mirror of
https://github.com/moby/moby.git
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6a4ac63aaa
Signed-off-by: Zhang Wei <zhangwei555@huawei.com>
463 lines
20 KiB
Markdown
463 lines
20 KiB
Markdown
<!--[metadata]>
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+++
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title = "Runtime metrics"
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description = "Measure the behavior of running containers"
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keywords = ["docker, metrics, CPU, memory, disk, IO, run, runtime, stats"]
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[menu.main]
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parent = "smn_administrate"
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weight = 4
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+++
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<![end-metadata]-->
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# Runtime metrics
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## Docker stats
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You can use the `docker stats` command to live stream a container's
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runtime metrics. The command supports CPU, memory usage, memory limit,
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and network IO metrics.
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The following is a sample output from the `docker stats` command
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$ docker stats redis1 redis2
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CONTAINER CPU % MEM USAGE / LIMIT MEM % NET I/O BLOCK I/O
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redis1 0.07% 796 KB / 64 MB 1.21% 788 B / 648 B 3.568 MB / 512 KB
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redis2 0.07% 2.746 MB / 64 MB 4.29% 1.266 KB / 648 B 12.4 MB / 0 B
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The [docker stats](/reference/commandline/stats/) reference page has
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more details about the `docker stats` command.
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## Control groups
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Linux Containers rely on [control groups](
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https://www.kernel.org/doc/Documentation/cgroups/cgroups.txt)
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which not only track groups of processes, but also expose metrics about
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CPU, memory, and block I/O usage. You can access those metrics and
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obtain network usage metrics as well. This is relevant for "pure" LXC
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containers, as well as for Docker containers.
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Control groups are exposed through a pseudo-filesystem. In recent
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distros, you should find this filesystem under `/sys/fs/cgroup`. Under
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that directory, you will see multiple sub-directories, called devices,
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freezer, blkio, etc.; each sub-directory actually corresponds to a different
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cgroup hierarchy.
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On older systems, the control groups might be mounted on `/cgroup`, without
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distinct hierarchies. In that case, instead of seeing the sub-directories,
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you will see a bunch of files in that directory, and possibly some directories
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corresponding to existing containers.
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To figure out where your control groups are mounted, you can run:
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$ grep cgroup /proc/mounts
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## Enumerating cgroups
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You can look into `/proc/cgroups` to see the different control group subsystems
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known to the system, the hierarchy they belong to, and how many groups they contain.
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You can also look at `/proc/<pid>/cgroup` to see which control groups a process
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belongs to. The control group will be shown as a path relative to the root of
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the hierarchy mountpoint; e.g., `/` means “this process has not been assigned into
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a particular group”, while `/lxc/pumpkin` means that the process is likely to be
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a member of a container named `pumpkin`.
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## Finding the cgroup for a given container
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For each container, one cgroup will be created in each hierarchy. On
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older systems with older versions of the LXC userland tools, the name of
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the cgroup will be the name of the container. With more recent versions
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of the LXC tools, the cgroup will be `lxc/<container_name>.`
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For Docker containers using cgroups, the container name will be the full
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ID or long ID of the container. If a container shows up as ae836c95b4c3
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in `docker ps`, its long ID might be something like
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`ae836c95b4c3c9e9179e0e91015512da89fdec91612f63cebae57df9a5444c79`. You can
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look it up with `docker inspect` or `docker ps --no-trunc`.
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Putting everything together to look at the memory metrics for a Docker
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container, take a look at `/sys/fs/cgroup/memory/lxc/<longid>/`.
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## Metrics from cgroups: memory, CPU, block I/O
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For each subsystem (memory, CPU, and block I/O), you will find one or
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more pseudo-files containing statistics.
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### Memory metrics: `memory.stat`
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Memory metrics are found in the "memory" cgroup. Note that the memory
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control group adds a little overhead, because it does very fine-grained
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accounting of the memory usage on your host. Therefore, many distros
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chose to not enable it by default. Generally, to enable it, all you have
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to do is to add some kernel command-line parameters:
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`cgroup_enable=memory swapaccount=1`.
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The metrics are in the pseudo-file `memory.stat`.
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Here is what it will look like:
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cache 11492564992
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rss 1930993664
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mapped_file 306728960
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pgpgin 406632648
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pgpgout 403355412
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swap 0
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pgfault 728281223
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pgmajfault 1724
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inactive_anon 46608384
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active_anon 1884520448
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inactive_file 7003344896
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active_file 4489052160
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unevictable 32768
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hierarchical_memory_limit 9223372036854775807
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hierarchical_memsw_limit 9223372036854775807
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total_cache 11492564992
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total_rss 1930993664
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total_mapped_file 306728960
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total_pgpgin 406632648
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total_pgpgout 403355412
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total_swap 0
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total_pgfault 728281223
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total_pgmajfault 1724
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total_inactive_anon 46608384
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total_active_anon 1884520448
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total_inactive_file 7003344896
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total_active_file 4489052160
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total_unevictable 32768
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The first half (without the `total_` prefix) contains statistics relevant
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to the processes within the cgroup, excluding sub-cgroups. The second half
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(with the `total_` prefix) includes sub-cgroups as well.
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Some metrics are "gauges", i.e., values that can increase or decrease
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(e.g., swap, the amount of swap space used by the members of the cgroup).
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Some others are "counters", i.e., values that can only go up, because
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they represent occurrences of a specific event (e.g., pgfault, which
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indicates the number of page faults which happened since the creation of
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the cgroup; this number can never decrease).
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- **cache:**
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the amount of memory used by the processes of this control group
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that can be associated precisely with a block on a block device.
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When you read from and write to files on disk, this amount will
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increase. This will be the case if you use "conventional" I/O
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(`open`, `read`,
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`write` syscalls) as well as mapped files (with
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`mmap`). It also accounts for the memory used by
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`tmpfs` mounts, though the reasons are unclear.
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- **rss:**
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the amount of memory that *doesn't* correspond to anything on disk:
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stacks, heaps, and anonymous memory maps.
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- **mapped_file:**
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indicates the amount of memory mapped by the processes in the
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control group. It doesn't give you information about *how much*
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memory is used; it rather tells you *how* it is used.
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- **pgfault and pgmajfault:**
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indicate the number of times that a process of the cgroup triggered
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a "page fault" and a "major fault", respectively. A page fault
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happens when a process accesses a part of its virtual memory space
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which is nonexistent or protected. The former can happen if the
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process is buggy and tries to access an invalid address (it will
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then be sent a `SIGSEGV` signal, typically
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killing it with the famous `Segmentation fault`
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message). The latter can happen when the process reads from a memory
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zone which has been swapped out, or which corresponds to a mapped
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file: in that case, the kernel will load the page from disk, and let
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the CPU complete the memory access. It can also happen when the
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process writes to a copy-on-write memory zone: likewise, the kernel
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will preempt the process, duplicate the memory page, and resume the
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write operation on the process` own copy of the page. "Major" faults
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happen when the kernel actually has to read the data from disk. When
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it just has to duplicate an existing page, or allocate an empty
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page, it's a regular (or "minor") fault.
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- **swap:**
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the amount of swap currently used by the processes in this cgroup.
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- **active_anon and inactive_anon:**
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the amount of *anonymous* memory that has been identified has
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respectively *active* and *inactive* by the kernel. "Anonymous"
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memory is the memory that is *not* linked to disk pages. In other
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words, that's the equivalent of the rss counter described above. In
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fact, the very definition of the rss counter is **active_anon** +
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**inactive_anon** - **tmpfs** (where tmpfs is the amount of memory
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used up by `tmpfs` filesystems mounted by this
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control group). Now, what's the difference between "active" and
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"inactive"? Pages are initially "active"; and at regular intervals,
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the kernel sweeps over the memory, and tags some pages as
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"inactive". Whenever they are accessed again, they are immediately
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retagged "active". When the kernel is almost out of memory, and time
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comes to swap out to disk, the kernel will swap "inactive" pages.
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- **active_file and inactive_file:**
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cache memory, with *active* and *inactive* similar to the *anon*
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memory above. The exact formula is cache = **active_file** +
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**inactive_file** + **tmpfs**. The exact rules used by the kernel
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to move memory pages between active and inactive sets are different
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from the ones used for anonymous memory, but the general principle
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is the same. Note that when the kernel needs to reclaim memory, it
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is cheaper to reclaim a clean (=non modified) page from this pool,
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since it can be reclaimed immediately (while anonymous pages and
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dirty/modified pages have to be written to disk first).
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- **unevictable:**
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the amount of memory that cannot be reclaimed; generally, it will
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account for memory that has been "locked" with `mlock`.
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It is often used by crypto frameworks to make sure that
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secret keys and other sensitive material never gets swapped out to
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disk.
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- **memory and memsw limits:**
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These are not really metrics, but a reminder of the limits applied
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to this cgroup. The first one indicates the maximum amount of
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physical memory that can be used by the processes of this control
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group; the second one indicates the maximum amount of RAM+swap.
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Accounting for memory in the page cache is very complex. If two
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processes in different control groups both read the same file
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(ultimately relying on the same blocks on disk), the corresponding
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memory charge will be split between the control groups. It's nice, but
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it also means that when a cgroup is terminated, it could increase the
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memory usage of another cgroup, because they are not splitting the cost
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anymore for those memory pages.
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### CPU metrics: `cpuacct.stat`
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Now that we've covered memory metrics, everything else will look very
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simple in comparison. CPU metrics will be found in the
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`cpuacct` controller.
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For each container, you will find a pseudo-file `cpuacct.stat`,
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containing the CPU usage accumulated by the processes of the container,
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broken down between `user` and `system` time. If you're not familiar
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with the distinction, `user` is the time during which the processes were
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in direct control of the CPU (i.e., executing process code), and `system`
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is the time during which the CPU was executing system calls on behalf of
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those processes.
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Those times are expressed in ticks of 1/100th of a second. Actually,
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they are expressed in "user jiffies". There are `USER_HZ`
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*"jiffies"* per second, and on x86 systems,
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`USER_HZ` is 100. This used to map exactly to the
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number of scheduler "ticks" per second; but with the advent of higher
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frequency scheduling, as well as [tickless kernels](
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http://lwn.net/Articles/549580/), the number of kernel ticks
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wasn't relevant anymore. It stuck around anyway, mainly for legacy and
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compatibility reasons.
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### Block I/O metrics
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Block I/O is accounted in the `blkio` controller.
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Different metrics are scattered across different files. While you can
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find in-depth details in the [blkio-controller](
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https://www.kernel.org/doc/Documentation/cgroups/blkio-controller.txt)
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file in the kernel documentation, here is a short list of the most
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relevant ones:
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- **blkio.sectors:**
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contain the number of 512-bytes sectors read and written by the
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processes member of the cgroup, device by device. Reads and writes
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are merged in a single counter.
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- **blkio.io_service_bytes:**
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indicates the number of bytes read and written by the cgroup. It has
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4 counters per device, because for each device, it differentiates
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between synchronous vs. asynchronous I/O, and reads vs. writes.
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- **blkio.io_serviced:**
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the number of I/O operations performed, regardless of their size. It
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also has 4 counters per device.
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- **blkio.io_queued:**
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indicates the number of I/O operations currently queued for this
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cgroup. In other words, if the cgroup isn't doing any I/O, this will
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be zero. Note that the opposite is not true. In other words, if
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there is no I/O queued, it does not mean that the cgroup is idle
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(I/O-wise). It could be doing purely synchronous reads on an
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otherwise quiescent device, which is therefore able to handle them
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immediately, without queuing. Also, while it is helpful to figure
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out which cgroup is putting stress on the I/O subsystem, keep in
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mind that is is a relative quantity. Even if a process group does
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not perform more I/O, its queue size can increase just because the
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device load increases because of other devices.
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## Network metrics
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Network metrics are not exposed directly by control groups. There is a
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good explanation for that: network interfaces exist within the context
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of *network namespaces*. The kernel could probably accumulate metrics
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about packets and bytes sent and received by a group of processes, but
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those metrics wouldn't be very useful. You want per-interface metrics
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(because traffic happening on the local `lo`
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interface doesn't really count). But since processes in a single cgroup
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can belong to multiple network namespaces, those metrics would be harder
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to interpret: multiple network namespaces means multiple `lo`
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interfaces, potentially multiple `eth0`
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interfaces, etc.; so this is why there is no easy way to gather network
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metrics with control groups.
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Instead we can gather network metrics from other sources:
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### IPtables
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IPtables (or rather, the netfilter framework for which iptables is just
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an interface) can do some serious accounting.
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For instance, you can setup a rule to account for the outbound HTTP
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traffic on a web server:
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$ iptables -I OUTPUT -p tcp --sport 80
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There is no `-j` or `-g` flag,
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so the rule will just count matched packets and go to the following
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rule.
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Later, you can check the values of the counters, with:
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$ iptables -nxvL OUTPUT
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Technically, `-n` is not required, but it will
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prevent iptables from doing DNS reverse lookups, which are probably
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useless in this scenario.
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Counters include packets and bytes. If you want to setup metrics for
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container traffic like this, you could execute a `for`
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loop to add two `iptables` rules per
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container IP address (one in each direction), in the `FORWARD`
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chain. This will only meter traffic going through the NAT
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layer; you will also have to add traffic going through the userland
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proxy.
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Then, you will need to check those counters on a regular basis. If you
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happen to use `collectd`, there is a [nice plugin](https://collectd.org/wiki/index.php/Plugin:IPTables)
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to automate iptables counters collection.
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### Interface-level counters
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Since each container has a virtual Ethernet interface, you might want to
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check directly the TX and RX counters of this interface. You will notice
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that each container is associated to a virtual Ethernet interface in
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your host, with a name like `vethKk8Zqi`. Figuring
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out which interface corresponds to which container is, unfortunately,
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difficult.
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But for now, the best way is to check the metrics *from within the
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containers*. To accomplish this, you can run an executable from the host
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environment within the network namespace of a container using **ip-netns
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magic**.
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The `ip-netns exec` command will let you execute any
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program (present in the host system) within any network namespace
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visible to the current process. This means that your host will be able
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to enter the network namespace of your containers, but your containers
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won't be able to access the host, nor their sibling containers.
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Containers will be able to “see” and affect their sub-containers,
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though.
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The exact format of the command is:
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$ ip netns exec <nsname> <command...>
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For example:
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$ ip netns exec mycontainer netstat -i
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`ip netns` finds the "mycontainer" container by
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using namespaces pseudo-files. Each process belongs to one network
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namespace, one PID namespace, one `mnt` namespace,
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etc., and those namespaces are materialized under
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`/proc/<pid>/ns/`. For example, the network
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namespace of PID 42 is materialized by the pseudo-file
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`/proc/42/ns/net`.
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When you run `ip netns exec mycontainer ...`, it
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expects `/var/run/netns/mycontainer` to be one of
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those pseudo-files. (Symlinks are accepted.)
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In other words, to execute a command within the network namespace of a
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container, we need to:
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- Find out the PID of any process within the container that we want to investigate;
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- Create a symlink from `/var/run/netns/<somename>` to `/proc/<thepid>/ns/net`
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- Execute `ip netns exec <somename> ....`
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Please review [*Enumerating Cgroups*](#enumerating-cgroups) to learn how to find
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the cgroup of a process running in the container of which you want to
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measure network usage. From there, you can examine the pseudo-file named
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`tasks`, which contains the PIDs that are in the
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control group (i.e., in the container). Pick any one of them.
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Putting everything together, if the "short ID" of a container is held in
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the environment variable `$CID`, then you can do this:
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$ TASKS=/sys/fs/cgroup/devices/$CID*/tasks
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$ PID=$(head -n 1 $TASKS)
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$ mkdir -p /var/run/netns
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$ ln -sf /proc/$PID/ns/net /var/run/netns/$CID
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$ ip netns exec $CID netstat -i
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## Tips for high-performance metric collection
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Note that running a new process each time you want to update metrics is
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(relatively) expensive. If you want to collect metrics at high
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resolutions, and/or over a large number of containers (think 1000
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containers on a single host), you do not want to fork a new process each
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time.
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Here is how to collect metrics from a single process. You will have to
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write your metric collector in C (or any language that lets you do
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low-level system calls). You need to use a special system call,
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`setns()`, which lets the current process enter any
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arbitrary namespace. It requires, however, an open file descriptor to
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the namespace pseudo-file (remember: that's the pseudo-file in
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`/proc/<pid>/ns/net`).
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However, there is a catch: you must not keep this file descriptor open.
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If you do, when the last process of the control group exits, the
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namespace will not be destroyed, and its network resources (like the
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virtual interface of the container) will stay around for ever (or until
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you close that file descriptor).
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The right approach would be to keep track of the first PID of each
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container, and re-open the namespace pseudo-file each time.
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## Collecting metrics when a container exits
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Sometimes, you do not care about real time metric collection, but when a
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container exits, you want to know how much CPU, memory, etc. it has
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used.
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Docker makes this difficult because it relies on `lxc-start`, which
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carefully cleans up after itself, but it is still possible. It is
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usually easier to collect metrics at regular intervals (e.g., every
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minute, with the collectd LXC plugin) and rely on that instead.
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But, if you'd still like to gather the stats when a container stops,
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here is how:
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For each container, start a collection process, and move it to the
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control groups that you want to monitor by writing its PID to the tasks
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file of the cgroup. The collection process should periodically re-read
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the tasks file to check if it's the last process of the control group.
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(If you also want to collect network statistics as explained in the
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previous section, you should also move the process to the appropriate
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network namespace.)
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When the container exits, `lxc-start` will try to
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delete the control groups. It will fail, since the control group is
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still in use; but that's fine. You process should now detect that it is
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the only one remaining in the group. Now is the right time to collect
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all the metrics you need!
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Finally, your process should move itself back to the root control group,
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and remove the container control group. To remove a control group, just
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`rmdir` its directory. It's counter-intuitive to
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`rmdir` a directory as it still contains files; but
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remember that this is a pseudo-filesystem, so usual rules don't apply.
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After the cleanup is done, the collection process can exit safely.
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