poky/documentation/kernel-dev/kernel-dev-intro.rst - openbmc/openbmc - Gitiles

 .. SPDX-License-Identifier: CC-BY-SA-2.0-UK

 ************
 Introduction
 ************

 .. _kernel-dev-overview:

 Overview
 ========

 Regardless of how you intend to make use of the Yocto Project, chances
 are you will work with the Linux kernel. This manual describes how to
 set up your build host to support kernel development, introduces the
 kernel development process, provides background information on the Yocto
 Linux kernel :term:`Metadata`, describes
 common tasks you can perform using the kernel tools, shows you how to
 use the kernel Metadata needed to work with the kernel inside the Yocto
 Project, and provides insight into how the Yocto Project team develops
 and maintains Yocto Linux kernel Git repositories and Metadata.

 Each Yocto Project release has a set of Yocto Linux kernel recipes,
 whose Git repositories you can view in the Yocto
 :yocto_git:`Source Repositories <>` under the "Yocto Linux Kernel"
 heading. New recipes for the release track the latest Linux kernel
 upstream developments from http://www.kernel.org> and introduce
 newly-supported platforms. Previous recipes in the release are refreshed
 and supported for at least one additional Yocto Project release. As they
 align, these previous releases are updated to include the latest from
 the Long Term Support Initiative (LTSI) project. You can learn more
 about Yocto Linux kernels and LTSI in the ":ref:`Yocto Project Kernel
 Development and Maintenance <kernel-big-picture>`" section.

 Also included is a Yocto Linux kernel development recipe
 (``linux-yocto-dev.bb``) should you want to work with the very latest in
 upstream Yocto Linux kernel development and kernel Metadata development.

 .. note::

    For more on Yocto Linux kernels, see the "
    Yocto Project Kernel Development and Maintenance
    section.

 The Yocto Project also provides a powerful set of kernel tools for
 managing Yocto Linux kernel sources and configuration data. You can use
 these tools to make a single configuration change, apply multiple
 patches, or work with your own kernel sources.

 In particular, the kernel tools allow you to generate configuration
 fragments that specify only what you must, and nothing more.
 Configuration fragments only need to contain the highest level visible
 ``CONFIG`` options as presented by the Yocto Linux kernel ``menuconfig``
 system. Contrast this against a complete Yocto Linux kernel ``.config``
 file, which includes all the automatically selected ``CONFIG`` options.
 This efficiency reduces your maintenance effort and allows you to
 further separate your configuration in ways that make sense for your
 project. A common split separates policy and hardware. For example, all
 your kernels might support the ``proc`` and ``sys`` filesystems, but
 only specific boards require sound, USB, or specific drivers. Specifying
 these configurations individually allows you to aggregate them together
 as needed, but maintains them in only one place. Similar logic applies
 to separating source changes.

 If you do not maintain your own kernel sources and need to make only
 minimal changes to the sources, the released recipes provide a vetted
 base upon which to layer your changes. Doing so allows you to benefit
 from the continual kernel integration and testing performed during
 development of the Yocto Project.

 If, instead, you have a very specific Linux kernel source tree and are
 unable to align with one of the official Yocto Linux kernel recipes, an
 alternative exists by which you can use the Yocto Project Linux kernel
 tools with your own kernel sources.

 The remainder of this manual provides instructions for completing
 specific Linux kernel development tasks. These instructions assume you
 are comfortable working with
 `BitBake <http://openembedded.org/wiki/Bitbake>`__ recipes and basic
 open-source development tools. Understanding these concepts will
 facilitate the process of working with the kernel recipes. If you find
 you need some additional background, please be sure to review and
 understand the following documentation:

 -  :doc:`../brief-yoctoprojectqs/brief-yoctoprojectqs` document.

 -  :doc:`../overview-manual/overview-manual`.

 -  :ref:`devtool
    workflow <sdk-manual/sdk-extensible:using \`\`devtool\`\` in your sdk workflow>`
    as described in the Yocto Project Application Development and the
    Extensible Software Development Kit (eSDK) manual.

 -  The ":ref:`dev-manual/dev-manual-common-tasks:understanding and creating layers`"
    section in the Yocto Project Development Tasks Manual.

 -  The "`Kernel Modification
    Workflow <#kernel-modification-workflow>`__" section.

 Kernel Modification Workflow
 ============================

 Kernel modification involves changing the Yocto Project kernel, which
 could involve changing configuration options as well as adding new
 kernel recipes. Configuration changes can be added in the form of
 configuration fragments, while recipe modification comes through the
 kernel's ``recipes-kernel`` area in a kernel layer you create.

 This section presents a high-level overview of the Yocto Project kernel
 modification workflow. The illustration and accompanying list provide
 general information and references for further information.

 .. image:: figures/kernel-dev-flow.png
    :align: center

 1. *Set up Your Host Development System to Support Development Using the
    Yocto Project*: See the ":doc:`../dev-manual/dev-manual-start`" section in
    the Yocto Project Development Tasks Manual for options on how to get
    a build host ready to use the Yocto Project.

 2. *Set Up Your Host Development System for Kernel Development:* It is
    recommended that you use ``devtool`` and an extensible SDK for kernel
    development. Alternatively, you can use traditional kernel
    development methods with the Yocto Project. Either way, there are
    steps you need to take to get the development environment ready.

    Using ``devtool`` and the eSDK requires that you have a clean build
    of the image and that you are set up with the appropriate eSDK. For
    more information, see the
    ":ref:`kernel-dev/kernel-dev-common:getting ready to develop using \`\`devtool\`\``"
    section.

    Using traditional kernel development requires that you have the
    kernel source available in an isolated local Git repository. For more
    information, see the
    ":ref:`kernel-dev/kernel-dev-common:getting ready for traditional kernel development`"
    section.

 3. *Make Changes to the Kernel Source Code if applicable:* Modifying the
    kernel does not always mean directly changing source files. However,
    if you have to do this, you make the changes to the files in the
    eSDK's Build Directory if you are using ``devtool``. For more
    information, see the
    ":ref:`kernel-dev/kernel-dev-common:using \`\`devtool\`\` to patch the kernel`"
    section.

    If you are using traditional kernel development, you edit the source
    files in the kernel's local Git repository. For more information, see the
    ":ref:`kernel-dev/kernel-dev-common:using traditional kernel development to patch the kernel`"
    section.

 4. *Make Kernel Configuration Changes if Applicable:* If your situation
    calls for changing the kernel's configuration, you can use
    :ref:`menuconfig <kernel-dev/kernel-dev-common:using \`\`menuconfig\`\`>`,
    which allows you to
    interactively develop and test the configuration changes you are
    making to the kernel. Saving changes you make with ``menuconfig``
    updates the kernel's ``.config`` file.

    .. note::

       Try to resist the temptation to directly edit an existing
       .config
       file, which is found in the Build Directory among the source code
       used for the build. Doing so, can produce unexpected results when
       the OpenEmbedded build system regenerates the configuration file.

    Once you are satisfied with the configuration changes made using
    ``menuconfig`` and you have saved them, you can directly compare the
    resulting ``.config`` file against an existing original and gather
    those changes into a `configuration fragment
    file <#creating-config-fragments>`__ to be referenced from within the
    kernel's ``.bbappend`` file.

    Additionally, if you are working in a BSP layer and need to modify
    the BSP's kernel's configuration, you can use ``menuconfig``.

 5. *Rebuild the Kernel Image With Your Changes:* Rebuilding the kernel
    image applies your changes. Depending on your target hardware, you
    can verify your changes on actual hardware or perhaps QEMU.

 The remainder of this developer's guide covers common tasks typically
 used during kernel development, advanced Metadata usage, and Yocto Linux
 kernel maintenance concepts.
	.. SPDX-License-Identifier: CC-BY-SA-2.0-UK

	************
	Introduction
	************

	.. _kernel-dev-overview:

	Overview
	========

	Regardless of how you intend to make use of the Yocto Project, chances
	are you will work with the Linux kernel. This manual describes how to
	set up your build host to support kernel development, introduces the
	kernel development process, provides background information on the Yocto
	Linux kernel :term:`Metadata`, describes
	common tasks you can perform using the kernel tools, shows you how to
	use the kernel Metadata needed to work with the kernel inside the Yocto
	Project, and provides insight into how the Yocto Project team develops
	and maintains Yocto Linux kernel Git repositories and Metadata.

	Each Yocto Project release has a set of Yocto Linux kernel recipes,
	whose Git repositories you can view in the Yocto
	:yocto_git:`Source Repositories <>` under the "Yocto Linux Kernel"
	heading. New recipes for the release track the latest Linux kernel
	upstream developments from http://www.kernel.org> and introduce
	newly-supported platforms. Previous recipes in the release are refreshed
	and supported for at least one additional Yocto Project release. As they
	align, these previous releases are updated to include the latest from
	the Long Term Support Initiative (LTSI) project. You can learn more
	about Yocto Linux kernels and LTSI in the ":ref:`Yocto Project Kernel
	Development and Maintenance <kernel-big-picture>`" section.

	Also included is a Yocto Linux kernel development recipe
	(``linux-yocto-dev.bb``) should you want to work with the very latest in
	upstream Yocto Linux kernel development and kernel Metadata development.

	.. note::

	For more on Yocto Linux kernels, see the "
	Yocto Project Kernel Development and Maintenance
	section.

	The Yocto Project also provides a powerful set of kernel tools for
	managing Yocto Linux kernel sources and configuration data. You can use
	these tools to make a single configuration change, apply multiple
	patches, or work with your own kernel sources.

	In particular, the kernel tools allow you to generate configuration
	fragments that specify only what you must, and nothing more.
	Configuration fragments only need to contain the highest level visible
	``CONFIG`` options as presented by the Yocto Linux kernel ``menuconfig``
	system. Contrast this against a complete Yocto Linux kernel ``.config``
	file, which includes all the automatically selected ``CONFIG`` options.
	This efficiency reduces your maintenance effort and allows you to
	further separate your configuration in ways that make sense for your
	project. A common split separates policy and hardware. For example, all
	your kernels might support the ``proc`` and ``sys`` filesystems, but
	only specific boards require sound, USB, or specific drivers. Specifying
	these configurations individually allows you to aggregate them together
	as needed, but maintains them in only one place. Similar logic applies
	to separating source changes.

	If you do not maintain your own kernel sources and need to make only
	minimal changes to the sources, the released recipes provide a vetted
	base upon which to layer your changes. Doing so allows you to benefit
	from the continual kernel integration and testing performed during
	development of the Yocto Project.

	If, instead, you have a very specific Linux kernel source tree and are
	unable to align with one of the official Yocto Linux kernel recipes, an
	alternative exists by which you can use the Yocto Project Linux kernel
	tools with your own kernel sources.

	The remainder of this manual provides instructions for completing
	specific Linux kernel development tasks. These instructions assume you
	are comfortable working with
	`BitBake <http://openembedded.org/wiki/Bitbake>`__ recipes and basic
	open-source development tools. Understanding these concepts will
	facilitate the process of working with the kernel recipes. If you find
	you need some additional background, please be sure to review and
	understand the following documentation:

	- :doc:`../brief-yoctoprojectqs/brief-yoctoprojectqs` document.

	- :doc:`../overview-manual/overview-manual`.

	- :ref:`devtool
	workflow <sdk-manual/sdk-extensible:using \`\`devtool\`\` in your sdk workflow>`
	as described in the Yocto Project Application Development and the
	Extensible Software Development Kit (eSDK) manual.

	- The ":ref:`dev-manual/dev-manual-common-tasks:understanding and creating layers`"
	section in the Yocto Project Development Tasks Manual.

	- The "`Kernel Modification
	Workflow <#kernel-modification-workflow>`__" section.

	Kernel Modification Workflow
	============================

	Kernel modification involves changing the Yocto Project kernel, which
	could involve changing configuration options as well as adding new
	kernel recipes. Configuration changes can be added in the form of
	configuration fragments, while recipe modification comes through the
	kernel's ``recipes-kernel`` area in a kernel layer you create.

	This section presents a high-level overview of the Yocto Project kernel
	modification workflow. The illustration and accompanying list provide
	general information and references for further information.

	.. image:: figures/kernel-dev-flow.png
	:align: center

	1. *Set up Your Host Development System to Support Development Using the
	Yocto Project*: See the ":doc:`../dev-manual/dev-manual-start`" section in
	the Yocto Project Development Tasks Manual for options on how to get
	a build host ready to use the Yocto Project.

	2. Set Up Your Host Development System for Kernel Development: It is
	recommended that you use ``devtool`` and an extensible SDK for kernel
	development. Alternatively, you can use traditional kernel
	development methods with the Yocto Project. Either way, there are
	steps you need to take to get the development environment ready.

	Using ``devtool`` and the eSDK requires that you have a clean build
	of the image and that you are set up with the appropriate eSDK. For
	more information, see the
	":ref:`kernel-dev/kernel-dev-common:getting ready to develop using \`\`devtool\`\``"
	section.

	Using traditional kernel development requires that you have the
	kernel source available in an isolated local Git repository. For more
	information, see the
	":ref:`kernel-dev/kernel-dev-common:getting ready for traditional kernel development`"
	section.

	3. Make Changes to the Kernel Source Code if applicable: Modifying the
	kernel does not always mean directly changing source files. However,
	if you have to do this, you make the changes to the files in the
	eSDK's Build Directory if you are using ``devtool``. For more
	information, see the
	":ref:`kernel-dev/kernel-dev-common:using \`\`devtool\`\` to patch the kernel`"
	section.

	If you are using traditional kernel development, you edit the source
	files in the kernel's local Git repository. For more information, see the
	":ref:`kernel-dev/kernel-dev-common:using traditional kernel development to patch the kernel`"
	section.

	4. Make Kernel Configuration Changes if Applicable: If your situation
	calls for changing the kernel's configuration, you can use
	:ref:`menuconfig <kernel-dev/kernel-dev-common:using \`\`menuconfig\`\`>`,
	which allows you to
	interactively develop and test the configuration changes you are
	making to the kernel. Saving changes you make with ``menuconfig``
	updates the kernel's ``.config`` file.

	.. note::

	Try to resist the temptation to directly edit an existing
	.config
	file, which is found in the Build Directory among the source code
	used for the build. Doing so, can produce unexpected results when
	the OpenEmbedded build system regenerates the configuration file.

	Once you are satisfied with the configuration changes made using
	``menuconfig`` and you have saved them, you can directly compare the
	resulting ``.config`` file against an existing original and gather
	those changes into a `configuration fragment
	file <#creating-config-fragments>`__ to be referenced from within the
	kernel's ``.bbappend`` file.

	Additionally, if you are working in a BSP layer and need to modify
	the BSP's kernel's configuration, you can use ``menuconfig``.

	5. Rebuild the Kernel Image With Your Changes: Rebuilding the kernel
	image applies your changes. Depending on your target hardware, you
	can verify your changes on actual hardware or perhaps QEMU.

	The remainder of this developer's guide covers common tasks typically
	used during kernel development, advanced Metadata usage, and Yocto Linux
	kernel maintenance concepts.