@@ -239,6 +239,34 @@ The camera stack comprises four software layers. From bottom to top:
libcamera framework or libcamera adaptation, and are outside of
the scope of the libcamera project.
+V4L2 Compatibility Layer
+ V4L2 compatibility is achieved through a shared library that traps all
+ accesses to camera devices and routes them to libcamera to emulate high-level
+ V4L2 camera devices. It is injected in a process address space through
+ ``LD_PRELOAD`` and is completely transparent for applications.
+
+ The compatibility layer exposes camera device features on a best-effort basis,
+ and aims for the level of features traditionally available from a UVC camera
+ designed for video conferencing.
+
+Android Camera HAL
+ Camera support for Android is achieved through a generic Android camera HAL
+ implementation on top of libcamera. The HAL implements features required by
+ Android and out of scope from libcamera, such as JPEG encoding support.
+
+ This component is used to provide support for ChromeOS platforms.
+
+GStreamer element (gstlibcamerasrc)
+ A `GStreamer element`_ is provided to allow capture from libcamera supported
+ devices through GStreamer pipelines, and connect to other elements for further
+ processing.
+
+Native libcamera API
+ Applications can make use of the libcamera API directly using the C++
+ API. An example application and walkthrough using the libcamera API can be
+ followed in the :doc:`Application writer's guide </guides/application-developer>`
+
+.. _GStreamer element: https://gstreamer.freedesktop.org/documentation/application-development/basics/elements.html
libcamera Architecture
======================
@@ -374,29 +402,3 @@ Helpers and Support Classes
self-contained support classes, even if such code is present only once in the
code base, in order to keep the source code clean and easy to read. This
should be the case for instance for plugin management.
-
-
-V4L2 Compatibility Layer
-------------------------
-
-V4L2 compatibility is achieved through a shared library that traps all
-accesses to camera devices and routes them to libcamera to emulate high-level
-V4L2 camera devices. It is injected in a process address space through
-`LD_PRELOAD` and is completely transparent for applications.
-
-The compatibility layer exposes camera device features on a best-effort basis,
-and aims for the level of features traditionally available from a UVC camera
-designed for video conferencing.
-
-
-Android Camera HAL
-------------------
-
-Camera support for Android is achieved through a generic Android
-camera HAL implementation on top of libcamera. The HAL will implement internally
-features required by Android and missing from libcamera, such as JPEG encoding
-support.
-
-The Android camera HAL implementation will initially target the
-LIMITED hardware level, with support for the FULL level then being gradually
-implemented.
@@ -26,8 +26,7 @@ desirable results from the camera.
.. _Media Controller: https://www.linuxtv.org/downloads/v4l-dvb-apis-new/userspace-api/mediactl/media-controller.html
-In this developers guide, we will explore the `Camera Stack`_ and how it is
-can be visualised at a high level, and explore the internal `Architecture`_ of
+In this developers guide, we will explore the internal `Architecture`_ of
the libcamera library with its components. The current `Platform Support`_ is
detailed, as well as an overview of the `Licensing`_ requirements of the
project.
@@ -42,112 +41,6 @@ provides a tutorial of the key APIs exposed by libcamera.
.. TODO: Correctly link to the other articles of the guide
-Camera Stack
-------------
-
-The libcamera library is implemented in userspace, and makes use of underlying
-kernel drivers that directly interact with hardware.
-
-Applications can make use of libcamera through the native `libcamera API`_'s or
-through an adaptation layer integrating libcamera into a larger framework.
-
-.. _libcamera API: https://www.libcamera.org/api-html/index.html
-
-::
-
- Application Layer
- / +--------------+ +--------------+ +--------------+ +--------------+
- | | Native | | Framework | | Native | | Android |
- | | V4L2 | | Application | | libcamera | | Camera |
- | | Application | | (gstreamer) | | Application | | Framework |
- \ +--------------+ +--------------+ +--------------+ +--------------+
-
- ^ ^ ^ ^
- | | | |
- | | | |
- v v | v
- Adaptation Layer |
- / +--------------+ +--------------+ | +--------------+
- | | V4L2 | | gstreamer | | | Android |
- | | Compatibility| | element | | | Camera |
- | | (preload) | |(libcamerasrc)| | | HAL |
- \ +--------------+ +--------------+ | +--------------+
- |
- ^ ^ | ^
- | | | |
- | | | |
- v v v v
- libcamera Framework
- / +--------------------------------------------------------------------+
- | | |
- | | libcamera |
- | | |
- \ +--------------------------------------------------------------------+
-
- ^ ^ ^
- Userspace | | |
- --------------------- | ---------------- | ---------------- | ---------------
- Kernel | | |
- v v v
-
- +-----------+ +-----------+ +-----------+
- | Media | <--> | Video | <--> | V4L2 |
- | Device | | Device | | Subdev |
- +-----------+ +-----------+ +-----------+
-
-The camera stack comprises of four software layers. From bottom to top:
-
-* The kernel drivers control the camera hardware and expose a low-level
- interface to userspace through the Linux kernel V4L2 family of APIs
- (Media Controller API, V4L2 Video Device API and V4L2 Subdev API).
-
-* The libcamera framework is the core part of the stack. It handles all control
- of the camera devices in its core component, libcamera, and exposes a native
- C++ API to upper layers.
-
-* The libcamera adaptation layer is an umbrella term designating the components
- that interface to libcamera in other frameworks. Notable examples are the V4L2
- compatibility layer, the gstreamer libcamera element, and the Android camera
- HAL implementation based on libcamera which are provided as a part of the
- libcamera project.
-
-* The applications and upper level frameworks are based on the libcamera
- framework or libcamera adaptation, and are outside of the scope of the
- libcamera project, however example native applications (cam, qcam) are
- provided for testing.
-
-
-V4L2 Compatibility Layer
- V4L2 compatibility is achieved through a shared library that traps all
- accesses to camera devices and routes them to libcamera to emulate high-level
- V4L2 camera devices. It is injected in a process address space through
- ``LD_PRELOAD`` and is completely transparent for applications.
-
- The compatibility layer exposes camera device features on a best-effort basis,
- and aims for the level of features traditionally available from a UVC camera
- designed for video conferencing.
-
-Android Camera HAL
- Camera support for Android is achieved through a generic Android camera HAL
- implementation on top of libcamera. The HAL implements features required by
- Android and out of scope from libcamera, such as JPEG encoding support.
-
- This component is used to provide support for ChromeOS platforms
-
-GStreamer element (gstlibcamerasrc)
- A `GStreamer element`_ is provided to allow capture from libcamera supported
- devices through GStreamer pipelines, and connect to other elements for further
- processing.
-
- Development of this element is ongoing and is limited to a single stream.
-
-Native libcamera API
- Applications can make use of the libcamera API directly using the C++
- API. An example application and walkthrough using the libcamera API can be
- followed in the `Application Writers Guide`_
-
-.. _GStreamer element: https://gstreamer.freedesktop.org/documentation/application-development/basics/elements.html
-
Architecture
------------