udocker is a basic user tool to execute simple docker containers in user space without requiring root privileges. Enables download and execution of docker containers by non-privileged users in Linux systems where docker is not available. It can be used to pull and execute docker containers in Linux batch systems and interactive clusters that are managed by other entities such as grid infrastructures or externally managed batch or interactive systems.
udocker does not require any type of privileges nor the deployment of services by system administrators. It can be downloaded and executed entirely by the end user.
udocker is a wrapper around several tools to mimic a subset of the docker capabilities including pulling images and running containers with minimal functionality.
How does it work
udocker is a simple tool written in Python, it has a minimal set of dependencies so that can be executed in a wide range of Linux systems.
udocker does not make use of docker nor requires its presence.
udocker "executes" the containers by simply providing a chroot like environment over the extracted container. The current implementation supports different methods to mimic chroot enabling execution of containers without requiring privileges under a chroot like environment. udocker transparently supports several methods to execute the containers using tools and libraries such as:
- Provides a docker like command line interface
- Supports a subset of docker commands: search, pull, import, export, load, create and run
- Understands docker container metadata
- Can be deployed by the end-user
- Does not require privileges for installation
- Does not require privileges for execution
- Does not require compilation, just transfer the Python script and run
- Encapsulates several execution methods
- Includes the required tools already compiled to work across systems
- Tested with GPGPU and MPI applications
- Runs both on new and older Linux distributions including: CentOS 6, CentOS 7, Ubuntu 14, Ubuntu 16, Ubunto 18, Fedora, etc
See the Installation manual
Commands: search <repo/image:tag> :Search dockerhub for container images pull <repo/image:tag> :Pull container image from dockerhub images :List container images create <repo/image:tag> :Create container from a pulled image ps :List created containers rm <container> :Delete container run <container> :Execute container inspect <container> :Low level information on container name <container_id> <name> :Give name to container rmname <name> :Delete name from container rmi <repo/image:tag> :Delete image rm <container-id> :Delete container import <tar> <repo/image:tag> :Import tar file (exported by docker) import - <repo/image:tag> :Import from stdin (exported by docker) load -i <exported-image> :Load image from file (saved by docker) load :Load image from stdin (saved by docker) export -o <tar> <container> :Export container rootfs to file export - <container> :Export container rootfs to stdin inspect <repo/image:tag> :Return low level information on image verify <repo/image:tag> :Verify a pulled image clone <container> :duplicate container protect <repo/image:tag> :Protect repository unprotect <repo/image:tag> :Unprotect repository protect <container> :Protect container unprotect <container> :Unprotect container mkrepo <topdir> :Create repository in another location setup :Change container execution settings login :Login into docker repository logout :Logout from docker repository help :This help run --help :Command specific help Options common to all commands must appear before the command: -D :Debug --repo=<directory> :Use repository at directory
Some examples of usage:
Search container images in dockerhub.
udocker search fedora udocker search ubuntu udocker search indigodatacloud
Pull from dockerhub and list the pulled images.
udocker pull fedora:25 udocker pull busybox udocker pull iscampos/openqcd udocker images
Pull from a registry other than dockerhub.
udocker pull --registry=https://registry.access.redhat.com rhel7 udocker create --name=rh7 rhel7 udocker run rh7
Create the container from a pulled image and run it.
udocker create --name=myfed fedora:25 udocker run myfed cat /etc/redhat-release
Run mounting the host /home/u457 into the container directory /home/cuser. Notice that you can "mount" any host directory inside the container, this is not a real mount but the directories will be visible inside the container.
udocker run -v /home/u457:/home/cuser -w /home/user myfed /bin/bash udocker run -v /var -v /proc -v /sys -v /tmp myfed /bin/bash
Put a script in your host /tmp and execute it in the container.
udocker run -v /tmp myfed /bin/bash -c 'cd /tmp; ./myscript.sh'
Run mounting the host /var, /proc, /sys and /tmp in the same container directories. Notice that the content of these container directories will be obfuscated.
udocker run -v /var -v /proc -v /sys -v /tmp myfed /bin/bash
Install software inside the container.
udocker run --user=root myfed yum install -y firefox pulseaudio gnash-plugin
Run as some user. The usernames should exist in the container.
udocker run --user 1000:1001 myfed /bin/id udocker run --user root myfed /bin/id udocker run --user jorge myfed /bin/id
./udocker run --bindhome --hostauth --hostenv \ -v /sys -v /proc -v /var/run -v /dev --user=jorge --dri myfed firefox
Change execution engine mode from PRoot to Fakechroot and run.
./udocker setup --execmode=F4 myfed ./udocker run --bindhome --hostauth --hostenv \ -v /sys -v /proc -v /var/run -v /dev --user=jorge --dri myfed firefox
Change execution engine mode to accelerated PRoot.
./udocker setup --execmode=P1 myfed
Change execution engine to runC.
./udocker setup --execmode=R1 myfed
Change execution engine to Singularity. Requires the availability of Singularity in the host system.
./udocker setup --execmode=S1 myfed
Since root privileges are not involved any operation that really requires such privileges will not be possible. The following are examples of operations that are not possible:
- accessing host protected devices and files
- listening on TCP/IP privileged ports (range below 1024)
- mount file-systems
- the su command will not work
- change the system time
- changing routing tables, firewall rules, or network interfaces
If the containers require such capabilities then docker should be used instead.
The current implementation is limited to the pulling of docker images and its execution. The actual containers should be built using docker and dockerfiles.
udocker does not provide all the docker features, and is not intended as a docker replacement.
Debugging inside of udocker with the PRoot engine will not work due to the way PRoot implements the chroot environment
udocker is mainly oriented at providing a run-time environment for containers execution in user space.
udocker is particularly suited to run user applications encapsulated in docker containers.
Because of the limitations described in the previous section udocker does not offer isolation features such as the ones offered by docker. If the containers content is not trusted then these containers should not be executed with udocker as they will run inside the user environment.
The containers data will be unpacked and stored in the user home directory or other location of choice. Therefore the containers data will be subjected to the same filesystem protections as other files owned by the user. If the containers have sensitive information the files and directories should be adequately protected by the user.
udocker does not require privileges and runs under the identity of the user invoking it.
Users can downloaded udocker and execute it without requiring system administrators intervention.
udocker via PRoot offers the emulation of the root user. This emulation mimics a real root user (e.g getuid will return 0). This is just an emulation no root privileges are involved. This feature makes possible the execution of some tools that do not require actual privileges but which refuse to work if the username or id are not root or 0. This enables for instance software installation using rpm, yum or dnf inside the container.
Due to the lack of isolation udocker must not be run by privileged users.
Notice that when using execution engines other than PRoot (Pn modes) the created containers cannot be moved across hosts. In this case convert back to a Pn mode before transfer.
The accelerated mode of PRoot (mode P1) may exhibit failures in Linux kernels above 4.0 with some applications due to kernel changes and upstream issues in this case use mode P2 or any of the other modes.
The runC mode requires a recent kernel with user namespaces enabled.
The singularity mode requires the availability of Singularity in the host system.
The full documentation is available at:
- GitBook: https://indigo-dc.gitbooks.io/udocker/content/
- master: https://github.com/indigo-dc/udocker/blob/master/SUMMARY.md
- devel: https://github.com/indigo-dc/udocker/blob/devel/SUMMARY.md
When citing udocker please use the following:
- Jorge Gomes, Emanuele Bagnaschi, Isabel Campos, Mario David, Luís Alves, João Martins, João Pina, Alvaro López-García, Pablo Orviz, Enabling rootless Linux Containers in multi-user environments: The udocker tool, Computer Physics Communications, Available online 6 June 2018, ISSN 0010-4655, https://doi.org/10.1016/j.cpc.2018.05.021
- Docker https://www.docker.com/
- PRoot https://proot-me.github.io/
- Fakechroot https://github.com/dex4er/fakechroot/wiki
- runC https://runc.io/
- Singularity https://www.sylabs.io/
- INDIGO DataCloud https://www.indigo-datacloud.eu
- EOSC-hub https://eosc-hub.eu
- DEEP-Hybrid-DataCloud https://deep-hybrid-datacloud.eu