Libcontainer provides a native Go implementation for creating containers with namespaces, cgroups, capabilities, and filesystem access controls. It allows you to manage the lifecycle of the container performing additional operations after the container is created.
A container is a self contained execution environment that shares the kernel of the host system and which is (optionally) isolated from other containers in the system.
To create a container you first have to initialize an instance of a factory that will handle the creation and initialization for a container.
Because containers are spawned in a two step process you will need to provide
arguments to a binary that will be executed as the init process for the container.
To use the current binary that is spawning the containers and acting as the parent
you can use os.Args[0] and we have a command called init setup.
root, err := libcontainer.New("/var/lib/container", libcontainer.InitArgs(os.Args[0], "init"))
if err != nil {
log.Fatal(err)
}Once you have an instance of the factory created we can create a configuration struct describing how the container is to be created. A sample would look similar to this:
config := &configs.Config{
Rootfs: rootfs,
Capabilities: []string{
"CHOWN",
"DAC_OVERRIDE",
"FSETID",
"FOWNER",
"MKNOD",
"NET_RAW",
"SETGID",
"SETUID",
"SETFCAP",
"SETPCAP",
"NET_BIND_SERVICE",
"SYS_CHROOT",
"KILL",
"AUDIT_WRITE",
},
Namespaces: configs.Namespaces([]configs.Namespace{
{Type: configs.NEWNS},
{Type: configs.NEWUTS},
{Type: configs.NEWIPC},
{Type: configs.NEWPID},
{Type: configs.NEWNET},
}),
Cgroups: &configs.Cgroup{
Name: "test-container",
Parent: "system",
AllowAllDevices: false,
AllowedDevices: configs.DefaultAllowedDevices,
},
Devices: configs.DefaultAutoCreatedDevices,
Hostname: "testing",
Networks: []*configs.Network{
{
Type: "loopback",
Address: "127.0.0.1/0",
Gateway: "localhost",
},
},
Rlimits: []configs.Rlimit{
{
Type: syscall.RLIMIT_NOFILE,
Hard: uint64(1024),
Soft: uint64(1024),
},
},
}Once you have the configuration populated you can create a container:
container, err := root.Create("container-id", config)To spawn bash as the initial process inside the container and have the processes pid returned in order to wait, signal, or kill the process:
process := &libcontainer.Process{
Args: []string{"/bin/bash"},
Env: []string{"PATH=/bin"},
User: "daemon",
Stdin: os.Stdin,
Stdout: os.Stdout,
Stderr: os.Stderr,
}
err := container.Start(process)
if err != nil {
log.Fatal(err)
}
// wait for the process to finish.
status, err := process.Wait()
if err != nil {
log.Fatal(err)
}
// destroy the container.
container.Destroy()Additional ways to interact with a running container are:
// return all the pids for all processes running inside the container.
processes, err := container.Processes()
// get detailed cpu, memory, io, and network statistics for the container and
// it's processes.
stats, err := container.Stats()
// pause all processes inside the container.
container.Pause()
// resume all paused processes.
container.Resume()nsinit is a cli application which demonstrates the use of libcontainer.
It is able to spawn new containers or join existing containers. A root
filesystem must be provided for use along with a container configuration file.
To build nsinit, run make binary. It will save the binary into
bundles/nsinit.
To use nsinit, cd into a Linux rootfs and copy a container.json file into
the directory with your specified configuration. Environment, networking,
and different capabilities for the container are specified in this file.
The configuration is used for each process executed inside the container.
See the sample_configs folder for examples of what the container configuration should look like.
To execute /bin/bash in the current directory as a container just run the following as root:
nsinit exec --tty /bin/bashIf you wish to spawn another process inside the container while your current bash session is running, run the same command again to get another bash shell (or change the command). If the original process (PID 1) dies, all other processes spawned inside the container will be killed and the namespace will be removed.
You can identify if a process is running in a container by
looking to see if state.json is in the root of the directory.
You may also specify an alternate root place where
the container.json file is read and where the state.json file will be saved.
libcontainer now integrates CRIU for checkpointing and restoring containers. This let's you save the state of a process running inside a container to disk, and then restore that state into a new process, on the same machine or on another machine.
criu version 1.5.2 or higher is required to use checkpoint and restore.
If you don't already have criu installed, you can build it from source, following the
online instructions. criu is also installed in the docker image
generated when building libcontainer with docker.
To try an example with nsinit, open two terminals to the same busybox directory.
In the first terminal, run a command like this one:
nsinit exec -- sh -c 'i=0; while true; do echo $i; i=$(expr $i + 1); sleep 1; done'You should see logs printing to the terminal every second. Now, in the second terminal, run:
nsinit checkpoint --image-path=/tmp/criuThe logs in your first terminal will stop and the process will exit. Finally, in the second terminal, run the restore command:
nsinit restore --image-path=/tmp/criuThe process will resume counting where it left off and printing to the new terminal window.
See the roadmap.
Code and documentation copyright 2014 Docker, inc. Code released under the Apache 2.0 license. Docs released under Creative commons.
First of all, please familiarise yourself with the libcontainer Principles.
If you're a contributor or aspiring contributor, you should read the Contributors' Guide.
If you're a maintainer or aspiring maintainer, you should read the Maintainers' Guide and "How can I become a maintainer?" in the Contributors' Guide.