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author | Jason M. Bills <jason.m.bills@linux.intel.com> | 2020-12-08 00:38:17 +0300 |
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committer | Jason M. Bills <jason.m.bills@linux.intel.com> | 2020-12-08 00:38:17 +0300 |
commit | 8d6ae7f2a817751fad151168fa10ce28ee0869d8 (patch) | |
tree | 281032f7ec07c41589aa094bd165cc2a98f2d3a7 /poky/documentation/kernel-dev/kernel-dev-common.rst | |
parent | c16fb8893b19075db4bcf3b5bf33c1db8c3ca2bd (diff) | |
parent | 5da3c2284560a7e08ffafd03c5b5ba44a3242228 (diff) | |
download | openbmc-8d6ae7f2a817751fad151168fa10ce28ee0869d8.tar.xz |
Merge tag '0.26' of ssh://git-amr-1.devtools.intel.com:29418/openbmc-openbmc into update
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diff --git a/poky/documentation/kernel-dev/kernel-dev-common.rst b/poky/documentation/kernel-dev/kernel-dev-common.rst new file mode 100644 index 000000000..d4b60a9dc --- /dev/null +++ b/poky/documentation/kernel-dev/kernel-dev-common.rst @@ -0,0 +1,2078 @@ +.. SPDX-License-Identifier: CC-BY-2.0-UK + +************ +Common Tasks +************ + +This chapter presents several common tasks you perform when you work +with the Yocto Project Linux kernel. These tasks include preparing your +host development system for kernel development, preparing a layer, +modifying an existing recipe, patching the kernel, configuring the +kernel, iterative development, working with your own sources, and +incorporating out-of-tree modules. + +.. note:: + + The examples presented in this chapter work with the Yocto Project + 2.4 Release and forward. + +Preparing the Build Host to Work on the Kernel +============================================== + +Before you can do any kernel development, you need to be sure your build +host is set up to use the Yocto Project. For information on how to get +set up, see the ":doc:`../dev-manual/dev-manual-start`" section in +the Yocto Project Development Tasks Manual. Part of preparing the system +is creating a local Git repository of the +:term:`Source Directory` (``poky``) on your system. Follow the steps in the +":ref:`dev-manual/dev-manual-start:cloning the \`\`poky\`\` repository`" +section in the Yocto Project Development Tasks Manual to set up your +Source Directory. + +.. note:: + + Be sure you check out the appropriate development branch or you + create your local branch by checking out a specific tag to get the + desired version of Yocto Project. See the " + Checking Out by Branch in Poky + " and " + Checking Out by Tag in Poky + " sections in the Yocto Project Development Tasks Manual for more + information. + +Kernel development is best accomplished using +:ref:`devtool <sdk-manual/sdk-extensible:using \`\`devtool\`\` in your sdk workflow>` +and not through traditional kernel workflow methods. The remainder of +this section provides information for both scenarios. + +Getting Ready to Develop Using ``devtool`` +------------------------------------------ + +Follow these steps to prepare to update the kernel image using +``devtool``. Completing this procedure leaves you with a clean kernel +image and ready to make modifications as described in the " +:ref:`kernel-dev/kernel-dev-common:using \`\`devtool\`\` to patch the kernel`" +section: + +1. *Initialize the BitBake Environment:* Before building an extensible + SDK, you need to initialize the BitBake build environment by sourcing + the build environment script (i.e. :ref:`structure-core-script`): + :: + + $ cd ~/poky + $ source oe-init-build-env + + .. note:: + + The previous commands assume the + Source Repositories + (i.e. + poky + ) have been cloned using Git and the local repository is named + "poky". + +2. *Prepare Your local.conf File:* By default, the + :term:`MACHINE` variable is set to + "qemux86-64", which is fine if you are building for the QEMU emulator + in 64-bit mode. However, if you are not, you need to set the + ``MACHINE`` variable appropriately in your ``conf/local.conf`` file + found in the + :term:`Build Directory` (i.e. + ``~/poky/build`` in this example). + + Also, since you are preparing to work on the kernel image, you need + to set the + :term:`MACHINE_ESSENTIAL_EXTRA_RRECOMMENDS` + variable to include kernel modules. + + In this example we wish to build for qemux86 so we must set the + ``MACHINE`` variable to "qemux86" and also add the "kernel-modules". + As described we do this by appending to ``conf/local.conf``: + :: + + MACHINE = "qemux86" + MACHINE_ESSENTIAL_EXTRA_RRECOMMENDS += "kernel-modules" + +3. *Create a Layer for Patches:* You need to create a layer to hold + patches created for the kernel image. You can use the + ``bitbake-layers create-layer`` command as follows: + :: + + $ cd ~/poky/build + $ bitbake-layers create-layer ../../meta-mylayer + NOTE: Starting bitbake server... + Add your new layer with 'bitbake-layers add-layer ../../meta-mylayer' + $ + + .. note:: + + For background information on working with common and BSP layers, + see the " + Understanding and Creating Layers + " section in the Yocto Project Development Tasks Manual and the " + BSP Layers + " section in the Yocto Project Board Support (BSP) Developer's + Guide, respectively. For information on how to use the + bitbake-layers create-layer + command to quickly set up a layer, see the " + Creating a General Layer Using the + bitbake-layers + Script + " section in the Yocto Project Development Tasks Manual. + +4. *Inform the BitBake Build Environment About Your Layer:* As directed + when you created your layer, you need to add the layer to the + :term:`BBLAYERS` variable in the + ``bblayers.conf`` file as follows: + :: + + $ cd ~/poky/build + $ bitbake-layers add-layer ../../meta-mylayer + NOTE: Starting bitbake server... + $ + +5. *Build the Extensible SDK:* Use BitBake to build the extensible SDK + specifically for use with images to be run using QEMU: + :: + + $ cd ~/poky/build + $ bitbake core-image-minimal -c populate_sdk_ext + + Once + the build finishes, you can find the SDK installer file (i.e. + ``*.sh`` file) in the following directory: + ~/poky/build/tmp/deploy/sdk For this example, the installer file is + named + ``poky-glibc-x86_64-core-image-minimal-i586-toolchain-ext-DISTRO.sh`` + +6. *Install the Extensible SDK:* Use the following command to install + the SDK. For this example, install the SDK in the default + ``~/poky_sdk`` directory: + :: + + $ cd ~/poky/build/tmp/deploy/sdk + $ ./poky-glibc-x86_64-core-image-minimal-i586-toolchain-ext-3.1.2.sh + Poky (Yocto Project Reference Distro) Extensible SDK installer version 3.1.2 + ============================================================================ + Enter target directory for SDK (default: ~/poky_sdk): + You are about to install the SDK to "/home/scottrif/poky_sdk". Proceed [Y/n]? Y + Extracting SDK......................................done + Setting it up... + Extracting buildtools... + Preparing build system... + Parsing recipes: 100% |#################################################################| Time: 0:00:52 + Initializing tasks: 100% |############## ###############################################| Time: 0:00:04 + Checking sstate mirror object availability: 100% |######################################| Time: 0:00:00 + Parsing recipes: 100% |#################################################################| Time: 0:00:33 + Initializing tasks: 100% |##############################################################| Time: 0:00:00 + done + SDK has been successfully set up and is ready to be used. + Each time you wish to use the SDK in a new shell session, you need to source the environment setup script e.g. + $ . /home/scottrif/poky_sdk/environment-setup-i586-poky-linux + + +7. *Set Up a New Terminal to Work With the Extensible SDK:* You must set + up a new terminal to work with the SDK. You cannot use the same + BitBake shell used to build the installer. + + After opening a new shell, run the SDK environment setup script as + directed by the output from installing the SDK: + :: + + $ source ~/poky_sdk/environment-setup-i586-poky-linux + "SDK environment now set up; additionally you may now run devtool to perform development tasks. + Run devtool --help for further details. + + .. note:: + + If you get a warning about attempting to use the extensible SDK in + an environment set up to run BitBake, you did not use a new shell. + +8. *Build the Clean Image:* The final step in preparing to work on the + kernel is to build an initial image using ``devtool`` in the new + terminal you just set up and initialized for SDK work: + :: + + $ devtool build-image + Parsing recipes: 100% |##########################################| Time: 0:00:05 + Parsing of 830 .bb files complete (0 cached, 830 parsed). 1299 targets, 47 skipped, 0 masked, 0 errors. + WARNING: No packages to add, building image core-image-minimal unmodified + Loading cache: 100% |############################################| Time: 0:00:00 + Loaded 1299 entries from dependency cache. + NOTE: Resolving any missing task queue dependencies + Initializing tasks: 100% |#######################################| Time: 0:00:07 + Checking sstate mirror object availability: 100% |###############| Time: 0:00:00 + NOTE: Executing SetScene Tasks + NOTE: Executing RunQueue Tasks + NOTE: Tasks Summary: Attempted 2866 tasks of which 2604 didn't need to be rerun and all succeeded. + NOTE: Successfully built core-image-minimal. You can find output files in /home/scottrif/poky_sdk/tmp/deploy/images/qemux86 + + If you were + building for actual hardware and not for emulation, you could flash + the image to a USB stick on ``/dev/sdd`` and boot your device. For an + example that uses a Minnowboard, see the + `TipsAndTricks/KernelDevelopmentWithEsdk <https://wiki.yoctoproject.org/wiki/TipsAndTricks/KernelDevelopmentWithEsdk>`__ + Wiki page. + +At this point you have set up to start making modifications to the +kernel by using the extensible SDK. For a continued example, see the +":ref:`kernel-dev/kernel-dev-common:using \`\`devtool\`\` to patch the kernel`" +section. + +Getting Ready for Traditional Kernel Development +------------------------------------------------ + +Getting ready for traditional kernel development using the Yocto Project +involves many of the same steps as described in the previous section. +However, you need to establish a local copy of the kernel source since +you will be editing these files. + +Follow these steps to prepare to update the kernel image using +traditional kernel development flow with the Yocto Project. Completing +this procedure leaves you ready to make modifications to the kernel +source as described in the ":ref:`kernel-dev/kernel-dev-common:using traditional kernel development to patch the kernel`" +section: + +1. *Initialize the BitBake Environment:* Before you can do anything + using BitBake, you need to initialize the BitBake build environment + by sourcing the build environment script (i.e. + :ref:`structure-core-script`). + Also, for this example, be sure that the local branch you have + checked out for ``poky`` is the Yocto Project &DISTRO_NAME; branch. If + you need to checkout out the &DISTRO_NAME; branch, see the + ":ref:`dev-manual/dev-manual-start:checking out by branch in poky`" + section in the Yocto Project Development Tasks Manual. + :: + + $ cd ~/poky + $ git branch + master + * &DISTRO_NAME; + $ source oe-init-build-env + + .. note:: + + The previous commands assume the + Source Repositories + (i.e. + poky + ) have been cloned using Git and the local repository is named + "poky". + +2. *Prepare Your local.conf File:* By default, the + :term:`MACHINE` variable is set to + "qemux86-64", which is fine if you are building for the QEMU emulator + in 64-bit mode. However, if you are not, you need to set the + ``MACHINE`` variable appropriately in your ``conf/local.conf`` file + found in the + :term:`Build Directory` (i.e. + ``~/poky/build`` in this example). + + Also, since you are preparing to work on the kernel image, you need + to set the + :term:`MACHINE_ESSENTIAL_EXTRA_RRECOMMENDS` + variable to include kernel modules. + + In this example we wish to build for qemux86 so we must set the + ``MACHINE`` variable to "qemux86" and also add the "kernel-modules". + As described we do this by appending to ``conf/local.conf``: + :: + + MACHINE = "qemux86" + MACHINE_ESSENTIAL_EXTRA_RRECOMMENDS += "kernel-modules" + +3. *Create a Layer for Patches:* You need to create a layer to hold + patches created for the kernel image. You can use the + ``bitbake-layers create-layer`` command as follows: + :: + + $ cd ~/poky/build + $ bitbake-layers create-layer ../../meta-mylayer + NOTE: Starting bitbake server... + Add your new layer with 'bitbake-layers add-layer ../../meta-mylayer' + + .. note:: + + For background information on working with common and BSP layers, + see the " + Understanding and Creating Layers + " section in the Yocto Project Development Tasks Manual and the " + BSP Layers + " section in the Yocto Project Board Support (BSP) Developer's + Guide, respectively. For information on how to use the + bitbake-layers create-layer + command to quickly set up a layer, see the " + Creating a General Layer Using the + bitbake-layers + Script + " section in the Yocto Project Development Tasks Manual. + +4. *Inform the BitBake Build Environment About Your Layer:* As directed + when you created your layer, you need to add the layer to the + :term:`BBLAYERS` variable in the + ``bblayers.conf`` file as follows: + :: + + $ cd ~/poky/build + $ bitbake-layers add-layer ../../meta-mylayer + NOTE: Starting bitbake server ... + $ + +5. *Create a Local Copy of the Kernel Git Repository:* You can find Git + repositories of supported Yocto Project kernels organized under + "Yocto Linux Kernel" in the Yocto Project Source Repositories at + :yocto_git:`/`. + + For simplicity, it is recommended that you create your copy of the + kernel Git repository outside of the + :term:`Source Directory`, which is + usually named ``poky``. Also, be sure you are in the + ``standard/base`` branch. + + The following commands show how to create a local copy of the + ``linux-yocto-4.12`` kernel and be in the ``standard/base`` branch. + + .. note:: + + The + linux-yocto-4.12 + kernel can be used with the Yocto Project 2.4 release and forward. + You cannot use the + linux-yocto-4.12 + kernel with releases prior to Yocto Project 2.4: + + :: + + $ cd ~ + $ git clone git://git.yoctoproject.org/linux-yocto-4.12 --branch standard/base + Cloning into 'linux-yocto-4.12'... + remote: Counting objects: 6097195, done. + remote: Compressing objects: 100% (901026/901026), done. + remote: Total 6097195 (delta 5152604), reused 6096847 (delta 5152256) + Receiving objects: 100% (6097195/6097195), 1.24 GiB | 7.81 MiB/s, done. + Resolving deltas: 100% (5152604/5152604), done. Checking connectivity... done. + Checking out files: 100% (59846/59846), done. + +6. *Create a Local Copy of the Kernel Cache Git Repository:* For + simplicity, it is recommended that you create your copy of the kernel + cache Git repository outside of the + :term:`Source Directory`, which is + usually named ``poky``. Also, for this example, be sure you are in + the ``yocto-4.12`` branch. + + The following commands show how to create a local copy of the + ``yocto-kernel-cache`` and be in the ``yocto-4.12`` branch: + :: + + $ cd ~ + $ git clone git://git.yoctoproject.org/yocto-kernel-cache --branch yocto-4.12 + Cloning into 'yocto-kernel-cache'... + remote: Counting objects: 22639, done. + remote: Compressing objects: 100% (9761/9761), done. + remote: Total 22639 (delta 12400), reused 22586 (delta 12347) + Receiving objects: 100% (22639/22639), 22.34 MiB | 6.27 MiB/s, done. + Resolving deltas: 100% (12400/12400), done. + Checking connectivity... done. + +At this point, you are ready to start making modifications to the kernel +using traditional kernel development steps. For a continued example, see +the "`Using Traditional Kernel Development to Patch the +Kernel <#using-traditional-kernel-development-to-patch-the-kernel>`__" +section. + +Creating and Preparing a Layer +============================== + +If you are going to be modifying kernel recipes, it is recommended that +you create and prepare your own layer in which to do your work. Your +layer contains its own :term:`BitBake` +append files (``.bbappend``) and provides a convenient mechanism to +create your own recipe files (``.bb``) as well as store and use kernel +patch files. For background information on working with layers, see the +":ref:`dev-manual/dev-manual-common-tasks:understanding and creating layers`" +section in the Yocto Project Development Tasks Manual. + +.. note:: + + The Yocto Project comes with many tools that simplify tasks you need + to perform. One such tool is the + bitbake-layers create-layer + command, which simplifies creating a new layer. See the " + Creating a General Layer Using the + bitbake-layers + Script + " section in the Yocto Project Development Tasks Manual for + information on how to use this script to quick set up a new layer. + +To better understand the layer you create for kernel development, the +following section describes how to create a layer without the aid of +tools. These steps assume creation of a layer named ``mylayer`` in your +home directory: + +1. *Create Structure*: Create the layer's structure: + :: + + $ cd $HOME + $ mkdir meta-mylayer + $ mkdir meta-mylayer/conf + $ mkdir meta-mylayer/recipes-kernel + $ mkdir meta-mylayer/recipes-kernel/linux + $ mkdir meta-mylayer/recipes-kernel/linux/linux-yocto + + The ``conf`` directory holds your configuration files, while the + ``recipes-kernel`` directory holds your append file and eventual + patch files. + +2. *Create the Layer Configuration File*: Move to the + ``meta-mylayer/conf`` directory and create the ``layer.conf`` file as + follows: + :: + + # We have a conf and classes directory, add to BBPATH + BBPATH .= ":${LAYERDIR}" + + # We have recipes-* directories, add to BBFILES + BBFILES += "${LAYERDIR}/recipes-*/*/*.bb \ + ${LAYERDIR}/recipes-*/*/*.bbappend" + + BBFILE_COLLECTIONS += "mylayer" + BBFILE_PATTERN_mylayer = "^${LAYERDIR}/" + BBFILE_PRIORITY_mylayer = "5" + + Notice ``mylayer`` as part of the last three statements. + +3. *Create the Kernel Recipe Append File*: Move to the + ``meta-mylayer/recipes-kernel/linux`` directory and create the + kernel's append file. This example uses the ``linux-yocto-4.12`` + kernel. Thus, the name of the append file is + ``linux-yocto_4.12.bbappend``: + :: + + FILESEXTRAPATHS_prepend := "${THISDIR}/${PN}:" + + SRC_URI_append = " file://patch-file-one" + SRC_URI_append = " file://patch-file-two" + SRC_URI_append = " file://patch-file-three" + + The :term:`FILESEXTRAPATHS` and :term:`SRC_URI` statements + enable the OpenEmbedded build system to find patch files. For more + information on using append files, see the + ":ref:`dev-manual/dev-manual-common-tasks:using .bbappend files in your layer`" + section in the Yocto Project Development Tasks Manual. + +Modifying an Existing Recipe +============================ + +In many cases, you can customize an existing linux-yocto recipe to meet +the needs of your project. Each release of the Yocto Project provides a +few Linux kernel recipes from which you can choose. These are located in +the :term:`Source Directory` in +``meta/recipes-kernel/linux``. + +Modifying an existing recipe can consist of the following: + +- Creating the append file + +- Applying patches + +- Changing the configuration + +Before modifying an existing recipe, be sure that you have created a +minimal, custom layer from which you can work. See the "`Creating and +Preparing a Layer <#creating-and-preparing-a-layer>`__" section for +information. + +Creating the Append File +------------------------ + +You create this file in your custom layer. You also name it accordingly +based on the linux-yocto recipe you are using. For example, if you are +modifying the ``meta/recipes-kernel/linux/linux-yocto_4.12.bb`` recipe, +the append file will typically be located as follows within your custom +layer: +:: + + your-layer/recipes-kernel/linux/linux-yocto_4.12.bbappend + +The append file should initially extend the +:term:`FILESPATH` search path by +prepending the directory that contains your files to the +:term:`FILESEXTRAPATHS` +variable as follows: +:: + + FILESEXTRAPATHS_prepend := "${THISDIR}/${PN}:" + +The path ``${``\ :term:`THISDIR`\ ``}/${``\ :term:`PN`\ ``}`` +expands to "linux-yocto" in the current directory for this example. If +you add any new files that modify the kernel recipe and you have +extended ``FILESPATH`` as described above, you must place the files in +your layer in the following area: +:: + + your-layer/recipes-kernel/linux/linux-yocto/ + +.. note:: + + If you are working on a new machine Board Support Package (BSP), be + sure to refer to the + Yocto Project Board Support Package (BSP) Developer's Guide + . + +As an example, consider the following append file used by the BSPs in +``meta-yocto-bsp``: +:: + + meta-yocto-bsp/recipes-kernel/linux/linux-yocto_4.12.bbappend + +The following listing shows the file. Be aware that the actual commit ID +strings in this example listing might be different than the actual +strings in the file from the ``meta-yocto-bsp`` layer upstream. +:: + + KBRANCH_genericx86 = "standard/base" + KBRANCH_genericx86-64 = "standard/base" + + KMACHINE_genericx86 ?= "common-pc" + KMACHINE_genericx86-64 ?= "common-pc-64" + KBRANCH_edgerouter = "standard/edgerouter" + KBRANCH_beaglebone = "standard/beaglebone" + + SRCREV_machine_genericx86 ?= "d09f2ce584d60ecb7890550c22a80c48b83c2e19" + SRCREV_machine_genericx86-64 ?= "d09f2ce584d60ecb7890550c22a80c48b83c2e19" + SRCREV_machine_edgerouter ?= "b5c8cfda2dfe296410d51e131289fb09c69e1e7d" + SRCREV_machine_beaglebone ?= "b5c8cfda2dfe296410d51e131289fb09c69e1e7d" + + + COMPATIBLE_MACHINE_genericx86 = "genericx86" + COMPATIBLE_MACHINE_genericx86-64 = "genericx86-64" + COMPATIBLE_MACHINE_edgerouter = "edgerouter" + COMPATIBLE_MACHINE_beaglebone = "beaglebone" + + LINUX_VERSION_genericx86 = "4.12.7" + LINUX_VERSION_genericx86-64 = "4.12.7" + LINUX_VERSION_edgerouter = "4.12.10" + LINUX_VERSION_beaglebone = "4.12.10" + +This append file +contains statements used to support several BSPs that ship with the +Yocto Project. The file defines machines using the +:term:`COMPATIBLE_MACHINE` +variable and uses the +:term:`KMACHINE` variable to ensure +the machine name used by the OpenEmbedded build system maps to the +machine name used by the Linux Yocto kernel. The file also uses the +optional :term:`KBRANCH` variable to +ensure the build process uses the appropriate kernel branch. + +Although this particular example does not use it, the +:term:`KERNEL_FEATURES` +variable could be used to enable features specific to the kernel. The +append file points to specific commits in the +:term:`Source Directory` Git repository and +the ``meta`` Git repository branches to identify the exact kernel needed +to build the BSP. + +One thing missing in this particular BSP, which you will typically need +when developing a BSP, is the kernel configuration file (``.config``) +for your BSP. When developing a BSP, you probably have a kernel +configuration file or a set of kernel configuration files that, when +taken together, define the kernel configuration for your BSP. You can +accomplish this definition by putting the configurations in a file or a +set of files inside a directory located at the same level as your +kernel's append file and having the same name as the kernel's main +recipe file. With all these conditions met, simply reference those files +in the :term:`SRC_URI` statement in +the append file. + +For example, suppose you had some configuration options in a file called +``network_configs.cfg``. You can place that file inside a directory +named ``linux-yocto`` and then add a ``SRC_URI`` statement such as the +following to the append file. When the OpenEmbedded build system builds +the kernel, the configuration options are picked up and applied. +:: + + SRC_URI += "file://network_configs.cfg" + +To group related configurations into multiple files, you perform a +similar procedure. Here is an example that groups separate +configurations specifically for Ethernet and graphics into their own +files and adds the configurations by using a ``SRC_URI`` statement like +the following in your append file: +:: + + SRC_URI += "file://myconfig.cfg \ + file://eth.cfg \ + file://gfx.cfg" + +Another variable you can use in your kernel recipe append file is the +:term:`FILESEXTRAPATHS` +variable. When you use this statement, you are extending the locations +used by the OpenEmbedded system to look for files and patches as the +recipe is processed. + +.. note:: + + Other methods exist to accomplish grouping and defining configuration + options. For example, if you are working with a local clone of the + kernel repository, you could checkout the kernel's ``meta`` branch, + make your changes, and then push the changes to the local bare clone + of the kernel. The result is that you directly add configuration + options to the ``meta`` branch for your BSP. The configuration + options will likely end up in that location anyway if the BSP gets + added to the Yocto Project. + + In general, however, the Yocto Project maintainers take care of + moving the ``SRC_URI``-specified configuration options to the + kernel's ``meta`` branch. Not only is it easier for BSP developers to + not have to worry about putting those configurations in the branch, + but having the maintainers do it allows them to apply 'global' + knowledge about the kinds of common configuration options multiple + BSPs in the tree are typically using. This allows for promotion of + common configurations into common features. + +Applying Patches +---------------- + +If you have a single patch or a small series of patches that you want to +apply to the Linux kernel source, you can do so just as you would with +any other recipe. You first copy the patches to the path added to +:term:`FILESEXTRAPATHS` in +your ``.bbappend`` file as described in the previous section, and then +reference them in :term:`SRC_URI` +statements. + +For example, you can apply a three-patch series by adding the following +lines to your linux-yocto ``.bbappend`` file in your layer: +:: + + SRC_URI += "file://0001-first-change.patch" + SRC_URI += "file://0002-second-change.patch" + SRC_URI += "file://0003-third-change.patch" + +The next time you run BitBake to build +the Linux kernel, BitBake detects the change in the recipe and fetches +and applies the patches before building the kernel. + +For a detailed example showing how to patch the kernel using +``devtool``, see the +":ref:`kernel-dev/kernel-dev-common:using \`\`devtool\`\` to patch the kernel`" +and +":ref:`kernel-dev/kernel-dev-common:using traditional kernel development to patch the kernel`" +sections. + +Changing the Configuration +-------------------------- + +You can make wholesale or incremental changes to the final ``.config`` +file used for the eventual Linux kernel configuration by including a +``defconfig`` file and by specifying configuration fragments in the +:term:`SRC_URI` to be applied to that +file. + +If you have a complete, working Linux kernel ``.config`` file you want +to use for the configuration, as before, copy that file to the +appropriate ``${PN}`` directory in your layer's ``recipes-kernel/linux`` +directory, and rename the copied file to "defconfig". Then, add the +following lines to the linux-yocto ``.bbappend`` file in your layer: +:: + + FILESEXTRAPATHS_prepend := "${THISDIR}/${PN}:" + SRC_URI += "file://defconfig" + +The ``SRC_URI`` tells the build system how to search +for the file, while the +:term:`FILESEXTRAPATHS` +extends the :term:`FILESPATH` +variable (search directories) to include the ``${PN}`` directory you +created to hold the configuration changes. + +.. note:: + + The build system applies the configurations from the + defconfig + file before applying any subsequent configuration fragments. The + final kernel configuration is a combination of the configurations in + the + defconfig + file and any configuration fragments you provide. You need to realize + that if you have any configuration fragments, the build system + applies these on top of and after applying the existing + defconfig + file configurations. + +Generally speaking, the preferred approach is to determine the +incremental change you want to make and add that as a configuration +fragment. For example, if you want to add support for a basic serial +console, create a file named ``8250.cfg`` in the ``${PN}`` directory +with the following content (without indentation): +:: + + CONFIG_SERIAL_8250=y + CONFIG_SERIAL_8250_CONSOLE=y + CONFIG_SERIAL_8250_PCI=y + CONFIG_SERIAL_8250_NR_UARTS=4 + CONFIG_SERIAL_8250_RUNTIME_UARTS=4 + CONFIG_SERIAL_CORE=y + CONFIG_SERIAL_CORE_CONSOLE=y + +Next, include this +configuration fragment and extend the ``FILESPATH`` variable in your +``.bbappend`` file: +:: + + FILESEXTRAPATHS_prepend := "${THISDIR}/${PN}:" + SRC_URI += "file://8250.cfg" + +The next time you run BitBake to build the +Linux kernel, BitBake detects the change in the recipe and fetches and +applies the new configuration before building the kernel. + +For a detailed example showing how to configure the kernel, see the +"`Configuring the Kernel <#configuring-the-kernel>`__" section. + +Using an "In-Tree" ``defconfig`` File +-------------------------------------- + +It might be desirable to have kernel configuration fragment support +through a ``defconfig`` file that is pulled from the kernel source tree +for the configured machine. By default, the OpenEmbedded build system +looks for ``defconfig`` files in the layer used for Metadata, which is +"out-of-tree", and then configures them using the following: +:: + + SRC_URI += "file://defconfig" + +If you do not want to maintain copies of +``defconfig`` files in your layer but would rather allow users to use +the default configuration from the kernel tree and still be able to add +configuration fragments to the +:term:`SRC_URI` through, for example, +append files, you can direct the OpenEmbedded build system to use a +``defconfig`` file that is "in-tree". + +To specify an "in-tree" ``defconfig`` file, use the following statement +form: +:: + + KBUILD_DEFCONFIG_KMACHINE ?= defconfig_file + +Here is an example +that assigns the ``KBUILD_DEFCONFIG`` variable based on "raspberrypi2" +and provides the path to the "in-tree" ``defconfig`` file to be used for +a Raspberry Pi 2, which is based on the Broadcom 2708/2709 chipset: +:: + + KBUILD_DEFCONFIG_raspberrypi2 ?= "bcm2709_defconfig" + +Aside from modifying your kernel recipe and providing your own +``defconfig`` file, you need to be sure no files or statements set +``SRC_URI`` to use a ``defconfig`` other than your "in-tree" file (e.g. +a kernel's ``linux-``\ machine\ ``.inc`` file). In other words, if the +build system detects a statement that identifies an "out-of-tree" +``defconfig`` file, that statement will override your +``KBUILD_DEFCONFIG`` variable. + +See the +:term:`KBUILD_DEFCONFIG` +variable description for more information. + +Using ``devtool`` to Patch the Kernel +===================================== + +The steps in this procedure show you how you can patch the kernel using +the extensible SDK and ``devtool``. + +.. note:: + + Before attempting this procedure, be sure you have performed the + steps to get ready for updating the kernel as described in the " + Getting Ready to Develop Using + devtool + " section. + +Patching the kernel involves changing or adding configurations to an +existing kernel, changing or adding recipes to the kernel that are +needed to support specific hardware features, or even altering the +source code itself. + +This example creates a simple patch by adding some QEMU emulator console +output at boot time through ``printk`` statements in the kernel's +``calibrate.c`` source code file. Applying the patch and booting the +modified image causes the added messages to appear on the emulator's +console. The example is a continuation of the setup procedure found in +the ":ref:`kernel-dev/kernel-dev-common:getting ready to develop using \`\`devtool\`\``" Section. + +1. *Check Out the Kernel Source Files:* First you must use ``devtool`` + to checkout the kernel source code in its workspace. Be sure you are + in the terminal set up to do work with the extensible SDK. + + .. note:: + + See this + step + in the " + Getting Ready to Develop Using + devtool + " section for more information. + + Use the following ``devtool`` command to check out the code: + :: + + $ devtool modify linux-yocto + + .. note:: + + During the checkout operation, a bug exists that could cause + errors such as the following to appear: + :: + + ERROR: Taskhash mismatch 2c793438c2d9f8c3681fd5f7bc819efa versus + be3a89ce7c47178880ba7bf6293d7404 for + /path/to/esdk/layers/poky/meta/recipes-kernel/linux/linux-yocto_4.10.bb.do_unpack + + + You can safely ignore these messages. The source code is correctly + checked out. + +2. *Edit the Source Files* Follow these steps to make some simple + changes to the source files: + + 1. *Change the working directory*: In the previous step, the output + noted where you can find the source files (e.g. + ``~/poky_sdk/workspace/sources/linux-yocto``). Change to where the + kernel source code is before making your edits to the + ``calibrate.c`` file: + :: + + $ cd ~/poky_sdk/workspace/sources/linux-yocto + + 2. *Edit the source file*: Edit the ``init/calibrate.c`` file to have + the following changes: + :: + + void calibrate_delay(void) + { + unsigned long lpj; + static bool printed; + int this_cpu = smp_processor_id(); + + printk("*************************************\n"); + printk("* *\n"); + printk("* HELLO YOCTO KERNEL *\n"); + printk("* *\n"); + printk("*************************************\n"); + + if (per_cpu(cpu_loops_per_jiffy, this_cpu)) { + . + . + . + +3. *Build the Updated Kernel Source:* To build the updated kernel + source, use ``devtool``: + :: + + $ devtool build linux-yocto + +4. *Create the Image With the New Kernel:* Use the + ``devtool build-image`` command to create a new image that has the + new kernel. + + .. note:: + + If the image you originally created resulted in a Wic file, you + can use an alternate method to create the new image with the + updated kernel. For an example, see the steps in the + TipsAndTricks/KernelDevelopmentWithEsdk + Wiki Page. + + :: + + $ cd ~ + $ devtool build-image core-image-minimal + +5. *Test the New Image:* For this example, you can run the new image + using QEMU to verify your changes: + + 1. *Boot the image*: Boot the modified image in the QEMU emulator + using this command: + :: + + $ runqemu qemux86 + + 2. *Verify the changes*: Log into the machine using ``root`` with no + password and then use the following shell command to scroll + through the console's boot output. + :: + + # dmesg | less + + You should see + the results of your ``printk`` statements as part of the output + when you scroll down the console window. + +6. *Stage and commit your changes*: Within your eSDK terminal, change + your working directory to where you modified the ``calibrate.c`` file + and use these Git commands to stage and commit your changes: + :: + + $ cd ~/poky_sdk/workspace/sources/linux-yocto + $ git status + $ git add init/calibrate.c + $ git commit -m "calibrate: Add printk example" + +7. *Export the Patches and Create an Append File:* To export your + commits as patches and create a ``.bbappend`` file, use the following + command in the terminal used to work with the extensible SDK. This + example uses the previously established layer named ``meta-mylayer``. + + .. note:: + + See Step 3 of the " + Getting Ready to Develop Using devtool + " section for information on setting up this layer. + + $ devtool finish linux-yocto ~/meta-mylayer + + Once the command + finishes, the patches and the ``.bbappend`` file are located in the + ``~/meta-mylayer/recipes-kernel/linux`` directory. + +8. *Build the Image With Your Modified Kernel:* You can now build an + image that includes your kernel patches. Execute the following + command from your + :term:`Build Directory` in the terminal + set up to run BitBake: + :: + + $ cd ~/poky/build + $ bitbake core-image-minimal + +Using Traditional Kernel Development to Patch the Kernel +======================================================== + +The steps in this procedure show you how you can patch the kernel using +traditional kernel development (i.e. not using ``devtool`` and the +extensible SDK as described in the +":ref:`kernel-dev/kernel-dev-common:using \`\`devtool\`\` to patch the kernel`" +section). + +.. note:: + + Before attempting this procedure, be sure you have performed the + steps to get ready for updating the kernel as described in the " + Getting Ready for Traditional Kernel Development + " section. + +Patching the kernel involves changing or adding configurations to an +existing kernel, changing or adding recipes to the kernel that are +needed to support specific hardware features, or even altering the +source code itself. + +The example in this section creates a simple patch by adding some QEMU +emulator console output at boot time through ``printk`` statements in +the kernel's ``calibrate.c`` source code file. Applying the patch and +booting the modified image causes the added messages to appear on the +emulator's console. The example is a continuation of the setup procedure +found in the "`Getting Ready for Traditional Kernel +Development <#getting-ready-for-traditional-kernel-development>`__" +Section. + +1. *Edit the Source Files* Prior to this step, you should have used Git + to create a local copy of the repository for your kernel. Assuming + you created the repository as directed in the "`Getting Ready for + Traditional Kernel + Development <#getting-ready-for-traditional-kernel-development>`__" + section, use the following commands to edit the ``calibrate.c`` file: + + 1. *Change the working directory*: You need to locate the source + files in the local copy of the kernel Git repository: Change to + where the kernel source code is before making your edits to the + ``calibrate.c`` file: + :: + + $ cd ~/linux-yocto-4.12/init + + 2. *Edit the source file*: Edit the ``calibrate.c`` file to have the + following changes: + :: + + void calibrate_delay(void) + { + unsigned long lpj; + static bool printed; + int this_cpu = smp_processor_id(); + + printk("*************************************\n"); + printk("* *\n"); + printk("* HELLO YOCTO KERNEL *\n"); + printk("* *\n"); + printk("*************************************\n"); + + if (per_cpu(cpu_loops_per_jiffy, this_cpu)) { + . + . + . + +2. *Stage and Commit Your Changes:* Use standard Git commands to stage + and commit the changes you just made: + :: + + $ git add calibrate.c + $ git commit -m "calibrate.c - Added some printk statements" + + If you do not + stage and commit your changes, the OpenEmbedded Build System will not + pick up the changes. + +3. *Update Your local.conf File to Point to Your Source Files:* In + addition to your ``local.conf`` file specifying to use + "kernel-modules" and the "qemux86" machine, it must also point to the + updated kernel source files. Add + :term:`SRC_URI` and + :term:`SRCREV` statements similar + to the following to your ``local.conf``: + :: + + $ cd ~/poky/build/conf + + Add the following to the ``local.conf``: + :: + + SRC_URI_pn-linux-yocto = "git:///path-to/linux-yocto-4.12;protocol=file;name=machine;branch=standard/base; \ + git:///path-to/yocto-kernel-cache;protocol=file;type=kmeta;name=meta;branch=yocto-4.12;destsuffix=${KMETA}" + SRCREV_meta_qemux86 = "${AUTOREV}" + SRCREV_machine_qemux86 = "${AUTOREV}" + + .. note:: + + Be sure to replace + path-to + with the pathname to your local Git repositories. Also, you must + be sure to specify the correct branch and machine types. For this + example, the branch is + standard/base + and the machine is "qemux86". + +4. *Build the Image:* With the source modified, your changes staged and + committed, and the ``local.conf`` file pointing to the kernel files, + you can now use BitBake to build the image: + :: + + $ cd ~/poky/build + $ bitbake core-image-minimal + +5. *Boot the image*: Boot the modified image in the QEMU emulator using + this command. When prompted to login to the QEMU console, use "root" + with no password: + :: + + $ cd ~/poky/build + $ runqemu qemux86 + +6. *Look for Your Changes:* As QEMU booted, you might have seen your + changes rapidly scroll by. If not, use these commands to see your + changes: + :: + + # dmesg | less + + You should see the results of your + ``printk`` statements as part of the output when you scroll down the + console window. + +7. *Generate the Patch File:* Once you are sure that your patch works + correctly, you can generate a ``*.patch`` file in the kernel source + repository: + :: + + $ cd ~/linux-yocto-4.12/init + $ git format-patch -1 + 0001-calibrate.c-Added-some-printk-statements.patch + +8. *Move the Patch File to Your Layer:* In order for subsequent builds + to pick up patches, you need to move the patch file you created in + the previous step to your layer ``meta-mylayer``. For this example, + the layer created earlier is located in your home directory as + ``meta-mylayer``. When the layer was created using the + ``yocto-create`` script, no additional hierarchy was created to + support patches. Before moving the patch file, you need to add + additional structure to your layer using the following commands: + :: + + $ cd ~/meta-mylayer + $ mkdir recipes-kernel + $ mkdir recipes-kernel/linux + $ mkdir recipes-kernel/linux/linux-yocto + + Once you have created this + hierarchy in your layer, you can move the patch file using the + following command: + :: + + $ mv ~/linux-yocto-4.12/init/0001-calibrate.c-Added-some-printk-statements.patch ~/meta-mylayer/recipes-kernel/linux/linux-yocto + +9. *Create the Append File:* Finally, you need to create the + ``linux-yocto_4.12.bbappend`` file and insert statements that allow + the OpenEmbedded build system to find the patch. The append file + needs to be in your layer's ``recipes-kernel/linux`` directory and it + must be named ``linux-yocto_4.12.bbappend`` and have the following + contents: + :: + + FILESEXTRAPATHS_prepend := "${THISDIR}/${PN}:" + SRC_URI_append = "file://0001-calibrate.c-Added-some-printk-statements.patch" + + The :term:`FILESEXTRAPATHS` and :term:`SRC_URI` statements + enable the OpenEmbedded build system to find the patch file. + + For more information on append files and patches, see the "`Creating + the Append File <#creating-the-append-file>`__" and "`Applying + Patches <#applying-patches>`__" sections. You can also see the + ":ref:`dev-manual/dev-manual-common-tasks:using .bbappend files in your layer`" + section in the Yocto Project Development Tasks Manual. + + .. note:: + + To build + core-image-minimal + again and see the effects of your patch, you can essentially + eliminate the temporary source files saved in + poky/build/tmp/work/... + and residual effects of the build by entering the following + sequence of commands: + :: + + $ cd ~/poky/build + $ bitbake -c cleanall yocto-linux + $ bitbake core-image-minimal -c cleanall + $ bitbake core-image-minimal + $ runqemu qemux86 + + +Configuring the Kernel +====================== + +Configuring the Yocto Project kernel consists of making sure the +``.config`` file has all the right information in it for the image you +are building. You can use the ``menuconfig`` tool and configuration +fragments to make sure your ``.config`` file is just how you need it. +You can also save known configurations in a ``defconfig`` file that the +build system can use for kernel configuration. + +This section describes how to use ``menuconfig``, create and use +configuration fragments, and how to interactively modify your +``.config`` file to create the leanest kernel configuration file +possible. + +For more information on kernel configuration, see the "`Changing the +Configuration <#changing-the-configuration>`__" section. + +Using ``menuconfig`` +--------------------- + +The easiest way to define kernel configurations is to set them through +the ``menuconfig`` tool. This tool provides an interactive method with +which to set kernel configurations. For general information on +``menuconfig``, see http://en.wikipedia.org/wiki/Menuconfig. + +To use the ``menuconfig`` tool in the Yocto Project development +environment, you must do the following: + +- Because you launch ``menuconfig`` using BitBake, you must be sure to + set up your environment by running the + :ref:`structure-core-script` script found in + the :term:`Build Directory`. + +- You must be sure of the state of your build's configuration in the + :term:`Source Directory`. + +- Your build host must have the following two packages installed: + :: + + libncurses5-dev + libtinfo-dev + +The following commands initialize the BitBake environment, run the +:ref:`ref-tasks-kernel_configme` +task, and launch ``menuconfig``. These commands assume the Source +Directory's top-level folder is ``~/poky``: +:: + + $ cd poky + $ source oe-init-build-env + $ bitbake linux-yocto -c kernel_configme -f + $ bitbake linux-yocto -c menuconfig + +Once ``menuconfig`` comes up, its standard +interface allows you to interactively examine and configure all the +kernel configuration parameters. After making your changes, simply exit +the tool and save your changes to create an updated version of the +``.config`` configuration file. + +.. note:: + + You can use the entire + .config + file as the + defconfig + file. For information on + defconfig + files, see the " + Changing the Configuration + ", " + Using an In-Tree + defconfig + File + , and " + Creating a + defconfig + File + " sections. + +Consider an example that configures the "CONFIG_SMP" setting for the +``linux-yocto-4.12`` kernel. + +.. note:: + + The OpenEmbedded build system recognizes this kernel as + linux-yocto + through Metadata (e.g. + PREFERRED_VERSION + \_linux-yocto ?= "12.4%" + ). + +Once ``menuconfig`` launches, use the interface to navigate through the +selections to find the configuration settings in which you are +interested. For this example, you deselect "CONFIG_SMP" by clearing the +"Symmetric Multi-Processing Support" option. Using the interface, you +can find the option under "Processor Type and Features". To deselect +"CONFIG_SMP", use the arrow keys to highlight "Symmetric +Multi-Processing Support" and enter "N" to clear the asterisk. When you +are finished, exit out and save the change. + +Saving the selections updates the ``.config`` configuration file. This +is the file that the OpenEmbedded build system uses to configure the +kernel during the build. You can find and examine this file in the Build +Directory in ``tmp/work/``. The actual ``.config`` is located in the +area where the specific kernel is built. For example, if you were +building a Linux Yocto kernel based on the ``linux-yocto-4.12`` kernel +and you were building a QEMU image targeted for ``x86`` architecture, +the ``.config`` file would be: +:: + + poky/build/tmp/work/qemux86-poky-linux/linux-yocto/4.12.12+gitAUTOINC+eda4d18... + ...967-r0/linux-qemux86-standard-build/.config + +.. note:: + + The previous example directory is artificially split and many of the + characters in the actual filename are omitted in order to make it + more readable. Also, depending on the kernel you are using, the exact + pathname might differ. + +Within the ``.config`` file, you can see the kernel settings. For +example, the following entry shows that symmetric multi-processor +support is not set: +:: + + # CONFIG_SMP is not set + +A good method to isolate changed configurations is to use a combination +of the ``menuconfig`` tool and simple shell commands. Before changing +configurations with ``menuconfig``, copy the existing ``.config`` and +rename it to something else, use ``menuconfig`` to make as many changes +as you want and save them, then compare the renamed configuration file +against the newly created file. You can use the resulting differences as +your base to create configuration fragments to permanently save in your +kernel layer. + +.. note:: + + Be sure to make a copy of the + .config + file and do not just rename it. The build system needs an existing + .config + file from which to work. + +Creating a ``defconfig`` File +------------------------------ + +A ``defconfig`` file in the context of the Yocto Project is often a +``.config`` file that is copied from a build or a ``defconfig`` taken +from the kernel tree and moved into recipe space. You can use a +``defconfig`` file to retain a known set of kernel configurations from +which the OpenEmbedded build system can draw to create the final +``.config`` file. + +.. note:: + + Out-of-the-box, the Yocto Project never ships a + defconfig + or + .config + file. The OpenEmbedded build system creates the final + .config + file used to configure the kernel. + +To create a ``defconfig``, start with a complete, working Linux kernel +``.config`` file. Copy that file to the appropriate +``${``\ :term:`PN`\ ``}`` directory in +your layer's ``recipes-kernel/linux`` directory, and rename the copied +file to "defconfig" (e.g. +``~/meta-mylayer/recipes-kernel/linux/linux-yocto/defconfig``). Then, +add the following lines to the linux-yocto ``.bbappend`` file in your +layer: +:: + + FILESEXTRAPATHS_prepend := "${THISDIR}/${PN}:" + SRC_URI += "file://defconfig" + +The :term:`SRC_URI` tells the build system how to search for the file, while the +:term:`FILESEXTRAPATHS` extends the :term:`FILESPATH` +variable (search directories) to include the ``${PN}`` directory you +created to hold the configuration changes. + +.. note:: + + The build system applies the configurations from the + defconfig + file before applying any subsequent configuration fragments. The + final kernel configuration is a combination of the configurations in + the + defconfig + file and any configuration fragments you provide. You need to realize + that if you have any configuration fragments, the build system + applies these on top of and after applying the existing defconfig + file configurations. + +For more information on configuring the kernel, see the "`Changing the +Configuration <#changing-the-configuration>`__" section. + +.. _creating-config-fragments: + +Creating Configuration Fragments +-------------------------------- + +Configuration fragments are simply kernel options that appear in a file +placed where the OpenEmbedded build system can find and apply them. The +build system applies configuration fragments after applying +configurations from a ``defconfig`` file. Thus, the final kernel +configuration is a combination of the configurations in the +``defconfig`` file and then any configuration fragments you provide. The +build system applies fragments on top of and after applying the existing +defconfig file configurations. + +Syntactically, the configuration statement is identical to what would +appear in the ``.config`` file, which is in the :term:`Build Directory`. + +.. note:: + + For more information about where the + .config + file is located, see the example in the + ":ref:`kernel-dev/kernel-dev-common:using \`\`menuconfig\`\``" + section. + +It is simple to create a configuration fragment. One method is to use +shell commands. For example, issuing the following from the shell +creates a configuration fragment file named ``my_smp.cfg`` that enables +multi-processor support within the kernel: +:: + + $ echo "CONFIG_SMP=y" >> my_smp.cfg + +.. note:: + + All configuration fragment files must use the + .cfg + extension in order for the OpenEmbedded build system to recognize + them as a configuration fragment. + +Another method is to create a configuration fragment using the +differences between two configuration files: one previously created and +saved, and one freshly created using the ``menuconfig`` tool. + +To create a configuration fragment using this method, follow these +steps: + +1. *Complete a Build Through Kernel Configuration:* Complete a build at + least through the kernel configuration task as follows: + :: + + $ bitbake linux-yocto -c kernel_configme -f + + This step ensures that you create a + ``.config`` file from a known state. Because situations exist where + your build state might become unknown, it is best to run this task + prior to starting ``menuconfig``. + +2. *Launch menuconfig:* Run the ``menuconfig`` command: + :: + + $ bitbake linux-yocto -c menuconfig + +3. *Create the Configuration Fragment:* Run the ``diffconfig`` command + to prepare a configuration fragment. The resulting file + ``fragment.cfg`` is placed in the + ``${``\ :term:`WORKDIR`\ ``}`` + directory: + :: + + $ bitbake linux-yocto -c diffconfig + +The ``diffconfig`` command creates a file that is a list of Linux kernel +``CONFIG_`` assignments. See the "`Changing the +Configuration <#changing-the-configuration>`__" section for additional +information on how to use the output as a configuration fragment. + +.. note:: + + You can also use this method to create configuration fragments for a + BSP. See the " + BSP Descriptions + " section for more information. + +Where do you put your configuration fragment files? You can place these +files in an area pointed to by +:term:`SRC_URI` as directed by your +``bblayers.conf`` file, which is located in your layer. The OpenEmbedded +build system picks up the configuration and adds it to the kernel's +configuration. For example, suppose you had a set of configuration +options in a file called ``myconfig.cfg``. If you put that file inside a +directory named ``linux-yocto`` that resides in the same directory as +the kernel's append file within your layer and then add the following +statements to the kernel's append file, those configuration options will +be picked up and applied when the kernel is built: +:: + + FILESEXTRAPATHS_prepend := "${THISDIR}/${PN}:" + SRC_URI += "file://myconfig.cfg" + +As mentioned earlier, you can group related configurations into multiple +files and name them all in the ``SRC_URI`` statement as well. For +example, you could group separate configurations specifically for +Ethernet and graphics into their own files and add those by using a +``SRC_URI`` statement like the following in your append file: +:: + + SRC_URI += "file://myconfig.cfg \ + file://eth.cfg \ + file://gfx.cfg" + +Validating Configuration +------------------------ + +You can use the +:ref:`ref-tasks-kernel_configcheck` +task to provide configuration validation: +:: + + $ bitbake linux-yocto -c kernel_configcheck -f + +Running this task produces warnings for when a +requested configuration does not appear in the final ``.config`` file or +when you override a policy configuration in a hardware configuration +fragment. + +In order to run this task, you must have an existing ``.config`` file. +See the ":ref:`kernel-dev/kernel-dev-common:using \`\`menuconfig\`\``" section for +information on how to create a configuration file. + +Following is sample output from the ``do_kernel_configcheck`` task: +:: + + Loading cache: 100% |########################################################| Time: 0:00:00 + Loaded 1275 entries from dependency cache. + NOTE: Resolving any missing task queue dependencies + + Build Configuration: + . + . + . + + NOTE: Executing SetScene Tasks + NOTE: Executing RunQueue Tasks + WARNING: linux-yocto-4.12.12+gitAUTOINC+eda4d18ce4_16de014967-r0 do_kernel_configcheck: + [kernel config]: specified values did not make it into the kernel's final configuration: + + ---------- CONFIG_X86_TSC ----------------- + Config: CONFIG_X86_TSC + From: /home/scottrif/poky/build/tmp/work-shared/qemux86/kernel-source/.kernel-meta/configs/standard/bsp/common-pc/common-pc-cpu.cfg + Requested value: CONFIG_X86_TSC=y + Actual value: + + + ---------- CONFIG_X86_BIGSMP ----------------- + Config: CONFIG_X86_BIGSMP + From: /home/scottrif/poky/build/tmp/work-shared/qemux86/kernel-source/.kernel-meta/configs/standard/cfg/smp.cfg + /home/scottrif/poky/build/tmp/work-shared/qemux86/kernel-source/.kernel-meta/configs/standard/defconfig + Requested value: # CONFIG_X86_BIGSMP is not set + Actual value: + + + ---------- CONFIG_NR_CPUS ----------------- + Config: CONFIG_NR_CPUS + From: /home/scottrif/poky/build/tmp/work-shared/qemux86/kernel-source/.kernel-meta/configs/standard/cfg/smp.cfg + /home/scottrif/poky/build/tmp/work-shared/qemux86/kernel-source/.kernel-meta/configs/standard/bsp/common-pc/common-pc.cfg + /home/scottrif/poky/build/tmp/work-shared/qemux86/kernel-source/.kernel-meta/configs/standard/defconfig + Requested value: CONFIG_NR_CPUS=8 + Actual value: CONFIG_NR_CPUS=1 + + + ---------- CONFIG_SCHED_SMT ----------------- + Config: CONFIG_SCHED_SMT + From: /home/scottrif/poky/build/tmp/work-shared/qemux86/kernel-source/.kernel-meta/configs/standard/cfg/smp.cfg + /home/scottrif/poky/build/tmp/work-shared/qemux86/kernel-source/.kernel-meta/configs/standard/defconfig + Requested value: CONFIG_SCHED_SMT=y + Actual value: + + + + NOTE: Tasks Summary: Attempted 288 tasks of which 285 didn't need to be rerun and all succeeded. + + Summary: There were 3 WARNING messages shown. + +.. note:: + + The previous output example has artificial line breaks to make it + more readable. + +The output describes the various problems that you can encounter along +with where to find the offending configuration items. You can use the +information in the logs to adjust your configuration files and then +repeat the +:ref:`ref-tasks-kernel_configme` +and +:ref:`ref-tasks-kernel_configcheck` +tasks until they produce no warnings. + +For more information on how to use the ``menuconfig`` tool, see the +:ref:`kernel-dev/kernel-dev-common:using \`\`menuconfig\`\`` section. + +Fine-Tuning the Kernel Configuration File +----------------------------------------- + +You can make sure the ``.config`` file is as lean or efficient as +possible by reading the output of the kernel configuration fragment +audit, noting any issues, making changes to correct the issues, and then +repeating. + +As part of the kernel build process, the ``do_kernel_configcheck`` task +runs. This task validates the kernel configuration by checking the final +``.config`` file against the input files. During the check, the task +produces warning messages for the following issues: + +- Requested options that did not make the final ``.config`` file. + +- Configuration items that appear twice in the same configuration + fragment. + +- Configuration items tagged as "required" that were overridden. + +- A board overrides a non-board specific option. + +- Listed options not valid for the kernel being processed. In other + words, the option does not appear anywhere. + +.. note:: + + The + do_kernel_configcheck + task can also optionally report if an option is overridden during + processing. + +For each output warning, a message points to the file that contains a +list of the options and a pointer to the configuration fragment that +defines them. Collectively, the files are the key to streamlining the +configuration. + +To streamline the configuration, do the following: + +1. *Use a Working Configuration:* Start with a full configuration that + you know works. Be sure the configuration builds and boots + successfully. Use this configuration file as your baseline. + +2. *Run Configure and Check Tasks:* Separately run the + ``do_kernel_configme`` and ``do_kernel_configcheck`` tasks: + :: + + $ bitbake linux-yocto -c kernel_configme -f + $ bitbake linux-yocto -c kernel_configcheck -f + +3. *Process the Results:* Take the resulting list of files from the + ``do_kernel_configcheck`` task warnings and do the following: + + - Drop values that are redefined in the fragment but do not change + the final ``.config`` file. + + - Analyze and potentially drop values from the ``.config`` file that + override required configurations. + + - Analyze and potentially remove non-board specific options. + + - Remove repeated and invalid options. + +4. *Re-Run Configure and Check Tasks:* After you have worked through the + output of the kernel configuration audit, you can re-run the + ``do_kernel_configme`` and ``do_kernel_configcheck`` tasks to see the + results of your changes. If you have more issues, you can deal with + them as described in the previous step. + +Iteratively working through steps two through four eventually yields a +minimal, streamlined configuration file. Once you have the best +``.config``, you can build the Linux Yocto kernel. + +Expanding Variables +=================== + +Sometimes it is helpful to determine what a variable expands to during a +build. You can do examine the values of variables by examining the +output of the ``bitbake -e`` command. The output is long and is more +easily managed in a text file, which allows for easy searches: +:: + + $ bitbake -e virtual/kernel > some_text_file + +Within the text file, you can see +exactly how each variable is expanded and used by the OpenEmbedded build +system. + +Working with a "Dirty" Kernel Version String +============================================ + +If you build a kernel image and the version string has a "+" or a +"-dirty" at the end, uncommitted modifications exist in the kernel's +source directory. Follow these steps to clean up the version string: + +1. *Discover the Uncommitted Changes:* Go to the kernel's locally cloned + Git repository (source directory) and use the following Git command + to list the files that have been changed, added, or removed: + :: + + $ git status + +2. *Commit the Changes:* You should commit those changes to the kernel + source tree regardless of whether or not you will save, export, or + use the changes: + :: + + $ git add + $ git commit -s -a -m "getting rid of -dirty" + +3. *Rebuild the Kernel Image:* Once you commit the changes, rebuild the + kernel. + + Depending on your particular kernel development workflow, the + commands you use to rebuild the kernel might differ. For information + on building the kernel image when using ``devtool``, see the + ":ref:`kernel-dev/kernel-dev-common:using \`\`devtool\`\` to patch the kernel`" + section. For + information on building the kernel image when using Bitbake, see the + "`Using Traditional Kernel Development to Patch the + Kernel <#using-traditional-kernel-development-to-patch-the-kernel>`__" + section. + +Working With Your Own Sources +============================= + +If you cannot work with one of the Linux kernel versions supported by +existing linux-yocto recipes, you can still make use of the Yocto +Project Linux kernel tooling by working with your own sources. When you +use your own sources, you will not be able to leverage the existing +kernel :term:`Metadata` and stabilization +work of the linux-yocto sources. However, you will be able to manage +your own Metadata in the same format as the linux-yocto sources. +Maintaining format compatibility facilitates converging with linux-yocto +on a future, mutually-supported kernel version. + +To help you use your own sources, the Yocto Project provides a +linux-yocto custom recipe (``linux-yocto-custom.bb``) that uses +``kernel.org`` sources and the Yocto Project Linux kernel tools for +managing kernel Metadata. You can find this recipe in the ``poky`` Git +repository of the Yocto Project :yocto_git:`Source Repository <>` +at: +:: + + poky/meta-skeleton/recipes-kernel/linux/linux-yocto-custom.bb + +Here are some basic steps you can use to work with your own sources: + +1. *Create a Copy of the Kernel Recipe:* Copy the + ``linux-yocto-custom.bb`` recipe to your layer and give it a + meaningful name. The name should include the version of the Yocto + Linux kernel you are using (e.g. ``linux-yocto-myproject_4.12.bb``, + where "4.12" is the base version of the Linux kernel with which you + would be working). + +2. *Create a Directory for Your Patches:* In the same directory inside + your layer, create a matching directory to store your patches and + configuration files (e.g. ``linux-yocto-myproject``). + +3. *Ensure You Have Configurations:* Make sure you have either a + ``defconfig`` file or configuration fragment files in your layer. + When you use the ``linux-yocto-custom.bb`` recipe, you must specify a + configuration. If you do not have a ``defconfig`` file, you can run + the following: + :: + + $ make defconfig + + After running the command, copy the + resulting ``.config`` file to the ``files`` directory in your layer + as "defconfig" and then add it to the + :term:`SRC_URI` variable in the + recipe. + + Running the ``make defconfig`` command results in the default + configuration for your architecture as defined by your kernel. + However, no guarantee exists that this configuration is valid for + your use case, or that your board will even boot. This is + particularly true for non-x86 architectures. + + To use non-x86 ``defconfig`` files, you need to be more specific and + find one that matches your board (i.e. for arm, you look in + ``arch/arm/configs`` and use the one that is the best starting point + for your board). + +4. *Edit the Recipe:* Edit the following variables in your recipe as + appropriate for your project: + + - :term:`SRC_URI`: The + ``SRC_URI`` should specify a Git repository that uses one of the + supported Git fetcher protocols (i.e. ``file``, ``git``, ``http``, + and so forth). The ``SRC_URI`` variable should also specify either + a ``defconfig`` file or some configuration fragment files. The + skeleton recipe provides an example ``SRC_URI`` as a syntax + reference. + + - :term:`LINUX_VERSION`: + The Linux kernel version you are using (e.g. "4.12"). + + - :term:`LINUX_VERSION_EXTENSION`: + The Linux kernel ``CONFIG_LOCALVERSION`` that is compiled into the + resulting kernel and visible through the ``uname`` command. + + - :term:`SRCREV`: The commit ID + from which you want to build. + + - :term:`PR`: Treat this variable the + same as you would in any other recipe. Increment the variable to + indicate to the OpenEmbedded build system that the recipe has + changed. + + - :term:`PV`: The default ``PV`` + assignment is typically adequate. It combines the + ``LINUX_VERSION`` with the Source Control Manager (SCM) revision + as derived from the :term:`SRCPV` + variable. The combined results are a string with the following + form: + 3.19.11+git1+68a635bf8dfb64b02263c1ac80c948647cc76d5f_1+218bd8d2022b9852c60d32f0d770931e3cf343e2 + While lengthy, the extra verbosity in ``PV`` helps ensure you are + using the exact sources from which you intend to build. + + - :term:`COMPATIBLE_MACHINE`: + A list of the machines supported by your new recipe. This variable + in the example recipe is set by default to a regular expression + that matches only the empty string, "(^$)". This default setting + triggers an explicit build failure. You must change it to match a + list of the machines that your new recipe supports. For example, + to support the ``qemux86`` and ``qemux86-64`` machines, use the + following form: COMPATIBLE_MACHINE = "qemux86|qemux86-64" + +5. *Customize Your Recipe as Needed:* Provide further customizations to + your recipe as needed just as you would customize an existing + linux-yocto recipe. See the "`Modifying an Existing + Recipe <#modifying-an-existing-recipe>`__" section for information. + +Working with Out-of-Tree Modules +================================ + +This section describes steps to build out-of-tree modules on your target +and describes how to incorporate out-of-tree modules in the build. + +Building Out-of-Tree Modules on the Target +------------------------------------------ + +While the traditional Yocto Project development model would be to +include kernel modules as part of the normal build process, you might +find it useful to build modules on the target. This could be the case if +your target system is capable and powerful enough to handle the +necessary compilation. Before deciding to build on your target, however, +you should consider the benefits of using a proper cross-development +environment from your build host. + +If you want to be able to build out-of-tree modules on the target, there +are some steps you need to take on the target that is running your SDK +image. Briefly, the ``kernel-dev`` package is installed by default on +all ``*.sdk`` images and the ``kernel-devsrc`` package is installed on +many of the ``*.sdk`` images. However, you need to create some scripts +prior to attempting to build the out-of-tree modules on the target that +is running that image. + +Prior to attempting to build the out-of-tree modules, you need to be on +the target as root and you need to change to the ``/usr/src/kernel`` +directory. Next, ``make`` the scripts: +:: + + # cd /usr/src/kernel + # make scripts + +Because all SDK image recipes include ``dev-pkgs``, the +``kernel-dev`` packages will be installed as part of the SDK image and +the ``kernel-devsrc`` packages will be installed as part of applicable +SDK images. The SDK uses the scripts when building out-of-tree modules. +Once you have switched to that directory and created the scripts, you +should be able to build your out-of-tree modules on the target. + +Incorporating Out-of-Tree Modules +--------------------------------- + +While it is always preferable to work with sources integrated into the +Linux kernel sources, if you need an external kernel module, the +``hello-mod.bb`` recipe is available as a template from which you can +create your own out-of-tree Linux kernel module recipe. + +This template recipe is located in the ``poky`` Git repository of the +Yocto Project :yocto_git:`Source Repository <>` at: +:: + + poky/meta-skeleton/recipes-kernel/hello-mod/hello-mod_0.1.bb + +To get started, copy this recipe to your layer and give it a meaningful +name (e.g. ``mymodule_1.0.bb``). In the same directory, create a new +directory named ``files`` where you can store any source files, patches, +or other files necessary for building the module that do not come with +the sources. Finally, update the recipe as needed for the module. +Typically, you will need to set the following variables: + +- :term:`DESCRIPTION` + +- :term:`LICENSE* <LICENSE>` + +- :term:`SRC_URI` + +- :term:`PV` + +Depending on the build system used by the module sources, you might need +to make some adjustments. For example, a typical module ``Makefile`` +looks much like the one provided with the ``hello-mod`` template: +:: + + obj-m := hello.o + + SRC := $(shell pwd) + + all: + $(MAKE) -C $(KERNEL_SRC) M=$(SRC) + + modules_install: + $(MAKE) -C $(KERNEL_SRC) M=$(SRC) modules_install + ... + +The important point to note here is the :term:`KERNEL_SRC` variable. The +:ref:`module <ref-classes-module>` class sets this variable and the +:term:`KERNEL_PATH` variable to +``${STAGING_KERNEL_DIR}`` with the necessary Linux kernel build +information to build modules. If your module ``Makefile`` uses a +different variable, you might want to override the +:ref:`ref-tasks-compile` step, or +create a patch to the ``Makefile`` to work with the more typical +``KERNEL_SRC`` or ``KERNEL_PATH`` variables. + +After you have prepared your recipe, you will likely want to include the +module in your images. To do this, see the documentation for the +following variables in the Yocto Project Reference Manual and set one of +them appropriately for your machine configuration file: + +- :term:`MACHINE_ESSENTIAL_EXTRA_RDEPENDS` + +- :term:`MACHINE_ESSENTIAL_EXTRA_RRECOMMENDS` + +- :term:`MACHINE_EXTRA_RDEPENDS` + +- :term:`MACHINE_EXTRA_RRECOMMENDS` + +Modules are often not required for boot and can be excluded from certain +build configurations. The following allows for the most flexibility: +:: + + MACHINE_EXTRA_RRECOMMENDS += "kernel-module-mymodule" + +The value is +derived by appending the module filename without the ``.ko`` extension +to the string "kernel-module-". + +Because the variable is +:term:`RRECOMMENDS` and not a +:term:`RDEPENDS` variable, the build +will not fail if this module is not available to include in the image. + +Inspecting Changes and Commits +============================== + +A common question when working with a kernel is: "What changes have been +applied to this tree?" Rather than using "grep" across directories to +see what has changed, you can use Git to inspect or search the kernel +tree. Using Git is an efficient way to see what has changed in the tree. + +What Changed in a Kernel? +------------------------- + +Following are a few examples that show how to use Git commands to +examine changes. These examples are by no means the only way to see +changes. + +.. note:: + + In the following examples, unless you provide a commit range, + kernel.org + history is blended with Yocto Project kernel changes. You can form + ranges by using branch names from the kernel tree as the upper and + lower commit markers with the Git commands. You can see the branch + names through the web interface to the Yocto Project source + repositories at + . + +To see a full range of the changes, use the ``git whatchanged`` command +and specify a commit range for the branch (commit\ ``..``\ commit). + +Here is an example that looks at what has changed in the ``emenlow`` +branch of the ``linux-yocto-3.19`` kernel. The lower commit range is the +commit associated with the ``standard/base`` branch, while the upper +commit range is the commit associated with the ``standard/emenlow`` +branch. +:: + + $ git whatchanged origin/standard/base..origin/standard/emenlow + +To see short, one line summaries of changes use the ``git log`` command: +:: + + $ git log --oneline origin/standard/base..origin/standard/emenlow + +Use this command to see code differences for the changes: +:: + + $ git diff origin/standard/base..origin/standard/emenlow + +Use this command to see the commit log messages and the text +differences: +:: + + $ git show origin/standard/base..origin/standard/emenlow + +Use this command to create individual patches for each change. Here is +an example that that creates patch files for each commit and places them +in your ``Documents`` directory: +:: + + $ git format-patch -o $HOME/Documents origin/standard/base..origin/standard/emenlow + +Showing a Particular Feature or Branch Change +--------------------------------------------- + +Tags in the Yocto Project kernel tree divide changes for significant +features or branches. The ``git show`` tag command shows changes based +on a tag. Here is an example that shows ``systemtap`` changes: +:: + + $ git show systemtap + +You can use the ``git branch --contains`` tag command to +show the branches that contain a particular feature. This command shows +the branches that contain the ``systemtap`` feature: +:: + + $ git branch --contains systemtap + +Adding Recipe-Space Kernel Features +=================================== + +You can add kernel features in the +`recipe-space <#recipe-space-metadata>`__ by using the +:term:`KERNEL_FEATURES` +variable and by specifying the feature's ``.scc`` file path in the +:term:`SRC_URI` statement. When you +add features using this method, the OpenEmbedded build system checks to +be sure the features are present. If the features are not present, the +build stops. Kernel features are the last elements processed for +configuring and patching the kernel. Therefore, adding features in this +manner is a way to enforce specific features are present and enabled +without needing to do a full audit of any other layer's additions to the +``SRC_URI`` statement. + +You add a kernel feature by providing the feature as part of the +``KERNEL_FEATURES`` variable and by providing the path to the feature's +``.scc`` file, which is relative to the root of the kernel Metadata. The +OpenEmbedded build system searches all forms of kernel Metadata on the +``SRC_URI`` statement regardless of whether the Metadata is in the +"kernel-cache", system kernel Metadata, or a recipe-space Metadata (i.e. +part of the kernel recipe). See the "`Kernel Metadata +Location <#kernel-metadata-location>`__" section for additional +information. + +When you specify the feature's ``.scc`` file on the ``SRC_URI`` +statement, the OpenEmbedded build system adds the directory of that +``.scc`` file along with all its subdirectories to the kernel feature +search path. Because subdirectories are searched, you can reference a +single ``.scc`` file in the ``SRC_URI`` statement to reference multiple +kernel features. + +Consider the following example that adds the "test.scc" feature to the +build. + +1. *Create the Feature File:* Create a ``.scc`` file and locate it just + as you would any other patch file, ``.cfg`` file, or fetcher item you + specify in the ``SRC_URI`` statement. + + .. note:: + + - You must add the directory of the ``.scc`` file to the + fetcher's search path in the same manner as you would add a + ``.patch`` file. + + - You can create additional ``.scc`` files beneath the directory + that contains the file you are adding. All subdirectories are + searched during the build as potential feature directories. + + Continuing with the example, suppose the "test.scc" feature you are + adding has a ``test.scc`` file in the following directory: + :: + + my_recipe + | + +-linux-yocto + | + +-test.cfg + +-test.scc + + In this example, the + ``linux-yocto`` directory has both the feature ``test.scc`` file and + a similarly named configuration fragment file ``test.cfg``. + +2. *Add the Feature File to SRC_URI:* Add the ``.scc`` file to the + recipe's ``SRC_URI`` statement: + :: + + SRC_URI_append = " file://test.scc" + + The leading space before the path is important as the path is + appended to the existing path. + +3. *Specify the Feature as a Kernel Feature:* Use the + ``KERNEL_FEATURES`` statement to specify the feature as a kernel + feature: + :: + + KERNEL_FEATURES_append = " test.scc" + + The OpenEmbedded build + system processes the kernel feature when it builds the kernel. + + .. note:: + + If other features are contained below "test.scc", then their + directories are relative to the directory containing the + test.scc + file. |