The memory controller implementation has been divided into phases. These are: 1. Memory controller 2. mlock(2) controller 3. Kernel user memory accounting and slab control 4. user mappings length controller The memory controller is the first controller developed. 2.1. Design The core of the design is a counter called the res_counter. The res_counter tracks the current memory usage and limit of the group of processes associated with the controller. Each cgroup has a memory controller specific data structure (mem_cgroup) associated with it. 2.2. Accounting +--------------------+ | mem_cgroup | | (res_counter) | +--------------------+ / ^ \ / | \ +---------------+ | +---------------+ | mm_struct | |.... | mm_struct | | | | | | +---------------+ | +---------------+ | + --------------+ | +---------------+ +------+--------+ | page +----------> page_cgroup| | | | | +---------------+ +---------------+ (Figure 1: Hierarchy of Accounting) Figure 1 shows the important aspects of the controller 1. Accounting happens per cgroup 2. Each mm_struct knows about which cgroup it belongs to 3. Each page has a pointer to the page_cgroup, which in turn knows the cgroup it belongs to The accounting is done as follows: mem_cgroup_charge() is invoked to setup the necessary data structures and check if the cgroup that is being charged is over its limit. If it is then reclaim is invoked on the cgroup. More details can be found in the reclaim section of this document. If everything goes well, a page meta-data-structure called page_cgroup is updated. page_cgroup has its own LRU on cgroup. (*) page_cgroup structure is allocated at boot/memory-hotplug time. 2.2.1 Accounting details All mapped anon pages (RSS) and cache pages (Page Cache) are accounted. Some pages which are never reclaimable and will not be on the global LRU are not accounted. We just account pages under usual VM management. RSS pages are accounted at page_fault unless they've already been accounted for earlier. A file page will be accounted for as Page Cache when it's inserted into inode (radix-tree). While it's mapped into the page tables of processes, duplicate accounting is carefully avoided. A RSS page is unaccounted when it's fully unmapped. A PageCache page is unaccounted when it's removed from radix-tree. Even if RSS pages are fully unmapped (by kswapd), they may exist as SwapCache in the system until they are really freed. Such SwapCaches also also accounted. A swapped-in page is not accounted until it's mapped. Note: The kernel does swapin-readahead and read multiple swaps at once. This means swapped-in pages may contain pages for other tasks than a task causing page fault. So, we avoid accounting at swap-in I/O. At page migration, accounting information is kept. Note: we just account pages-on-LRU because our purpose is to control amount of used pages; not-on-LRU pages tend to be out-of-control from VM view. 2.3 Shared Page Accounting Shared pages are accounted on the basis of the first touch approach. The cgroup that first touches a page is accounted for the page. The principle behind this approach is that a cgroup that aggressively uses a shared page will eventually get charged for it (once it is uncharged from the cgroup that brought it in -- this will happen on memory pressure). Exception: If CONFIG_CGROUP_CGROUP_MEM_RES_CTLR_SWAP is not used.. When you do swapoff and make swapped-out pages of shmem(tmpfs) to be backed into memory in force, charges for pages are accounted against the caller of swapoff rather than the users of shmem. 2.4 Swap Extension (CONFIG_CGROUP_MEM_RES_CTLR_SWAP) Swap Extension allows you to record charge for swap. A swapped-in page is charged back to original page allocator if possible. When swap is accounted, following files are added. - memory.memsw.usage_in_bytes. - memory.memsw.limit_in_bytes. memsw means memory+swap. Usage of memory+swap is limited by memsw.limit_in_bytes. Example: Assume a system with 4G of swap. A task which allocates 6G of memory (by mistake) under 2G memory limitation will use all swap. In this case, setting memsw.limit_in_bytes=3G will prevent bad use of swap. By using memsw limit, you can avoid system OOM which can be caused by swap shortage. * why 'memory+swap' rather than swap. The global LRU(kswapd) can swap out arbitrary pages. Swap-out means to move account from memory to swap...there is no change in usage of memory+swap. In other words, when we want to limit the usage of swap without affecting global LRU, memory+swap limit is better than just limiting swap from OS point of view. * What happens when a cgroup hits memory.memsw.limit_in_bytes When a cgroup his memory.memsw.limit_in_bytes, it's useless to do swap-out in this cgroup. Then, swap-out will not be done by cgroup routine and file caches are dropped. But as mentioned above, global LRU can do swapout memory from it for sanity of the system's memory management state. You can't forbid it by cgroup. 2.5 Reclaim Each cgroup maintains a per cgroup LRU which has the same structure as global VM. When a cgroup goes over its limit, we first try to reclaim memory from the cgroup so as to make space for the new pages that the cgroup has touched. If the reclaim is unsuccessful, an OOM routine is invoked to select and kill the bulkiest task in the cgroup. (See 10. OOM Control below.) The reclaim algorithm has not been modified for cgroups, except that pages that are selected for reclaiming come from the per cgroup LRU list. NOTE: Reclaim does not work for the root cgroup, since we cannot set any limits on the root cgroup. Note2: When panic_on_oom is set to "2", the whole system will panic. When oom event notifier is registered, event will be delivered. (See oom_control section) 2.6 Locking lock_page_cgroup()/unlock_page_cgroup() should not be called under mapping->tree_lock. Other lock order is following: PG_locked. mm->page_table_lock zone->lru_lock lock_page_cgroup. In many cases, just lock_page_cgroup() is called. per-zone-per-cgroup LRU (cgroup's private LRU) is just guarded by zone->lru_lock, it has no lock of its own. 3. User Interface 0. Configuration a. Enable CONFIG_CGROUPS b. Enable CONFIG_RESOURCE_COUNTERS c. Enable CONFIG_CGROUP_MEM_RES_CTLR d. Enable CONFIG_CGROUP_MEM_RES_CTLR_SWAP (to use swap extension) 1. Prepare the cgroups # mkdir -p /cgroups # mount -t cgroup none /cgroups -o memory 2. Make the new group and move bash into it # mkdir /cgroups/0 # echo $$ > /cgroups/0/tasks Since now we're in the 0 cgroup, we can alter the memory limit: # echo 4M > /cgroups/0/memory.limit_in_bytes NOTE: We can use a suffix (k, K, m, M, g or G) to indicate values in kilo, mega or gigabytes. (Here, Kilo, Mega, Giga are Kibibytes, Mebibytes, Gibibytes.) NOTE: We can write "-1" to reset the *.limit_in_bytes(unlimited). NOTE: We cannot set limits on the root cgroup any more. # cat /cgroups/0/memory.limit_in_bytes 4194304 We can check the usage: # cat /cgroups/0/memory.usage_in_bytes 1216512 A successful write to this file does not guarantee a successful set of this limit to the value written into the file. This can be due to a number of factors, such as rounding up to page boundaries or the total availability of memory on the system. The user is required to re-read this file after a write to guarantee the value committed by the kernel. # echo 1 > memory.limit_in_bytes # cat memory.limit_in_bytes 4096 The memory.failcnt field gives the number of times that the cgroup limit was exceeded. The memory.stat file gives accounting information. Now, the number of caches, RSS and Active pages/Inactive pages are shown. 4. Testing For testing features and implementation, see memcg_test.txt. Performance test is also important. To see pure memory controller's overhead, testing on tmpfs will give you good numbers of small overheads. Example: do kernel make on tmpfs. Page-fault scalability is also important. At measuring parallel page fault test, multi-process test may be better than multi-thread test because it has noise of shared objects/status. But the above two are testing extreme situations. Trying usual test under memory controller is always helpful. 4.1 Troubleshooting Sometimes a user might find that the application under a cgroup is terminated by OOM killer. There are several causes for this: 1. The cgroup limit is too low (just too low to do anything useful) 2. The user is using anonymous memory and swap is turned off or too low A sync followed by echo 1 > /proc/sys/vm/drop_caches will help get rid of some of the pages cached in the cgroup (page cache pages). To know what happens, disable OOM_Kill by 10. OOM Control(see below) and seeing what happens will be helpful. 4.2 Task migration When a task migrates from one cgroup to another, its charge is not carried forward by default. The pages allocated from the original cgroup still remain charged to it, the charge is dropped when the page is freed or reclaimed. You can move charges of a task along with task migration. See 8. "Move charges at task migration" 4.3 Removing a cgroup A cgroup can be removed by rmdir, but as discussed in sections 4.1 and 4.2, a cgroup might have some charge associated with it, even though all tasks have migrated away from it. (because we charge against pages, not against tasks.) Such charges are freed or moved to their parent. At moving, both of RSS and CACHES are moved to parent. rmdir() may return -EBUSY if freeing/moving fails. See 5.1 also. Charges recorded in swap information is not updated at removal of cgroup. Recorded information is discarded and a cgroup which uses swap (swapcache) will be charged as a new owner of it. 5. Misc. interfaces. 5.1 force_empty memory.force_empty interface is provided to make cgroup's memory usage empty. You can use this interface only when the cgroup has no tasks. When writing anything to this # echo 0 > memory.force_empty Almost all pages tracked by this memory cgroup will be unmapped and freed. Some pages cannot be freed because they are locked or in-use. Such pages are moved to parent and this cgroup will be empty. This may return -EBUSY if VM is too busy to free/move all pages immediately. Typical use case of this interface is that calling this before rmdir(). Because rmdir() moves all pages to parent, some out-of-use page caches can be moved to the parent. If you want to avoid that, force_empty will be useful. 5.2 stat file memory.stat file includes following statistics # per-memory cgroup local status cache - # of bytes of page cache memory. rss - # of bytes of anonymous and swap cache memory. mapped_file - # of bytes of mapped file (includes tmpfs/shmem) pgpgin - # of pages paged in (equivalent to # of charging events). pgpgout - # of pages paged out (equivalent to # of uncharging events). swap - # of bytes of swap usage dirty - # of bytes that are waiting to get written back to the disk. writeback - # of bytes that are actively being written back to the disk. nfs_unstable - # of bytes sent to the NFS server, but not yet committed to the actual storage. inactive_anon - # of bytes of anonymous memory and swap cache memory on LRU list. active_anon - # of bytes of anonymous and swap cache memory on active inactive LRU list. inactive_file - # of bytes of file-backed memory on inactive LRU list. active_file - # of bytes of file-backed memory on active LRU list. unevictable - # of bytes of memory that cannot be reclaimed (mlocked etc). # status considering hierarchy (see memory.use_hierarchy settings) hierarchical_memory_limit - # of bytes of memory limit with regard to hierarchy under which the memory cgroup is hierarchical_memsw_limit - # of bytes of memory+swap limit with regard to hierarchy under which memory cgroup is. total_cache - sum of all children's "cache" total_rss - sum of all children's "rss" total_mapped_file - sum of all children's "cache" total_pgpgin - sum of all children's "pgpgin" total_pgpgout - sum of all children's "pgpgout" total_swap - sum of all children's "swap" total_dirty - sum of all children's "dirty" total_writeback - sum of all children's "writeback" total_nfs_unstable - sum of all children's "nfs_unstable" total_inactive_anon - sum of all children's "inactive_anon" total_active_anon - sum of all children's "active_anon" total_inactive_file - sum of all children's "inactive_file" total_active_file - sum of all children's "active_file" total_unevictable - sum of all children's "unevictable" # The following additional stats are dependent on CONFIG_DEBUG_VM. inactive_ratio - VM internal parameter. (see mm/page_alloc.c) recent_rotated_anon - VM internal parameter. (see mm/vmscan.c) recent_rotated_file - VM internal parameter. (see mm/vmscan.c) recent_scanned_anon - VM internal parameter. (see mm/vmscan.c) recent_scanned_file - VM internal parameter. (see mm/vmscan.c) Memo: recent_rotated means recent frequency of LRU rotation. recent_scanned means recent # of scans to LRU. showing for better debug please see the code for meanings. Note: Only anonymous and swap cache memory is listed as part of 'rss' stat. This should not be confused with the true 'resident set size' or the amount of physical memory used by the cgroup. 'rss + file_mapped" will give you resident set size of cgroup. (Note: file and shmem may be shared among other cgroups. In that case, file_mapped is accounted only when the memory cgroup is owner of page cache.) 5.3 swappiness Similar to /proc/sys/vm/swappiness, but affecting a hierarchy of groups only. Following cgroups' swappiness can't be changed. - root cgroup (uses /proc/sys/vm/swappiness). - a cgroup which uses hierarchy and it has other cgroup(s) below it. - a cgroup which uses hierarchy and not the root of hierarchy. 5.4 failcnt A memory cgroup provides memory.failcnt and memory.memsw.failcnt files. This failcnt(== failure count) shows the number of times that a usage counter hit its limit. When a memory cgroup hits a limit, failcnt increases and memory under it will be reclaimed. You can reset failcnt by writing 0 to failcnt file. # echo 0 > .../memory.failcnt 5.5 dirty memory Control the maximum amount of dirty pages a cgroup can have at any given time. Limiting dirty memory is like fixing the max amount of dirty (hard to reclaim) page cache used by a cgroup. So, in case of multiple cgroup writers, they will not be able to consume more than their designated share of dirty pages and will be forced to perform write-out if they cross that limit. The interface is equivalent to the procfs interface: /proc/sys/vm/dirty_*. It is possible to configure a limit to trigger both a direct writeback or a background writeback performed by per-bdi flusher threads. The root cgroup memory.dirty_* control files are read-only and match the contents of the /proc/sys/vm/dirty_* files. Per-cgroup dirty limits can be set using the following files in the cgroupfs: - memory.dirty_ratio: the amount of dirty memory (expressed as a percentage of cgroup memory) at which a process generating dirty pages will itself start writing out dirty data. - memory.dirty_limit_in_bytes: the amount of dirty memory (expressed in bytes) in the cgroup at which a process generating dirty pages will start itself writing out dirty data. Suffix (k, K, m, M, g, or G) can be used to indicate that value is kilo, mega or gigabytes. Note: memory.dirty_limit_in_bytes is the counterpart of memory.dirty_ratio. Only one of them may be specified at a time. When one is written it is immediately taken into account to evaluate the dirty memory limits and the other appears as 0 when read. - memory.dirty_background_ratio: the amount of dirty memory of the cgroup (expressed as a percentage of cgroup memory) at which background writeback kernel threads will start writing out dirty data. - memory.dirty_background_limit_in_bytes: the amount of dirty memory (expressed in bytes) in the cgroup at which background writeback kernel threads will start writing out dirty data. Suffix (k, K, m, M, g, or G) can be used to indicate that value is kilo, mega or gigabytes. Note: memory.dirty_background_limit_in_bytes is the counterpart of memory.dirty_background_ratio. Only one of them may be specified at a time. When one is written it is immediately taken into account to evaluate the dirty memory limits and the other appears as 0 when read. A cgroup may contain more dirty memory than its dirty limit. This is possible because of the principle that the first cgroup to touch a page is charged for it. Subsequent page counting events (dirty, writeback, nfs_unstable) are also counted to the originally charged cgroup. Example: If page is allocated by a cgroup A task, then the page is charged to cgroup A. If the page is later dirtied by a task in cgroup B, then the cgroup A dirty count will be incremented. If cgroup A is over its dirty limit but cgroup B is not, then dirtying a cgroup A page from a cgroup B task may push cgroup A over its dirty limit without throttling the dirtying cgroup B task. When use_hierarchy=0, each cgroup has dirty memory usage and limits. System-wide dirty limits are also consulted. Dirty memory consumption is checked against both system-wide and per-cgroup dirty limits. The current implementation does not enforce per-cgroup dirty limits when use_hierarchy=1. System-wide dirty limits are used for processes in such cgroups. Attempts to read memory.dirty_* files return the system-wide values. Writes to the memory.dirty_* files return error. An enhanced implementation is needed to check the chain of parents to ensure that no dirty limit is exceeded. 6. Hierarchy support The memory controller supports a deep hierarchy and hierarchical accounting. The hierarchy is created by creating the appropriate cgroups in the cgroup filesystem. Consider for example, the following cgroup filesystem hierarchy root / | \ / | \ a b c | \ | \ d e In the diagram above, with hierarchical accounting enabled, all memory usage of e, is accounted to its ancestors up until the root (i.e, c and root), that has memory.use_hierarchy enabled. If one of the ancestors goes over its limit, the reclaim algorithm reclaims from the tasks in the ancestor and the children of the ancestor. 6.1 Enabling hierarchical accounting and reclaim A memory cgroup by default disables the hierarchy feature. Support can be enabled by writing 1 to memory.use_hierarchy file of the root cgroup # echo 1 > memory.use_hierarchy The feature can be disabled by # echo 0 > memory.use_hierarchy NOTE1: Enabling/disabling will fail if the cgroup already has other cgroups created below it. NOTE2: When panic_on_oom is set to "2", the whole system will panic in case of an OOM event in any cgroup. 7. Soft limits Soft limits allow for greater sharing of memory. The idea behind soft limits is to allow control groups to use as much of the memory as needed, provided a. There is no memory contention b. They do not exceed their hard limit When the system detects memory contention or low memory, control groups are pushed back to their soft limits. If the soft limit of each control group is very high, they are pushed back as much as possible to make sure that one control group does not starve the others of memory. Please note that soft limits is a best effort feature, it comes with no guarantees, but it does its best to make sure that when memory is heavily contended for, memory is allocated based on the soft limit hints/setup. Currently soft limit based reclaim is setup such that it gets invoked from balance_pgdat (kswapd). 7.1 Interface Soft limits can be setup by using the following commands (in this example we assume a soft limit of 256 MiB) # echo 256M > memory.soft_limit_in_bytes If we want to change this to 1G, we can at any time use # echo 1G > memory.soft_limit_in_bytes NOTE1: Soft limits take effect over a long period of time, since they involve reclaiming memory for balancing between memory cgroups NOTE2: It is recommended to set the soft limit always below the hard limit, otherwise the hard limit will take precedence. 8. Move charges at task migration Users can move charges associated with a task along with task migration, that is, uncharge task's pages from the old cgroup and charge them to the new cgroup. This feature is not supported in !CONFIG_MMU environments because of lack of page tables. 8.1 Interface This feature is disabled by default. It can be enabled(and disabled again) by writing to memory.move_charge_at_immigrate of the destination cgroup. If you want to enable it: # echo (some positive value) > memory.move_charge_at_immigrate Note: Each bits of move_charge_at_immigrate has its own meaning about what type of charges should be moved. See 8.2 for details. Note: Charges are moved only when you move mm->owner, IOW, a leader of a thread group. Note: If we cannot find enough space for the task in the destination cgroup, we try to make space by reclaiming memory. Task migration may fail if we cannot make enough space. Note: It can take several seconds if you move charges much. And if you want disable it again: # echo 0 > memory.move_charge_at_immigrate 8.2 Type of charges which can be move Each bits of move_charge_at_immigrate has its own meaning about what type of charges should be moved. But in any cases, it must be noted that an account of a page or a swap can be moved only when it is charged to the task's current(old) memory cgroup. bit | what type of charges would be moved ? -----+------------------------------------------------------------------------ 0 | A charge of an anonymous page(or swap of it) used by the target task. | Those pages and swaps must be used only by the target task. You must | enable Swap Extension(see 2.4) to enable move of swap charges. -----+------------------------------------------------------------------------ 1 | A charge of file pages(normal file, tmpfs file(e.g. ipc shared memory) | and swaps of tmpfs file) mmapped by the target task. Unlike the case of | anonymous pages, file pages(and swaps) in the range mmapped by the task | will be moved even if the task hasn't done page fault, i.e. they might | not be the task's "RSS", but other task's "RSS" that maps the same file. | And mapcount of the page is ignored(the page can be moved even if | page_mapcount(page) > 1). You must enable Swap Extension(see 2.4) to | enable move of swap charges. 8.3 TODO - Implement madvise(2) to let users decide the vma to be moved or not to be moved. - All of moving charge operations are done under cgroup_mutex. It's not good behavior to hold the mutex too long, so we may need some trick. 9. Memory thresholds Memory cgroup implements memory thresholds using cgroups notification API (see cgroups.txt). It allows to register multiple memory and memsw thresholds and gets notifications when it crosses. To register a threshold application need: - create an eventfd using eventfd(2); - open memory.usage_in_bytes or memory.memsw.usage_in_bytes; - write string like " " to cgroup.event_control. Application will be notified through eventfd when memory usage crosses threshold in any direction. It's applicable for root and non-root cgroup. 10. OOM Control memory.oom_control file is for OOM notification and other controls. Memory cgroup implements OOM notifier using cgroup notification API (See cgroups.txt). It allows to register multiple OOM notification delivery and gets notification when OOM happens. To register a notifier, application need: - create an eventfd using eventfd(2) - open memory.oom_control file - write string like " " to cgroup.event_control Application will be notified through eventfd when OOM happens. OOM notification doesn't work for root cgroup. You can disable OOM-killer by writing "1" to memory.oom_control file, as: #echo 1 > memory.oom_control This operation is only allowed to the top cgroup of sub-hierarchy. If OOM-killer is disabled, tasks under cgroup will hang/sleep in memory cgroup's OOM-waitqueue when they request accountable memory. For running them, you have to relax the memory cgroup's OOM status by * enlarge limit or reduce usage. To reduce usage, * kill some tasks. * move some tasks to other group with account migration. * remove some files (on tmpfs?) Then, stopped tasks will work again. At reading, current status of OOM is shown. oom_kill_disable 0 or 1 (if 1, oom-killer is disabled) under_oom 0 or 1 (if 1, the memory cgroup is under OOM, tasks may be stopped.) 11. TODO 1. Add support for accounting huge pages (as a separate controller) 2. Make per-cgroup scanner reclaim not-shared pages first 3. Teach controller to account for shared-pages 4. Start reclamation in the background when the limit is not yet hit but the usage is getting closer Summary Overall, the memory controller has been a stable controller and has been commented and discussed quite extensively in the community. References 1. Singh, Balbir. RFC: Memory Controller, http://lwn.net/Articles/206697/ 2. Singh, Balbir. Memory Controller (RSS Control), http://lwn.net/Articles/222762/ 3. Emelianov, Pavel. Resource controllers based on process cgroups http://lkml.org/lkml/2007/3/6/198 4. Emelianov, Pavel. RSS controller based on process cgroups (v2) http://lkml.org/lkml/2007/4/9/78 5. Emelianov, Pavel. RSS controller based on process cgroups (v3) http://lkml.org/lkml/2007/5/30/244 6. Menage, Paul. Control Groups v10, http://lwn.net/Articles/236032/ 7. Vaidyanathan, Srinivasan, Control Groups: Pagecache accounting and control subsystem (v3), http://lwn.net/Articles/235534/ 8. Singh, Balbir. RSS controller v2 test results (lmbench), http://lkml.org/lkml/2007/5/17/232 9. Singh, Balbir. RSS controller v2 AIM9 results http://lkml.org/lkml/2007/5/18/1 10. Singh, Balbir. Memory controller v6 test results, http://lkml.org/lkml/2007/8/19/36 11. Singh, Balbir. Memory controller introduction (v6), http://lkml.org/lkml/2007/8/17/69 12. Corbet, Jonathan, Controlling memory use in cgroups, http://lwn.net/Articles/243795/