Arcan is a powerful development framework for creating virtually anything from user interfaces for specialized embedded applications all the way to full-blown standalone desktop environments.
At its heart lies a robust and portable multimedia engine, with a well-tested and well-documented Lua scripting interface. The development emphasizes security, debuggability and performance -- guided by a principle of least surprise in terms of API design.
For more details about capabilities, design, goals, current development, roadmap, changelogs, notes on contributing and so on, please refer to the arcan-wiki.
There is also a website that collects other links, announcements, releases, videos / presentations and so on.
For community contact, check out the IRC channel #arcan on irc.freenode.net.
For developer information, see the HACKING.md
Some distributions, e.g. voidlinux have most of arcan as part of its packages, so you can save yourself some work going for one of those.
Docker- container templates (mainly used for headless development and testing) can be found here, quality varies wildly from bad to poor (just like Docker): dockerfiles.
There are many ways to tune the build steps in order to reduce dependencies. There are even more ways to configure and integrate the components depending on what you are going for,
Most options are exposed via the build output from running cmake on the src directory.
For the sake of simplicity over size, there is a build preset, 'everything' which is the one we will use here.
Specific package names depend on your distribution, but common ones are:
sqlite3, openal-soft, sdl2, opengl, luajit, gbm, kms, freetype, harfbuzz libxkbcommon
For encoding and decoding options you would also want:
libvlc-core (videolan), the ffmpeg suite, leptonica, tesseract libvncserver libusb1
First we need some in-source dependencies that are cloned manually for now:
git clone https://github.com/letoram/arcan.git cd external/git ../clone.sh cd ../arcan
These are typically not needed, with the exception of our temporary openAL patches pending refactoring of that subsystem in time for the ~0.7 series of releases.
Now we can configure and build the main engine:
mkdir build cd build cmake -DBUILD_PRESET="everything" ../src
Like with other CMake based projects, you can add:
To switch from a release build to a debug one.
When it has finished probing dependencies, you will get a report of which dependencies that has been found and which features that were turned on/off, or alert you if some of the required dependencies could not be found.
Make and install like normal (i.e. make, sudo make install). A number of binaries are produced, with the 'main' one being called simply arcan. To test 'in source' (without installing) you should be able to run:
./arcan -T ../data/scripts -p ../data/resources ../data/appl/welcome
The -T argument sets our built-in/shared set of scripts, the -p where shared resources like fonts and so on can be found, and the last argument being the actual 'script' to run.
With installation, this should reduce to:
It will automatically try to figure out if it should be a native display server or run nested within another or even itself based on the presence of various environment variables (DISPLAY, WAYLAND_DISPLAY, ARCAN_CONNPATH).
'welcome' is a name of a simple builtin welcome screen, that will shut down automatically after a few seconds of use.
For something of more directly useful, you can try the builtin appl 'console':
Which should work just like your normal console command-line, but with the added twist of being able to run (arcan compatible) graphical applications as well. For other projects, see the 'Related Projects' further below.
If input devices are misbehaving, the quick and dirty 'eventtest' in:
Might be useful in figuring out who to blame.
Another way to extend engine behavior regardless of the appl being used are so called hook-scripts. These reside inside the 'system script path' covered by the -T command-line argument, or the default of shared/arcan/scripts.
The idea is that these should be able to provide 'toggle on' features that would need cooperation from within the engine, in order to do quick custom modifications or help bridge other tools.
A good example is 'external_input':
arcan -H hooks/external_input.lua -H hooks/external_input.lua myappl
This would open up two connection points, 'extio_1', 'extio_2' that will allow one client to connect and provide input that will appear to the 'myappl' appl as coming from the engine.
These are covered in more detail in the manpage.
Arcan-net is a binary that allows you to forward one or many arcan clients over a network. It is built by default, and can be triggered both as a separate network tool as well as being launched indirectly from shmif by setting ARCAN_CONNPATH=a12://[email protected]:port, or when issuing a migration request by the window manager.
See also: src/a12/net/README.md and src/a12/net/HACKING.md.
The 'arcan-wayland' or 'waybridge', as it is refered to in some places is binary adds support for wayland and X clients (via Xwayland). It can be run as either a global system service, e.g.
Or on a case by case basis, like:
arcan-wayland -exec weston-terminal
For a compliant wayland client, and:
arcan-wayland -xwl -exec xterm
For an X client. The 'per case' basis is recommended as it is safer and more secure than letting multiple clients share the same bridge process, at a negilable cost. The downside is that some complex clients that rely on making multiple distinct wayland connections may fail to do so.
There is a number of tuning and troubleshooting options due to the complexity of using wayland, consult the manpage and --help toggle.
All runtime configuration is consolidated into a database, either the default 'arcan.sqlite' one or an explicitly set one (arcan -d mydb.sqlite).
This is used for platform specific options, engine specific options and for trusted clients that the running scripts are allowed to start. It is also used as a configuration key-value store for any arcan applications that are running.
As a quick example, this is how to inspect and modify keys that 'Durden' are currently using:
arcan_db show_appl durden arcan_db add_appl_kv durden shadow_on true
Advanced configuration for some video platforms can be set via the reserved arcan appl name. This would, for instance, set the primary graphics card device name for the 'egl-dri' platform version:
arcan_db add_appl_kv arcan video_device=/dev/dri/card2
To add 'launch targets', you can use something like:
arcan_db add_target net BIN /usr/bin/arcan-net -l netfwd arcan_db add_config arcan-net default 10.0.0.10 6666 arcan_db add_target xterm BIN /usr/bin/arcan-wayland -exec-x11
This allow applications to start a program as a trusted child (that inherits its connection primitives rather than to try and find them using some OS dependent namespace). The example above would have spawned arcan-net in the local mode where clients connecting to the 'netfwd' connpath would be redirected to the server listening at 10.0.0.10:6666.
There are many controls and options for this tool, so it is suggested that you look at its manpage for further detail and instructions.
The 'everything' build option should also produce a binary called 'arcan_headless', at least on BSDs and Linux. This binary can be used to run arcan without interfering with your other graphics and display system. Given access to a 'render node' (/dev/dri/renderD128 and so on) and it should also work fine inside containers and other strict sandboxing solutions.
To make it useful, it can record/stream to a virtual screen. An example of such a setup following the example above would be:
ARCAN_VIDEO_ENCODE=protocol=vnc arcan_headless console
Assuming the build-system found the libvncserver dependency, this should leave you with an exposed (insecure, unprotected, ...) vnc server at localhost+5900. See afsrv_encode for a list of arguments that can be added to the encode environment in order to control what happens.
If you are not interested in developing something of your own, you will likely find little use with the parts of this project alone. Here are some projects that you might want to look into:
Durden is the main desktop environment that uses this project as its display server.
Safespaces is an experimental VR/3D desktop environment.
Prio is a simple window manager that mimics Plan9- Rio.
Arcan-Devices accumulates extra drivers.
To get support for more types of clients and so on, there is also:
Wayland support (see Wayland section below, and src/wayland/README.md).
QEmu a patched QEmu version that adds a -ui arcan option.
Xarcan is a patched Xorg that allows you to run an X session 'as a window'.
There is also a number of helper tools that can be used to add certain features, such as support for VR devices and tray-icons. These are built separately and can be found in the tools/ subdirectory. They have their own separate build systems and corresponding README.md files.
They work on the assumption that arcan and its respective libraries have been built and installed. They are lockstepped and versioned to the engine, so if you upgrade it, make sure to rebuild the tools as well.
The main tools of interest are:
Acfgfs is a tool that lets you mount certain arcan applications as a FUSE file-system. The application has to explicitly support it. For the Durden desktop environment, you can use global/settings/system/control=somename and then:
arcan_cfgfs --control=/path/to/durden/ipc/somename /mnt/desktop
And desktop control / configuration should be exposed in the specified mountpoint.
Aclip is a clipboard manager similar to Xclip. It allows for bridging the clipboard between a desktop environment like Durden, and that of an X server.
This requires that clipboard bridging has been allowed (disabled by default for security reaons). In Durden this is activated via global/settings/system/clipboard where you can control how much clipboard access the tool gets.
Aloadimage is a simple sandboxing image loader, similar to xloadimage. It is useful both for testing client behavior when developing applications using arcan, but also as an image viewer in its own right, with reasonably fast image loading, basic playlist controls and so on.
VR bridge is an optional input driver that provides the arcan_vr binary which adds support for various head-mounted displays. More detailed instructions on its setup and use can be found as part of the Safespaces project mentioned in the 'Related Projects 'section.
Arcan-trayicon is a tool that chain-loads another arcan client, along with two reference images (active and inactive). It tries to register itself in the icon-tray of a running arcan application, though it must explicitly enable the support. In Durden, this is done via the path:
Then you can use:
ARCAN_CONNPATH=tray arcan-trayicon active.svg inactive.svg afsrv_terminal
Or some other arcan client that will then be loaded when the tray button is clicked, confined into a popup and then killed off as the popup is destroyed. This is a quick and convenient way to wrap various system services and external command scripts.