978dc07222
Currently, libcamera can be configured in runtime using several
environment variables. With introducing more and more variables, this
mechanism reaches its limits. It would be simpler and more flexible if
it was possible to configure libcamera in a single file.
For example, there was a request to define pipeline precedence in
runtime. We want to compile in multiple pipelines, in order to have
them accessible within single packages in distributions. And then being
able to select among the pipelines manually as needed based on the
particular hardware or operating system environment. Having the
configuration file then allows easy switching between hardware, GPU or
CPU IPAs. The configuration file can also be used to enable or disable
experimental features and avoid the need to track local patches changing
configuration options hard-wired in the code when working on new
features.
This patch introduces basic support for configuration files.
GlobalConfiguration class reads and stores the configuration. Its
instance can be used by other libcamera objects to access the
configuration. A GlobalConfiguration instance is supposed to be stored
in a well-defined place, e.g. a CameraManager instance. It is possible
to have multiple GlobalConfiguration instances, which may or may not
make sense.
libcamera configuration can be specified using a system-wide
configuration file or a user configuration file. The user configuration
file takes precedence if present. There is currently no way to merge
multiple configuration files, the one found is used as the only
configuration file. If no configuration file is present, nothing
changes to the current libcamera behavior (except for some log
messages related to configuration file lookup).
The configuration file is a YAML file. We already have a mechanism for
handling YAML configuration files in libcamera and the given
infrastructure can be reused for the purpose. However, the
configuration type is abstracted to make contingent future change of the
underlying class easier while retaining (most of) the original API.
The configuration is versioned. This has currently no particular
meaning but is likely to have its purpose in future, especially once
configuration validation is introduced.
The configuration YAML file looks as follows:
---
version: 1
configuration:
WHATEVER CONFIGURATION NEEDED
This patch introduces just the basic idea. Actually using the
configuration in the corresponding places (everything what is currently
configurable via environment variables should be configurable in the
file configuration) and other enhancements are implemented in the
followup patches.
Signed-off-by: Milan Zamazal <mzamazal@redhat.com>
Reviewed-by: Paul Elder <paul.elder@ideasonboard.com>
Reviewed-by: Laurent Pinchart <laurent.pinchart@ideasonboard.com>
Signed-off-by: Laurent Pinchart <laurent.pinchart@ideasonboard.com>
.. SPDX-License-Identifier: CC-BY-SA-4.0
===========
libcamera
===========
**A complex camera support library for Linux, Android, and ChromeOS**
Cameras are complex devices that need heavy hardware image processing
operations. Control of the processing is based on advanced algorithms that must
run on a programmable processor. This has traditionally been implemented in a
dedicated MCU in the camera, but in embedded devices algorithms have been moved
to the main CPU to save cost. Blurring the boundary between camera devices and
Linux often left the user with no other option than a vendor-specific
closed-source solution.
To address this problem the Linux media community has very recently started
collaboration with the industry to develop a camera stack that will be
open-source-friendly while still protecting vendor core IP. libcamera was born
out of that collaboration and will offer modern camera support to Linux-based
systems, including traditional Linux distributions, ChromeOS and Android.
.. section-begin-getting-started
Getting Started
---------------
To fetch the sources, build and install:
.. code::
git clone https://git.libcamera.org/libcamera/libcamera.git
cd libcamera
meson setup build
ninja -C build install
Dependencies
~~~~~~~~~~~~
The following Debian/Ubuntu packages are required for building libcamera.
Other distributions may have differing package names:
A C++ toolchain: [required]
Either {g++, clang}
Meson Build system: [required]
meson (>= 1.0.1) ninja-build pkg-config
for the libcamera core: [required]
libyaml-dev python3-yaml python3-ply python3-jinja2
for IPA module signing: [recommended]
Either libgnutls28-dev or libssl-dev, openssl
Without IPA module signing, all IPA modules will be isolated in a
separate process. This adds an unnecessary extra overhead at runtime.
for improved debugging: [optional]
libdw-dev libunwind-dev
libdw and libunwind provide backtraces to help debugging assertion
failures. Their functions overlap, libdw provides the most detailed
information, and libunwind is not needed if both libdw and the glibc
backtrace() function are available.
for device hotplug enumeration: [optional]
libudev-dev
for documentation: [optional]
doxygen graphviz python3-sphinx python3-sphinx-book-theme
python3-sphinxcontrib.doxylink (>= 1.6.1) texlive-latex-extra
for gstreamer: [optional]
libgstreamer1.0-dev libgstreamer-plugins-base1.0-dev
for Python bindings: [optional]
libpython3-dev pybind11-dev
for cam: [optional]
libevent-dev is required to support cam, however the following
optional dependencies bring more functionality to the cam test
tool:
- libdrm-dev: Enables the KMS sink
- libjpeg-dev: Enables MJPEG on the SDL sink
- libsdl2-dev: Enables the SDL sink
- libtiff-dev: Enables writing DNG
for qcam: [optional]
libtiff-dev qt6-base-dev
for tracing with lttng: [optional]
liblttng-ust-dev python3-jinja2 lttng-tools
for android: [optional]
libexif-dev libjpeg-dev
for lc-compliance: [optional]
libevent-dev libgtest-dev
for abi-compat.sh: [optional]
abi-compliance-checker
Basic testing with cam utility
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The ``cam`` utility can be used for basic testing. You can list the cameras
detected on the system with ``cam -l``, and capture ten frames from the first
camera and save them to disk with ``cam -c 1 --capture=10 --file``. See
``cam -h`` for more information about the ``cam`` tool.
In case of problems, a detailed debug log can be obtained from libcamera by
setting the ``LIBCAMERA_LOG_LEVELS`` environment variable:
.. code::
:~$ LIBCAMERA_LOG_LEVELS=*:DEBUG cam -l
Using GStreamer plugin
~~~~~~~~~~~~~~~~~~~~~~
To use the GStreamer plugin from the source tree, use the meson ``devenv``
command. This will create a new shell instance with the ``GST_PLUGIN_PATH``
environment set accordingly.
.. code::
meson devenv -C build
The debugging tool ``gst-launch-1.0`` can be used to construct a pipeline and
test it. The following pipeline will stream from the camera named "Camera 1"
onto the OpenGL accelerated display element on your system.
.. code::
gst-launch-1.0 libcamerasrc camera-name="Camera 1" ! queue ! glimagesink
To show the first camera found you can omit the camera-name property, or you
can list the cameras and their capabilities using:
.. code::
gst-device-monitor-1.0 Video
This will also show the supported stream sizes which can be manually selected
if desired with a pipeline such as:
.. code::
gst-launch-1.0 libcamerasrc ! 'video/x-raw,width=1280,height=720' ! \
queue ! glimagesink
The libcamerasrc element has two log categories, named libcamera-provider (for
the video device provider) and libcamerasrc (for the operation of the camera).
All corresponding debug messages can be enabled by setting the ``GST_DEBUG``
environment variable to ``libcamera*:7``.
Presently, to prevent element negotiation failures it is required to specify
the colorimetry and framerate as part of your pipeline construction. For
instance, to capture and encode as a JPEG stream and receive on another device
the following example could be used as a starting point:
.. code::
gst-launch-1.0 libcamerasrc ! \
video/x-raw,colorimetry=bt709,format=NV12,width=1280,height=720,framerate=30/1 ! \
queue ! jpegenc ! multipartmux ! \
tcpserversink host=0.0.0.0 port=5000
Which can be received on another device over the network with:
.. code::
gst-launch-1.0 tcpclientsrc host=$DEVICE_IP port=5000 ! \
multipartdemux ! jpegdec ! autovideosink
The GStreamer element also supports multiple streams. This is achieved by
requesting additional source pads. Downstream caps filters can be used
to choose specific parameters like resolution and pixel format. The pad
property ``stream-role`` can be used to select a role.
The following example displays a 640x480 view finder while streaming JPEG
encoded 800x600 video. You can use the receiver pipeline above to view the
remote stream from another device.
.. code::
gst-launch-1.0 libcamerasrc name=cs src::stream-role=view-finder src_0::stream-role=video-recording \
cs.src ! queue ! video/x-raw,width=640,height=480 ! videoconvert ! autovideosink \
cs.src_0 ! queue ! video/x-raw,width=800,height=600 ! videoconvert ! \
jpegenc ! multipartmux ! tcpserversink host=0.0.0.0 port=5000
.. section-end-getting-started
Troubleshooting
~~~~~~~~~~~~~~~
Several users have reported issues with meson installation, crux of the issue
is a potential version mismatch between the version that root uses, and the
version that the normal user uses. On calling `ninja -C build`, it can't find
the build.ninja module. This is a snippet of the error message.
::
ninja: Entering directory `build'
ninja: error: loading 'build.ninja': No such file or directory
This can be solved in two ways:
1. Don't install meson again if it is already installed system-wide.
2. If a version of meson which is different from the system-wide version is
already installed, uninstall that meson using pip3, and install again without
the --user argument.