cri-o/vendor/github.com/opencontainers/runtime-spec/config-linux.md
Mrunal Patel 8e5b17cf13 Switch to github.com/golang/dep for vendoring
Signed-off-by: Mrunal Patel <mrunalp@gmail.com>
2017-01-31 16:45:59 -08:00

20 KiB

Linux-specific Container Configuration

This document describes the schema for the Linux-specific section of the container configuration. The Linux container specification uses various kernel features like namespaces, cgroups, capabilities, LSM, and file system jails to fulfill the spec.

Default File Systems

The Linux ABI includes both syscalls and several special file paths. Applications expecting a Linux environment will very likely expect these files paths to be setup correctly.

The following filesystems MUST be made available in each application's filesystem

Path Type
/proc procfs
/sys sysfs
/dev/pts devpts
/dev/shm tmpfs

Namespaces

A namespace wraps a global system resource in an abstraction that makes it appear to the processes within the namespace that they have their own isolated instance of the global resource. Changes to the global resource are visible to other processes that are members of the namespace, but are invisible to other processes. For more information, see the man page.

Namespaces are specified as an array of entries inside the namespaces root field. The following parameters can be specified to setup namespaces:

  • type (string, required) - namespace type. The following namespaces types are supported:

    • pid processes inside the container will only be able to see other processes inside the same container.
    • network the container will have its own network stack.
    • mount the container will have an isolated mount table.
    • ipc processes inside the container will only be able to communicate to other processes inside the same container via system level IPC.
    • uts the container will be able to have its own hostname and domain name.
    • user the container will be able to remap user and group IDs from the host to local users and groups within the container.
    • cgroup the container will have an isolated view of the cgroup hierarchy.
  • path (string, optional) - path to namespace file in the runtime mount namespace

If a path is specified, that particular file is used to join that type of namespace. Also, when a path is specified, a runtime MUST assume that the setup for that particular namespace has already been done and error out if the config specifies anything else related to that namespace.

Example
    "namespaces": [
        {
            "type": "pid",
            "path": "/proc/1234/ns/pid"
        },
        {
            "type": "network",
            "path": "/var/run/netns/neta"
        },
        {
            "type": "mount"
        },
        {
            "type": "ipc"
        },
        {
            "type": "uts"
        },
        {
            "type": "user"
        },
        {
            "type": "cgroup"
        }
    ]

User namespace mappings

Example
    "uidMappings": [
        {
            "hostID": 1000,
            "containerID": 0,
            "size": 10
        }
    ],
    "gidMappings": [
        {
            "hostID": 1000,
            "containerID": 0,
            "size": 10
        }
    ]

uid/gid mappings describe the user namespace mappings from the host to the container. The runtime SHOULD NOT modify the ownership of referenced filesystems to realize the mapping. hostID is the starting uid/gid on the host to be mapped to containerID which is the starting uid/gid in the container and size refers to the number of ids to be mapped. There is a limit of 5 mappings which is the Linux kernel hard limit.

Devices

devices is an array specifying the list of devices that MUST be available in the container. The runtime may supply them however it likes (with mknod, by bind mounting from the runtime mount namespace, etc.).

The following parameters can be specified:

  • type (string, required) - type of device: c, b, u or p. More info in mknod(1).
  • path (string, required) - full path to device inside container.
  • major, minor (int64, required unless type is p) - major, minor numbers for the device.
  • fileMode (uint32, optional) - file mode for the device. You can also control access to devices with cgroups.
  • uid (uint32, optional) - id of device owner.
  • gid (uint32, optional) - id of device group.
Example
   "devices": [
        {
            "path": "/dev/fuse",
            "type": "c",
            "major": 10,
            "minor": 229,
            "fileMode": 438,
            "uid": 0,
            "gid": 0
        },
        {
            "path": "/dev/sda",
            "type": "b",
            "major": 8,
            "minor": 0,
            "fileMode": 432,
            "uid": 0,
            "gid": 0
        }
    ]
Default Devices

In addition to any devices configured with this setting, the runtime MUST also supply:

Control groups

Also known as cgroups, they are used to restrict resource usage for a container and handle device access. cgroups provide controls to restrict cpu, memory, IO, pids and network for the container. For more information, see the kernel cgroups documentation.

The path to the cgroups can be specified in the Spec via cgroupsPath. cgroupsPath is expected to be relative to the cgroups mount point. If cgroupsPath is not specified, implementations can define the default cgroup path. Implementations of the Spec can choose to name cgroups in any manner. The Spec does not include naming schema for cgroups. The Spec does not support split hierarchy. The cgroups will be created if they don't exist.

Example
   "cgroupsPath": "/myRuntime/myContainer"

cgroupsPath can be used to either control the cgroups hierarchy for containers or to run a new process in an existing container.

You can configure a container's cgroups via the resources field of the Linux configuration. Do not specify resources unless limits have to be updated. For example, to run a new process in an existing container without updating limits, resources need not be specified.

Device whitelist

devices is an array of entries to control the device whitelist. The runtime MUST apply entries in the listed order.

The following parameters can be specified:

  • allow (boolean, required) - whether the entry is allowed or denied.
  • type (string, optional) - type of device: a (all), c (char), or b (block). null or unset values mean "all", mapping to a.
  • major, minor (int64, optional) - major, minor numbers for the device. null or unset values mean "all", mapping to * in the filesystem API.
  • access (string, optional) - cgroup permissions for device. A composition of r (read), w (write), and m (mknod).
Example
   "devices": [
        {
            "allow": false,
            "access": "rwm"
        },
        {
            "allow": true,
            "type": "c",
            "major": 10,
            "minor": 229,
            "access": "rw"
        },
        {
            "allow": true,
            "type": "b",
            "major": 8,
            "minor": 0,
            "access": "r"
        }
    ]

Disable out-of-memory killer

disableOOMKiller contains a boolean (true or false) that enables or disables the Out of Memory killer for a cgroup. If enabled (false), tasks that attempt to consume more memory than they are allowed are immediately killed by the OOM killer. The OOM killer is enabled by default in every cgroup using the memory subsystem. To disable it, specify a value of true. For more information, see the memory cgroup man page.

  • disableOOMKiller (bool, optional) - enables or disables the OOM killer
Example
    "disableOOMKiller": false

Set oom_score_adj

oomScoreAdj sets heuristic regarding how the process is evaluated by the kernel during memory pressure. For more information, see the proc filesystem documentation section 3.1. This is a kernel/system level setting, where as disableOOMKiller is scoped for a memory cgroup. For more information on how these two settings work together, see the memory cgroup documentation section 10. OOM Contol.

  • oomScoreAdj (int, optional) - adjust the oom-killer score
Example
    "oomScoreAdj": 100

Memory

memory represents the cgroup subsystem memory and it's used to set limits on the container's memory usage. For more information, see the memory cgroup man page.

The following parameters can be specified to setup the controller:

  • limit (uint64, optional) - sets limit of memory usage in bytes

  • reservation (uint64, optional) - sets soft limit of memory usage in bytes

  • swap (uint64, optional) - sets limit of memory+Swap usage

  • kernel (uint64, optional) - sets hard limit for kernel memory

  • kernelTCP (uint64, optional) - sets hard limit in bytes for kernel TCP buffer memory

  • swappiness (uint64, optional) - sets swappiness parameter of vmscan (See sysctl's vm.swappiness)

Example
    "memory": {
        "limit": 536870912,
        "reservation": 536870912,
        "swap": 536870912,
        "kernel": 0,
        "kernelTCP": 0,
        "swappiness": 0
    }

CPU

cpu represents the cgroup subsystems cpu and cpusets. For more information, see the cpusets cgroup man page.

The following parameters can be specified to setup the controller:

  • shares (uint64, optional) - specifies a relative share of CPU time available to the tasks in a cgroup

  • quota (uint64, optional) - specifies the total amount of time in microseconds for which all tasks in a cgroup can run during one period (as defined by period below)

  • period (uint64, optional) - specifies a period of time in microseconds for how regularly a cgroup's access to CPU resources should be reallocated (CFS scheduler only)

  • realtimeRuntime (uint64, optional) - specifies a period of time in microseconds for the longest continuous period in which the tasks in a cgroup have access to CPU resources

  • realtimePeriod (uint64, optional) - same as period but applies to realtime scheduler only

  • cpus (string, optional) - list of CPUs the container will run in

  • mems (string, optional) - list of Memory Nodes the container will run in

Example
    "cpu": {
        "shares": 1024,
        "quota": 1000000,
        "period": 500000,
        "realtimeRuntime": 950000,
        "realtimePeriod": 1000000,
        "cpus": "2-3",
        "mems": "0-7"
    }

Block IO Controller

blockIO represents the cgroup subsystem blkio which implements the block io controller. For more information, see the kernel cgroups documentation about blkio.

The following parameters can be specified to setup the controller:

  • blkioWeight (uint16, optional) - specifies per-cgroup weight. This is default weight of the group on all devices until and unless overridden by per-device rules. The range is from 10 to 1000.

  • blkioLeafWeight (uint16, optional) - equivalents of blkioWeight for the purpose of deciding how much weight tasks in the given cgroup has while competing with the cgroup's child cgroups. The range is from 10 to 1000.

  • blkioWeightDevice (array, optional) - specifies the list of devices which will be bandwidth rate limited. The following parameters can be specified per-device:

    • major, minor (int64, required) - major, minor numbers for device. More info in man mknod.
    • weight (uint16, optional) - bandwidth rate for the device, range is from 10 to 1000
    • leafWeight (uint16, optional) - bandwidth rate for the device while competing with the cgroup's child cgroups, range is from 10 to 1000, CFQ scheduler only

    You must specify at least one of weight or leafWeight in a given entry, and can specify both.

  • blkioThrottleReadBpsDevice, blkioThrottleWriteBpsDevice, blkioThrottleReadIOPSDevice, blkioThrottleWriteIOPSDevice (array, optional) - specify the list of devices which will be IO rate limited. The following parameters can be specified per-device:

    • major, minor (int64, required) - major, minor numbers for device. More info in man mknod.
    • rate (uint64, required) - IO rate limit for the device
Example
    "blockIO": {
        "blkioWeight": 10,
        "blkioLeafWeight": 10,
        "blkioWeightDevice": [
            {
                "major": 8,
                "minor": 0,
                "weight": 500,
                "leafWeight": 300
            },
            {
                "major": 8,
                "minor": 16,
                "weight": 500
            }
        ],
        "blkioThrottleReadBpsDevice": [
            {
                "major": 8,
                "minor": 0,
                "rate": 600
            }
        ],
        "blkioThrottleWriteIOPSDevice": [
            {
                "major": 8,
                "minor": 16,
                "rate": 300
            }
        ]
    }

Huge page limits

hugepageLimits represents the hugetlb controller which allows to limit the HugeTLB usage per control group and enforces the controller limit during page fault. For more information, see the kernel cgroups documentation about HugeTLB.

hugepageLimits is an array of entries, each having the following structure:

  • pageSize (string, required) - hugepage size

  • limit (uint64, required) - limit in bytes of hugepagesize HugeTLB usage

Example
   "hugepageLimits": [
        {
            "pageSize": "2MB",
            "limit": 9223372036854771712
        }
   ]

Network

network represents the cgroup subsystems net_cls and net_prio. For more information, see the net_cls cgroup man page and the net_prio cgroup man page.

The following parameters can be specified to setup these cgroup controllers:

  • classID (uint32, optional) - is the network class identifier the cgroup's network packets will be tagged with

  • priorities (array, optional) - specifies a list of objects of the priorities assigned to traffic originating from processes in the group and egressing the system on various interfaces. The following parameters can be specified per-priority:

    • name (string, required) - interface name
    • priority (uint32, required) - priority applied to the interface
Example
   "network": {
        "classID": 1048577,
        "priorities": [
            {
                "name": "eth0",
                "priority": 500
            },
            {
                "name": "eth1",
                "priority": 1000
            }
        ]
   }

PIDs

pids represents the cgroup subsystem pids. For more information, see the pids cgroup man page.

The following parameters can be specified to setup the controller:

  • limit (int64, required) - specifies the maximum number of tasks in the cgroup
Example
   "pids": {
        "limit": 32771
   }

Sysctl

sysctl allows kernel parameters to be modified at runtime for the container. For more information, see the man page

Example
   "sysctl": {
        "net.ipv4.ip_forward": "1",
        "net.core.somaxconn": "256"
   }

seccomp

Seccomp provides application sandboxing mechanism in the Linux kernel. Seccomp configuration allows one to configure actions to take for matched syscalls and furthermore also allows matching on values passed as arguments to syscalls. For more information about Seccomp, see Seccomp kernel documentation The actions, architectures, and operators are strings that match the definitions in seccomp.h from libseccomp and are translated to corresponding values. A valid list of constants as of libseccomp v2.3.0 is shown below.

Architecture Constants

  • SCMP_ARCH_X86
  • SCMP_ARCH_X86_64
  • SCMP_ARCH_X32
  • SCMP_ARCH_ARM
  • SCMP_ARCH_AARCH64
  • SCMP_ARCH_MIPS
  • SCMP_ARCH_MIPS64
  • SCMP_ARCH_MIPS64N32
  • SCMP_ARCH_MIPSEL
  • SCMP_ARCH_MIPSEL64
  • SCMP_ARCH_MIPSEL64N32
  • SCMP_ARCH_PPC
  • SCMP_ARCH_PPC64
  • SCMP_ARCH_PPC64LE
  • SCMP_ARCH_S390
  • SCMP_ARCH_S390X

Action Constants:

  • SCMP_ACT_KILL
  • SCMP_ACT_TRAP
  • SCMP_ACT_ERRNO
  • SCMP_ACT_TRACE
  • SCMP_ACT_ALLOW

Operator Constants:

  • SCMP_CMP_NE
  • SCMP_CMP_LT
  • SCMP_CMP_LE
  • SCMP_CMP_EQ
  • SCMP_CMP_GE
  • SCMP_CMP_GT
  • SCMP_CMP_MASKED_EQ
Example
   "seccomp": {
       "defaultAction": "SCMP_ACT_ALLOW",
       "architectures": [
           "SCMP_ARCH_X86"
       ],
       "syscalls": [
           {
               "name": "getcwd",
               "action": "SCMP_ACT_ERRNO"
           }
       ]
   }

Rootfs Mount Propagation

rootfsPropagation sets the rootfs's mount propagation. Its value is either slave, private, or shared. The kernel doc has more information about mount propagation.

Example
    "rootfsPropagation": "slave",

Masked Paths

maskedPaths will mask over the provided paths inside the container so that they cannot be read.

Example
    "maskedPaths": [
        "/proc/kcore"
    ]

Readonly Paths

readonlyPaths will set the provided paths as readonly inside the container.

Example
    "readonlyPaths": [
        "/proc/sys"
    ]

Mount Label

mountLabel will set the Selinux context for the mounts in the container.

Example
    "mountLabel": "system_u:object_r:svirt_sandbox_file_t:s0:c715,c811"