989 lines
39 KiB
ReStructuredText
989 lines
39 KiB
ReStructuredText
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==========================
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Memory Resource Controller
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==========================
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NOTE:
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This document is hopelessly outdated and it asks for a complete
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rewrite. It still contains a useful information so we are keeping it
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here but make sure to check the current code if you need a deeper
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understanding.
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NOTE:
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The Memory Resource Controller has generically been referred to as the
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memory controller in this document. Do not confuse memory controller
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used here with the memory controller that is used in hardware.
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(For editors) In this document:
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When we mention a cgroup (cgroupfs's directory) with memory controller,
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we call it "memory cgroup". When you see git-log and source code, you'll
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see patch's title and function names tend to use "memcg".
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In this document, we avoid using it.
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Benefits and Purpose of the memory controller
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=============================================
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The memory controller isolates the memory behaviour of a group of tasks
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from the rest of the system. The article on LWN [12] mentions some probable
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uses of the memory controller. The memory controller can be used to
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a. Isolate an application or a group of applications
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Memory-hungry applications can be isolated and limited to a smaller
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amount of memory.
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b. Create a cgroup with a limited amount of memory; this can be used
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as a good alternative to booting with mem=XXXX.
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c. Virtualization solutions can control the amount of memory they want
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to assign to a virtual machine instance.
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d. A CD/DVD burner could control the amount of memory used by the
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rest of the system to ensure that burning does not fail due to lack
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of available memory.
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e. There are several other use cases; find one or use the controller just
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for fun (to learn and hack on the VM subsystem).
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Current Status: linux-2.6.34-mmotm(development version of 2010/April)
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Features:
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- accounting anonymous pages, file caches, swap caches usage and limiting them.
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- pages are linked to per-memcg LRU exclusively, and there is no global LRU.
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- optionally, memory+swap usage can be accounted and limited.
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- hierarchical accounting
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- soft limit
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- moving (recharging) account at moving a task is selectable.
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- usage threshold notifier
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- memory pressure notifier
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- oom-killer disable knob and oom-notifier
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- Root cgroup has no limit controls.
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Kernel memory support is a work in progress, and the current version provides
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basically functionality. (See Section 2.7)
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Brief summary of control files.
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==================================== ==========================================
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tasks attach a task(thread) and show list of
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threads
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cgroup.procs show list of processes
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cgroup.event_control an interface for event_fd()
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This knob is not available on CONFIG_PREEMPT_RT systems.
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memory.usage_in_bytes show current usage for memory
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(See 5.5 for details)
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memory.memsw.usage_in_bytes show current usage for memory+Swap
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(See 5.5 for details)
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memory.limit_in_bytes set/show limit of memory usage
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memory.memsw.limit_in_bytes set/show limit of memory+Swap usage
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memory.failcnt show the number of memory usage hits limits
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memory.memsw.failcnt show the number of memory+Swap hits limits
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memory.max_usage_in_bytes show max memory usage recorded
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memory.memsw.max_usage_in_bytes show max memory+Swap usage recorded
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memory.soft_limit_in_bytes set/show soft limit of memory usage
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This knob is not available on CONFIG_PREEMPT_RT systems.
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memory.stat show various statistics
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memory.use_hierarchy set/show hierarchical account enabled
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This knob is deprecated and shouldn't be
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used.
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memory.force_empty trigger forced page reclaim
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memory.pressure_level set memory pressure notifications
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memory.swappiness set/show swappiness parameter of vmscan
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(See sysctl's vm.swappiness)
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memory.move_charge_at_immigrate set/show controls of moving charges
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This knob is deprecated and shouldn't be
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used.
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memory.oom_control set/show oom controls.
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memory.numa_stat show the number of memory usage per numa
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node
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memory.kmem.limit_in_bytes This knob is deprecated and writing to
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it will return -ENOTSUPP.
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memory.kmem.usage_in_bytes show current kernel memory allocation
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memory.kmem.failcnt show the number of kernel memory usage
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hits limits
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memory.kmem.max_usage_in_bytes show max kernel memory usage recorded
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memory.kmem.tcp.limit_in_bytes set/show hard limit for tcp buf memory
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memory.kmem.tcp.usage_in_bytes show current tcp buf memory allocation
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memory.kmem.tcp.failcnt show the number of tcp buf memory usage
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hits limits
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memory.kmem.tcp.max_usage_in_bytes show max tcp buf memory usage recorded
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==================================== ==========================================
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1. History
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==========
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The memory controller has a long history. A request for comments for the memory
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controller was posted by Balbir Singh [1]. At the time the RFC was posted
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there were several implementations for memory control. The goal of the
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RFC was to build consensus and agreement for the minimal features required
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for memory control. The first RSS controller was posted by Balbir Singh[2]
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in Feb 2007. Pavel Emelianov [3][4][5] has since posted three versions of the
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RSS controller. At OLS, at the resource management BoF, everyone suggested
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that we handle both page cache and RSS together. Another request was raised
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to allow user space handling of OOM. The current memory controller is
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at version 6; it combines both mapped (RSS) and unmapped Page
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Cache Control [11].
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2. Memory Control
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=================
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Memory is a unique resource in the sense that it is present in a limited
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amount. If a task requires a lot of CPU processing, the task can spread
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its processing over a period of hours, days, months or years, but with
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memory, the same physical memory needs to be reused to accomplish the task.
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The memory controller implementation has been divided into phases. These
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are:
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1. Memory controller
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2. mlock(2) controller
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3. Kernel user memory accounting and slab control
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4. user mappings length controller
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The memory controller is the first controller developed.
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2.1. Design
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-----------
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The core of the design is a counter called the page_counter. The
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page_counter tracks the current memory usage and limit of the group of
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processes associated with the controller. Each cgroup has a memory controller
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specific data structure (mem_cgroup) associated with it.
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2.2. Accounting
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---------------
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::
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+--------------------+
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| mem_cgroup |
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| (page_counter) |
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+--------------------+
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/ ^ \
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/ | \
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+---------------+ | +---------------+
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| mm_struct | |.... | mm_struct |
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| | | | |
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+---------------+ | +---------------+
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+ --------------+
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+---------------+ +------+--------+
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| page +----------> page_cgroup|
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| | | |
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+---------------+ +---------------+
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(Figure 1: Hierarchy of Accounting)
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Figure 1 shows the important aspects of the controller
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1. Accounting happens per cgroup
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2. Each mm_struct knows about which cgroup it belongs to
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3. Each page has a pointer to the page_cgroup, which in turn knows the
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cgroup it belongs to
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The accounting is done as follows: mem_cgroup_charge_common() is invoked to
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set up the necessary data structures and check if the cgroup that is being
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charged is over its limit. If it is, then reclaim is invoked on the cgroup.
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More details can be found in the reclaim section of this document.
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If everything goes well, a page meta-data-structure called page_cgroup is
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updated. page_cgroup has its own LRU on cgroup.
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(*) page_cgroup structure is allocated at boot/memory-hotplug time.
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2.2.1 Accounting details
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------------------------
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All mapped anon pages (RSS) and cache pages (Page Cache) are accounted.
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Some pages which are never reclaimable and will not be on the LRU
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are not accounted. We just account pages under usual VM management.
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RSS pages are accounted at page_fault unless they've already been accounted
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for earlier. A file page will be accounted for as Page Cache when it's
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inserted into inode (radix-tree). While it's mapped into the page tables of
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processes, duplicate accounting is carefully avoided.
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An RSS page is unaccounted when it's fully unmapped. A PageCache page is
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unaccounted when it's removed from radix-tree. Even if RSS pages are fully
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unmapped (by kswapd), they may exist as SwapCache in the system until they
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are really freed. Such SwapCaches are also accounted.
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A swapped-in page is accounted after adding into swapcache.
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Note: The kernel does swapin-readahead and reads multiple swaps at once.
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Since page's memcg recorded into swap whatever memsw enabled, the page will
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be accounted after swapin.
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At page migration, accounting information is kept.
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Note: we just account pages-on-LRU because our purpose is to control amount
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of used pages; not-on-LRU pages tend to be out-of-control from VM view.
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2.3 Shared Page Accounting
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--------------------------
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Shared pages are accounted on the basis of the first touch approach. The
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cgroup that first touches a page is accounted for the page. The principle
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behind this approach is that a cgroup that aggressively uses a shared
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page will eventually get charged for it (once it is uncharged from
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the cgroup that brought it in -- this will happen on memory pressure).
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But see section 8.2: when moving a task to another cgroup, its pages may
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be recharged to the new cgroup, if move_charge_at_immigrate has been chosen.
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2.4 Swap Extension
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--------------------------------------
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Swap usage is always recorded for each of cgroup. Swap Extension allows you to
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read and limit it.
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When CONFIG_SWAP is enabled, following files are added.
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- memory.memsw.usage_in_bytes.
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- memory.memsw.limit_in_bytes.
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memsw means memory+swap. Usage of memory+swap is limited by
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memsw.limit_in_bytes.
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Example: Assume a system with 4G of swap. A task which allocates 6G of memory
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(by mistake) under 2G memory limitation will use all swap.
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In this case, setting memsw.limit_in_bytes=3G will prevent bad use of swap.
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By using the memsw limit, you can avoid system OOM which can be caused by swap
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shortage.
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**why 'memory+swap' rather than swap**
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The global LRU(kswapd) can swap out arbitrary pages. Swap-out means
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to move account from memory to swap...there is no change in usage of
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memory+swap. In other words, when we want to limit the usage of swap without
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affecting global LRU, memory+swap limit is better than just limiting swap from
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an OS point of view.
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**What happens when a cgroup hits memory.memsw.limit_in_bytes**
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When a cgroup hits memory.memsw.limit_in_bytes, it's useless to do swap-out
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in this cgroup. Then, swap-out will not be done by cgroup routine and file
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caches are dropped. But as mentioned above, global LRU can do swapout memory
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from it for sanity of the system's memory management state. You can't forbid
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it by cgroup.
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2.5 Reclaim
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-----------
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Each cgroup maintains a per cgroup LRU which has the same structure as
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global VM. When a cgroup goes over its limit, we first try
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to reclaim memory from the cgroup so as to make space for the new
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pages that the cgroup has touched. If the reclaim is unsuccessful,
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an OOM routine is invoked to select and kill the bulkiest task in the
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cgroup. (See 10. OOM Control below.)
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The reclaim algorithm has not been modified for cgroups, except that
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pages that are selected for reclaiming come from the per-cgroup LRU
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list.
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NOTE:
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Reclaim does not work for the root cgroup, since we cannot set any
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limits on the root cgroup.
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Note2:
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When panic_on_oom is set to "2", the whole system will panic.
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When oom event notifier is registered, event will be delivered.
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(See oom_control section)
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2.6 Locking
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-----------
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Lock order is as follows:
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Page lock (PG_locked bit of page->flags)
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mm->page_table_lock or split pte_lock
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lock_page_memcg (memcg->move_lock)
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mapping->i_pages lock
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lruvec->lru_lock.
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Per-node-per-memcgroup LRU (cgroup's private LRU) is guarded by
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lruvec->lru_lock; PG_lru bit of page->flags is cleared before
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isolating a page from its LRU under lruvec->lru_lock.
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2.7 Kernel Memory Extension
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-----------------------------------------------
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With the Kernel memory extension, the Memory Controller is able to limit
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the amount of kernel memory used by the system. Kernel memory is fundamentally
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different than user memory, since it can't be swapped out, which makes it
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possible to DoS the system by consuming too much of this precious resource.
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Kernel memory accounting is enabled for all memory cgroups by default. But
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it can be disabled system-wide by passing cgroup.memory=nokmem to the kernel
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at boot time. In this case, kernel memory will not be accounted at all.
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Kernel memory limits are not imposed for the root cgroup. Usage for the root
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cgroup may or may not be accounted. The memory used is accumulated into
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memory.kmem.usage_in_bytes, or in a separate counter when it makes sense.
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(currently only for tcp).
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The main "kmem" counter is fed into the main counter, so kmem charges will
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also be visible from the user counter.
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Currently no soft limit is implemented for kernel memory. It is future work
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to trigger slab reclaim when those limits are reached.
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2.7.1 Current Kernel Memory resources accounted
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-----------------------------------------------
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stack pages:
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every process consumes some stack pages. By accounting into
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kernel memory, we prevent new processes from being created when the kernel
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memory usage is too high.
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slab pages:
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pages allocated by the SLAB or SLUB allocator are tracked. A copy
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of each kmem_cache is created every time the cache is touched by the first time
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from inside the memcg. The creation is done lazily, so some objects can still be
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skipped while the cache is being created. All objects in a slab page should
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belong to the same memcg. This only fails to hold when a task is migrated to a
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different memcg during the page allocation by the cache.
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sockets memory pressure:
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some sockets protocols have memory pressure
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thresholds. The Memory Controller allows them to be controlled individually
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per cgroup, instead of globally.
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tcp memory pressure:
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sockets memory pressure for the tcp protocol.
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2.7.2 Common use cases
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----------------------
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Because the "kmem" counter is fed to the main user counter, kernel memory can
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never be limited completely independently of user memory. Say "U" is the user
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limit, and "K" the kernel limit. There are three possible ways limits can be
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set:
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U != 0, K = unlimited:
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This is the standard memcg limitation mechanism already present before kmem
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accounting. Kernel memory is completely ignored.
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U != 0, K < U:
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Kernel memory is a subset of the user memory. This setup is useful in
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deployments where the total amount of memory per-cgroup is overcommitted.
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Overcommitting kernel memory limits is definitely not recommended, since the
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box can still run out of non-reclaimable memory.
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In this case, the admin could set up K so that the sum of all groups is
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never greater than the total memory, and freely set U at the cost of his
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QoS.
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WARNING:
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In the current implementation, memory reclaim will NOT be
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triggered for a cgroup when it hits K while staying below U, which makes
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this setup impractical.
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U != 0, K >= U:
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Since kmem charges will also be fed to the user counter and reclaim will be
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triggered for the cgroup for both kinds of memory. This setup gives the
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admin a unified view of memory, and it is also useful for people who just
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want to track kernel memory usage.
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3. User Interface
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=================
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3.0. Configuration
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------------------
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a. Enable CONFIG_CGROUPS
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b. Enable CONFIG_MEMCG
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3.1. Prepare the cgroups (see cgroups.txt, Why are cgroups needed?)
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-------------------------------------------------------------------
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::
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# mount -t tmpfs none /sys/fs/cgroup
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# mkdir /sys/fs/cgroup/memory
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# mount -t cgroup none /sys/fs/cgroup/memory -o memory
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3.2. Make the new group and move bash into it::
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# mkdir /sys/fs/cgroup/memory/0
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# echo $$ > /sys/fs/cgroup/memory/0/tasks
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Since now we're in the 0 cgroup, we can alter the memory limit::
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# echo 4M > /sys/fs/cgroup/memory/0/memory.limit_in_bytes
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NOTE:
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We can use a suffix (k, K, m, M, g or G) to indicate values in kilo,
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mega or gigabytes. (Here, Kilo, Mega, Giga are Kibibytes, Mebibytes,
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Gibibytes.)
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NOTE:
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We can write "-1" to reset the ``*.limit_in_bytes(unlimited)``.
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|
NOTE:
|
||
|
We cannot set limits on the root cgroup any more.
|
||
|
|
||
|
::
|
||
|
|
||
|
# cat /sys/fs/cgroup/memory/0/memory.limit_in_bytes
|
||
|
4194304
|
||
|
|
||
|
We can check the usage::
|
||
|
|
||
|
# cat /sys/fs/cgroup/memory/0/memory.usage_in_bytes
|
||
|
1216512
|
||
|
|
||
|
A successful write to this file does not guarantee a successful setting 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 the 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, disabling OOM_Kill as per "10. OOM Control" (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.)
|
||
|
|
||
|
We move the stats to parent, and no change on the charge except uncharging
|
||
|
from the child.
|
||
|
|
||
|
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.
|
||
|
When writing anything to this::
|
||
|
|
||
|
# echo 0 > memory.force_empty
|
||
|
|
||
|
the cgroup will be reclaimed and as many pages reclaimed as possible.
|
||
|
|
||
|
The typical use case for this interface is before calling rmdir().
|
||
|
Though rmdir() offlines memcg, but the memcg may still stay there due to
|
||
|
charged file caches. Some out-of-use page caches may keep charged until
|
||
|
memory pressure happens. 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 (includes
|
||
|
transparent hugepages).
|
||
|
rss_huge # of bytes of anonymous transparent hugepages.
|
||
|
mapped_file # of bytes of mapped file (includes tmpfs/shmem)
|
||
|
pgpgin # of charging events to the memory cgroup. The charging
|
||
|
event happens each time a page is accounted as either mapped
|
||
|
anon page(RSS) or cache page(Page Cache) to the cgroup.
|
||
|
pgpgout # of uncharging events to the memory cgroup. The uncharging
|
||
|
event happens each time a page is unaccounted from the cgroup.
|
||
|
swap # of bytes of swap usage
|
||
|
dirty # of bytes that are waiting to get written back to the disk.
|
||
|
writeback # of bytes of file/anon cache that are queued for syncing to
|
||
|
disk.
|
||
|
inactive_anon # of bytes of anonymous and swap cache memory on inactive
|
||
|
LRU list.
|
||
|
active_anon # of bytes of anonymous and swap cache memory on active
|
||
|
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_<counter> # hierarchical version of <counter>, which in
|
||
|
addition to the cgroup's own value includes the
|
||
|
sum of all hierarchical children's values of
|
||
|
<counter>, i.e. total_cache
|
||
|
========================= ===================================================
|
||
|
|
||
|
The following additional stats are dependent on CONFIG_DEBUG_VM
|
||
|
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
|
||
|
|
||
|
========================= ========================================
|
||
|
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 + mapped_file" will give you resident set size of cgroup.
|
||
|
|
||
|
(Note: file and shmem may be shared among other cgroups. In that case,
|
||
|
mapped_file is accounted only when the memory cgroup is owner of page
|
||
|
cache.)
|
||
|
|
||
|
5.3 swappiness
|
||
|
--------------
|
||
|
|
||
|
Overrides /proc/sys/vm/swappiness for the particular group. The tunable
|
||
|
in the root cgroup corresponds to the global swappiness setting.
|
||
|
|
||
|
Please note that unlike during the global reclaim, limit reclaim
|
||
|
enforces that 0 swappiness really prevents from any swapping even if
|
||
|
there is a swap storage available. This might lead to memcg OOM killer
|
||
|
if there are no file pages to reclaim.
|
||
|
|
||
|
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 usage_in_bytes
|
||
|
------------------
|
||
|
|
||
|
For efficiency, as other kernel components, memory cgroup uses some optimization
|
||
|
to avoid unnecessary cacheline false sharing. usage_in_bytes is affected by the
|
||
|
method and doesn't show 'exact' value of memory (and swap) usage, it's a fuzz
|
||
|
value for efficient access. (Of course, when necessary, it's synchronized.)
|
||
|
If you want to know more exact memory usage, you should use RSS+CACHE(+SWAP)
|
||
|
value in memory.stat(see 5.2).
|
||
|
|
||
|
5.6 numa_stat
|
||
|
-------------
|
||
|
|
||
|
This is similar to numa_maps but operates on a per-memcg basis. This is
|
||
|
useful for providing visibility into the numa locality information within
|
||
|
an memcg since the pages are allowed to be allocated from any physical
|
||
|
node. One of the use cases is evaluating application performance by
|
||
|
combining this information with the application's CPU allocation.
|
||
|
|
||
|
Each memcg's numa_stat file includes "total", "file", "anon" and "unevictable"
|
||
|
per-node page counts including "hierarchical_<counter>" which sums up all
|
||
|
hierarchical children's values in addition to the memcg's own value.
|
||
|
|
||
|
The output format of memory.numa_stat is::
|
||
|
|
||
|
total=<total pages> N0=<node 0 pages> N1=<node 1 pages> ...
|
||
|
file=<total file pages> N0=<node 0 pages> N1=<node 1 pages> ...
|
||
|
anon=<total anon pages> N0=<node 0 pages> N1=<node 1 pages> ...
|
||
|
unevictable=<total anon pages> N0=<node 0 pages> N1=<node 1 pages> ...
|
||
|
hierarchical_<counter>=<counter pages> N0=<node 0 pages> N1=<node 1 pages> ...
|
||
|
|
||
|
The "total" count is sum of file + anon + unevictable.
|
||
|
|
||
|
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).
|
||
|
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 Hierarchical accounting and reclaim
|
||
|
---------------------------------------
|
||
|
|
||
|
Hierarchical accounting is enabled by default. Disabling the hierarchical
|
||
|
accounting is deprecated. An attempt to do it will result in a failure
|
||
|
and a warning printed to dmesg.
|
||
|
|
||
|
For compatibility reasons writing 1 to memory.use_hierarchy will always pass::
|
||
|
|
||
|
# echo 1 > memory.use_hierarchy
|
||
|
|
||
|
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 set up 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 (DEPRECATED!)
|
||
|
===============================================
|
||
|
|
||
|
THIS IS DEPRECATED!
|
||
|
|
||
|
It's expensive and unreliable! It's better practice to launch workload
|
||
|
tasks directly from inside their target cgroup. Use dedicated workload
|
||
|
cgroups to allow fine-grained policy adjustments without having to
|
||
|
move physical pages between control domains.
|
||
|
|
||
|
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, in other words,
|
||
|
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 moved
|
||
|
--------------------------------------
|
||
|
|
||
|
Each bit in move_charge_at_immigrate has its own meaning about what type of
|
||
|
charges should be moved. But in any case, 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. |
|
||
|
| | 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
|
||
|
--------
|
||
|
|
||
|
- 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 the 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, an application must:
|
||
|
|
||
|
- create an eventfd using eventfd(2);
|
||
|
- open memory.usage_in_bytes or memory.memsw.usage_in_bytes;
|
||
|
- write string like "<event_fd> <fd of memory.usage_in_bytes> <threshold>" 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 the cgroup notification
|
||
|
API (See cgroups.txt). It allows to register multiple OOM notification
|
||
|
delivery and gets notification when OOM happens.
|
||
|
|
||
|
To register a notifier, an application must:
|
||
|
|
||
|
- create an eventfd using eventfd(2)
|
||
|
- open memory.oom_control file
|
||
|
- write string like "<event_fd> <fd of memory.oom_control>" to
|
||
|
cgroup.event_control
|
||
|
|
||
|
The application will be notified through eventfd when OOM happens.
|
||
|
OOM notification doesn't work for the root cgroup.
|
||
|
|
||
|
You can disable the OOM-killer by writing "1" to memory.oom_control file, as:
|
||
|
|
||
|
#echo 1 > memory.oom_control
|
||
|
|
||
|
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.)
|
||
|
- oom_kill integer counter
|
||
|
The number of processes belonging to this cgroup killed by any
|
||
|
kind of OOM killer.
|
||
|
|
||
|
11. Memory Pressure
|
||
|
===================
|
||
|
|
||
|
The pressure level notifications can be used to monitor the memory
|
||
|
allocation cost; based on the pressure, applications can implement
|
||
|
different strategies of managing their memory resources. The pressure
|
||
|
levels are defined as following:
|
||
|
|
||
|
The "low" level means that the system is reclaiming memory for new
|
||
|
allocations. Monitoring this reclaiming activity might be useful for
|
||
|
maintaining cache level. Upon notification, the program (typically
|
||
|
"Activity Manager") might analyze vmstat and act in advance (i.e.
|
||
|
prematurely shutdown unimportant services).
|
||
|
|
||
|
The "medium" level means that the system is experiencing medium memory
|
||
|
pressure, the system might be making swap, paging out active file caches,
|
||
|
etc. Upon this event applications may decide to further analyze
|
||
|
vmstat/zoneinfo/memcg or internal memory usage statistics and free any
|
||
|
resources that can be easily reconstructed or re-read from a disk.
|
||
|
|
||
|
The "critical" level means that the system is actively thrashing, it is
|
||
|
about to out of memory (OOM) or even the in-kernel OOM killer is on its
|
||
|
way to trigger. Applications should do whatever they can to help the
|
||
|
system. It might be too late to consult with vmstat or any other
|
||
|
statistics, so it's advisable to take an immediate action.
|
||
|
|
||
|
By default, events are propagated upward until the event is handled, i.e. the
|
||
|
events are not pass-through. For example, you have three cgroups: A->B->C. Now
|
||
|
you set up an event listener on cgroups A, B and C, and suppose group C
|
||
|
experiences some pressure. In this situation, only group C will receive the
|
||
|
notification, i.e. groups A and B will not receive it. This is done to avoid
|
||
|
excessive "broadcasting" of messages, which disturbs the system and which is
|
||
|
especially bad if we are low on memory or thrashing. Group B, will receive
|
||
|
notification only if there are no event listers for group C.
|
||
|
|
||
|
There are three optional modes that specify different propagation behavior:
|
||
|
|
||
|
- "default": this is the default behavior specified above. This mode is the
|
||
|
same as omitting the optional mode parameter, preserved by backwards
|
||
|
compatibility.
|
||
|
|
||
|
- "hierarchy": events always propagate up to the root, similar to the default
|
||
|
behavior, except that propagation continues regardless of whether there are
|
||
|
event listeners at each level, with the "hierarchy" mode. In the above
|
||
|
example, groups A, B, and C will receive notification of memory pressure.
|
||
|
|
||
|
- "local": events are pass-through, i.e. they only receive notifications when
|
||
|
memory pressure is experienced in the memcg for which the notification is
|
||
|
registered. In the above example, group C will receive notification if
|
||
|
registered for "local" notification and the group experiences memory
|
||
|
pressure. However, group B will never receive notification, regardless if
|
||
|
there is an event listener for group C or not, if group B is registered for
|
||
|
local notification.
|
||
|
|
||
|
The level and event notification mode ("hierarchy" or "local", if necessary) are
|
||
|
specified by a comma-delimited string, i.e. "low,hierarchy" specifies
|
||
|
hierarchical, pass-through, notification for all ancestor memcgs. Notification
|
||
|
that is the default, non pass-through behavior, does not specify a mode.
|
||
|
"medium,local" specifies pass-through notification for the medium level.
|
||
|
|
||
|
The file memory.pressure_level is only used to setup an eventfd. To
|
||
|
register a notification, an application must:
|
||
|
|
||
|
- create an eventfd using eventfd(2);
|
||
|
- open memory.pressure_level;
|
||
|
- write string as "<event_fd> <fd of memory.pressure_level> <level[,mode]>"
|
||
|
to cgroup.event_control.
|
||
|
|
||
|
Application will be notified through eventfd when memory pressure is at
|
||
|
the specific level (or higher). Read/write operations to
|
||
|
memory.pressure_level are no implemented.
|
||
|
|
||
|
Test:
|
||
|
|
||
|
Here is a small script example that makes a new cgroup, sets up a
|
||
|
memory limit, sets up a notification in the cgroup and then makes child
|
||
|
cgroup experience a critical pressure::
|
||
|
|
||
|
# cd /sys/fs/cgroup/memory/
|
||
|
# mkdir foo
|
||
|
# cd foo
|
||
|
# cgroup_event_listener memory.pressure_level low,hierarchy &
|
||
|
# echo 8000000 > memory.limit_in_bytes
|
||
|
# echo 8000000 > memory.memsw.limit_in_bytes
|
||
|
# echo $$ > tasks
|
||
|
# dd if=/dev/zero | read x
|
||
|
|
||
|
(Expect a bunch of notifications, and eventually, the oom-killer will
|
||
|
trigger.)
|
||
|
|
||
|
12. TODO
|
||
|
========
|
||
|
|
||
|
1. Make per-cgroup scanner reclaim not-shared pages first
|
||
|
2. Teach controller to account for shared-pages
|
||
|
3. 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
|
||
|
https://lore.kernel.org/r/45ED7DEC.7010403@sw.ru
|
||
|
4. Emelianov, Pavel. RSS controller based on process cgroups (v2)
|
||
|
https://lore.kernel.org/r/461A3010.90403@sw.ru
|
||
|
5. Emelianov, Pavel. RSS controller based on process cgroups (v3)
|
||
|
https://lore.kernel.org/r/465D9739.8070209@openvz.org
|
||
|
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),
|
||
|
https://lore.kernel.org/r/464C95D4.7070806@linux.vnet.ibm.com
|
||
|
9. Singh, Balbir. RSS controller v2 AIM9 results
|
||
|
https://lore.kernel.org/r/464D267A.50107@linux.vnet.ibm.com
|
||
|
10. Singh, Balbir. Memory controller v6 test results,
|
||
|
https://lore.kernel.org/r/20070819094658.654.84837.sendpatchset@balbir-laptop
|
||
|
11. Singh, Balbir. Memory controller introduction (v6),
|
||
|
https://lore.kernel.org/r/20070817084228.26003.12568.sendpatchset@balbir-laptop
|
||
|
12. Corbet, Jonathan, Controlling memory use in cgroups,
|
||
|
http://lwn.net/Articles/243795/
|