forked from luck/tmp_suning_uos_patched
8dc4f3e17d
Move the calls to the cgroup subsystem destroy() methods from cgroup_rmdir() to cgroup_diput(). This allows control file reads and writes to access their subsystem state without having to be concerned with locking against cgroup destruction - the control file dentry will keep the cgroup and its subsystem state objects alive until the file is closed. The documentation is updated to reflect the changed semantics of destroy(); additionally the locking comments for destroy() and some other methods were clarified and decrustified. Signed-off-by: Paul Menage <menage@google.com> Cc: Paul Jackson <pj@sgi.com> Signed-off-by: Andrew Morton <akpm@linux-foundation.org> Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
546 lines
21 KiB
Plaintext
546 lines
21 KiB
Plaintext
CGROUPS
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-------
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Written by Paul Menage <menage@google.com> based on Documentation/cpusets.txt
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Original copyright statements from cpusets.txt:
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Portions Copyright (C) 2004 BULL SA.
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Portions Copyright (c) 2004-2006 Silicon Graphics, Inc.
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Modified by Paul Jackson <pj@sgi.com>
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Modified by Christoph Lameter <clameter@sgi.com>
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CONTENTS:
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=========
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1. Control Groups
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1.1 What are cgroups ?
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1.2 Why are cgroups needed ?
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1.3 How are cgroups implemented ?
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1.4 What does notify_on_release do ?
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1.5 How do I use cgroups ?
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2. Usage Examples and Syntax
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2.1 Basic Usage
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2.2 Attaching processes
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3. Kernel API
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3.1 Overview
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3.2 Synchronization
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3.3 Subsystem API
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4. Questions
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1. Control Groups
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==========
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1.1 What are cgroups ?
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----------------------
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Control Groups provide a mechanism for aggregating/partitioning sets of
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tasks, and all their future children, into hierarchical groups with
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specialized behaviour.
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Definitions:
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A *cgroup* associates a set of tasks with a set of parameters for one
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or more subsystems.
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A *subsystem* is a module that makes use of the task grouping
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facilities provided by cgroups to treat groups of tasks in
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particular ways. A subsystem is typically a "resource controller" that
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schedules a resource or applies per-cgroup limits, but it may be
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anything that wants to act on a group of processes, e.g. a
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virtualization subsystem.
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A *hierarchy* is a set of cgroups arranged in a tree, such that
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every task in the system is in exactly one of the cgroups in the
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hierarchy, and a set of subsystems; each subsystem has system-specific
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state attached to each cgroup in the hierarchy. Each hierarchy has
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an instance of the cgroup virtual filesystem associated with it.
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At any one time there may be multiple active hierachies of task
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cgroups. Each hierarchy is a partition of all tasks in the system.
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User level code may create and destroy cgroups by name in an
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instance of the cgroup virtual file system, specify and query to
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which cgroup a task is assigned, and list the task pids assigned to
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a cgroup. Those creations and assignments only affect the hierarchy
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associated with that instance of the cgroup file system.
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On their own, the only use for cgroups is for simple job
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tracking. The intention is that other subsystems hook into the generic
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cgroup support to provide new attributes for cgroups, such as
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accounting/limiting the resources which processes in a cgroup can
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access. For example, cpusets (see Documentation/cpusets.txt) allows
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you to associate a set of CPUs and a set of memory nodes with the
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tasks in each cgroup.
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1.2 Why are cgroups needed ?
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----------------------------
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There are multiple efforts to provide process aggregations in the
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Linux kernel, mainly for resource tracking purposes. Such efforts
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include cpusets, CKRM/ResGroups, UserBeanCounters, and virtual server
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namespaces. These all require the basic notion of a
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grouping/partitioning of processes, with newly forked processes ending
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in the same group (cgroup) as their parent process.
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The kernel cgroup patch provides the minimum essential kernel
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mechanisms required to efficiently implement such groups. It has
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minimal impact on the system fast paths, and provides hooks for
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specific subsystems such as cpusets to provide additional behaviour as
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desired.
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Multiple hierarchy support is provided to allow for situations where
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the division of tasks into cgroups is distinctly different for
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different subsystems - having parallel hierarchies allows each
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hierarchy to be a natural division of tasks, without having to handle
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complex combinations of tasks that would be present if several
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unrelated subsystems needed to be forced into the same tree of
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cgroups.
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At one extreme, each resource controller or subsystem could be in a
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separate hierarchy; at the other extreme, all subsystems
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would be attached to the same hierarchy.
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As an example of a scenario (originally proposed by vatsa@in.ibm.com)
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that can benefit from multiple hierarchies, consider a large
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university server with various users - students, professors, system
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tasks etc. The resource planning for this server could be along the
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following lines:
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CPU : Top cpuset
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/ \
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CPUSet1 CPUSet2
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(Profs) (Students)
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In addition (system tasks) are attached to topcpuset (so
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that they can run anywhere) with a limit of 20%
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Memory : Professors (50%), students (30%), system (20%)
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Disk : Prof (50%), students (30%), system (20%)
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Network : WWW browsing (20%), Network File System (60%), others (20%)
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/ \
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Prof (15%) students (5%)
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Browsers like firefox/lynx go into the WWW network class, while (k)nfsd go
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into NFS network class.
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At the same time firefox/lynx will share an appropriate CPU/Memory class
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depending on who launched it (prof/student).
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With the ability to classify tasks differently for different resources
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(by putting those resource subsystems in different hierarchies) then
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the admin can easily set up a script which receives exec notifications
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and depending on who is launching the browser he can
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# echo browser_pid > /mnt/<restype>/<userclass>/tasks
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With only a single hierarchy, he now would potentially have to create
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a separate cgroup for every browser launched and associate it with
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approp network and other resource class. This may lead to
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proliferation of such cgroups.
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Also lets say that the administrator would like to give enhanced network
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access temporarily to a student's browser (since it is night and the user
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wants to do online gaming :) OR give one of the students simulation
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apps enhanced CPU power,
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With ability to write pids directly to resource classes, its just a
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matter of :
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# echo pid > /mnt/network/<new_class>/tasks
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(after some time)
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# echo pid > /mnt/network/<orig_class>/tasks
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Without this ability, he would have to split the cgroup into
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multiple separate ones and then associate the new cgroups with the
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new resource classes.
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1.3 How are cgroups implemented ?
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---------------------------------
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Control Groups extends the kernel as follows:
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- Each task in the system has a reference-counted pointer to a
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css_set.
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- A css_set contains a set of reference-counted pointers to
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cgroup_subsys_state objects, one for each cgroup subsystem
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registered in the system. There is no direct link from a task to
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the cgroup of which it's a member in each hierarchy, but this
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can be determined by following pointers through the
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cgroup_subsys_state objects. This is because accessing the
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subsystem state is something that's expected to happen frequently
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and in performance-critical code, whereas operations that require a
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task's actual cgroup assignments (in particular, moving between
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cgroups) are less common. A linked list runs through the cg_list
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field of each task_struct using the css_set, anchored at
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css_set->tasks.
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- A cgroup hierarchy filesystem can be mounted for browsing and
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manipulation from user space.
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- You can list all the tasks (by pid) attached to any cgroup.
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The implementation of cgroups requires a few, simple hooks
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into the rest of the kernel, none in performance critical paths:
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- in init/main.c, to initialize the root cgroups and initial
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css_set at system boot.
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- in fork and exit, to attach and detach a task from its css_set.
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In addition a new file system, of type "cgroup" may be mounted, to
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enable browsing and modifying the cgroups presently known to the
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kernel. When mounting a cgroup hierarchy, you may specify a
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comma-separated list of subsystems to mount as the filesystem mount
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options. By default, mounting the cgroup filesystem attempts to
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mount a hierarchy containing all registered subsystems.
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If an active hierarchy with exactly the same set of subsystems already
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exists, it will be reused for the new mount. If no existing hierarchy
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matches, and any of the requested subsystems are in use in an existing
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hierarchy, the mount will fail with -EBUSY. Otherwise, a new hierarchy
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is activated, associated with the requested subsystems.
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It's not currently possible to bind a new subsystem to an active
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cgroup hierarchy, or to unbind a subsystem from an active cgroup
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hierarchy. This may be possible in future, but is fraught with nasty
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error-recovery issues.
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When a cgroup filesystem is unmounted, if there are any
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child cgroups created below the top-level cgroup, that hierarchy
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will remain active even though unmounted; if there are no
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child cgroups then the hierarchy will be deactivated.
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No new system calls are added for cgroups - all support for
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querying and modifying cgroups is via this cgroup file system.
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Each task under /proc has an added file named 'cgroup' displaying,
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for each active hierarchy, the subsystem names and the cgroup name
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as the path relative to the root of the cgroup file system.
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Each cgroup is represented by a directory in the cgroup file system
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containing the following files describing that cgroup:
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- tasks: list of tasks (by pid) attached to that cgroup
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- notify_on_release flag: run /sbin/cgroup_release_agent on exit?
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Other subsystems such as cpusets may add additional files in each
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cgroup dir
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New cgroups are created using the mkdir system call or shell
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command. The properties of a cgroup, such as its flags, are
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modified by writing to the appropriate file in that cgroups
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directory, as listed above.
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The named hierarchical structure of nested cgroups allows partitioning
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a large system into nested, dynamically changeable, "soft-partitions".
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The attachment of each task, automatically inherited at fork by any
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children of that task, to a cgroup allows organizing the work load
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on a system into related sets of tasks. A task may be re-attached to
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any other cgroup, if allowed by the permissions on the necessary
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cgroup file system directories.
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When a task is moved from one cgroup to another, it gets a new
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css_set pointer - if there's an already existing css_set with the
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desired collection of cgroups then that group is reused, else a new
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css_set is allocated. Note that the current implementation uses a
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linear search to locate an appropriate existing css_set, so isn't
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very efficient. A future version will use a hash table for better
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performance.
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To allow access from a cgroup to the css_sets (and hence tasks)
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that comprise it, a set of cg_cgroup_link objects form a lattice;
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each cg_cgroup_link is linked into a list of cg_cgroup_links for
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a single cgroup on its cont_link_list field, and a list of
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cg_cgroup_links for a single css_set on its cg_link_list.
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Thus the set of tasks in a cgroup can be listed by iterating over
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each css_set that references the cgroup, and sub-iterating over
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each css_set's task set.
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The use of a Linux virtual file system (vfs) to represent the
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cgroup hierarchy provides for a familiar permission and name space
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for cgroups, with a minimum of additional kernel code.
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1.4 What does notify_on_release do ?
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------------------------------------
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*** notify_on_release is disabled in the current patch set. It will be
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*** reactivated in a future patch in a less-intrusive manner
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If the notify_on_release flag is enabled (1) in a cgroup, then
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whenever the last task in the cgroup leaves (exits or attaches to
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some other cgroup) and the last child cgroup of that cgroup
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is removed, then the kernel runs the command specified by the contents
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of the "release_agent" file in that hierarchy's root directory,
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supplying the pathname (relative to the mount point of the cgroup
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file system) of the abandoned cgroup. This enables automatic
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removal of abandoned cgroups. The default value of
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notify_on_release in the root cgroup at system boot is disabled
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(0). The default value of other cgroups at creation is the current
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value of their parents notify_on_release setting. The default value of
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a cgroup hierarchy's release_agent path is empty.
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1.5 How do I use cgroups ?
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--------------------------
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To start a new job that is to be contained within a cgroup, using
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the "cpuset" cgroup subsystem, the steps are something like:
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1) mkdir /dev/cgroup
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2) mount -t cgroup -ocpuset cpuset /dev/cgroup
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3) Create the new cgroup by doing mkdir's and write's (or echo's) in
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the /dev/cgroup virtual file system.
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4) Start a task that will be the "founding father" of the new job.
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5) Attach that task to the new cgroup by writing its pid to the
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/dev/cgroup tasks file for that cgroup.
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6) fork, exec or clone the job tasks from this founding father task.
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For example, the following sequence of commands will setup a cgroup
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named "Charlie", containing just CPUs 2 and 3, and Memory Node 1,
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and then start a subshell 'sh' in that cgroup:
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mount -t cgroup cpuset -ocpuset /dev/cgroup
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cd /dev/cgroup
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mkdir Charlie
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cd Charlie
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/bin/echo 2-3 > cpus
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/bin/echo 1 > mems
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/bin/echo $$ > tasks
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sh
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# The subshell 'sh' is now running in cgroup Charlie
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# The next line should display '/Charlie'
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cat /proc/self/cgroup
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2. Usage Examples and Syntax
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============================
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2.1 Basic Usage
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---------------
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Creating, modifying, using the cgroups can be done through the cgroup
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virtual filesystem.
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To mount a cgroup hierarchy will all available subsystems, type:
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# mount -t cgroup xxx /dev/cgroup
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The "xxx" is not interpreted by the cgroup code, but will appear in
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/proc/mounts so may be any useful identifying string that you like.
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To mount a cgroup hierarchy with just the cpuset and numtasks
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subsystems, type:
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# mount -t cgroup -o cpuset,numtasks hier1 /dev/cgroup
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To change the set of subsystems bound to a mounted hierarchy, just
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remount with different options:
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# mount -o remount,cpuset,ns /dev/cgroup
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Note that changing the set of subsystems is currently only supported
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when the hierarchy consists of a single (root) cgroup. Supporting
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the ability to arbitrarily bind/unbind subsystems from an existing
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cgroup hierarchy is intended to be implemented in the future.
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Then under /dev/cgroup you can find a tree that corresponds to the
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tree of the cgroups in the system. For instance, /dev/cgroup
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is the cgroup that holds the whole system.
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If you want to create a new cgroup under /dev/cgroup:
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# cd /dev/cgroup
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# mkdir my_cgroup
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Now you want to do something with this cgroup.
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# cd my_cgroup
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In this directory you can find several files:
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# ls
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notify_on_release release_agent tasks
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(plus whatever files are added by the attached subsystems)
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Now attach your shell to this cgroup:
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# /bin/echo $$ > tasks
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You can also create cgroups inside your cgroup by using mkdir in this
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directory.
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# mkdir my_sub_cs
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To remove a cgroup, just use rmdir:
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# rmdir my_sub_cs
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This will fail if the cgroup is in use (has cgroups inside, or
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has processes attached, or is held alive by other subsystem-specific
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reference).
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2.2 Attaching processes
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-----------------------
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# /bin/echo PID > tasks
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Note that it is PID, not PIDs. You can only attach ONE task at a time.
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If you have several tasks to attach, you have to do it one after another:
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# /bin/echo PID1 > tasks
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# /bin/echo PID2 > tasks
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...
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# /bin/echo PIDn > tasks
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3. Kernel API
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=============
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3.1 Overview
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------------
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Each kernel subsystem that wants to hook into the generic cgroup
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system needs to create a cgroup_subsys object. This contains
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various methods, which are callbacks from the cgroup system, along
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with a subsystem id which will be assigned by the cgroup system.
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Other fields in the cgroup_subsys object include:
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- subsys_id: a unique array index for the subsystem, indicating which
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entry in cgroup->subsys[] this subsystem should be
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managing. Initialized by cgroup_register_subsys(); prior to this
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it should be initialized to -1
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- hierarchy: an index indicating which hierarchy, if any, this
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subsystem is currently attached to. If this is -1, then the
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subsystem is not attached to any hierarchy, and all tasks should be
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considered to be members of the subsystem's top_cgroup. It should
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be initialized to -1.
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- name: should be initialized to a unique subsystem name prior to
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calling cgroup_register_subsystem. Should be no longer than
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MAX_CGROUP_TYPE_NAMELEN
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Each cgroup object created by the system has an array of pointers,
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indexed by subsystem id; this pointer is entirely managed by the
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subsystem; the generic cgroup code will never touch this pointer.
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3.2 Synchronization
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-------------------
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There is a global mutex, cgroup_mutex, used by the cgroup
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system. This should be taken by anything that wants to modify a
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cgroup. It may also be taken to prevent cgroups from being
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modified, but more specific locks may be more appropriate in that
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situation.
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See kernel/cgroup.c for more details.
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Subsystems can take/release the cgroup_mutex via the functions
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cgroup_lock()/cgroup_unlock(), and can
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take/release the callback_mutex via the functions
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cgroup_lock()/cgroup_unlock().
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Accessing a task's cgroup pointer may be done in the following ways:
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- while holding cgroup_mutex
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- while holding the task's alloc_lock (via task_lock())
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- inside an rcu_read_lock() section via rcu_dereference()
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3.3 Subsystem API
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--------------------------
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Each subsystem should:
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- add an entry in linux/cgroup_subsys.h
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- define a cgroup_subsys object called <name>_subsys
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Each subsystem may export the following methods. The only mandatory
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methods are create/destroy. Any others that are null are presumed to
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be successful no-ops.
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struct cgroup_subsys_state *create(struct cgroup *cont)
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(cgroup_mutex held by caller)
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Called to create a subsystem state object for a cgroup. The
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subsystem should allocate its subsystem state object for the passed
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cgroup, returning a pointer to the new object on success or a
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negative error code. On success, the subsystem pointer should point to
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a structure of type cgroup_subsys_state (typically embedded in a
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larger subsystem-specific object), which will be initialized by the
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cgroup system. Note that this will be called at initialization to
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create the root subsystem state for this subsystem; this case can be
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identified by the passed cgroup object having a NULL parent (since
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it's the root of the hierarchy) and may be an appropriate place for
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initialization code.
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void destroy(struct cgroup *cont)
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(cgroup_mutex held by caller)
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The cgroup system is about to destroy the passed cgroup; the subsystem
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should do any necessary cleanup and free its subsystem state
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object. By the time this method is called, the cgroup has already been
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unlinked from the file system and from the child list of its parent;
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cgroup->parent is still valid. (Note - can also be called for a
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newly-created cgroup if an error occurs after this subsystem's
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create() method has been called for the new cgroup).
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int can_attach(struct cgroup_subsys *ss, struct cgroup *cont,
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struct task_struct *task)
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(cgroup_mutex held by caller)
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Called prior to moving a task into a cgroup; if the subsystem
|
|
returns an error, this will abort the attach operation. If a NULL
|
|
task is passed, then a successful result indicates that *any*
|
|
unspecified task can be moved into the cgroup. Note that this isn't
|
|
called on a fork. If this method returns 0 (success) then this should
|
|
remain valid while the caller holds cgroup_mutex.
|
|
|
|
void attach(struct cgroup_subsys *ss, struct cgroup *cont,
|
|
struct cgroup *old_cont, struct task_struct *task)
|
|
|
|
Called after the task has been attached to the cgroup, to allow any
|
|
post-attachment activity that requires memory allocations or blocking.
|
|
|
|
void fork(struct cgroup_subsy *ss, struct task_struct *task)
|
|
|
|
Called when a task is forked into a cgroup. Also called during
|
|
registration for all existing tasks.
|
|
|
|
void exit(struct cgroup_subsys *ss, struct task_struct *task)
|
|
|
|
Called during task exit
|
|
|
|
int populate(struct cgroup_subsys *ss, struct cgroup *cont)
|
|
|
|
Called after creation of a cgroup to allow a subsystem to populate
|
|
the cgroup directory with file entries. The subsystem should make
|
|
calls to cgroup_add_file() with objects of type cftype (see
|
|
include/linux/cgroup.h for details). Note that although this
|
|
method can return an error code, the error code is currently not
|
|
always handled well.
|
|
|
|
void post_clone(struct cgroup_subsys *ss, struct cgroup *cont)
|
|
|
|
Called at the end of cgroup_clone() to do any paramater
|
|
initialization which might be required before a task could attach. For
|
|
example in cpusets, no task may attach before 'cpus' and 'mems' are set
|
|
up.
|
|
|
|
void bind(struct cgroup_subsys *ss, struct cgroup *root)
|
|
(cgroup_mutex held by caller)
|
|
|
|
Called when a cgroup subsystem is rebound to a different hierarchy
|
|
and root cgroup. Currently this will only involve movement between
|
|
the default hierarchy (which never has sub-cgroups) and a hierarchy
|
|
that is being created/destroyed (and hence has no sub-cgroups).
|
|
|
|
4. Questions
|
|
============
|
|
|
|
Q: what's up with this '/bin/echo' ?
|
|
A: bash's builtin 'echo' command does not check calls to write() against
|
|
errors. If you use it in the cgroup file system, you won't be
|
|
able to tell whether a command succeeded or failed.
|
|
|
|
Q: When I attach processes, only the first of the line gets really attached !
|
|
A: We can only return one error code per call to write(). So you should also
|
|
put only ONE pid.
|
|
|