This is a docker baseimage that can be used to create containers able to run any X application on a headless server very easily. The application's GUI is accessed through a modern web browser (no installation or configuration needed on client side) or via any VNC client.
- A minimal docker baseimage to ease creation of X graphical application containers
- Table of Content
- Images
- Getting started
- Environment Variables
- Config Directory
- Ports
- User/Group IDs
- Locales
- Accessing the GUI
- Security
- Building A Container
- Selecting Baseimage Tag
- Referencing Linux User/Group
- Default Configuration Files
- Adding/Removing Packages
- Modifying Files With Sed
- Modifying Baseimage Content
- Application's Data
- $HOME Environment Variable
- Service Dependencies
- Service Readiness
- Log Monitor
- Application Icon
- Maximizing Only the Main Window
- S6 Overlay Documentation
Different docker images are available:
Base distribution | Tag | Size |
---|---|---|
Alpine 3.5 | alpine-3.5 | |
Alpine 3.6 | alpine-3.6 | |
Alpine 3.7 | alpine-3.7 | |
Alpine 3.8 | alpine-3.8 | |
Alpine 3.9 | alpine-3.9 | |
Alpine 3.10 | alpine-3.10 | |
Alpine 3.11 | alpine-3.11 | |
Alpine 3.5 | alpine-3.5-glibc | |
Alpine 3.6 | alpine-3.6-glibc | |
Alpine 3.7 | alpine-3.7-glibc | |
Alpine 3.8 | alpine-3.8-glibc | |
Alpine 3.9 | alpine-3.9-glibc | |
Alpine 3.10 | alpine-3.10-glibc | |
Alpine 3.11 | alpine-3.11-glibc | |
Debian 8 | debian-8 | |
Debian 9 | debian-9 | |
Debian 10 | debian-10 | |
Ubuntu 16.04 LTS | ubuntu-16.04 | |
Ubuntu 18.04 LTS | ubuntu-18.04 |
Due to its size, the Alpine
image is recommended. However, it may be harder
to integrate your application (especially third party ones without source code),
because:
- Packages repository may not be as complete as
Ubuntu
/Debian
. - Third party applications may not support
Alpine
. - The
Alpine
distribution uses the musl C standard library instead of GNU C library (glibc).
Note that using the Alpine
image with glibc integrated (alpine-3.5-glibc
tag) may ease integration of applications.
The next choice is to use the Debian
image. It provides a great compatibility
and its size is smaller than the Ubuntu
one. Finally, if for any reason you
prefer an Ubuntu
image, one based on the stable 16.04 LTS
version is
provided.
Here are the main components of the baseimage:
- S6-overlay, a process supervisor for containers.
- x11vnc, a X11 VNC server.
- xvfb, a X virtual framebuffer display server.
- openbox, a windows manager.
- noVNC, a HTML5 VNC client.
- NGINX, a high-performance HTTP server.
- stunnel, a proxy encrypting arbitrary TCP connections with SSL/TLS.
- Useful tools to ease container building.
- Environment to better support dockerized applications.
Images are versioned. Version number is in the form MAJOR.MINOR.PATCH
, where
an increment of the:
- MAJOR version indicates that a backwards-incompatible change has been done.
- MINOR version indicates that functionality has been added in a backwards-compatible manner.
- PATCH version indicates that a bug fix has been done in a backwards-compatible manner.
For each distribution-specific image, multiple tags are available:
Tag | Description |
---|---|
distro-vX.Y.Z | Exact version of the image. |
distro-vX.Y | Latest version of a specific minor version of the image. |
distro-vX | Latest version of a specific major version of the image. |
distro | Latest version of the image. |
The Dockerfile
for your application can be very simple, as only three things
are required:
- Instructions to install the application.
- A script that starts the application (stored at
/startapp.sh
in container). - The name of the application.
Here is an example of a docker file that would be used to run the xterm
terminal.
In Dockerfile
:
# Pull base image.
FROM jlesage/baseimage-gui:alpine-3.6
# Install xterm.
RUN add-pkg xterm
# Copy the start script.
COPY startapp.sh /startapp.sh
# Set the name of the application.
ENV APP_NAME="Xterm"
In startapp.sh
:
#!/bin/sh
exec /usr/bin/xterm
Then, build your docker image:
docker build -t docker-xterm .
And run it:
docker run --rm -p 5800:5800 -p 5900:5900 docker-xterm
You should be able to access the xterm GUI by opening in a web browser:
http://[HOST IP ADDR]:5800
Some environment variables can be set to customize the behavior of the container and its application. The following list give more details about them.
Environment variables can be set directly in your Dockerfile
via the ENV
instruction or dynamically by adding one or more arguments -e "<VAR>=<VALUE>"
to the docker run
command.
Variable | Description | Default |
---|---|---|
APP_NAME |
Name of the application. | DockerApp |
USER_ID |
ID of the user the application runs as. See User/Group IDs to better understand when this should be set. | 1000 |
GROUP_ID |
ID of the group the application runs as. See User/Group IDs to better understand when this should be set. | 1000 |
SUP_GROUP_IDS |
Comma-separated list of supplementary group IDs of the application. | (unset) |
UMASK |
Mask that controls how file permissions are set for newly created files. The value of the mask is in octal notation. By default, this variable is not set and the default umask of 022 is used, meaning that newly created files are readable by everyone, but only writable by the owner. See the following online umask calculator: http://wintelguy.com/umask-calc.pl |
(unset) |
TZ |
TimeZone of the container. Timezone can also be set by mapping /etc/localtime between the host and the container. |
Etc/UTC |
KEEP_APP_RUNNING |
When set to 1 , the application will be automatically restarted if it crashes or if user quits it. |
0 |
APP_NICENESS |
Priority at which the application should run. A niceness value of -20 is the highest priority and 19 is the lowest priority. By default, niceness is not set, meaning that the default niceness of 0 is used. NOTE: A negative niceness (priority increase) requires additional permissions. In this case, the container should be run with the docker option --cap-add=SYS_NICE . |
(unset) |
TAKE_CONFIG_OWNERSHIP |
When set to 1 , owner and group of /config (including all its files and subfolders) are automatically set during container startup to USER_ID and GROUP_ID respectively. |
1 |
CLEAN_TMP_DIR |
When set to 1 , all files in the /tmp directory are delete during the container startup. |
1 |
DISPLAY_WIDTH |
Width (in pixels) of the application's window. | 1280 |
DISPLAY_HEIGHT |
Height (in pixels) of the application's window. | 768 |
SECURE_CONNECTION |
When set to 1 , an encrypted connection is used to access the application's GUI (either via web browser or VNC client). See the Security section for more details. |
0 |
VNC_PASSWORD |
Password needed to connect to the application's GUI. See the VNC Password section for more details. | (unset) |
X11VNC_EXTRA_OPTS |
Extra options to pass to the x11vnc server running in the Docker container. WARNING: For advanced users. Do not use unless you know what you are doing. | (unset) |
ENABLE_CJK_FONT |
When set to 1 , open source computer font WenQuanYi Zen Hei is installed. This font contains a large range of Chinese/Japanese/Korean characters. |
0 |
USE_WINDOW_DECORATION |
When set to 1 , enable window decorations in all windows. |
0 |
Inside the container, the application's configuration should be stored in the
/config
directory.
This directory is also used to store the VNC password. See the VNC Pasword section for more details.
NOTE: By default, during the container startup, the user which runs the
application (i.e. user defined by USER_ID
) will claim ownership of the
entire content of this directory. This behavior can be changed via the
TAKE_CONFIG_OWNERSHIP
environment variable. See the
Environment Variables section for more details.
Here is the list of ports used by container. They can be mapped to the host
via the -p <HOST_PORT>:<CONTAINER_PORT>
parameter. The port number inside the
container cannot be changed, but you are free to use any port on the host side.
Port | Mapping to host | Description |
---|---|---|
5800 | Mandatory | Port used to access the application's GUI via the web interface. |
5900 | Optional | Port used to access the application's GUI via the VNC protocol. Optional if no VNC client is used. |
When using data volumes (-v
flags), permissions issues can occur between the
host and the container. For example, the user within the container may not
exists on the host. This could prevent the host from properly accessing files
and folders on the shared volume.
To avoid any problem, you can specify the user the application should run as.
This is done by passing the user ID and group ID to the container via the
USER_ID
and GROUP_ID
environment variables.
To find the right IDs to use, issue the following command on the host, with the user owning the data volume on the host:
id <username>
Which gives an output like this one:
uid=1000(myuser) gid=1000(myuser) groups=1000(myuser),4(adm),24(cdrom),27(sudo),46(plugdev),113(lpadmin)
The value of uid
(user ID) and gid
(group ID) are the ones that you should
be given the container.
The default locale of the container is set to POSIX
. If this cause issues
with your application, the proper locale can be set via your Dockerfile
, by adding these two lines:
ENV LANG=en_US.UTF-8
RUN locale-gen en_CA.UTF-8
NOTE: Locales are not supported by musl
C standard library on Alpine
.
See:
Assuming that container's ports are mapped to the same host's ports, the graphical interface of the application can be accessed via:
- A web browser:
http://<HOST IP ADDR>:5800
- Any VNC client:
<HOST IP ADDR>:5900
By default, access to the application's GUI is done over an unencrypted connection (HTTP or VNC).
Secure connection can be enabled via the SECURE_CONNECTION
environment
variable. See the Environment Variables section for
more details on how to set an environment variable.
When enabled, application's GUI is performed over an HTTPs connection when accessed with a browser. All HTTP accesses are automatically redirected to HTTPs.
When using a VNC client, the VNC connection is performed over SSL. Note that few VNC clients support this method. SSVNC is one of them.
SSVNC is a VNC viewer that adds encryption security to VNC connections.
While the Linux version of SSVNC works well, the Windows version has some
issues. At the time of writing, the latest version 1.0.30
is not functional,
as a connection fails with the following error:
ReadExact: Socket error while reading
However, for your convienence, an unoffical and working version is provided here:
The only difference with the offical package is that the bundled version of
stunnel
has been upgraded to version 5.49
, which fixes the connection
problems.
Here are the certificate files needed by the container. By default, when they are missing, self-signed certificates are generated and used. All files have PEM encoded, x509 certificates.
Container Path | Purpose | Content |
---|---|---|
/config/certs/vnc-server.pem |
VNC connection encryption. | VNC server's private key and certificate, bundled with any root and intermediate certificates. |
/config/certs/web-privkey.pem |
HTTPs connection encryption. | Web server's private key. |
/config/certs/web-fullchain.pem |
HTTPs connection encryption. | Web server's certificate, bundled with any root and intermediate certificates. |
NOTE: To prevent any certificate validity warnings/errors from the browser or VNC client, make sure to supply your own valid certificates.
NOTE: Certificate files are monitored and relevant daemons are automatically restarted when changes are detected.
To restrict access to your application, a password can be specified. This can be done via two methods:
- By using the
VNC_PASSWORD
environment variable. - By creating a
.vncpass_clear
file at the root of the/config
volume. This file should contains the password in clear-text. During the container startup, content of the file is obfuscated and moved to.vncpass
.
The level of security provided by the VNC password depends on two things:
- The type of communication channel (encrypted/unencrypted).
- How secure access to the host is.
When using a VNC password, it is highly desirable to enable the secure connection to prevent sending the password in clear over an unencrypted channel.
Access to the host by unexpected users with sufficient privileges can be dangerous as they can retrieve the password with the following methods:
- By looking at the
VNC_PASSWORD
environment variable value via thedocker inspect
command. By defaut, thedocker
command can be run only by the root user. However, it is possible to configure the system to allow thedocker
command to be run by any users part of a specific group. - By decrypting the
/config/.vncpass
file. This requires the user to have the appropriate permission to read the file: it has to be root or be the user defined by theUSER_ID
environment variable. Also, to be able to retrieve the correct decryption key, one needs to know that the content of the file was generated byx11vnc
.
Diffie-Hellman (DH) parameters define how the DH key-exchange is performed. More details about this algorithm can be found on the OpenSSL Wiki.
DH Parameters are saved into the PEM encoded file located inside the container
at /config/certs/dhparam.pem
. By default, when this file is missing, 2048
bits DH parameters are automatically generated. Note that this one-time
operation takes some time to perform and increases the startup time of the
container.
This section provides useful tips for building containers based on this baseimage.
Properly select the baseimage tag to use. For a better control and prevent
breaking your container, use a tag for an exact version of the baseimage
(e.g. alpine-3.6-v2.0.0
). Using the latest version of the baseimage
(alpine-3.6
) is not recommended, since automatic upgrades between major
versions will probably break your container build/execution.
Reference the Linux user/group under which the application is running by its ID
(USER_ID
/GROUP_ID
) instead of its name. Name could change in different
baseimage versions while the ID won't.
Default configuration files should be stored in /defaults
in the container.
To add or remove packages, use the helpers add-pkg
and del-pkg
provided by
this baseimage. To minimze the size of the container, these tools perform
proper cleanup and make sure that no useless files are left after an addition
or removal of packages.
Also, when packages need to be added temporarily, use the --virtual NAME
parameter. This allows installing missing packages and then remove them
easily using the provided NAME
(no need to repeat given packages). Note that
if a specified package is already installed, it will be ignored and will not be
removed automatically.
Here is an example of a command that could be added to Dockerfile
to compile
a project:
RUN \
add-pkg --virtual build-dependencies build-base cmake git && \
# Compile your project here...
git clone https://myproject.com/myproject.git
... && \
del-pkg build-dependencies
Supposing that, in the example above, the git
package is already installed
when the call to add-pk
is performed, running del-pkg build-dependencies
doesn't remove it.
sed
is a useful tool and is often used in container builds to modify files.
However, one downside of this method is that there is no easy way to determine
if sed
actually modified the file or not.
It's for this reason that the baseimage includes a helper that gives sed
a
"patch-like" behavior: if the application of a sed expression results in no
change on the target file, then an error is reported. This helper is named
sed-patch
and has the following usage:
sed-patch [SED_OPT]... SED_EXPRESSION FILE
Note that the sed option -i
(edit files in place) is already supplied by the
helper.
It can be used in Dockerfile
, for example, like this:
RUN sed-patch 's/Replace this/By this/' /etc/myfile
If running this sed expression doesn't bring any change to /etc/myfiles
, the
command fails and thus, the Docker build also.
Try to minimize modifications to files provided by the baseimage. This minimizes to risk of breaking your container after using a new baseimage version.
Applications often needs to write configuration, data, logs, etc. Always
make sure they are all written under /config
. This directory is a volume
intended to be mapped to a folder on the host. The goal is to write stuff
outside the container and keep these data persistent.
A lot of applications use the environment variables defined in the
XDG Base Directory Specification to determine where to store
various data. The baseimage sets these variables so they all fall under
/config/
:
- XDG_DATA_HOME=/config/xdg/data
- XDG_CONFIG_HOME=/config/xdg/config
- XDG_CACHE_HOME=/config/xdg/cache
The application is run under a user having its own UID. This user can't be used to login with, has no password, no valid login shell and no home directory. It is effectively a kind of user used by daemons.
Thus, by default, the $HOME
environment variable is not set. While this
should be fine in most case, some applications may expect the $HOME
environment variable to be set (since normally the application is run by a
logged user) and may not behave correctly otherwise.
To make the application happy, the home directory can be set at the beginning
of the startapp.sh
script:
export HOME=/config
Adjust the location of the home directory to fit your needs. However, if the
application uses the home directory to write stuff, make sure it is done in a
volume mapped to the host (e.g. /config
),
Note that the same technique can be used by services, by exporting the home
directory into their run
script.
When running multiple services, service srvB
may need to start only after
service SrvA
.
Service dependencies are defined by creating a regular file in the service's
directory, its name being the name of the dependent service with the .dep
extension. For example, touching the file:
/etc/services.d/srvB/srvA.dep
indicates that service srvB
depends on service srvA
.
By default, a service is considered ready when the supervisor successfully forked and executed the daemon. However, some daemons do a lot of initialization work before they're actually ready to serve.
Hopefully, the S6 supervisor supports service startup notifications. This is a simple mechanism allowing daemons to notify the supervisor when they are ready to serve.
While support for this mechanism can be implemented natively in the daemon, the use of the s6-notifyoncheck program makes it possible for services to use the S6 notification mechanism with any daemon.
This baseimage include a simple log monitor. This monitor allows sending notification(s) when a particular message is detected in a log file.
This system has two main component: notification definitions and notifications backends (targets). Definitions describe properties of a notification (title, message, severity, etc) and how it is triggered (i.e. filtering function). Once a matching string is found in a log file, a notification is triggered and sent via one or more backends. A backend can implement any functionality. For example, it could send the notification to the standard output, a file or an online service.
File(s) to be monitored can be set in the configuration file located at
/etc/logmonitor/logmonitor.conf
. There are two settings to look at:
LOG_FILES
: List of absolute paths to log files to be monitored. A log file is a file having new content appended to it.STATUS_FILES
: List of absolute paths to status files to be monitored. A status file doesn't have new content appended. Instead, its whole content is refreshed/overwritten periodically.
The definition of a notification consists in multiple files, stored in a
directory under /etc/logmonitor/notifications.d
. For example, definition of
notification NOTIF
is found under /etc/logmonitor/notifications.d/NOTIF/
.
The following table describe files part of the definition:
File | Mandatory? | Description |
---|---|---|
filter |
Yes | Program (script or binary with executable permission) used to filter messages from a log file. It is invoked by the log monitor with a single argument: a line from the log file. On a match, the program should exit with a value of 0 . Any other values is interpreted as non-match. |
title |
Yes | File containing the title of the notification. To produce dynamic content, the file can be a program (script or binary with executable permission). In this case, the program is invoked by the log monitor with the matched message from the log file as the single argument. Output of the program is used as the notification's title. |
desc |
Yes | File containing the description/message of the notification. To produce dynamic content, the file can be a program (script or binary with executable permission). In this case, the program is invoked by the log monitor with the matched message from the log file as the single argument. Output of the program is used as the notification's description/message. |
level |
Yes | File containing severity level of the notification. Valid severity level values are ERROR , WARNING or INFO . To produce dynamic content, the file can be a program (script or binary with executable permission). In this case, the program is invoked by the log monitor with the matched message from the log file as the single argument. Output of the program is used as the notification's severity level. |
Definition of notification backend is stored in a directory under
/etc/logmonitor/targets.d
. For example, definition of STDOUT
backend is
found under /etc/logmonitor/notifications.d/STDOUT/
. The following table
describe files part of the definition:
File | Mandatory? | Description |
---|---|---|
send |
Yes | Program (script or binary with executable permission) that sends the notification. It is invoked by the log monitor with the following notification properties as arguments: title, description/message and the severity level. |
debouncing |
No | File containing the minimum amount time (in seconds) that must elapse before sending the same notification with the current backend. A value of 0 means infinite (notification is sent once). If this file is missing, no debouncing is done. |
By default, the baseimage contains the following notification backends:
Backend | Description | Debouncing time |
---|---|---|
stdout |
Display a message to the standard output, make it visible in the container's log. Message of the format is {LEVEL}: {TITLE} {MESSAGE} . |
21 600s (6 hours) |
yad |
Display the notification in a window box, visible in the application's GUI. NOTE: yad must be installed for this to work. |
Infinite |
A picture of your application can be added to the image. This picture is displayed in the WEB interface's navigation bar. Also, multiple favicons are generated, supporting all browsers and platforms.
Add the following command to your Dockerfile
, with the proper URL pointing to
your master icon: The master icon should be a square PNG image with a size of
at least 260x260 for optimal results.
# Generate and install favicons.
RUN \
APP_ICON_URL=https://github.com/jlesage/docker-templates/raw/master/jlesage/images/generic-app-icon.png && \
install_app_icon.sh "$APP_ICON_URL"
Favicons are generated by RealFaviconGenerator. You can tweak yourself their display with the following method:
- Generate favicons yourself with RealFaviconGenerator.
- Set the path to
/images/icons/
. - Enable versioning and set it to
v=ICON_VERSION
.
- Set the path to
- At the installation page, choose the
Node CLI
tab. - Copy the content of
faviconDescription.json
. - Minify the JSON using an online JSON minifier.
- Before running the minifier, modify the
masterPicture
field to/opt/novnc/images/icons/master_icon.png
.
- Before running the minifier, modify the
- Copy-paste the result in your
Dockerfile
. It will be passed to the install script. - Your Dockerfile should have something like:
# Generate and install favicons.
RUN \
APP_ICON_URL=https://github.com/jlesage/docker-templates/raw/master/jlesage/images/generic-app-icon.png && \
APP_ICON_DESC='{"masterPicture":"/opt/novnc/images/icons/master_icon.png","iconsPath":"/images/icons/","design":{"ios":{"pictureAspect":"backgroundAndMargin","backgroundColor":"#ffffff","margin":"14%","assets":{"ios6AndPriorIcons":false,"ios7AndLaterIcons":false,"precomposedIcons":false,"declareOnlyDefaultIcon":true}},"desktopBrowser":{},"windows":{"pictureAspect":"noChange","backgroundColor":"#2d89ef","onConflict":"override","assets":{"windows80Ie10Tile":false,"windows10Ie11EdgeTiles":{"small":false,"medium":true,"big":false,"rectangle":false}}},"androidChrome":{"pictureAspect":"noChange","themeColor":"#ffffff","manifest":{"display":"standalone","orientation":"notSet","onConflict":"override","declared":true},"assets":{"legacyIcon":false,"lowResolutionIcons":false}},"safariPinnedTab":{"pictureAspect":"silhouette","themeColor":"#5bbad5"}},"settings":{"scalingAlgorithm":"Mitchell","errorOnImageTooSmall":false},"versioning":{"paramName":"v","paramValue":"ICON_VERSION"}}' && \
install_app_icon.sh "$APP_ICON_URL" "$APP_ICON_DESC"
By default, the application's window is maximized and decorations are hidden. However, when the application has multiple windows, this behavior may need to be restricted only to the main one.
This can be achieved by matching on more window parameters: class, name, role,
title and type. By default, only the type
parameter is used and must equal to
normal
.
To find all parameters of the main window:
- While the application is running and the main window is focused, login to the container.
docker exec -ti [container name or id] sh
- Execute
obxprop --root | grep "^_NET_ACTIVE_WINDOW"
. The output will look like:
_NET_ACTIVE_WINDOW(WINDOW) = 16777220
- Using this ID, show the parameters by executing
obxprop --id [MAIN WINDOW ID] | grep "^_OB_APP"
. The output will look like:
_OB_APP_TYPE(UTF8_STRING) = "normal"
_OB_APP_CLASS(UTF8_STRING) = "Google-chrome"
_OB_APP_NAME(UTF8_STRING) = "google-chrome"
_OB_APP_ROLE(UTF8_STRING) =
_OB_APP_TITLE(UTF8_STRING) = "Google Chrome"
Finally, in the Dockerfile
of your container, modify the configuration file of
openbox
(located at /etc/xdg/openbox/rc.xml
) to apply window restriction.
Usually, specifying the window's title is enough.
sed-patch 's/<application type="normal">/<application type="normal" title="Google Chrome">/' /etc/xdg/openbox/rc.xml
See the openbox's documentation for more details: http://openbox.org/wiki/Help:Applications
- Make sure to read the S6 overlay documentation. It contains information that can help building your image. For example, the S6 overlay allows you to easily add initialization scripts and services.