| .. SPDX-License-Identifier: CC-BY-SA-2.0-UK |
| |
| ************ |
| Common Tasks |
| ************ |
| |
| This chapter describes fundamental procedures such as creating layers, |
| adding new software packages, extending or customizing images, porting |
| work to new hardware (adding a new machine), and so forth. You will find |
| that the procedures documented here occur often in the development cycle |
| using the Yocto Project. |
| |
| Understanding and Creating Layers |
| ================================= |
| |
| The OpenEmbedded build system supports organizing |
| :term:`Metadata` into multiple layers. |
| Layers allow you to isolate different types of customizations from each |
| other. For introductory information on the Yocto Project Layer Model, |
| see the |
| ":ref:`overview-manual/yp-intro:the yocto project layer model`" |
| section in the Yocto Project Overview and Concepts Manual. |
| |
| Creating Your Own Layer |
| ----------------------- |
| |
| .. note:: |
| |
| It is very easy to create your own layers to use with the OpenEmbedded |
| build system, as the Yocto Project ships with tools that speed up creating |
| layers. This section describes the steps you perform by hand to create |
| layers so that you can better understand them. For information about the |
| layer-creation tools, see the |
| ":ref:`bsp-guide/bsp:creating a new bsp layer using the \`\`bitbake-layers\`\` script`" |
| section in the Yocto Project Board Support Package (BSP) Developer's |
| Guide and the ":ref:`dev-manual/common-tasks:creating a general layer using the \`\`bitbake-layers\`\` script`" |
| section further down in this manual. |
| |
| Follow these general steps to create your layer without using tools: |
| |
| 1. *Check Existing Layers:* Before creating a new layer, you should be |
| sure someone has not already created a layer containing the Metadata |
| you need. You can see the :oe_layerindex:`OpenEmbedded Metadata Index <>` |
| for a list of layers from the OpenEmbedded community that can be used in |
| the Yocto Project. You could find a layer that is identical or close |
| to what you need. |
| |
| 2. *Create a Directory:* Create the directory for your layer. When you |
| create the layer, be sure to create the directory in an area not |
| associated with the Yocto Project :term:`Source Directory` |
| (e.g. the cloned ``poky`` repository). |
| |
| While not strictly required, prepend the name of the directory with |
| the string "meta-". For example:: |
| |
| meta-mylayer |
| meta-GUI_xyz |
| meta-mymachine |
| |
| With rare exceptions, a layer's name follows this form:: |
| |
| meta-root_name |
| |
| Following this layer naming convention can save |
| you trouble later when tools, components, or variables "assume" your |
| layer name begins with "meta-". A notable example is in configuration |
| files as shown in the following step where layer names without the |
| "meta-" string are appended to several variables used in the |
| configuration. |
| |
| 3. *Create a Layer Configuration File:* Inside your new layer folder, |
| you need to create a ``conf/layer.conf`` file. It is easiest to take |
| an existing layer configuration file and copy that to your layer's |
| ``conf`` directory and then modify the file as needed. |
| |
| The ``meta-yocto-bsp/conf/layer.conf`` file in the Yocto Project |
| :yocto_git:`Source Repositories </poky/tree/meta-yocto-bsp/conf>` |
| demonstrates the required syntax. For your layer, you need to replace |
| "yoctobsp" with a unique identifier for your layer (e.g. "machinexyz" |
| for a layer named "meta-machinexyz"):: |
| |
| # We have a conf and classes directory, add to BBPATH |
| BBPATH .= ":${LAYERDIR}" |
| |
| # We have recipes-* directories, add to BBFILES |
| BBFILES += "${LAYERDIR}/recipes-*/*/*.bb \ |
| ${LAYERDIR}/recipes-*/*/*.bbappend" |
| |
| BBFILE_COLLECTIONS += "yoctobsp" |
| BBFILE_PATTERN_yoctobsp = "^${LAYERDIR}/" |
| BBFILE_PRIORITY_yoctobsp = "5" |
| LAYERVERSION_yoctobsp = "4" |
| LAYERSERIES_COMPAT_yoctobsp = "dunfell" |
| |
| Following is an explanation of the layer configuration file: |
| |
| - :term:`BBPATH`: Adds the layer's |
| root directory to BitBake's search path. Through the use of the |
| :term:`BBPATH` variable, BitBake locates class files (``.bbclass``), |
| configuration files, and files that are included with ``include`` |
| and ``require`` statements. For these cases, BitBake uses the |
| first file that matches the name found in :term:`BBPATH`. This is |
| similar to the way the ``PATH`` variable is used for binaries. It |
| is recommended, therefore, that you use unique class and |
| configuration filenames in your custom layer. |
| |
| - :term:`BBFILES`: Defines the |
| location for all recipes in the layer. |
| |
| - :term:`BBFILE_COLLECTIONS`: |
| Establishes the current layer through a unique identifier that is |
| used throughout the OpenEmbedded build system to refer to the |
| layer. In this example, the identifier "yoctobsp" is the |
| representation for the container layer named "meta-yocto-bsp". |
| |
| - :term:`BBFILE_PATTERN`: |
| Expands immediately during parsing to provide the directory of the |
| layer. |
| |
| - :term:`BBFILE_PRIORITY`: |
| Establishes a priority to use for recipes in the layer when the |
| OpenEmbedded build finds recipes of the same name in different |
| layers. |
| |
| - :term:`LAYERVERSION`: |
| Establishes a version number for the layer. You can use this |
| version number to specify this exact version of the layer as a |
| dependency when using the |
| :term:`LAYERDEPENDS` |
| variable. |
| |
| - :term:`LAYERDEPENDS`: |
| Lists all layers on which this layer depends (if any). |
| |
| - :term:`LAYERSERIES_COMPAT`: |
| Lists the :yocto_wiki:`Yocto Project </Releases>` |
| releases for which the current version is compatible. This |
| variable is a good way to indicate if your particular layer is |
| current. |
| |
| 4. *Add Content:* Depending on the type of layer, add the content. If |
| the layer adds support for a machine, add the machine configuration |
| in a ``conf/machine/`` file within the layer. If the layer adds |
| distro policy, add the distro configuration in a ``conf/distro/`` |
| file within the layer. If the layer introduces new recipes, put the |
| recipes you need in ``recipes-*`` subdirectories within the layer. |
| |
| .. note:: |
| |
| For an explanation of layer hierarchy that is compliant with the |
| Yocto Project, see the ":ref:`bsp-guide/bsp:example filesystem layout`" |
| section in the Yocto Project Board Support Package (BSP) Developer's Guide. |
| |
| 5. *Optionally Test for Compatibility:* If you want permission to use |
| the Yocto Project Compatibility logo with your layer or application |
| that uses your layer, perform the steps to apply for compatibility. |
| See the |
| ":ref:`dev-manual/common-tasks:making sure your layer is compatible with yocto project`" |
| section for more information. |
| |
| Following Best Practices When Creating Layers |
| --------------------------------------------- |
| |
| To create layers that are easier to maintain and that will not impact |
| builds for other machines, you should consider the information in the |
| following list: |
| |
| - *Avoid "Overlaying" Entire Recipes from Other Layers in Your |
| Configuration:* In other words, do not copy an entire recipe into |
| your layer and then modify it. Rather, use an append file |
| (``.bbappend``) to override only those parts of the original recipe |
| you need to modify. |
| |
| - *Avoid Duplicating Include Files:* Use append files (``.bbappend``) |
| for each recipe that uses an include file. Or, if you are introducing |
| a new recipe that requires the included file, use the path relative |
| to the original layer directory to refer to the file. For example, |
| use ``require recipes-core/``\ `package`\ ``/``\ `file`\ ``.inc`` instead |
| of ``require`` `file`\ ``.inc``. If you're finding you have to overlay |
| the include file, it could indicate a deficiency in the include file |
| in the layer to which it originally belongs. If this is the case, you |
| should try to address that deficiency instead of overlaying the |
| include file. For example, you could address this by getting the |
| maintainer of the include file to add a variable or variables to make |
| it easy to override the parts needing to be overridden. |
| |
| - *Structure Your Layers:* Proper use of overrides within append files |
| and placement of machine-specific files within your layer can ensure |
| that a build is not using the wrong Metadata and negatively impacting |
| a build for a different machine. Following are some examples: |
| |
| - *Modify Variables to Support a Different Machine:* Suppose you |
| have a layer named ``meta-one`` that adds support for building |
| machine "one". To do so, you use an append file named |
| ``base-files.bbappend`` and create a dependency on "foo" by |
| altering the :term:`DEPENDS` |
| variable:: |
| |
| DEPENDS = "foo" |
| |
| The dependency is created during any |
| build that includes the layer ``meta-one``. However, you might not |
| want this dependency for all machines. For example, suppose you |
| are building for machine "two" but your ``bblayers.conf`` file has |
| the ``meta-one`` layer included. During the build, the |
| ``base-files`` for machine "two" will also have the dependency on |
| ``foo``. |
| |
| To make sure your changes apply only when building machine "one", |
| use a machine override with the :term:`DEPENDS` statement:: |
| |
| DEPENDS:one = "foo" |
| |
| You should follow the same strategy when using ``:append`` |
| and ``:prepend`` operations:: |
| |
| DEPENDS:append:one = " foo" |
| DEPENDS:prepend:one = "foo " |
| |
| As an actual example, here's a |
| snippet from the generic kernel include file ``linux-yocto.inc``, |
| wherein the kernel compile and link options are adjusted in the |
| case of a subset of the supported architectures:: |
| |
| DEPENDS:append:aarch64 = " libgcc" |
| KERNEL_CC:append:aarch64 = " ${TOOLCHAIN_OPTIONS}" |
| KERNEL_LD:append:aarch64 = " ${TOOLCHAIN_OPTIONS}" |
| |
| DEPENDS:append:nios2 = " libgcc" |
| KERNEL_CC:append:nios2 = " ${TOOLCHAIN_OPTIONS}" |
| KERNEL_LD:append:nios2 = " ${TOOLCHAIN_OPTIONS}" |
| |
| DEPENDS:append:arc = " libgcc" |
| KERNEL_CC:append:arc = " ${TOOLCHAIN_OPTIONS}" |
| KERNEL_LD:append:arc = " ${TOOLCHAIN_OPTIONS}" |
| |
| KERNEL_FEATURES:append:qemuall=" features/debug/printk.scc" |
| |
| - *Place Machine-Specific Files in Machine-Specific Locations:* When |
| you have a base recipe, such as ``base-files.bb``, that contains a |
| :term:`SRC_URI` statement to a |
| file, you can use an append file to cause the build to use your |
| own version of the file. For example, an append file in your layer |
| at ``meta-one/recipes-core/base-files/base-files.bbappend`` could |
| extend :term:`FILESPATH` using :term:`FILESEXTRAPATHS` as follows:: |
| |
| FILESEXTRAPATHS:prepend := "${THISDIR}/${BPN}:" |
| |
| The build for machine "one" will pick up your machine-specific file as |
| long as you have the file in |
| ``meta-one/recipes-core/base-files/base-files/``. However, if you |
| are building for a different machine and the ``bblayers.conf`` |
| file includes the ``meta-one`` layer and the location of your |
| machine-specific file is the first location where that file is |
| found according to :term:`FILESPATH`, builds for all machines will |
| also use that machine-specific file. |
| |
| You can make sure that a machine-specific file is used for a |
| particular machine by putting the file in a subdirectory specific |
| to the machine. For example, rather than placing the file in |
| ``meta-one/recipes-core/base-files/base-files/`` as shown above, |
| put it in ``meta-one/recipes-core/base-files/base-files/one/``. |
| Not only does this make sure the file is used only when building |
| for machine "one", but the build process locates the file more |
| quickly. |
| |
| In summary, you need to place all files referenced from |
| :term:`SRC_URI` in a machine-specific subdirectory within the layer in |
| order to restrict those files to machine-specific builds. |
| |
| - *Perform Steps to Apply for Yocto Project Compatibility:* If you want |
| permission to use the Yocto Project Compatibility logo with your |
| layer or application that uses your layer, perform the steps to apply |
| for compatibility. See the |
| ":ref:`dev-manual/common-tasks:making sure your layer is compatible with yocto project`" |
| section for more information. |
| |
| - *Follow the Layer Naming Convention:* Store custom layers in a Git |
| repository that use the ``meta-layer_name`` format. |
| |
| - *Group Your Layers Locally:* Clone your repository alongside other |
| cloned ``meta`` directories from the :term:`Source Directory`. |
| |
| Making Sure Your Layer is Compatible With Yocto Project |
| ------------------------------------------------------- |
| |
| When you create a layer used with the Yocto Project, it is advantageous |
| to make sure that the layer interacts well with existing Yocto Project |
| layers (i.e. the layer is compatible with the Yocto Project). Ensuring |
| compatibility makes the layer easy to be consumed by others in the Yocto |
| Project community and could allow you permission to use the Yocto |
| Project Compatible Logo. |
| |
| .. note:: |
| |
| Only Yocto Project member organizations are permitted to use the |
| Yocto Project Compatible Logo. The logo is not available for general |
| use. For information on how to become a Yocto Project member |
| organization, see the :yocto_home:`Yocto Project Website <>`. |
| |
| The Yocto Project Compatibility Program consists of a layer application |
| process that requests permission to use the Yocto Project Compatibility |
| Logo for your layer and application. The process consists of two parts: |
| |
| 1. Successfully passing a script (``yocto-check-layer``) that when run |
| against your layer, tests it against constraints based on experiences |
| of how layers have worked in the real world and where pitfalls have |
| been found. Getting a "PASS" result from the script is required for |
| successful compatibility registration. |
| |
| 2. Completion of an application acceptance form, which you can find at |
| :yocto_home:`/webform/yocto-project-compatible-registration`. |
| |
| To be granted permission to use the logo, you need to satisfy the |
| following: |
| |
| - Be able to check the box indicating that you got a "PASS" when |
| running the script against your layer. |
| |
| - Answer "Yes" to the questions on the form or have an acceptable |
| explanation for any questions answered "No". |
| |
| - Be a Yocto Project Member Organization. |
| |
| The remainder of this section presents information on the registration |
| form and on the ``yocto-check-layer`` script. |
| |
| Yocto Project Compatible Program Application |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| Use the form to apply for your layer's approval. Upon successful |
| application, you can use the Yocto Project Compatibility Logo with your |
| layer and the application that uses your layer. |
| |
| To access the form, use this link: |
| :yocto_home:`/webform/yocto-project-compatible-registration`. |
| Follow the instructions on the form to complete your application. |
| |
| The application consists of the following sections: |
| |
| - *Contact Information:* Provide your contact information as the fields |
| require. Along with your information, provide the released versions |
| of the Yocto Project for which your layer is compatible. |
| |
| - *Acceptance Criteria:* Provide "Yes" or "No" answers for each of the |
| items in the checklist. There is space at the bottom of the form for |
| any explanations for items for which you answered "No". |
| |
| - *Recommendations:* Provide answers for the questions regarding Linux |
| kernel use and build success. |
| |
| ``yocto-check-layer`` Script |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| The ``yocto-check-layer`` script provides you a way to assess how |
| compatible your layer is with the Yocto Project. You should run this |
| script prior to using the form to apply for compatibility as described |
| in the previous section. You need to achieve a "PASS" result in order to |
| have your application form successfully processed. |
| |
| The script divides tests into three areas: COMMON, BSP, and DISTRO. For |
| example, given a distribution layer (DISTRO), the layer must pass both |
| the COMMON and DISTRO related tests. Furthermore, if your layer is a BSP |
| layer, the layer must pass the COMMON and BSP set of tests. |
| |
| To execute the script, enter the following commands from your build |
| directory:: |
| |
| $ source oe-init-build-env |
| $ yocto-check-layer your_layer_directory |
| |
| Be sure to provide the actual directory for your |
| layer as part of the command. |
| |
| Entering the command causes the script to determine the type of layer |
| and then to execute a set of specific tests against the layer. The |
| following list overviews the test: |
| |
| - ``common.test_readme``: Tests if a ``README`` file exists in the |
| layer and the file is not empty. |
| |
| - ``common.test_parse``: Tests to make sure that BitBake can parse the |
| files without error (i.e. ``bitbake -p``). |
| |
| - ``common.test_show_environment``: Tests that the global or per-recipe |
| environment is in order without errors (i.e. ``bitbake -e``). |
| |
| - ``common.test_world``: Verifies that ``bitbake world`` works. |
| |
| - ``common.test_signatures``: Tests to be sure that BSP and DISTRO |
| layers do not come with recipes that change signatures. |
| |
| - ``common.test_layerseries_compat``: Verifies layer compatibility is |
| set properly. |
| |
| - ``bsp.test_bsp_defines_machines``: Tests if a BSP layer has machine |
| configurations. |
| |
| - ``bsp.test_bsp_no_set_machine``: Tests to ensure a BSP layer does not |
| set the machine when the layer is added. |
| |
| - ``bsp.test_machine_world``: Verifies that ``bitbake world`` works |
| regardless of which machine is selected. |
| |
| - ``bsp.test_machine_signatures``: Verifies that building for a |
| particular machine affects only the signature of tasks specific to |
| that machine. |
| |
| - ``distro.test_distro_defines_distros``: Tests if a DISTRO layer has |
| distro configurations. |
| |
| - ``distro.test_distro_no_set_distros``: Tests to ensure a DISTRO layer |
| does not set the distribution when the layer is added. |
| |
| Enabling Your Layer |
| ------------------- |
| |
| Before the OpenEmbedded build system can use your new layer, you need to |
| enable it. To enable your layer, simply add your layer's path to the |
| :term:`BBLAYERS` variable in your ``conf/bblayers.conf`` file, which is |
| found in the :term:`Build Directory`. |
| The following example shows how to enable your new |
| ``meta-mylayer`` layer (note how your new layer exists outside of |
| the official ``poky`` repository which you would have checked out earlier):: |
| |
| # POKY_BBLAYERS_CONF_VERSION is increased each time build/conf/bblayers.conf |
| # changes incompatibly |
| POKY_BBLAYERS_CONF_VERSION = "2" |
| BBPATH = "${TOPDIR}" |
| BBFILES ?= "" |
| BBLAYERS ?= " \ |
| /home/user/poky/meta \ |
| /home/user/poky/meta-poky \ |
| /home/user/poky/meta-yocto-bsp \ |
| /home/user/mystuff/meta-mylayer \ |
| " |
| |
| BitBake parses each ``conf/layer.conf`` file from the top down as |
| specified in the :term:`BBLAYERS` variable within the ``conf/bblayers.conf`` |
| file. During the processing of each ``conf/layer.conf`` file, BitBake |
| adds the recipes, classes and configurations contained within the |
| particular layer to the source directory. |
| |
| Appending Other Layers Metadata With Your Layer |
| ----------------------------------------------- |
| |
| A recipe that appends Metadata to another recipe is called a BitBake |
| append file. A BitBake append file uses the ``.bbappend`` file type |
| suffix, while the corresponding recipe to which Metadata is being |
| appended uses the ``.bb`` file type suffix. |
| |
| You can use a ``.bbappend`` file in your layer to make additions or |
| changes to the content of another layer's recipe without having to copy |
| the other layer's recipe into your layer. Your ``.bbappend`` file |
| resides in your layer, while the main ``.bb`` recipe file to which you |
| are appending Metadata resides in a different layer. |
| |
| Being able to append information to an existing recipe not only avoids |
| duplication, but also automatically applies recipe changes from a |
| different layer into your layer. If you were copying recipes, you would |
| have to manually merge changes as they occur. |
| |
| When you create an append file, you must use the same root name as the |
| corresponding recipe file. For example, the append file |
| ``someapp_3.1.bbappend`` must apply to ``someapp_3.1.bb``. This |
| means the original recipe and append filenames are version |
| number-specific. If the corresponding recipe is renamed to update to a |
| newer version, you must also rename and possibly update the |
| corresponding ``.bbappend`` as well. During the build process, BitBake |
| displays an error on starting if it detects a ``.bbappend`` file that |
| does not have a corresponding recipe with a matching name. See the |
| :term:`BB_DANGLINGAPPENDS_WARNONLY` |
| variable for information on how to handle this error. |
| |
| Overlaying a File Using Your Layer |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| As an example, consider the main formfactor recipe and a corresponding |
| formfactor append file both from the :term:`Source Directory`. |
| Here is the main |
| formfactor recipe, which is named ``formfactor_0.0.bb`` and located in |
| the "meta" layer at ``meta/recipes-bsp/formfactor``:: |
| |
| SUMMARY = "Device formfactor information" |
| DESCRIPTION = "A formfactor configuration file provides information about the \ |
| target hardware for which the image is being built and information that the \ |
| build system cannot obtain from other sources such as the kernel." |
| SECTION = "base" |
| LICENSE = "MIT" |
| LIC_FILES_CHKSUM = "file://${COREBASE}/meta/COPYING.MIT;md5=3da9cfbcb788c80a0384361b4de20420" |
| PR = "r45" |
| |
| SRC_URI = "file://config file://machconfig" |
| S = "${WORKDIR}" |
| |
| PACKAGE_ARCH = "${MACHINE_ARCH}" |
| INHIBIT_DEFAULT_DEPS = "1" |
| |
| do_install() { |
| # Install file only if it has contents |
| install -d ${D}${sysconfdir}/formfactor/ |
| install -m 0644 ${S}/config ${D}${sysconfdir}/formfactor/ |
| if [ -s "${S}/machconfig" ]; then |
| install -m 0644 ${S}/machconfig ${D}${sysconfdir}/formfactor/ |
| fi |
| } |
| |
| In the main recipe, note the :term:`SRC_URI` |
| variable, which tells the OpenEmbedded build system where to find files |
| during the build. |
| |
| Following is the append file, which is named ``formfactor_0.0.bbappend`` |
| and is from the Raspberry Pi BSP Layer named ``meta-raspberrypi``. The |
| file is in the layer at ``recipes-bsp/formfactor``:: |
| |
| FILESEXTRAPATHS:prepend := "${THISDIR}/${PN}:" |
| |
| By default, the build system uses the |
| :term:`FILESPATH` variable to |
| locate files. This append file extends the locations by setting the |
| :term:`FILESEXTRAPATHS` |
| variable. Setting this variable in the ``.bbappend`` file is the most |
| reliable and recommended method for adding directories to the search |
| path used by the build system to find files. |
| |
| The statement in this example extends the directories to include |
| ``${``\ :term:`THISDIR`\ ``}/${``\ :term:`PN`\ ``}``, |
| which resolves to a directory named ``formfactor`` in the same directory |
| in which the append file resides (i.e. |
| ``meta-raspberrypi/recipes-bsp/formfactor``. This implies that you must |
| have the supporting directory structure set up that will contain any |
| files or patches you will be including from the layer. |
| |
| Using the immediate expansion assignment operator ``:=`` is important |
| because of the reference to :term:`THISDIR`. The trailing colon character is |
| important as it ensures that items in the list remain colon-separated. |
| |
| .. note:: |
| |
| BitBake automatically defines the :term:`THISDIR` variable. You should |
| never set this variable yourself. Using ":prepend" as part of the |
| :term:`FILESEXTRAPATHS` ensures your path will be searched prior to other |
| paths in the final list. |
| |
| Also, not all append files add extra files. Many append files simply |
| allow to add build options (e.g. ``systemd``). For these cases, your |
| append file would not even use the :term:`FILESEXTRAPATHS` statement. |
| |
| The end result of this ``.bbappend`` file is that on a Raspberry Pi, where |
| ``rpi`` will exist in the list of :term:`OVERRIDES`, the file |
| ``meta-raspberrypi/recipes-bsp/formfactor/formfactor/rpi/machconfig`` will be |
| used during :ref:`ref-tasks-fetch` and the test for a non-zero file size in |
| :ref:`ref-tasks-install` will return true, and the file will be installed. |
| |
| Installing Additional Files Using Your Layer |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| As another example, consider the main ``xserver-xf86-config`` recipe and a |
| corresponding ``xserver-xf86-config`` append file both from the :term:`Source |
| Directory`. Here is the main ``xserver-xf86-config`` recipe, which is named |
| ``xserver-xf86-config_0.1.bb`` and located in the "meta" layer at |
| ``meta/recipes-graphics/xorg-xserver``:: |
| |
| SUMMARY = "X.Org X server configuration file" |
| HOMEPAGE = "http://www.x.org" |
| SECTION = "x11/base" |
| LICENSE = "MIT-X" |
| LIC_FILES_CHKSUM = "file://${COREBASE}/meta/COPYING.MIT;md5=3da9cfbcb788c80a0384361b4de20420" |
| PR = "r33" |
| |
| SRC_URI = "file://xorg.conf" |
| |
| S = "${WORKDIR}" |
| |
| CONFFILES:${PN} = "${sysconfdir}/X11/xorg.conf" |
| |
| PACKAGE_ARCH = "${MACHINE_ARCH}" |
| ALLOW_EMPTY:${PN} = "1" |
| |
| do_install () { |
| if test -s ${WORKDIR}/xorg.conf; then |
| install -d ${D}/${sysconfdir}/X11 |
| install -m 0644 ${WORKDIR}/xorg.conf ${D}/${sysconfdir}/X11/ |
| fi |
| } |
| |
| Following is the append file, which is named ``xserver-xf86-config_%.bbappend`` |
| and is from the Raspberry Pi BSP Layer named ``meta-raspberrypi``. The |
| file is in the layer at ``recipes-graphics/xorg-xserver``:: |
| |
| FILESEXTRAPATHS:prepend := "${THISDIR}/${PN}:" |
| |
| SRC_URI:append:rpi = " \ |
| file://xorg.conf.d/98-pitft.conf \ |
| file://xorg.conf.d/99-calibration.conf \ |
| " |
| do_install:append:rpi () { |
| PITFT="${@bb.utils.contains("MACHINE_FEATURES", "pitft", "1", "0", d)}" |
| if [ "${PITFT}" = "1" ]; then |
| install -d ${D}/${sysconfdir}/X11/xorg.conf.d/ |
| install -m 0644 ${WORKDIR}/xorg.conf.d/98-pitft.conf ${D}/${sysconfdir}/X11/xorg.conf.d/ |
| install -m 0644 ${WORKDIR}/xorg.conf.d/99-calibration.conf ${D}/${sysconfdir}/X11/xorg.conf.d/ |
| fi |
| } |
| |
| FILES:${PN}:append:rpi = " ${sysconfdir}/X11/xorg.conf.d/*" |
| |
| Building off of the previous example, we once again are setting the |
| :term:`FILESEXTRAPATHS` variable. In this case we are also using |
| :term:`SRC_URI` to list additional source files to use when ``rpi`` is found in |
| the list of :term:`OVERRIDES`. The :ref:`ref-tasks-install` task will then perform a |
| check for an additional :term:`MACHINE_FEATURES` that if set will cause these |
| additional files to be installed. These additional files are listed in |
| :term:`FILES` so that they will be packaged. |
| |
| Prioritizing Your Layer |
| ----------------------- |
| |
| Each layer is assigned a priority value. Priority values control which |
| layer takes precedence if there are recipe files with the same name in |
| multiple layers. For these cases, the recipe file from the layer with a |
| higher priority number takes precedence. Priority values also affect the |
| order in which multiple ``.bbappend`` files for the same recipe are |
| applied. You can either specify the priority manually, or allow the |
| build system to calculate it based on the layer's dependencies. |
| |
| To specify the layer's priority manually, use the |
| :term:`BBFILE_PRIORITY` |
| variable and append the layer's root name:: |
| |
| BBFILE_PRIORITY_mylayer = "1" |
| |
| .. note:: |
| |
| It is possible for a recipe with a lower version number |
| :term:`PV` in a layer that has a higher |
| priority to take precedence. |
| |
| Also, the layer priority does not currently affect the precedence |
| order of ``.conf`` or ``.bbclass`` files. Future versions of BitBake |
| might address this. |
| |
| Managing Layers |
| --------------- |
| |
| You can use the BitBake layer management tool ``bitbake-layers`` to |
| provide a view into the structure of recipes across a multi-layer |
| project. Being able to generate output that reports on configured layers |
| with their paths and priorities and on ``.bbappend`` files and their |
| applicable recipes can help to reveal potential problems. |
| |
| For help on the BitBake layer management tool, use the following |
| command:: |
| |
| $ bitbake-layers --help |
| NOTE: Starting bitbake server... |
| usage: bitbake-layers [-d] [-q] [-F] [--color COLOR] [-h] <subcommand> ... |
| |
| BitBake layers utility |
| |
| optional arguments: |
| -d, --debug Enable debug output |
| -q, --quiet Print only errors |
| -F, --force Force add without recipe parse verification |
| --color COLOR Colorize output (where COLOR is auto, always, never) |
| -h, --help show this help message and exit |
| |
| subcommands: |
| <subcommand> |
| layerindex-fetch Fetches a layer from a layer index along with its |
| dependent layers, and adds them to conf/bblayers.conf. |
| layerindex-show-depends |
| Find layer dependencies from layer index. |
| add-layer Add one or more layers to bblayers.conf. |
| remove-layer Remove one or more layers from bblayers.conf. |
| flatten flatten layer configuration into a separate output |
| directory. |
| show-layers show current configured layers. |
| show-overlayed list overlayed recipes (where the same recipe exists |
| in another layer) |
| show-recipes list available recipes, showing the layer they are |
| provided by |
| show-appends list bbappend files and recipe files they apply to |
| show-cross-depends Show dependencies between recipes that cross layer |
| boundaries. |
| create-layer Create a basic layer |
| |
| Use bitbake-layers <subcommand> --help to get help on a specific command |
| |
| The following list describes the available commands: |
| |
| - ``help:`` Displays general help or help on a specified command. |
| |
| - ``show-layers:`` Shows the current configured layers. |
| |
| - ``show-overlayed:`` Lists overlayed recipes. A recipe is overlayed |
| when a recipe with the same name exists in another layer that has a |
| higher layer priority. |
| |
| - ``show-recipes:`` Lists available recipes and the layers that |
| provide them. |
| |
| - ``show-appends:`` Lists ``.bbappend`` files and the recipe files to |
| which they apply. |
| |
| - ``show-cross-depends:`` Lists dependency relationships between |
| recipes that cross layer boundaries. |
| |
| - ``add-layer:`` Adds a layer to ``bblayers.conf``. |
| |
| - ``remove-layer:`` Removes a layer from ``bblayers.conf`` |
| |
| - ``flatten:`` Flattens the layer configuration into a separate |
| output directory. Flattening your layer configuration builds a |
| "flattened" directory that contains the contents of all layers, with |
| any overlayed recipes removed and any ``.bbappend`` files appended to |
| the corresponding recipes. You might have to perform some manual |
| cleanup of the flattened layer as follows: |
| |
| - Non-recipe files (such as patches) are overwritten. The flatten |
| command shows a warning for these files. |
| |
| - Anything beyond the normal layer setup has been added to the |
| ``layer.conf`` file. Only the lowest priority layer's |
| ``layer.conf`` is used. |
| |
| - Overridden and appended items from ``.bbappend`` files need to be |
| cleaned up. The contents of each ``.bbappend`` end up in the |
| flattened recipe. However, if there are appended or changed |
| variable values, you need to tidy these up yourself. Consider the |
| following example. Here, the ``bitbake-layers`` command adds the |
| line ``#### bbappended ...`` so that you know where the following |
| lines originate:: |
| |
| ... |
| DESCRIPTION = "A useful utility" |
| ... |
| EXTRA_OECONF = "--enable-something" |
| ... |
| |
| #### bbappended from meta-anotherlayer #### |
| |
| DESCRIPTION = "Customized utility" |
| EXTRA_OECONF += "--enable-somethingelse" |
| |
| |
| Ideally, you would tidy up these utilities as follows:: |
| |
| ... |
| DESCRIPTION = "Customized utility" |
| ... |
| EXTRA_OECONF = "--enable-something --enable-somethingelse" |
| ... |
| |
| - ``layerindex-fetch``: Fetches a layer from a layer index, along |
| with its dependent layers, and adds the layers to the |
| ``conf/bblayers.conf`` file. |
| |
| - ``layerindex-show-depends``: Finds layer dependencies from the |
| layer index. |
| |
| - ``create-layer``: Creates a basic layer. |
| |
| Creating a General Layer Using the ``bitbake-layers`` Script |
| ------------------------------------------------------------ |
| |
| The ``bitbake-layers`` script with the ``create-layer`` subcommand |
| simplifies creating a new general layer. |
| |
| .. note:: |
| |
| - For information on BSP layers, see the ":ref:`bsp-guide/bsp:bsp layers`" |
| section in the Yocto |
| Project Board Specific (BSP) Developer's Guide. |
| |
| - In order to use a layer with the OpenEmbedded build system, you |
| need to add the layer to your ``bblayers.conf`` configuration |
| file. See the ":ref:`dev-manual/common-tasks:adding a layer using the \`\`bitbake-layers\`\` script`" |
| section for more information. |
| |
| The default mode of the script's operation with this subcommand is to |
| create a layer with the following: |
| |
| - A layer priority of 6. |
| |
| - A ``conf`` subdirectory that contains a ``layer.conf`` file. |
| |
| - A ``recipes-example`` subdirectory that contains a further |
| subdirectory named ``example``, which contains an ``example.bb`` |
| recipe file. |
| |
| - A ``COPYING.MIT``, which is the license statement for the layer. The |
| script assumes you want to use the MIT license, which is typical for |
| most layers, for the contents of the layer itself. |
| |
| - A ``README`` file, which is a file describing the contents of your |
| new layer. |
| |
| In its simplest form, you can use the following command form to create a |
| layer. The command creates a layer whose name corresponds to |
| "your_layer_name" in the current directory:: |
| |
| $ bitbake-layers create-layer your_layer_name |
| |
| As an example, the following command creates a layer named ``meta-scottrif`` |
| in your home directory:: |
| |
| $ cd /usr/home |
| $ bitbake-layers create-layer meta-scottrif |
| NOTE: Starting bitbake server... |
| Add your new layer with 'bitbake-layers add-layer meta-scottrif' |
| |
| If you want to set the priority of the layer to other than the default |
| value of "6", you can either use the ``--priority`` option or you |
| can edit the |
| :term:`BBFILE_PRIORITY` value |
| in the ``conf/layer.conf`` after the script creates it. Furthermore, if |
| you want to give the example recipe file some name other than the |
| default, you can use the ``--example-recipe-name`` option. |
| |
| The easiest way to see how the ``bitbake-layers create-layer`` command |
| works is to experiment with the script. You can also read the usage |
| information by entering the following:: |
| |
| $ bitbake-layers create-layer --help |
| NOTE: Starting bitbake server... |
| usage: bitbake-layers create-layer [-h] [--priority PRIORITY] |
| [--example-recipe-name EXAMPLERECIPE] |
| layerdir |
| |
| Create a basic layer |
| |
| positional arguments: |
| layerdir Layer directory to create |
| |
| optional arguments: |
| -h, --help show this help message and exit |
| --priority PRIORITY, -p PRIORITY |
| Layer directory to create |
| --example-recipe-name EXAMPLERECIPE, -e EXAMPLERECIPE |
| Filename of the example recipe |
| |
| Adding a Layer Using the ``bitbake-layers`` Script |
| -------------------------------------------------- |
| |
| Once you create your general layer, you must add it to your |
| ``bblayers.conf`` file. Adding the layer to this configuration file |
| makes the OpenEmbedded build system aware of your layer so that it can |
| search it for metadata. |
| |
| Add your layer by using the ``bitbake-layers add-layer`` command:: |
| |
| $ bitbake-layers add-layer your_layer_name |
| |
| Here is an example that adds a |
| layer named ``meta-scottrif`` to the configuration file. Following the |
| command that adds the layer is another ``bitbake-layers`` command that |
| shows the layers that are in your ``bblayers.conf`` file:: |
| |
| $ bitbake-layers add-layer meta-scottrif |
| NOTE: Starting bitbake server... |
| Parsing recipes: 100% |##########################################################| Time: 0:00:49 |
| Parsing of 1441 .bb files complete (0 cached, 1441 parsed). 2055 targets, 56 skipped, 0 masked, 0 errors. |
| $ bitbake-layers show-layers |
| NOTE: Starting bitbake server... |
| layer path priority |
| ========================================================================== |
| meta /home/scottrif/poky/meta 5 |
| meta-poky /home/scottrif/poky/meta-poky 5 |
| meta-yocto-bsp /home/scottrif/poky/meta-yocto-bsp 5 |
| workspace /home/scottrif/poky/build/workspace 99 |
| meta-scottrif /home/scottrif/poky/build/meta-scottrif 6 |
| |
| |
| Adding the layer to this file |
| enables the build system to locate the layer during the build. |
| |
| .. note:: |
| |
| During a build, the OpenEmbedded build system looks in the layers |
| from the top of the list down to the bottom in that order. |
| |
| Customizing Images |
| ================== |
| |
| You can customize images to satisfy particular requirements. This |
| section describes several methods and provides guidelines for each. |
| |
| Customizing Images Using ``local.conf`` |
| --------------------------------------- |
| |
| Probably the easiest way to customize an image is to add a package by |
| way of the ``local.conf`` configuration file. Because it is limited to |
| local use, this method generally only allows you to add packages and is |
| not as flexible as creating your own customized image. When you add |
| packages using local variables this way, you need to realize that these |
| variable changes are in effect for every build and consequently affect |
| all images, which might not be what you require. |
| |
| To add a package to your image using the local configuration file, use |
| the :term:`IMAGE_INSTALL` variable with the ``:append`` operator:: |
| |
| IMAGE_INSTALL:append = " strace" |
| |
| Use of the syntax is important; specifically, the leading space |
| after the opening quote and before the package name, which is |
| ``strace`` in this example. This space is required since the ``:append`` |
| operator does not add the space. |
| |
| Furthermore, you must use ``:append`` instead of the ``+=`` operator if |
| you want to avoid ordering issues. The reason for this is because doing |
| so unconditionally appends to the variable and avoids ordering problems |
| due to the variable being set in image recipes and ``.bbclass`` files |
| with operators like ``?=``. Using ``:append`` ensures the operation |
| takes effect. |
| |
| As shown in its simplest use, ``IMAGE_INSTALL:append`` affects all |
| images. It is possible to extend the syntax so that the variable applies |
| to a specific image only. Here is an example:: |
| |
| IMAGE_INSTALL:append:pn-core-image-minimal = " strace" |
| |
| This example adds ``strace`` to the ``core-image-minimal`` image only. |
| |
| You can add packages using a similar approach through the |
| :term:`CORE_IMAGE_EXTRA_INSTALL` variable. If you use this variable, only |
| ``core-image-*`` images are affected. |
| |
| Customizing Images Using Custom ``IMAGE_FEATURES`` and ``EXTRA_IMAGE_FEATURES`` |
| ------------------------------------------------------------------------------- |
| |
| Another method for customizing your image is to enable or disable |
| high-level image features by using the |
| :term:`IMAGE_FEATURES` and |
| :term:`EXTRA_IMAGE_FEATURES` |
| variables. Although the functions for both variables are nearly |
| equivalent, best practices dictate using :term:`IMAGE_FEATURES` from within |
| a recipe and using :term:`EXTRA_IMAGE_FEATURES` from within your |
| ``local.conf`` file, which is found in the |
| :term:`Build Directory`. |
| |
| To understand how these features work, the best reference is |
| :ref:`meta/classes/image.bbclass <ref-classes-image>`. |
| This class lists out the available |
| :term:`IMAGE_FEATURES` of which most map to package groups while some, such |
| as ``debug-tweaks`` and ``read-only-rootfs``, resolve as general |
| configuration settings. |
| |
| In summary, the file looks at the contents of the :term:`IMAGE_FEATURES` |
| variable and then maps or configures the feature accordingly. Based on |
| this information, the build system automatically adds the appropriate |
| packages or configurations to the |
| :term:`IMAGE_INSTALL` variable. |
| Effectively, you are enabling extra features by extending the class or |
| creating a custom class for use with specialized image ``.bb`` files. |
| |
| Use the :term:`EXTRA_IMAGE_FEATURES` variable from within your local |
| configuration file. Using a separate area from which to enable features |
| with this variable helps you avoid overwriting the features in the image |
| recipe that are enabled with :term:`IMAGE_FEATURES`. The value of |
| :term:`EXTRA_IMAGE_FEATURES` is added to :term:`IMAGE_FEATURES` within |
| ``meta/conf/bitbake.conf``. |
| |
| To illustrate how you can use these variables to modify your image, |
| consider an example that selects the SSH server. The Yocto Project ships |
| with two SSH servers you can use with your images: Dropbear and OpenSSH. |
| Dropbear is a minimal SSH server appropriate for resource-constrained |
| environments, while OpenSSH is a well-known standard SSH server |
| implementation. By default, the ``core-image-sato`` image is configured |
| to use Dropbear. The ``core-image-full-cmdline`` and ``core-image-lsb`` |
| images both include OpenSSH. The ``core-image-minimal`` image does not |
| contain an SSH server. |
| |
| You can customize your image and change these defaults. Edit the |
| :term:`IMAGE_FEATURES` variable in your recipe or use the |
| :term:`EXTRA_IMAGE_FEATURES` in your ``local.conf`` file so that it |
| configures the image you are working with to include |
| ``ssh-server-dropbear`` or ``ssh-server-openssh``. |
| |
| .. note:: |
| |
| See the ":ref:`ref-manual/features:image features`" section in the Yocto |
| Project Reference Manual for a complete list of image features that ship |
| with the Yocto Project. |
| |
| Customizing Images Using Custom .bb Files |
| ----------------------------------------- |
| |
| You can also customize an image by creating a custom recipe that defines |
| additional software as part of the image. The following example shows |
| the form for the two lines you need:: |
| |
| IMAGE_INSTALL = "packagegroup-core-x11-base package1 package2" |
| inherit core-image |
| |
| Defining the software using a custom recipe gives you total control over |
| the contents of the image. It is important to use the correct names of |
| packages in the :term:`IMAGE_INSTALL` variable. You must use the |
| OpenEmbedded notation and not the Debian notation for the names (e.g. |
| ``glibc-dev`` instead of ``libc6-dev``). |
| |
| The other method for creating a custom image is to base it on an |
| existing image. For example, if you want to create an image based on |
| ``core-image-sato`` but add the additional package ``strace`` to the |
| image, copy the ``meta/recipes-sato/images/core-image-sato.bb`` to a new |
| ``.bb`` and add the following line to the end of the copy:: |
| |
| IMAGE_INSTALL += "strace" |
| |
| Customizing Images Using Custom Package Groups |
| ---------------------------------------------- |
| |
| For complex custom images, the best approach for customizing an image is |
| to create a custom package group recipe that is used to build the image |
| or images. A good example of a package group recipe is |
| ``meta/recipes-core/packagegroups/packagegroup-base.bb``. |
| |
| If you examine that recipe, you see that the :term:`PACKAGES` variable lists |
| the package group packages to produce. The ``inherit packagegroup`` |
| statement sets appropriate default values and automatically adds |
| ``-dev``, ``-dbg``, and ``-ptest`` complementary packages for each |
| package specified in the :term:`PACKAGES` statement. |
| |
| .. note:: |
| |
| The ``inherit packagegroup`` line should be located near the top of the |
| recipe, certainly before the :term:`PACKAGES` statement. |
| |
| For each package you specify in :term:`PACKAGES`, you can use :term:`RDEPENDS` |
| and :term:`RRECOMMENDS` entries to provide a list of packages the parent |
| task package should contain. You can see examples of these further down |
| in the ``packagegroup-base.bb`` recipe. |
| |
| Here is a short, fabricated example showing the same basic pieces for a |
| hypothetical packagegroup defined in ``packagegroup-custom.bb``, where |
| the variable :term:`PN` is the standard way to abbreviate the reference to |
| the full packagegroup name ``packagegroup-custom``:: |
| |
| DESCRIPTION = "My Custom Package Groups" |
| |
| inherit packagegroup |
| |
| PACKAGES = "\ |
| ${PN}-apps \ |
| ${PN}-tools \ |
| " |
| |
| RDEPENDS:${PN}-apps = "\ |
| dropbear \ |
| portmap \ |
| psplash" |
| |
| RDEPENDS:${PN}-tools = "\ |
| oprofile \ |
| oprofileui-server \ |
| lttng-tools" |
| |
| RRECOMMENDS:${PN}-tools = "\ |
| kernel-module-oprofile" |
| |
| In the previous example, two package group packages are created with |
| their dependencies and their recommended package dependencies listed: |
| ``packagegroup-custom-apps``, and ``packagegroup-custom-tools``. To |
| build an image using these package group packages, you need to add |
| ``packagegroup-custom-apps`` and/or ``packagegroup-custom-tools`` to |
| :term:`IMAGE_INSTALL`. For other forms of image dependencies see the other |
| areas of this section. |
| |
| Customizing an Image Hostname |
| ----------------------------- |
| |
| By default, the configured hostname (i.e. ``/etc/hostname``) in an image |
| is the same as the machine name. For example, if |
| :term:`MACHINE` equals "qemux86", the |
| configured hostname written to ``/etc/hostname`` is "qemux86". |
| |
| You can customize this name by altering the value of the "hostname" |
| variable in the ``base-files`` recipe using either an append file or a |
| configuration file. Use the following in an append file:: |
| |
| hostname = "myhostname" |
| |
| Use the following in a configuration file:: |
| |
| hostname:pn-base-files = "myhostname" |
| |
| Changing the default value of the variable "hostname" can be useful in |
| certain situations. For example, suppose you need to do extensive |
| testing on an image and you would like to easily identify the image |
| under test from existing images with typical default hostnames. In this |
| situation, you could change the default hostname to "testme", which |
| results in all the images using the name "testme". Once testing is |
| complete and you do not need to rebuild the image for test any longer, |
| you can easily reset the default hostname. |
| |
| Another point of interest is that if you unset the variable, the image |
| will have no default hostname in the filesystem. Here is an example that |
| unsets the variable in a configuration file:: |
| |
| hostname:pn-base-files = "" |
| |
| Having no default hostname in the filesystem is suitable for |
| environments that use dynamic hostnames such as virtual machines. |
| |
| Writing a New Recipe |
| ==================== |
| |
| Recipes (``.bb`` files) are fundamental components in the Yocto Project |
| environment. Each software component built by the OpenEmbedded build |
| system requires a recipe to define the component. This section describes |
| how to create, write, and test a new recipe. |
| |
| .. note:: |
| |
| For information on variables that are useful for recipes and for |
| information about recipe naming issues, see the |
| ":ref:`ref-manual/varlocality:recipes`" section of the Yocto Project |
| Reference Manual. |
| |
| Overview |
| -------- |
| |
| The following figure shows the basic process for creating a new recipe. |
| The remainder of the section provides details for the steps. |
| |
| .. image:: figures/recipe-workflow.png |
| :align: center |
| |
| Locate or Automatically Create a Base Recipe |
| -------------------------------------------- |
| |
| You can always write a recipe from scratch. However, there are three choices |
| that can help you quickly get started with a new recipe: |
| |
| - ``devtool add``: A command that assists in creating a recipe and an |
| environment conducive to development. |
| |
| - ``recipetool create``: A command provided by the Yocto Project that |
| automates creation of a base recipe based on the source files. |
| |
| - *Existing Recipes:* Location and modification of an existing recipe |
| that is similar in function to the recipe you need. |
| |
| .. note:: |
| |
| For information on recipe syntax, see the |
| ":ref:`dev-manual/common-tasks:recipe syntax`" section. |
| |
| Creating the Base Recipe Using ``devtool add`` |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| The ``devtool add`` command uses the same logic for auto-creating the |
| recipe as ``recipetool create``, which is listed below. Additionally, |
| however, ``devtool add`` sets up an environment that makes it easy for |
| you to patch the source and to make changes to the recipe as is often |
| necessary when adding a recipe to build a new piece of software to be |
| included in a build. |
| |
| You can find a complete description of the ``devtool add`` command in |
| the ":ref:`sdk-manual/extensible:a closer look at \`\`devtool add\`\``" section |
| in the Yocto Project Application Development and the Extensible Software |
| Development Kit (eSDK) manual. |
| |
| Creating the Base Recipe Using ``recipetool create`` |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| ``recipetool create`` automates creation of a base recipe given a set of |
| source code files. As long as you can extract or point to the source |
| files, the tool will construct a recipe and automatically configure all |
| pre-build information into the recipe. For example, suppose you have an |
| application that builds using Autotools. Creating the base recipe using |
| ``recipetool`` results in a recipe that has the pre-build dependencies, |
| license requirements, and checksums configured. |
| |
| To run the tool, you just need to be in your |
| :term:`Build Directory` and have sourced the |
| build environment setup script (i.e. |
| :ref:`structure-core-script`). |
| To get help on the tool, use the following command:: |
| |
| $ recipetool -h |
| NOTE: Starting bitbake server... |
| usage: recipetool [-d] [-q] [--color COLOR] [-h] <subcommand> ... |
| |
| OpenEmbedded recipe tool |
| |
| options: |
| -d, --debug Enable debug output |
| -q, --quiet Print only errors |
| --color COLOR Colorize output (where COLOR is auto, always, never) |
| -h, --help show this help message and exit |
| |
| subcommands: |
| create Create a new recipe |
| newappend Create a bbappend for the specified target in the specified |
| layer |
| setvar Set a variable within a recipe |
| appendfile Create/update a bbappend to replace a target file |
| appendsrcfiles Create/update a bbappend to add or replace source files |
| appendsrcfile Create/update a bbappend to add or replace a source file |
| Use recipetool <subcommand> --help to get help on a specific command |
| |
| Running ``recipetool create -o OUTFILE`` creates the base recipe and |
| locates it properly in the layer that contains your source files. |
| Following are some syntax examples: |
| |
| - Use this syntax to generate a recipe based on source. Once generated, |
| the recipe resides in the existing source code layer:: |
| |
| recipetool create -o OUTFILE source |
| |
| - Use this syntax to generate a recipe using code that |
| you extract from source. The extracted code is placed in its own layer |
| defined by :term:`EXTERNALSRC`. |
| :: |
| |
| recipetool create -o OUTFILE -x EXTERNALSRC source |
| |
| - Use this syntax to generate a recipe based on source. The options |
| direct ``recipetool`` to generate debugging information. Once generated, |
| the recipe resides in the existing source code layer:: |
| |
| recipetool create -d -o OUTFILE source |
| |
| Locating and Using a Similar Recipe |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| Before writing a recipe from scratch, it is often useful to discover |
| whether someone else has already written one that meets (or comes close |
| to meeting) your needs. The Yocto Project and OpenEmbedded communities |
| maintain many recipes that might be candidates for what you are doing. |
| You can find a good central index of these recipes in the |
| :oe_layerindex:`OpenEmbedded Layer Index <>`. |
| |
| Working from an existing recipe or a skeleton recipe is the best way to |
| get started. Here are some points on both methods: |
| |
| - *Locate and modify a recipe that is close to what you want to do:* |
| This method works when you are familiar with the current recipe |
| space. The method does not work so well for those new to the Yocto |
| Project or writing recipes. |
| |
| Some risks associated with this method are using a recipe that has |
| areas totally unrelated to what you are trying to accomplish with |
| your recipe, not recognizing areas of the recipe that you might have |
| to add from scratch, and so forth. All these risks stem from |
| unfamiliarity with the existing recipe space. |
| |
| - *Use and modify the following skeleton recipe:* If for some reason |
| you do not want to use ``recipetool`` and you cannot find an existing |
| recipe that is close to meeting your needs, you can use the following |
| structure to provide the fundamental areas of a new recipe. |
| :: |
| |
| DESCRIPTION = "" |
| HOMEPAGE = "" |
| LICENSE = "" |
| SECTION = "" |
| DEPENDS = "" |
| LIC_FILES_CHKSUM = "" |
| |
| SRC_URI = "" |
| |
| Storing and Naming the Recipe |
| ----------------------------- |
| |
| Once you have your base recipe, you should put it in your own layer and |
| name it appropriately. Locating it correctly ensures that the |
| OpenEmbedded build system can find it when you use BitBake to process |
| the recipe. |
| |
| - *Storing Your Recipe:* The OpenEmbedded build system locates your |
| recipe through the layer's ``conf/layer.conf`` file and the |
| :term:`BBFILES` variable. This |
| variable sets up a path from which the build system can locate |
| recipes. Here is the typical use:: |
| |
| BBFILES += "${LAYERDIR}/recipes-*/*/*.bb \ |
| ${LAYERDIR}/recipes-*/*/*.bbappend" |
| |
| Consequently, you need to be sure you locate your new recipe inside |
| your layer such that it can be found. |
| |
| You can find more information on how layers are structured in the |
| ":ref:`dev-manual/common-tasks:understanding and creating layers`" section. |
| |
| - *Naming Your Recipe:* When you name your recipe, you need to follow |
| this naming convention:: |
| |
| basename_version.bb |
| |
| Use lower-cased characters and do not include the reserved suffixes |
| ``-native``, ``-cross``, ``-initial``, or ``-dev`` casually (i.e. do not use |
| them as part of your recipe name unless the string applies). Here are some |
| examples: |
| |
| .. code-block:: none |
| |
| cups_1.7.0.bb |
| gawk_4.0.2.bb |
| irssi_0.8.16-rc1.bb |
| |
| Running a Build on the Recipe |
| ----------------------------- |
| |
| Creating a new recipe is usually an iterative process that requires |
| using BitBake to process the recipe multiple times in order to |
| progressively discover and add information to the recipe file. |
| |
| Assuming you have sourced the build environment setup script (i.e. |
| :ref:`structure-core-script`) and you are in |
| the :term:`Build Directory`, use |
| BitBake to process your recipe. All you need to provide is the |
| ``basename`` of the recipe as described in the previous section:: |
| |
| $ bitbake basename |
| |
| During the build, the OpenEmbedded build system creates a temporary work |
| directory for each recipe |
| (``${``\ :term:`WORKDIR`\ ``}``) |
| where it keeps extracted source files, log files, intermediate |
| compilation and packaging files, and so forth. |
| |
| The path to the per-recipe temporary work directory depends on the |
| context in which it is being built. The quickest way to find this path |
| is to have BitBake return it by running the following:: |
| |
| $ bitbake -e basename | grep ^WORKDIR= |
| |
| As an example, assume a Source Directory |
| top-level folder named ``poky``, a default Build Directory at |
| ``poky/build``, and a ``qemux86-poky-linux`` machine target system. |
| Furthermore, suppose your recipe is named ``foo_1.3.0.bb``. In this |
| case, the work directory the build system uses to build the package |
| would be as follows:: |
| |
| poky/build/tmp/work/qemux86-poky-linux/foo/1.3.0-r0 |
| |
| Inside this directory you can find sub-directories such as ``image``, |
| ``packages-split``, and ``temp``. After the build, you can examine these |
| to determine how well the build went. |
| |
| .. note:: |
| |
| You can find log files for each task in the recipe's ``temp`` |
| directory (e.g. ``poky/build/tmp/work/qemux86-poky-linux/foo/1.3.0-r0/temp``). |
| Log files are named ``log.taskname`` (e.g. ``log.do_configure``, |
| ``log.do_fetch``, and ``log.do_compile``). |
| |
| You can find more information about the build process in |
| ":doc:`/overview-manual/development-environment`" |
| chapter of the Yocto Project Overview and Concepts Manual. |
| |
| Fetching Code |
| ------------- |
| |
| The first thing your recipe must do is specify how to fetch the source |
| files. Fetching is controlled mainly through the |
| :term:`SRC_URI` variable. Your recipe |
| must have a :term:`SRC_URI` variable that points to where the source is |
| located. For a graphical representation of source locations, see the |
| ":ref:`overview-manual/concepts:sources`" section in |
| the Yocto Project Overview and Concepts Manual. |
| |
| The :ref:`ref-tasks-fetch` task uses |
| the prefix of each entry in the :term:`SRC_URI` variable value to determine |
| which :ref:`fetcher <bitbake:bitbake-user-manual/bitbake-user-manual-fetching:fetchers>` to use to get your |
| source files. It is the :term:`SRC_URI` variable that triggers the fetcher. |
| The :ref:`ref-tasks-patch` task uses |
| the variable after source is fetched to apply patches. The OpenEmbedded |
| build system uses |
| :term:`FILESOVERRIDES` for |
| scanning directory locations for local files in :term:`SRC_URI`. |
| |
| The :term:`SRC_URI` variable in your recipe must define each unique location |
| for your source files. It is good practice to not hard-code version |
| numbers in a URL used in :term:`SRC_URI`. Rather than hard-code these |
| values, use ``${``\ :term:`PV`\ ``}``, |
| which causes the fetch process to use the version specified in the |
| recipe filename. Specifying the version in this manner means that |
| upgrading the recipe to a future version is as simple as renaming the |
| recipe to match the new version. |
| |
| Here is a simple example from the |
| ``meta/recipes-devtools/strace/strace_5.5.bb`` recipe where the source |
| comes from a single tarball. Notice the use of the |
| :term:`PV` variable:: |
| |
| SRC_URI = "https://strace.io/files/${PV}/strace-${PV}.tar.xz \ |
| |
| Files mentioned in :term:`SRC_URI` whose names end in a typical archive |
| extension (e.g. ``.tar``, ``.tar.gz``, ``.tar.bz2``, ``.zip``, and so |
| forth), are automatically extracted during the |
| :ref:`ref-tasks-unpack` task. For |
| another example that specifies these types of files, see the |
| ":ref:`dev-manual/common-tasks:autotooled package`" section. |
| |
| Another way of specifying source is from an SCM. For Git repositories, |
| you must specify :term:`SRCREV` and |
| you should specify :term:`PV` to include |
| the revision with :term:`SRCPV`. Here |
| is an example from the recipe |
| ``meta/recipes-kernel/blktrace/blktrace_git.bb``:: |
| |
| SRCREV = "d6918c8832793b4205ed3bfede78c2f915c23385" |
| |
| PR = "r6" |
| PV = "1.0.5+git${SRCPV}" |
| |
| SRC_URI = "git://git.kernel.dk/blktrace.git \ |
| file://ldflags.patch" |
| |
| If your :term:`SRC_URI` statement includes URLs pointing to individual files |
| fetched from a remote server other than a version control system, |
| BitBake attempts to verify the files against checksums defined in your |
| recipe to ensure they have not been tampered with or otherwise modified |
| since the recipe was written. Two checksums are used: |
| ``SRC_URI[md5sum]`` and ``SRC_URI[sha256sum]``. |
| |
| If your :term:`SRC_URI` variable points to more than a single URL (excluding |
| SCM URLs), you need to provide the ``md5`` and ``sha256`` checksums for |
| each URL. For these cases, you provide a name for each URL as part of |
| the :term:`SRC_URI` and then reference that name in the subsequent checksum |
| statements. Here is an example combining lines from the files |
| ``git.inc`` and ``git_2.24.1.bb``:: |
| |
| SRC_URI = "${KERNELORG_MIRROR}/software/scm/git/git-${PV}.tar.gz;name=tarball \ |
| ${KERNELORG_MIRROR}/software/scm/git/git-manpages-${PV}.tar.gz;name=manpages" |
| |
| SRC_URI[tarball.md5sum] = "166bde96adbbc11c8843d4f8f4f9811b" |
| SRC_URI[tarball.sha256sum] = "ad5334956301c86841eb1e5b1bb20884a6bad89a10a6762c958220c7cf64da02" |
| SRC_URI[manpages.md5sum] = "31c2272a8979022497ba3d4202df145d" |
| SRC_URI[manpages.sha256sum] = "9a7ae3a093bea39770eb96ca3e5b40bff7af0b9f6123f089d7821d0e5b8e1230" |
| |
| Proper values for ``md5`` and ``sha256`` checksums might be available |
| with other signatures on the download page for the upstream source (e.g. |
| ``md5``, ``sha1``, ``sha256``, ``GPG``, and so forth). Because the |
| OpenEmbedded build system only deals with ``sha256sum`` and ``md5sum``, |
| you should verify all the signatures you find by hand. |
| |
| If no :term:`SRC_URI` checksums are specified when you attempt to build the |
| recipe, or you provide an incorrect checksum, the build will produce an |
| error for each missing or incorrect checksum. As part of the error |
| message, the build system provides the checksum string corresponding to |
| the fetched file. Once you have the correct checksums, you can copy and |
| paste them into your recipe and then run the build again to continue. |
| |
| .. note:: |
| |
| As mentioned, if the upstream source provides signatures for |
| verifying the downloaded source code, you should verify those |
| manually before setting the checksum values in the recipe and |
| continuing with the build. |
| |
| This final example is a bit more complicated and is from the |
| ``meta/recipes-sato/rxvt-unicode/rxvt-unicode_9.20.bb`` recipe. The |
| example's :term:`SRC_URI` statement identifies multiple files as the source |
| files for the recipe: a tarball, a patch file, a desktop file, and an |
| icon. |
| :: |
| |
| SRC_URI = "http://dist.schmorp.de/rxvt-unicode/Attic/rxvt-unicode-${PV}.tar.bz2 \ |
| file://xwc.patch \ |
| file://rxvt.desktop \ |
| file://rxvt.png" |
| |
| When you specify local files using the ``file://`` URI protocol, the |
| build system fetches files from the local machine. The path is relative |
| to the :term:`FILESPATH` variable |
| and searches specific directories in a certain order: |
| ``${``\ :term:`BP`\ ``}``, |
| ``${``\ :term:`BPN`\ ``}``, and |
| ``files``. The directories are assumed to be subdirectories of the |
| directory in which the recipe or append file resides. For another |
| example that specifies these types of files, see the |
| ":ref:`dev-manual/common-tasks:single .c file package (hello world!)`" section. |
| |
| The previous example also specifies a patch file. Patch files are files |
| whose names usually end in ``.patch`` or ``.diff`` but can end with |
| compressed suffixes such as ``diff.gz`` and ``patch.bz2``, for example. |
| The build system automatically applies patches as described in the |
| ":ref:`dev-manual/common-tasks:patching code`" section. |
| |
| Unpacking Code |
| -------------- |
| |
| During the build, the |
| :ref:`ref-tasks-unpack` task unpacks |
| the source with ``${``\ :term:`S`\ ``}`` |
| pointing to where it is unpacked. |
| |
| If you are fetching your source files from an upstream source archived |
| tarball and the tarball's internal structure matches the common |
| convention of a top-level subdirectory named |
| ``${``\ :term:`BPN`\ ``}-${``\ :term:`PV`\ ``}``, |
| then you do not need to set :term:`S`. However, if :term:`SRC_URI` specifies to |
| fetch source from an archive that does not use this convention, or from |
| an SCM like Git or Subversion, your recipe needs to define :term:`S`. |
| |
| If processing your recipe using BitBake successfully unpacks the source |
| files, you need to be sure that the directory pointed to by ``${S}`` |
| matches the structure of the source. |
| |
| Patching Code |
| ------------- |
| |
| Sometimes it is necessary to patch code after it has been fetched. Any |
| files mentioned in :term:`SRC_URI` whose names end in ``.patch`` or |
| ``.diff`` or compressed versions of these suffixes (e.g. ``diff.gz`` are |
| treated as patches. The |
| :ref:`ref-tasks-patch` task |
| automatically applies these patches. |
| |
| The build system should be able to apply patches with the "-p1" option |
| (i.e. one directory level in the path will be stripped off). If your |
| patch needs to have more directory levels stripped off, specify the |
| number of levels using the "striplevel" option in the :term:`SRC_URI` entry |
| for the patch. Alternatively, if your patch needs to be applied in a |
| specific subdirectory that is not specified in the patch file, use the |
| "patchdir" option in the entry. |
| |
| As with all local files referenced in |
| :term:`SRC_URI` using ``file://``, |
| you should place patch files in a directory next to the recipe either |
| named the same as the base name of the recipe |
| (:term:`BP` and |
| :term:`BPN`) or "files". |
| |
| Licensing |
| --------- |
| |
| Your recipe needs to have both the |
| :term:`LICENSE` and |
| :term:`LIC_FILES_CHKSUM` |
| variables: |
| |
| - :term:`LICENSE`: This variable specifies the license for the software. |
| If you do not know the license under which the software you are |
| building is distributed, you should go to the source code and look |
| for that information. Typical files containing this information |
| include ``COPYING``, :term:`LICENSE`, and ``README`` files. You could |
| also find the information near the top of a source file. For example, |
| given a piece of software licensed under the GNU General Public |
| License version 2, you would set :term:`LICENSE` as follows:: |
| |
| LICENSE = "GPLv2" |
| |
| The licenses you specify within :term:`LICENSE` can have any name as long |
| as you do not use spaces, since spaces are used as separators between |
| license names. For standard licenses, use the names of the files in |
| ``meta/files/common-licenses/`` or the :term:`SPDXLICENSEMAP` flag names |
| defined in ``meta/conf/licenses.conf``. |
| |
| - :term:`LIC_FILES_CHKSUM`: The OpenEmbedded build system uses this |
| variable to make sure the license text has not changed. If it has, |
| the build produces an error and it affords you the chance to figure |
| it out and correct the problem. |
| |
| You need to specify all applicable licensing files for the software. |
| At the end of the configuration step, the build process will compare |
| the checksums of the files to be sure the text has not changed. Any |
| differences result in an error with the message containing the |
| current checksum. For more explanation and examples of how to set the |
| :term:`LIC_FILES_CHKSUM` variable, see the |
| ":ref:`dev-manual/common-tasks:tracking license changes`" section. |
| |
| To determine the correct checksum string, you can list the |
| appropriate files in the :term:`LIC_FILES_CHKSUM` variable with incorrect |
| md5 strings, attempt to build the software, and then note the |
| resulting error messages that will report the correct md5 strings. |
| See the ":ref:`dev-manual/common-tasks:fetching code`" section for |
| additional information. |
| |
| Here is an example that assumes the software has a ``COPYING`` file:: |
| |
| LIC_FILES_CHKSUM = "file://COPYING;md5=xxx" |
| |
| When you try to build the |
| software, the build system will produce an error and give you the |
| correct string that you can substitute into the recipe file for a |
| subsequent build. |
| |
| Dependencies |
| ------------ |
| |
| Most software packages have a short list of other packages that they |
| require, which are called dependencies. These dependencies fall into two |
| main categories: build-time dependencies, which are required when the |
| software is built; and runtime dependencies, which are required to be |
| installed on the target in order for the software to run. |
| |
| Within a recipe, you specify build-time dependencies using the |
| :term:`DEPENDS` variable. Although there are nuances, |
| items specified in :term:`DEPENDS` should be names of other |
| recipes. It is important that you specify all build-time dependencies |
| explicitly. |
| |
| Another consideration is that configure scripts might automatically |
| check for optional dependencies and enable corresponding functionality |
| if those dependencies are found. If you wish to make a recipe that is |
| more generally useful (e.g. publish the recipe in a layer for others to |
| use), instead of hard-disabling the functionality, you can use the |
| :term:`PACKAGECONFIG` variable to allow functionality and the |
| corresponding dependencies to be enabled and disabled easily by other |
| users of the recipe. |
| |
| Similar to build-time dependencies, you specify runtime dependencies |
| through a variable - |
| :term:`RDEPENDS`, which is |
| package-specific. All variables that are package-specific need to have |
| the name of the package added to the end as an override. Since the main |
| package for a recipe has the same name as the recipe, and the recipe's |
| name can be found through the |
| ``${``\ :term:`PN`\ ``}`` variable, then |
| you specify the dependencies for the main package by setting |
| ``RDEPENDS:${PN}``. If the package were named ``${PN}-tools``, then you |
| would set ``RDEPENDS:${PN}-tools``, and so forth. |
| |
| Some runtime dependencies will be set automatically at packaging time. |
| These dependencies include any shared library dependencies (i.e. if a |
| package "example" contains "libexample" and another package "mypackage" |
| contains a binary that links to "libexample" then the OpenEmbedded build |
| system will automatically add a runtime dependency to "mypackage" on |
| "example"). See the |
| ":ref:`overview-manual/concepts:automatically added runtime dependencies`" |
| section in the Yocto Project Overview and Concepts Manual for further |
| details. |
| |
| Configuring the Recipe |
| ---------------------- |
| |
| Most software provides some means of setting build-time configuration |
| options before compilation. Typically, setting these options is |
| accomplished by running a configure script with options, or by modifying |
| a build configuration file. |
| |
| .. note:: |
| |
| As of Yocto Project Release 1.7, some of the core recipes that |
| package binary configuration scripts now disable the scripts due to |
| the scripts previously requiring error-prone path substitution. The |
| OpenEmbedded build system uses ``pkg-config`` now, which is much more |
| robust. You can find a list of the ``*-config`` scripts that are disabled |
| in the ":ref:`migration-1.7-binary-configuration-scripts-disabled`" section |
| in the Yocto Project Reference Manual. |
| |
| A major part of build-time configuration is about checking for |
| build-time dependencies and possibly enabling optional functionality as |
| a result. You need to specify any build-time dependencies for the |
| software you are building in your recipe's |
| :term:`DEPENDS` value, in terms of |
| other recipes that satisfy those dependencies. You can often find |
| build-time or runtime dependencies described in the software's |
| documentation. |
| |
| The following list provides configuration items of note based on how |
| your software is built: |
| |
| - *Autotools:* If your source files have a ``configure.ac`` file, then |
| your software is built using Autotools. If this is the case, you just |
| need to modify the configuration. |
| |
| When using Autotools, your recipe needs to inherit the |
| :ref:`autotools <ref-classes-autotools>` class |
| and your recipe does not have to contain a |
| :ref:`ref-tasks-configure` task. |
| However, you might still want to make some adjustments. For example, |
| you can set |
| :term:`EXTRA_OECONF` or |
| :term:`PACKAGECONFIG_CONFARGS` |
| to pass any needed configure options that are specific to the recipe. |
| |
| - *CMake:* If your source files have a ``CMakeLists.txt`` file, then |
| your software is built using CMake. If this is the case, you just |
| need to modify the configuration. |
| |
| When you use CMake, your recipe needs to inherit the |
| :ref:`cmake <ref-classes-cmake>` class and your |
| recipe does not have to contain a |
| :ref:`ref-tasks-configure` task. |
| You can make some adjustments by setting |
| :term:`EXTRA_OECMAKE` to |
| pass any needed configure options that are specific to the recipe. |
| |
| .. note:: |
| |
| If you need to install one or more custom CMake toolchain files |
| that are supplied by the application you are building, install the |
| files to ``${D}${datadir}/cmake/Modules`` during ``do_install``. |
| |
| - *Other:* If your source files do not have a ``configure.ac`` or |
| ``CMakeLists.txt`` file, then your software is built using some |
| method other than Autotools or CMake. If this is the case, you |
| normally need to provide a |
| :ref:`ref-tasks-configure` task |
| in your recipe unless, of course, there is nothing to configure. |
| |
| Even if your software is not being built by Autotools or CMake, you |
| still might not need to deal with any configuration issues. You need |
| to determine if configuration is even a required step. You might need |
| to modify a Makefile or some configuration file used for the build to |
| specify necessary build options. Or, perhaps you might need to run a |
| provided, custom configure script with the appropriate options. |
| |
| For the case involving a custom configure script, you would run |
| ``./configure --help`` and look for the options you need to set. |
| |
| Once configuration succeeds, it is always good practice to look at the |
| ``log.do_configure`` file to ensure that the appropriate options have |
| been enabled and no additional build-time dependencies need to be added |
| to :term:`DEPENDS`. For example, if the configure script reports that it |
| found something not mentioned in :term:`DEPENDS`, or that it did not find |
| something that it needed for some desired optional functionality, then |
| you would need to add those to :term:`DEPENDS`. Looking at the log might |
| also reveal items being checked for, enabled, or both that you do not |
| want, or items not being found that are in :term:`DEPENDS`, in which case |
| you would need to look at passing extra options to the configure script |
| as needed. For reference information on configure options specific to |
| the software you are building, you can consult the output of the |
| ``./configure --help`` command within ``${S}`` or consult the software's |
| upstream documentation. |
| |
| Using Headers to Interface with Devices |
| --------------------------------------- |
| |
| If your recipe builds an application that needs to communicate with some |
| device or needs an API into a custom kernel, you will need to provide |
| appropriate header files. Under no circumstances should you ever modify |
| the existing |
| ``meta/recipes-kernel/linux-libc-headers/linux-libc-headers.inc`` file. |
| These headers are used to build ``libc`` and must not be compromised |
| with custom or machine-specific header information. If you customize |
| ``libc`` through modified headers all other applications that use |
| ``libc`` thus become affected. |
| |
| .. note:: |
| |
| Never copy and customize the ``libc`` header file (i.e. |
| ``meta/recipes-kernel/linux-libc-headers/linux-libc-headers.inc``). |
| |
| The correct way to interface to a device or custom kernel is to use a |
| separate package that provides the additional headers for the driver or |
| other unique interfaces. When doing so, your application also becomes |
| responsible for creating a dependency on that specific provider. |
| |
| Consider the following: |
| |
| - Never modify ``linux-libc-headers.inc``. Consider that file to be |
| part of the ``libc`` system, and not something you use to access the |
| kernel directly. You should access ``libc`` through specific ``libc`` |
| calls. |
| |
| - Applications that must talk directly to devices should either provide |
| necessary headers themselves, or establish a dependency on a special |
| headers package that is specific to that driver. |
| |
| For example, suppose you want to modify an existing header that adds I/O |
| control or network support. If the modifications are used by a small |
| number programs, providing a unique version of a header is easy and has |
| little impact. When doing so, bear in mind the guidelines in the |
| previous list. |
| |
| .. note:: |
| |
| If for some reason your changes need to modify the behavior of the ``libc``, |
| and subsequently all other applications on the system, use a ``.bbappend`` |
| to modify the ``linux-kernel-headers.inc`` file. However, take care to not |
| make the changes machine specific. |
| |
| Consider a case where your kernel is older and you need an older |
| ``libc`` ABI. The headers installed by your recipe should still be a |
| standard mainline kernel, not your own custom one. |
| |
| When you use custom kernel headers you need to get them from |
| :term:`STAGING_KERNEL_DIR`, |
| which is the directory with kernel headers that are required to build |
| out-of-tree modules. Your recipe will also need the following:: |
| |
| do_configure[depends] += "virtual/kernel:do_shared_workdir" |
| |
| Compilation |
| ----------- |
| |
| During a build, the ``do_compile`` task happens after source is fetched, |
| unpacked, and configured. If the recipe passes through ``do_compile`` |
| successfully, nothing needs to be done. |
| |
| However, if the compile step fails, you need to diagnose the failure. |
| Here are some common issues that cause failures. |
| |
| .. note:: |
| |
| For cases where improper paths are detected for configuration files |
| or for when libraries/headers cannot be found, be sure you are using |
| the more robust ``pkg-config``. See the note in section |
| ":ref:`dev-manual/common-tasks:Configuring the Recipe`" for additional information. |
| |
| - *Parallel build failures:* These failures manifest themselves as |
| intermittent errors, or errors reporting that a file or directory |
| that should be created by some other part of the build process could |
| not be found. This type of failure can occur even if, upon |
| inspection, the file or directory does exist after the build has |
| failed, because that part of the build process happened in the wrong |
| order. |
| |
| To fix the problem, you need to either satisfy the missing dependency |
| in the Makefile or whatever script produced the Makefile, or (as a |
| workaround) set :term:`PARALLEL_MAKE` to an empty string:: |
| |
| PARALLEL_MAKE = "" |
| |
| For information on parallel Makefile issues, see the |
| ":ref:`dev-manual/common-tasks:debugging parallel make races`" section. |
| |
| - *Improper host path usage:* This failure applies to recipes building |
| for the target or ``nativesdk`` only. The failure occurs when the |
| compilation process uses improper headers, libraries, or other files |
| from the host system when cross-compiling for the target. |
| |
| To fix the problem, examine the ``log.do_compile`` file to identify |
| the host paths being used (e.g. ``/usr/include``, ``/usr/lib``, and |
| so forth) and then either add configure options, apply a patch, or do |
| both. |
| |
| - *Failure to find required libraries/headers:* If a build-time |
| dependency is missing because it has not been declared in |
| :term:`DEPENDS`, or because the |
| dependency exists but the path used by the build process to find the |
| file is incorrect and the configure step did not detect it, the |
| compilation process could fail. For either of these failures, the |
| compilation process notes that files could not be found. In these |
| cases, you need to go back and add additional options to the |
| configure script as well as possibly add additional build-time |
| dependencies to :term:`DEPENDS`. |
| |
| Occasionally, it is necessary to apply a patch to the source to |
| ensure the correct paths are used. If you need to specify paths to |
| find files staged into the sysroot from other recipes, use the |
| variables that the OpenEmbedded build system provides (e.g. |
| :term:`STAGING_BINDIR`, :term:`STAGING_INCDIR`, :term:`STAGING_DATADIR`, and so |
| forth). |
| |
| Installing |
| ---------- |
| |
| During ``do_install``, the task copies the built files along with their |
| hierarchy to locations that would mirror their locations on the target |
| device. The installation process copies files from the |
| ``${``\ :term:`S`\ ``}``, |
| ``${``\ :term:`B`\ ``}``, and |
| ``${``\ :term:`WORKDIR`\ ``}`` |
| directories to the ``${``\ :term:`D`\ ``}`` |
| directory to create the structure as it should appear on the target |
| system. |
| |
| How your software is built affects what you must do to be sure your |
| software is installed correctly. The following list describes what you |
| must do for installation depending on the type of build system used by |
| the software being built: |
| |
| - *Autotools and CMake:* If the software your recipe is building uses |
| Autotools or CMake, the OpenEmbedded build system understands how to |
| install the software. Consequently, you do not have to have a |
| ``do_install`` task as part of your recipe. You just need to make |
| sure the install portion of the build completes with no issues. |
| However, if you wish to install additional files not already being |
| installed by ``make install``, you should do this using a |
| ``do_install:append`` function using the install command as described |
| in the "Manual" bulleted item later in this list. |
| |
| - *Other (using* ``make install``\ *)*: You need to define a ``do_install`` |
| function in your recipe. The function should call |
| ``oe_runmake install`` and will likely need to pass in the |
| destination directory as well. How you pass that path is dependent on |
| how the ``Makefile`` being run is written (e.g. ``DESTDIR=${D}``, |
| ``PREFIX=${D}``, ``INSTALLROOT=${D}``, and so forth). |
| |
| For an example recipe using ``make install``, see the |
| ":ref:`dev-manual/common-tasks:makefile-based package`" section. |
| |
| - *Manual:* You need to define a ``do_install`` function in your |
| recipe. The function must first use ``install -d`` to create the |
| directories under |
| ``${``\ :term:`D`\ ``}``. Once the |
| directories exist, your function can use ``install`` to manually |
| install the built software into the directories. |
| |
| You can find more information on ``install`` at |
| https://www.gnu.org/software/coreutils/manual/html_node/install-invocation.html. |
| |
| For the scenarios that do not use Autotools or CMake, you need to track |
| the installation and diagnose and fix any issues until everything |
| installs correctly. You need to look in the default location of |
| ``${D}``, which is ``${WORKDIR}/image``, to be sure your files have been |
| installed correctly. |
| |
| .. note:: |
| |
| - During the installation process, you might need to modify some of |
| the installed files to suit the target layout. For example, you |
| might need to replace hard-coded paths in an initscript with |
| values of variables provided by the build system, such as |
| replacing ``/usr/bin/`` with ``${bindir}``. If you do perform such |
| modifications during ``do_install``, be sure to modify the |
| destination file after copying rather than before copying. |
| Modifying after copying ensures that the build system can |
| re-execute ``do_install`` if needed. |
| |
| - ``oe_runmake install``, which can be run directly or can be run |
| indirectly by the |
| :ref:`autotools <ref-classes-autotools>` and |
| :ref:`cmake <ref-classes-cmake>` classes, |
| runs ``make install`` in parallel. Sometimes, a Makefile can have |
| missing dependencies between targets that can result in race |
| conditions. If you experience intermittent failures during |
| ``do_install``, you might be able to work around them by disabling |
| parallel Makefile installs by adding the following to the recipe:: |
| |
| PARALLEL_MAKEINST = "" |
| |
| See :term:`PARALLEL_MAKEINST` for additional information. |
| |
| - If you need to install one or more custom CMake toolchain files |
| that are supplied by the application you are building, install the |
| files to ``${D}${datadir}/cmake/Modules`` during |
| :ref:`ref-tasks-install`. |
| |
| Enabling System Services |
| ------------------------ |
| |
| If you want to install a service, which is a process that usually starts |
| on boot and runs in the background, then you must include some |
| additional definitions in your recipe. |
| |
| If you are adding services and the service initialization script or the |
| service file itself is not installed, you must provide for that |
| installation in your recipe using a ``do_install:append`` function. If |
| your recipe already has a ``do_install`` function, update the function |
| near its end rather than adding an additional ``do_install:append`` |
| function. |
| |
| When you create the installation for your services, you need to |
| accomplish what is normally done by ``make install``. In other words, |
| make sure your installation arranges the output similar to how it is |
| arranged on the target system. |
| |
| The OpenEmbedded build system provides support for starting services two |
| different ways: |
| |
| - *SysVinit:* SysVinit is a system and service manager that manages the |
| init system used to control the very basic functions of your system. |
| The init program is the first program started by the Linux kernel |
| when the system boots. Init then controls the startup, running and |
| shutdown of all other programs. |
| |
| To enable a service using SysVinit, your recipe needs to inherit the |
| :ref:`update-rc.d <ref-classes-update-rc.d>` |
| class. The class helps facilitate safely installing the package on |
| the target. |
| |
| You will need to set the |
| :term:`INITSCRIPT_PACKAGES`, |
| :term:`INITSCRIPT_NAME`, |
| and |
| :term:`INITSCRIPT_PARAMS` |
| variables within your recipe. |
| |
| - *systemd:* System Management Daemon (systemd) was designed to replace |
| SysVinit and to provide enhanced management of services. For more |
| information on systemd, see the systemd homepage at |
| https://freedesktop.org/wiki/Software/systemd/. |
| |
| To enable a service using systemd, your recipe needs to inherit the |
| :ref:`systemd <ref-classes-systemd>` class. See |
| the ``systemd.bbclass`` file located in your :term:`Source Directory` |
| section for |
| more information. |
| |
| Packaging |
| --------- |
| |
| Successful packaging is a combination of automated processes performed |
| by the OpenEmbedded build system and some specific steps you need to |
| take. The following list describes the process: |
| |
| - *Splitting Files*: The ``do_package`` task splits the files produced |
| by the recipe into logical components. Even software that produces a |
| single binary might still have debug symbols, documentation, and |
| other logical components that should be split out. The ``do_package`` |
| task ensures that files are split up and packaged correctly. |
| |
| - *Running QA Checks*: The |
| :ref:`insane <ref-classes-insane>` class adds a |
| step to the package generation process so that output quality |
| assurance checks are generated by the OpenEmbedded build system. This |
| step performs a range of checks to be sure the build's output is free |
| of common problems that show up during runtime. For information on |
| these checks, see the |
| :ref:`insane <ref-classes-insane>` class and |
| the ":ref:`ref-manual/qa-checks:qa error and warning messages`" |
| chapter in the Yocto Project Reference Manual. |
| |
| - *Hand-Checking Your Packages*: After you build your software, you |
| need to be sure your packages are correct. Examine the |
| ``${``\ :term:`WORKDIR`\ ``}/packages-split`` |
| directory and make sure files are where you expect them to be. If you |
| discover problems, you can set |
| :term:`PACKAGES`, |
| :term:`FILES`, |
| ``do_install(:append)``, and so forth as needed. |
| |
| - *Splitting an Application into Multiple Packages*: If you need to |
| split an application into several packages, see the |
| ":ref:`dev-manual/common-tasks:splitting an application into multiple packages`" |
| section for an example. |
| |
| - *Installing a Post-Installation Script*: For an example showing how |
| to install a post-installation script, see the |
| ":ref:`dev-manual/common-tasks:post-installation scripts`" section. |
| |
| - *Marking Package Architecture*: Depending on what your recipe is |
| building and how it is configured, it might be important to mark the |
| packages produced as being specific to a particular machine, or to |
| mark them as not being specific to a particular machine or |
| architecture at all. |
| |
| By default, packages apply to any machine with the same architecture |
| as the target machine. When a recipe produces packages that are |
| machine-specific (e.g. the |
| :term:`MACHINE` value is passed |
| into the configure script or a patch is applied only for a particular |
| machine), you should mark them as such by adding the following to the |
| recipe:: |
| |
| PACKAGE_ARCH = "${MACHINE_ARCH}" |
| |
| On the other hand, if the recipe produces packages that do not |
| contain anything specific to the target machine or architecture at |
| all (e.g. recipes that simply package script files or configuration |
| files), you should use the |
| :ref:`allarch <ref-classes-allarch>` class to |
| do this for you by adding this to your recipe:: |
| |
| inherit allarch |
| |
| Ensuring that the package architecture is correct is not critical |
| while you are doing the first few builds of your recipe. However, it |
| is important in order to ensure that your recipe rebuilds (or does |
| not rebuild) appropriately in response to changes in configuration, |
| and to ensure that you get the appropriate packages installed on the |
| target machine, particularly if you run separate builds for more than |
| one target machine. |
| |
| Sharing Files Between Recipes |
| ----------------------------- |
| |
| Recipes often need to use files provided by other recipes on the build |
| host. For example, an application linking to a common library needs |
| access to the library itself and its associated headers. The way this |
| access is accomplished is by populating a sysroot with files. Each |
| recipe has two sysroots in its work directory, one for target files |
| (``recipe-sysroot``) and one for files that are native to the build host |
| (``recipe-sysroot-native``). |
| |
| .. note:: |
| |
| You could find the term "staging" used within the Yocto project |
| regarding files populating sysroots (e.g. the :term:`STAGING_DIR` |
| variable). |
| |
| Recipes should never populate the sysroot directly (i.e. write files |
| into sysroot). Instead, files should be installed into standard |
| locations during the |
| :ref:`ref-tasks-install` task within |
| the ``${``\ :term:`D`\ ``}`` directory. The |
| reason for this limitation is that almost all files that populate the |
| sysroot are cataloged in manifests in order to ensure the files can be |
| removed later when a recipe is either modified or removed. Thus, the |
| sysroot is able to remain free from stale files. |
| |
| A subset of the files installed by the :ref:`ref-tasks-install` task are |
| used by the :ref:`ref-tasks-populate_sysroot` task as defined by the the |
| :term:`SYSROOT_DIRS` variable to automatically populate the sysroot. It |
| is possible to modify the list of directories that populate the sysroot. |
| The following example shows how you could add the ``/opt`` directory to |
| the list of directories within a recipe:: |
| |
| SYSROOT_DIRS += "/opt" |
| |
| .. note:: |
| |
| The `/sysroot-only` is to be used by recipes that generate artifacts |
| that are not included in the target filesystem, allowing them to share |
| these artifacts without needing to use the :term:`DEPLOY_DIR`. |
| |
| For a more complete description of the :ref:`ref-tasks-populate_sysroot` |
| task and its associated functions, see the |
| :ref:`staging <ref-classes-staging>` class. |
| |
| Using Virtual Providers |
| ----------------------- |
| |
| Prior to a build, if you know that several different recipes provide the |
| same functionality, you can use a virtual provider (i.e. ``virtual/*``) |
| as a placeholder for the actual provider. The actual provider is |
| determined at build-time. |
| |
| A common scenario where a virtual provider is used would be for the |
| kernel recipe. Suppose you have three kernel recipes whose |
| :term:`PN` values map to ``kernel-big``, |
| ``kernel-mid``, and ``kernel-small``. Furthermore, each of these recipes |
| in some way uses a :term:`PROVIDES` |
| statement that essentially identifies itself as being able to provide |
| ``virtual/kernel``. Here is one way through the |
| :ref:`kernel <ref-classes-kernel>` class:: |
| |
| PROVIDES += "${@ "virtual/kernel" if (d.getVar("KERNEL_PACKAGE_NAME") == "kernel") else "" }" |
| |
| Any recipe that inherits the :ref:`kernel <ref-classes-kernel>` class is |
| going to utilize a :term:`PROVIDES` statement that identifies that recipe as |
| being able to provide the ``virtual/kernel`` item. |
| |
| Now comes the time to actually build an image and you need a kernel |
| recipe, but which one? You can configure your build to call out the |
| kernel recipe you want by using the :term:`PREFERRED_PROVIDER` variable. As |
| an example, consider the :yocto_git:`x86-base.inc |
| </poky/tree/meta/conf/machine/include/x86/x86-base.inc>` include file, which is a |
| machine (i.e. :term:`MACHINE`) configuration file. This include file is the |
| reason all x86-based machines use the ``linux-yocto`` kernel. Here are the |
| relevant lines from the include file:: |
| |
| PREFERRED_PROVIDER_virtual/kernel ??= "linux-yocto" |
| PREFERRED_VERSION_linux-yocto ??= "4.15%" |
| |
| When you use a virtual provider, you do not have to "hard code" a recipe |
| name as a build dependency. You can use the |
| :term:`DEPENDS` variable to state the |
| build is dependent on ``virtual/kernel`` for example:: |
| |
| DEPENDS = "virtual/kernel" |
| |
| During the build, the OpenEmbedded build system picks |
| the correct recipe needed for the ``virtual/kernel`` dependency based on |
| the :term:`PREFERRED_PROVIDER` variable. If you want to use the small kernel |
| mentioned at the beginning of this section, configure your build as |
| follows:: |
| |
| PREFERRED_PROVIDER_virtual/kernel ??= "kernel-small" |
| |
| .. note:: |
| |
| Any recipe that :term:`PROVIDES` a ``virtual/*`` item that is ultimately not |
| selected through :term:`PREFERRED_PROVIDER` does not get built. Preventing these |
| recipes from building is usually the desired behavior since this mechanism's |
| purpose is to select between mutually exclusive alternative providers. |
| |
| The following lists specific examples of virtual providers: |
| |
| - ``virtual/kernel``: Provides the name of the kernel recipe to use |
| when building a kernel image. |
| |
| - ``virtual/bootloader``: Provides the name of the bootloader to use |
| when building an image. |
| |
| - ``virtual/libgbm``: Provides ``gbm.pc``. |
| |
| - ``virtual/egl``: Provides ``egl.pc`` and possibly ``wayland-egl.pc``. |
| |
| - ``virtual/libgl``: Provides ``gl.pc`` (i.e. libGL). |
| |
| - ``virtual/libgles1``: Provides ``glesv1_cm.pc`` (i.e. libGLESv1_CM). |
| |
| - ``virtual/libgles2``: Provides ``glesv2.pc`` (i.e. libGLESv2). |
| |
| .. note:: |
| |
| Virtual providers only apply to build time dependencies specified with |
| :term:`PROVIDES` and :term:`DEPENDS`. They do not apply to runtime |
| dependencies specified with :term:`RPROVIDES` and :term:`RDEPENDS`. |
| |
| Properly Versioning Pre-Release Recipes |
| --------------------------------------- |
| |
| Sometimes the name of a recipe can lead to versioning problems when the |
| recipe is upgraded to a final release. For example, consider the |
| ``irssi_0.8.16-rc1.bb`` recipe file in the list of example recipes in |
| the ":ref:`dev-manual/common-tasks:storing and naming the recipe`" section. |
| This recipe is at a release candidate stage (i.e. "rc1"). When the recipe is |
| released, the recipe filename becomes ``irssi_0.8.16.bb``. The version |
| change from ``0.8.16-rc1`` to ``0.8.16`` is seen as a decrease by the |
| build system and package managers, so the resulting packages will not |
| correctly trigger an upgrade. |
| |
| In order to ensure the versions compare properly, the recommended |
| convention is to set :term:`PV` within the |
| recipe to "previous_version+current_version". You can use an additional |
| variable so that you can use the current version elsewhere. Here is an |
| example:: |
| |
| REALPV = "0.8.16-rc1" |
| PV = "0.8.15+${REALPV}" |
| |
| Post-Installation Scripts |
| ------------------------- |
| |
| Post-installation scripts run immediately after installing a package on |
| the target or during image creation when a package is included in an |
| image. To add a post-installation script to a package, add a |
| ``pkg_postinst:``\ `PACKAGENAME`\ ``()`` function to the recipe file |
| (``.bb``) and replace `PACKAGENAME` with the name of the package you want |
| to attach to the ``postinst`` script. To apply the post-installation |
| script to the main package for the recipe, which is usually what is |
| required, specify |
| ``${``\ :term:`PN`\ ``}`` in place of |
| PACKAGENAME. |
| |
| A post-installation function has the following structure:: |
| |
| pkg_postinst:PACKAGENAME() { |
| # Commands to carry out |
| } |
| |
| The script defined in the post-installation function is called when the |
| root filesystem is created. If the script succeeds, the package is |
| marked as installed. |
| |
| .. note:: |
| |
| Any RPM post-installation script that runs on the target should |
| return a 0 exit code. RPM does not allow non-zero exit codes for |
| these scripts, and the RPM package manager will cause the package to |
| fail installation on the target. |
| |
| Sometimes it is necessary for the execution of a post-installation |
| script to be delayed until the first boot. For example, the script might |
| need to be executed on the device itself. To delay script execution |
| until boot time, you must explicitly mark post installs to defer to the |
| target. You can use ``pkg_postinst_ontarget()`` or call |
| ``postinst_intercept delay_to_first_boot`` from ``pkg_postinst()``. Any |
| failure of a ``pkg_postinst()`` script (including exit 1) triggers an |
| error during the |
| :ref:`ref-tasks-rootfs` task. |
| |
| If you have recipes that use ``pkg_postinst`` function and they require |
| the use of non-standard native tools that have dependencies during |
| root filesystem construction, you need to use the |
| :term:`PACKAGE_WRITE_DEPS` |
| variable in your recipe to list these tools. If you do not use this |
| variable, the tools might be missing and execution of the |
| post-installation script is deferred until first boot. Deferring the |
| script to the first boot is undesirable and impossible for read-only |
| root filesystems. |
| |
| .. note:: |
| |
| There is equivalent support for pre-install, pre-uninstall, and post-uninstall |
| scripts by way of ``pkg_preinst``, ``pkg_prerm``, and ``pkg_postrm``, |
| respectively. These scrips work in exactly the same way as does |
| ``pkg_postinst`` with the exception that they run at different times. Also, |
| because of when they run, they are not applicable to being run at image |
| creation time like ``pkg_postinst``. |
| |
| Testing |
| ------- |
| |
| The final step for completing your recipe is to be sure that the |
| software you built runs correctly. To accomplish runtime testing, add |
| the build's output packages to your image and test them on the target. |
| |
| For information on how to customize your image by adding specific |
| packages, see ":ref:`dev-manual/common-tasks:customizing images`" section. |
| |
| Examples |
| -------- |
| |
| To help summarize how to write a recipe, this section provides some |
| examples given various scenarios: |
| |
| - Recipes that use local files |
| |
| - Using an Autotooled package |
| |
| - Using a Makefile-based package |
| |
| - Splitting an application into multiple packages |
| |
| - Adding binaries to an image |
| |
| Single .c File Package (Hello World!) |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| Building an application from a single file that is stored locally (e.g. |
| under ``files``) requires a recipe that has the file listed in the |
| :term:`SRC_URI` variable. Additionally, you need to manually write the |
| ``do_compile`` and ``do_install`` tasks. The :term:`S` variable defines the |
| directory containing the source code, which is set to |
| :term:`WORKDIR` in this case - the |
| directory BitBake uses for the build. |
| :: |
| |
| SUMMARY = "Simple helloworld application" |
| SECTION = "examples" |
| LICENSE = "MIT" |
| LIC_FILES_CHKSUM = "file://${COMMON_LICENSE_DIR}/MIT;md5=0835ade698e0bcf8506ecda2f7b4f302" |
| |
| SRC_URI = "file://helloworld.c" |
| |
| S = "${WORKDIR}" |
| |
| do_compile() { |
| ${CC} ${LDFLAGS} helloworld.c -o helloworld |
| } |
| |
| do_install() { |
| install -d ${D}${bindir} |
| install -m 0755 helloworld ${D}${bindir} |
| } |
| |
| By default, the ``helloworld``, ``helloworld-dbg``, and |
| ``helloworld-dev`` packages are built. For information on how to |
| customize the packaging process, see the |
| ":ref:`dev-manual/common-tasks:splitting an application into multiple packages`" |
| section. |
| |
| Autotooled Package |
| ~~~~~~~~~~~~~~~~~~ |
| |
| Applications that use Autotools such as ``autoconf`` and ``automake`` |
| require a recipe that has a source archive listed in :term:`SRC_URI` and |
| also inherit the |
| :ref:`autotools <ref-classes-autotools>` class, |
| which contains the definitions of all the steps needed to build an |
| Autotool-based application. The result of the build is automatically |
| packaged. And, if the application uses NLS for localization, packages |
| with local information are generated (one package per language). |
| Following is one example: (``hello_2.3.bb``) |
| :: |
| |
| SUMMARY = "GNU Helloworld application" |
| SECTION = "examples" |
| LICENSE = "GPLv2+" |
| LIC_FILES_CHKSUM = "file://COPYING;md5=751419260aa954499f7abaabaa882bbe" |
| |
| SRC_URI = "${GNU_MIRROR}/hello/hello-${PV}.tar.gz" |
| |
| inherit autotools gettext |
| |
| The variable :term:`LIC_FILES_CHKSUM` is used to track source license |
| changes as described in the |
| ":ref:`dev-manual/common-tasks:tracking license changes`" section in |
| the Yocto Project Overview and Concepts Manual. You can quickly create |
| Autotool-based recipes in a manner similar to the previous example. |
| |
| Makefile-Based Package |
| ~~~~~~~~~~~~~~~~~~~~~~ |
| |
| Applications that use GNU ``make`` also require a recipe that has the |
| source archive listed in :term:`SRC_URI`. You do not need to add a |
| ``do_compile`` step since by default BitBake starts the ``make`` command |
| to compile the application. If you need additional ``make`` options, you |
| should store them in the |
| :term:`EXTRA_OEMAKE` or |
| :term:`PACKAGECONFIG_CONFARGS` |
| variables. BitBake passes these options into the GNU ``make`` |
| invocation. Note that a ``do_install`` task is still required. |
| Otherwise, BitBake runs an empty ``do_install`` task by default. |
| |
| Some applications might require extra parameters to be passed to the |
| compiler. For example, the application might need an additional header |
| path. You can accomplish this by adding to the :term:`CFLAGS` variable. The |
| following example shows this:: |
| |
| CFLAGS:prepend = "-I ${S}/include " |
| |
| In the following example, ``mtd-utils`` is a makefile-based package:: |
| |
| SUMMARY = "Tools for managing memory technology devices" |
| SECTION = "base" |
| DEPENDS = "zlib lzo e2fsprogs util-linux" |
| HOMEPAGE = "http://www.linux-mtd.infradead.org/" |
| LICENSE = "GPLv2+" |
| LIC_FILES_CHKSUM = "file://COPYING;md5=0636e73ff0215e8d672dc4c32c317bb3 \ |
| file://include/common.h;beginline=1;endline=17;md5=ba05b07912a44ea2bf81ce409380049c" |
| |
| # Use the latest version at 26 Oct, 2013 |
| SRCREV = "9f107132a6a073cce37434ca9cda6917dd8d866b" |
| SRC_URI = "git://git.infradead.org/mtd-utils.git \ |
| file://add-exclusion-to-mkfs-jffs2-git-2.patch \ |
| " |
| |
| PV = "1.5.1+git${SRCPV}" |
| |
| S = "${WORKDIR}/git" |
| |
| EXTRA_OEMAKE = "'CC=${CC}' 'RANLIB=${RANLIB}' 'AR=${AR}' 'CFLAGS=${CFLAGS} -I${S}/include -DWITHOUT_XATTR' 'BUILDDIR=${S}'" |
| |
| do_install () { |
| oe_runmake install DESTDIR=${D} SBINDIR=${sbindir} MANDIR=${mandir} INCLUDEDIR=${includedir} |
| } |
| |
| PACKAGES =+ "mtd-utils-jffs2 mtd-utils-ubifs mtd-utils-misc" |
| |
| FILES:mtd-utils-jffs2 = "${sbindir}/mkfs.jffs2 ${sbindir}/jffs2dump ${sbindir}/jffs2reader ${sbindir}/sumtool" |
| FILES:mtd-utils-ubifs = "${sbindir}/mkfs.ubifs ${sbindir}/ubi*" |
| FILES:mtd-utils-misc = "${sbindir}/nftl* ${sbindir}/ftl* ${sbindir}/rfd* ${sbindir}/doc* ${sbindir}/serve_image ${sbindir}/recv_image" |
| |
| PARALLEL_MAKE = "" |
| |
| BBCLASSEXTEND = "native" |
| |
| Splitting an Application into Multiple Packages |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| You can use the variables :term:`PACKAGES` and :term:`FILES` to split an |
| application into multiple packages. |
| |
| Following is an example that uses the ``libxpm`` recipe. By default, |
| this recipe generates a single package that contains the library along |
| with a few binaries. You can modify the recipe to split the binaries |
| into separate packages:: |
| |
| require xorg-lib-common.inc |
| |
| SUMMARY = "Xpm: X Pixmap extension library" |
| LICENSE = "MIT" |
| LIC_FILES_CHKSUM = "file://COPYING;md5=51f4270b012ecd4ab1a164f5f4ed6cf7" |
| DEPENDS += "libxext libsm libxt" |
| PE = "1" |
| |
| XORG_PN = "libXpm" |
| |
| PACKAGES =+ "sxpm cxpm" |
| FILES:cxpm = "${bindir}/cxpm" |
| FILES:sxpm = "${bindir}/sxpm" |
| |
| In the previous example, we want to ship the ``sxpm`` and ``cxpm`` |
| binaries in separate packages. Since ``bindir`` would be packaged into |
| the main :term:`PN` package by default, we prepend the :term:`PACKAGES` variable |
| so additional package names are added to the start of list. This results |
| in the extra ``FILES:*`` variables then containing information that |
| define which files and directories go into which packages. Files |
| included by earlier packages are skipped by latter packages. Thus, the |
| main :term:`PN` package does not include the above listed files. |
| |
| Packaging Externally Produced Binaries |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| Sometimes, you need to add pre-compiled binaries to an image. For |
| example, suppose that there are binaries for proprietary code, |
| created by a particular division of a company. Your part of the company |
| needs to use those binaries as part of an image that you are building |
| using the OpenEmbedded build system. Since you only have the binaries |
| and not the source code, you cannot use a typical recipe that expects to |
| fetch the source specified in |
| :term:`SRC_URI` and then compile it. |
| |
| One method is to package the binaries and then install them as part of |
| the image. Generally, it is not a good idea to package binaries since, |
| among other things, it can hinder the ability to reproduce builds and |
| could lead to compatibility problems with ABI in the future. However, |
| sometimes you have no choice. |
| |
| The easiest solution is to create a recipe that uses the |
| :ref:`bin_package <ref-classes-bin-package>` class |
| and to be sure that you are using default locations for build artifacts. |
| In most cases, the :ref:`bin_package <ref-classes-bin-package>` class handles "skipping" the |
| configure and compile steps as well as sets things up to grab packages |
| from the appropriate area. In particular, this class sets ``noexec`` on |
| both the :ref:`ref-tasks-configure` |
| and :ref:`ref-tasks-compile` tasks, |
| sets ``FILES:${PN}`` to "/" so that it picks up all files, and sets up a |
| :ref:`ref-tasks-install` task, which |
| effectively copies all files from ``${S}`` to ``${D}``. The |
| :ref:`bin_package <ref-classes-bin-package>` class works well when the files extracted into ``${S}`` |
| are already laid out in the way they should be laid out on the target. |
| For more information on these variables, see the |
| :term:`FILES`, |
| :term:`PN`, |
| :term:`S`, and |
| :term:`D` variables in the Yocto Project |
| Reference Manual's variable glossary. |
| |
| .. note:: |
| |
| - Using :term:`DEPENDS` is a good |
| idea even for components distributed in binary form, and is often |
| necessary for shared libraries. For a shared library, listing the |
| library dependencies in :term:`DEPENDS` makes sure that the libraries |
| are available in the staging sysroot when other recipes link |
| against the library, which might be necessary for successful |
| linking. |
| |
| - Using :term:`DEPENDS` also allows runtime dependencies between |
| packages to be added automatically. See the |
| ":ref:`overview-manual/concepts:automatically added runtime dependencies`" |
| section in the Yocto Project Overview and Concepts Manual for more |
| information. |
| |
| If you cannot use the :ref:`bin_package <ref-classes-bin-package>` class, you need to be sure you are |
| doing the following: |
| |
| - Create a recipe where the |
| :ref:`ref-tasks-configure` and |
| :ref:`ref-tasks-compile` tasks do |
| nothing: It is usually sufficient to just not define these tasks in |
| the recipe, because the default implementations do nothing unless a |
| Makefile is found in |
| ``${``\ :term:`S`\ ``}``. |
| |
| If ``${S}`` might contain a Makefile, or if you inherit some class |
| that replaces ``do_configure`` and ``do_compile`` with custom |
| versions, then you can use the |
| ``[``\ :ref:`noexec <bitbake-user-manual/bitbake-user-manual-metadata:variable flags>`\ ``]`` |
| flag to turn the tasks into no-ops, as follows:: |
| |
| do_configure[noexec] = "1" |
| do_compile[noexec] = "1" |
| |
| Unlike |
| :ref:`bitbake:bitbake-user-manual/bitbake-user-manual-metadata:deleting a task`, |
| using the flag preserves the dependency chain from the |
| :ref:`ref-tasks-fetch`, |
| :ref:`ref-tasks-unpack`, and |
| :ref:`ref-tasks-patch` tasks to the |
| :ref:`ref-tasks-install` task. |
| |
| - Make sure your ``do_install`` task installs the binaries |
| appropriately. |
| |
| - Ensure that you set up :term:`FILES` |
| (usually |
| ``FILES:${``\ :term:`PN`\ ``}``) to |
| point to the files you have installed, which of course depends on |
| where you have installed them and whether those files are in |
| different locations than the defaults. |
| |
| .. note:: |
| |
| If image prelinking is enabled (e.g. :ref:`image-prelink <ref-classes-image-prelink>` is in :term:`USER_CLASSES` |
| which it is by default), prelink will change the binaries in the generated images |
| and this often catches people out. Remove that class to ensure binaries are |
| preserved exactly if that is necessary. |
| |
| Following Recipe Style Guidelines |
| --------------------------------- |
| |
| When writing recipes, it is good to conform to existing style |
| guidelines. The :oe_wiki:`OpenEmbedded Styleguide </Styleguide>` wiki page |
| provides rough guidelines for preferred recipe style. |
| |
| It is common for existing recipes to deviate a bit from this style. |
| However, aiming for at least a consistent style is a good idea. Some |
| practices, such as omitting spaces around ``=`` operators in assignments |
| or ordering recipe components in an erratic way, are widely seen as poor |
| style. |
| |
| Recipe Syntax |
| ------------- |
| |
| Understanding recipe file syntax is important for writing recipes. The |
| following list overviews the basic items that make up a BitBake recipe |
| file. For more complete BitBake syntax descriptions, see the |
| ":doc:`bitbake-user-manual/bitbake-user-manual-metadata`" |
| chapter of the BitBake User Manual. |
| |
| - *Variable Assignments and Manipulations:* Variable assignments allow |
| a value to be assigned to a variable. The assignment can be static |
| text or might include the contents of other variables. In addition to |
| the assignment, appending and prepending operations are also |
| supported. |
| |
| The following example shows some of the ways you can use variables in |
| recipes:: |
| |
| S = "${WORKDIR}/postfix-${PV}" |
| CFLAGS += "-DNO_ASM" |
| SRC_URI:append = " file://fixup.patch" |
| |
| - *Functions:* Functions provide a series of actions to be performed. |
| You usually use functions to override the default implementation of a |
| task function or to complement a default function (i.e. append or |
| prepend to an existing function). Standard functions use ``sh`` shell |
| syntax, although access to OpenEmbedded variables and internal |
| methods are also available. |
| |
| Here is an example function from the ``sed`` recipe:: |
| |
| do_install () { |
| autotools_do_install |
| install -d ${D}${base_bindir} |
| mv ${D}${bindir}/sed ${D}${base_bindir}/sed |
| rmdir ${D}${bindir}/ |
| } |
| |
| It is |
| also possible to implement new functions that are called between |
| existing tasks as long as the new functions are not replacing or |
| complementing the default functions. You can implement functions in |
| Python instead of shell. Both of these options are not seen in the |
| majority of recipes. |
| |
| - *Keywords:* BitBake recipes use only a few keywords. You use keywords |
| to include common functions (``inherit``), load parts of a recipe |
| from other files (``include`` and ``require``) and export variables |
| to the environment (``export``). |
| |
| The following example shows the use of some of these keywords:: |
| |
| export POSTCONF = "${STAGING_BINDIR}/postconf" |
| inherit autoconf |
| require otherfile.inc |
| |
| - *Comments (#):* Any lines that begin with the hash character (``#``) |
| are treated as comment lines and are ignored:: |
| |
| # This is a comment |
| |
| This next list summarizes the most important and most commonly used |
| parts of the recipe syntax. For more information on these parts of the |
| syntax, you can reference the |
| :doc:`bitbake:bitbake-user-manual/bitbake-user-manual-metadata` chapter |
| in the BitBake User Manual. |
| |
| - *Line Continuation (\\):* Use the backward slash (``\``) character to |
| split a statement over multiple lines. Place the slash character at |
| the end of the line that is to be continued on the next line:: |
| |
| VAR = "A really long \ |
| line" |
| |
| .. note:: |
| |
| You cannot have any characters including spaces or tabs after the |
| slash character. |
| |
| - *Using Variables (${VARNAME}):* Use the ``${VARNAME}`` syntax to |
| access the contents of a variable:: |
| |
| SRC_URI = "${SOURCEFORGE_MIRROR}/libpng/zlib-${PV}.tar.gz" |
| |
| .. note:: |
| |
| It is important to understand that the value of a variable |
| expressed in this form does not get substituted automatically. The |
| expansion of these expressions happens on-demand later (e.g. |
| usually when a function that makes reference to the variable |
| executes). This behavior ensures that the values are most |
| appropriate for the context in which they are finally used. On the |
| rare occasion that you do need the variable expression to be |
| expanded immediately, you can use the |
| := |
| operator instead of |
| = |
| when you make the assignment, but this is not generally needed. |
| |
| - *Quote All Assignments ("value"):* Use double quotes around values in |
| all variable assignments (e.g. ``"value"``). Following is an example:: |
| |
| VAR1 = "${OTHERVAR}" |
| VAR2 = "The version is ${PV}" |
| |
| - *Conditional Assignment (?=):* Conditional assignment is used to |
| assign a value to a variable, but only when the variable is currently |
| unset. Use the question mark followed by the equal sign (``?=``) to |
| make a "soft" assignment used for conditional assignment. Typically, |
| "soft" assignments are used in the ``local.conf`` file for variables |
| that are allowed to come through from the external environment. |
| |
| Here is an example where ``VAR1`` is set to "New value" if it is |
| currently empty. However, if ``VAR1`` has already been set, it |
| remains unchanged:: |
| |
| VAR1 ?= "New value" |
| |
| In this next example, ``VAR1`` is left with the value "Original value":: |
| |
| VAR1 = "Original value" |
| VAR1 ?= "New value" |
| |
| - *Appending (+=):* Use the plus character followed by the equals sign |
| (``+=``) to append values to existing variables. |
| |
| .. note:: |
| |
| This operator adds a space between the existing content of the |
| variable and the new content. |
| |
| Here is an example:: |
| |
| SRC_URI += "file://fix-makefile.patch" |
| |
| - *Prepending (=+):* Use the equals sign followed by the plus character |
| (``=+``) to prepend values to existing variables. |
| |
| .. note:: |
| |
| This operator adds a space between the new content and the |
| existing content of the variable. |
| |
| Here is an example:: |
| |
| VAR =+ "Starts" |
| |
| - *Appending (:append):* Use the ``:append`` operator to append values |
| to existing variables. This operator does not add any additional |
| space. Also, the operator is applied after all the ``+=``, and ``=+`` |
| operators have been applied and after all ``=`` assignments have |
| occurred. |
| |
| The following example shows the space being explicitly added to the |
| start to ensure the appended value is not merged with the existing |
| value:: |
| |
| SRC_URI:append = " file://fix-makefile.patch" |
| |
| You can also use |
| the ``:append`` operator with overrides, which results in the actions |
| only being performed for the specified target or machine:: |
| |
| SRC_URI:append:sh4 = " file://fix-makefile.patch" |
| |
| - *Prepending (:prepend):* Use the ``:prepend`` operator to prepend |
| values to existing variables. This operator does not add any |
| additional space. Also, the operator is applied after all the ``+=``, |
| and ``=+`` operators have been applied and after all ``=`` |
| assignments have occurred. |
| |
| The following example shows the space being explicitly added to the |
| end to ensure the prepended value is not merged with the existing |
| value:: |
| |
| CFLAGS:prepend = "-I${S}/myincludes " |
| |
| You can also use the |
| ``:prepend`` operator with overrides, which results in the actions |
| only being performed for the specified target or machine:: |
| |
| CFLAGS:prepend:sh4 = "-I${S}/myincludes " |
| |
| - *Overrides:* You can use overrides to set a value conditionally, |
| typically based on how the recipe is being built. For example, to set |
| the :term:`KBRANCH` variable's |
| value to "standard/base" for any target |
| :term:`MACHINE`, except for |
| qemuarm where it should be set to "standard/arm-versatile-926ejs", |
| you would do the following:: |
| |
| KBRANCH = "standard/base" |
| KBRANCH:qemuarm = "standard/arm-versatile-926ejs" |
| |
| Overrides are also used to separate |
| alternate values of a variable in other situations. For example, when |
| setting variables such as |
| :term:`FILES` and |
| :term:`RDEPENDS` that are |
| specific to individual packages produced by a recipe, you should |
| always use an override that specifies the name of the package. |
| |
| - *Indentation:* Use spaces for indentation rather than tabs. For |
| shell functions, both currently work. However, it is a policy |
| decision of the Yocto Project to use tabs in shell functions. Realize |
| that some layers have a policy to use spaces for all indentation. |
| |
| - *Using Python for Complex Operations:* For more advanced processing, |
| it is possible to use Python code during variable assignments (e.g. |
| search and replacement on a variable). |
| |
| You indicate Python code using the ``${@python_code}`` syntax for the |
| variable assignment:: |
| |
| SRC_URI = "ftp://ftp.info-zip.org/pub/infozip/src/zip${@d.getVar('PV',1).replace('.', '')}.tgz |
| |
| - *Shell Function Syntax:* Write shell functions as if you were writing |
| a shell script when you describe a list of actions to take. You |
| should ensure that your script works with a generic ``sh`` and that |
| it does not require any ``bash`` or other shell-specific |
| functionality. The same considerations apply to various system |
| utilities (e.g. ``sed``, ``grep``, ``awk``, and so forth) that you |
| might wish to use. If in doubt, you should check with multiple |
| implementations - including those from BusyBox. |
| |
| Adding a New Machine |
| ==================== |
| |
| Adding a new machine to the Yocto Project is a straightforward process. |
| This section describes how to add machines that are similar to those |
| that the Yocto Project already supports. |
| |
| .. note:: |
| |
| Although well within the capabilities of the Yocto Project, adding a |
| totally new architecture might require changes to ``gcc``/``glibc`` |
| and to the site information, which is beyond the scope of this |
| manual. |
| |
| For a complete example that shows how to add a new machine, see the |
| ":ref:`bsp-guide/bsp:creating a new bsp layer using the \`\`bitbake-layers\`\` script`" |
| section in the Yocto Project Board Support Package (BSP) Developer's |
| Guide. |
| |
| Adding the Machine Configuration File |
| ------------------------------------- |
| |
| To add a new machine, you need to add a new machine configuration file |
| to the layer's ``conf/machine`` directory. This configuration file |
| provides details about the device you are adding. |
| |
| The OpenEmbedded build system uses the root name of the machine |
| configuration file to reference the new machine. For example, given a |
| machine configuration file named ``crownbay.conf``, the build system |
| recognizes the machine as "crownbay". |
| |
| The most important variables you must set in your machine configuration |
| file or include from a lower-level configuration file are as follows: |
| |
| - :term:`TARGET_ARCH` (e.g. "arm") |
| |
| - ``PREFERRED_PROVIDER_virtual/kernel`` |
| |
| - :term:`MACHINE_FEATURES` (e.g. "apm screen wifi") |
| |
| You might also need these variables: |
| |
| - :term:`SERIAL_CONSOLES` (e.g. "115200;ttyS0 115200;ttyS1") |
| |
| - :term:`KERNEL_IMAGETYPE` (e.g. "zImage") |
| |
| - :term:`IMAGE_FSTYPES` (e.g. "tar.gz jffs2") |
| |
| You can find full details on these variables in the reference section. |
| You can leverage existing machine ``.conf`` files from |
| ``meta-yocto-bsp/conf/machine/``. |
| |
| Adding a Kernel for the Machine |
| ------------------------------- |
| |
| The OpenEmbedded build system needs to be able to build a kernel for the |
| machine. You need to either create a new kernel recipe for this machine, |
| or extend an existing kernel recipe. You can find several kernel recipe |
| examples in the Source Directory at ``meta/recipes-kernel/linux`` that |
| you can use as references. |
| |
| If you are creating a new kernel recipe, normal recipe-writing rules |
| apply for setting up a :term:`SRC_URI`. Thus, you need to specify any |
| necessary patches and set :term:`S` to point at the source code. You need to |
| create a ``do_configure`` task that configures the unpacked kernel with |
| a ``defconfig`` file. You can do this by using a ``make defconfig`` |
| command or, more commonly, by copying in a suitable ``defconfig`` file |
| and then running ``make oldconfig``. By making use of ``inherit kernel`` |
| and potentially some of the ``linux-*.inc`` files, most other |
| functionality is centralized and the defaults of the class normally work |
| well. |
| |
| If you are extending an existing kernel recipe, it is usually a matter |
| of adding a suitable ``defconfig`` file. The file needs to be added into |
| a location similar to ``defconfig`` files used for other machines in a |
| given kernel recipe. A possible way to do this is by listing the file in |
| the :term:`SRC_URI` and adding the machine to the expression in |
| :term:`COMPATIBLE_MACHINE`:: |
| |
| COMPATIBLE_MACHINE = '(qemux86|qemumips)' |
| |
| For more information on ``defconfig`` files, see the |
| ":ref:`kernel-dev/common:changing the configuration`" |
| section in the Yocto Project Linux Kernel Development Manual. |
| |
| Adding a Formfactor Configuration File |
| -------------------------------------- |
| |
| A formfactor configuration file provides information about the target |
| hardware for which the image is being built and information that the |
| build system cannot obtain from other sources such as the kernel. Some |
| examples of information contained in a formfactor configuration file |
| include framebuffer orientation, whether or not the system has a |
| keyboard, the positioning of the keyboard in relation to the screen, and |
| the screen resolution. |
| |
| The build system uses reasonable defaults in most cases. However, if |
| customization is necessary, you need to create a ``machconfig`` file in |
| the ``meta/recipes-bsp/formfactor/files`` directory. This directory |
| contains directories for specific machines such as ``qemuarm`` and |
| ``qemux86``. For information about the settings available and the |
| defaults, see the ``meta/recipes-bsp/formfactor/files/config`` file |
| found in the same area. |
| |
| Following is an example for "qemuarm" machine:: |
| |
| HAVE_TOUCHSCREEN=1 |
| HAVE_KEYBOARD=1 |
| DISPLAY_CAN_ROTATE=0 |
| DISPLAY_ORIENTATION=0 |
| #DISPLAY_WIDTH_PIXELS=640 |
| #DISPLAY_HEIGHT_PIXELS=480 |
| #DISPLAY_BPP=16 |
| DISPLAY_DPI=150 |
| DISPLAY_SUBPIXEL_ORDER=vrgb |
| |
| Upgrading Recipes |
| ================= |
| |
| Over time, upstream developers publish new versions for software built |
| by layer recipes. It is recommended to keep recipes up-to-date with |
| upstream version releases. |
| |
| While there are several methods to upgrade a recipe, you might |
| consider checking on the upgrade status of a recipe first. You can do so |
| using the ``devtool check-upgrade-status`` command. See the |
| ":ref:`devtool-checking-on-the-upgrade-status-of-a-recipe`" |
| section in the Yocto Project Reference Manual for more information. |
| |
| The remainder of this section describes three ways you can upgrade a |
| recipe. You can use the Automated Upgrade Helper (AUH) to set up |
| automatic version upgrades. Alternatively, you can use |
| ``devtool upgrade`` to set up semi-automatic version upgrades. Finally, |
| you can manually upgrade a recipe by editing the recipe itself. |
| |
| Using the Auto Upgrade Helper (AUH) |
| ----------------------------------- |
| |
| The AUH utility works in conjunction with the OpenEmbedded build system |
| in order to automatically generate upgrades for recipes based on new |
| versions being published upstream. Use AUH when you want to create a |
| service that performs the upgrades automatically and optionally sends |
| you an email with the results. |
| |
| AUH allows you to update several recipes with a single use. You can also |
| optionally perform build and integration tests using images with the |
| results saved to your hard drive and emails of results optionally sent |
| to recipe maintainers. Finally, AUH creates Git commits with appropriate |
| commit messages in the layer's tree for the changes made to recipes. |
| |
| .. note:: |
| |
| In some conditions, you should not use AUH to upgrade recipes |
| and should instead use either ``devtool upgrade`` or upgrade your |
| recipes manually: |
| |
| - When AUH cannot complete the upgrade sequence. This situation |
| usually results because custom patches carried by the recipe |
| cannot be automatically rebased to the new version. In this case, |
| ``devtool upgrade`` allows you to manually resolve conflicts. |
| |
| - When for any reason you want fuller control over the upgrade |
| process. For example, when you want special arrangements for |
| testing. |
| |
| The following steps describe how to set up the AUH utility: |
| |
| 1. *Be Sure the Development Host is Set Up:* You need to be sure that |
| your development host is set up to use the Yocto Project. For |
| information on how to set up your host, see the |
| ":ref:`dev-manual/start:Preparing the Build Host`" section. |
| |
| 2. *Make Sure Git is Configured:* The AUH utility requires Git to be |
| configured because AUH uses Git to save upgrades. Thus, you must have |
| Git user and email configured. The following command shows your |
| configurations:: |
| |
| $ git config --list |
| |
| If you do not have the user and |
| email configured, you can use the following commands to do so:: |
| |
| $ git config --global user.name some_name |
| $ git config --global user.email username@domain.com |
| |
| 3. *Clone the AUH Repository:* To use AUH, you must clone the repository |
| onto your development host. The following command uses Git to create |
| a local copy of the repository on your system:: |
| |
| $ git clone git://git.yoctoproject.org/auto-upgrade-helper |
| Cloning into 'auto-upgrade-helper'... remote: Counting objects: 768, done. |
| remote: Compressing objects: 100% (300/300), done. |
| remote: Total 768 (delta 499), reused 703 (delta 434) |
| Receiving objects: 100% (768/768), 191.47 KiB | 98.00 KiB/s, done. |
| Resolving deltas: 100% (499/499), done. |
| Checking connectivity... done. |
| |
| AUH is not part of the :term:`OpenEmbedded-Core (OE-Core)` or |
| :term:`Poky` repositories. |
| |
| 4. *Create a Dedicated Build Directory:* Run the |
| :ref:`structure-core-script` |
| script to create a fresh build directory that you use exclusively for |
| running the AUH utility:: |
| |
| $ cd poky |
| $ source oe-init-build-env your_AUH_build_directory |
| |
| Re-using an existing build directory and its configurations is not |
| recommended as existing settings could cause AUH to fail or behave |
| undesirably. |
| |
| 5. *Make Configurations in Your Local Configuration File:* Several |
| settings are needed in the ``local.conf`` file in the build |
| directory you just created for AUH. Make these following |
| configurations: |
| |
| - If you want to enable :ref:`Build |
| History <dev-manual/common-tasks:maintaining build output quality>`, |
| which is optional, you need the following lines in the |
| ``conf/local.conf`` file:: |
| |
| INHERIT =+ "buildhistory" |
| BUILDHISTORY_COMMIT = "1" |
| |
| With this configuration and a successful |
| upgrade, a build history "diff" file appears in the |
| ``upgrade-helper/work/recipe/buildhistory-diff.txt`` file found in |
| your build directory. |
| |
| - If you want to enable testing through the |
| :ref:`testimage <ref-classes-testimage*>` |
| class, which is optional, you need to have the following set in |
| your ``conf/local.conf`` file:: |
| |
| INHERIT += "testimage" |
| |
| .. note:: |
| |
| If your distro does not enable by default ptest, which Poky |
| does, you need the following in your ``local.conf`` file:: |
| |
| DISTRO_FEATURES:append = " ptest" |
| |
| |
| 6. *Optionally Start a vncserver:* If you are running in a server |
| without an X11 session, you need to start a vncserver:: |
| |
| $ vncserver :1 |
| $ export DISPLAY=:1 |
| |
| 7. *Create and Edit an AUH Configuration File:* You need to have the |
| ``upgrade-helper/upgrade-helper.conf`` configuration file in your |
| build directory. You can find a sample configuration file in the |
| :yocto_git:`AUH source repository </auto-upgrade-helper/tree/>`. |
| |
| Read through the sample file and make configurations as needed. For |
| example, if you enabled build history in your ``local.conf`` as |
| described earlier, you must enable it in ``upgrade-helper.conf``. |
| |
| Also, if you are using the default ``maintainers.inc`` file supplied |
| with Poky and located in ``meta-yocto`` and you do not set a |
| "maintainers_whitelist" or "global_maintainer_override" in the |
| ``upgrade-helper.conf`` configuration, and you specify "-e all" on |
| the AUH command-line, the utility automatically sends out emails to |
| all the default maintainers. Please avoid this. |
| |
| This next set of examples describes how to use the AUH: |
| |
| - *Upgrading a Specific Recipe:* To upgrade a specific recipe, use the |
| following form:: |
| |
| $ upgrade-helper.py recipe_name |
| |
| For example, this command upgrades the ``xmodmap`` recipe:: |
| |
| $ upgrade-helper.py xmodmap |
| |
| - *Upgrading a Specific Recipe to a Particular Version:* To upgrade a |
| specific recipe to a particular version, use the following form:: |
| |
| $ upgrade-helper.py recipe_name -t version |
| |
| For example, this command upgrades the ``xmodmap`` recipe to version 1.2.3:: |
| |
| $ upgrade-helper.py xmodmap -t 1.2.3 |
| |
| - *Upgrading all Recipes to the Latest Versions and Suppressing Email |
| Notifications:* To upgrade all recipes to their most recent versions |
| and suppress the email notifications, use the following command:: |
| |
| $ upgrade-helper.py all |
| |
| - *Upgrading all Recipes to the Latest Versions and Send Email |
| Notifications:* To upgrade all recipes to their most recent versions |
| and send email messages to maintainers for each attempted recipe as |
| well as a status email, use the following command:: |
| |
| $ upgrade-helper.py -e all |
| |
| Once you have run the AUH utility, you can find the results in the AUH |
| build directory:: |
| |
| ${BUILDDIR}/upgrade-helper/timestamp |
| |
| The AUH utility |
| also creates recipe update commits from successful upgrade attempts in |
| the layer tree. |
| |
| You can easily set up to run the AUH utility on a regular basis by using |
| a cron job. See the |
| :yocto_git:`weeklyjob.sh </auto-upgrade-helper/tree/weeklyjob.sh>` |
| file distributed with the utility for an example. |
| |
| Using ``devtool upgrade`` |
| ------------------------- |
| |
| As mentioned earlier, an alternative method for upgrading recipes to |
| newer versions is to use |
| :doc:`devtool upgrade </ref-manual/devtool-reference>`. |
| You can read about ``devtool upgrade`` in general in the |
| ":ref:`sdk-manual/extensible:use \`\`devtool upgrade\`\` to create a version of the recipe that supports a newer version of the software`" |
| section in the Yocto Project Application Development and the Extensible |
| Software Development Kit (eSDK) Manual. |
| |
| To see all the command-line options available with ``devtool upgrade``, |
| use the following help command:: |
| |
| $ devtool upgrade -h |
| |
| If you want to find out what version a recipe is currently at upstream |
| without any attempt to upgrade your local version of the recipe, you can |
| use the following command:: |
| |
| $ devtool latest-version recipe_name |
| |
| As mentioned in the previous section describing AUH, ``devtool upgrade`` |
| works in a less-automated manner than AUH. Specifically, |
| ``devtool upgrade`` only works on a single recipe that you name on the |
| command line, cannot perform build and integration testing using images, |
| and does not automatically generate commits for changes in the source |
| tree. Despite all these "limitations", ``devtool upgrade`` updates the |
| recipe file to the new upstream version and attempts to rebase custom |
| patches contained by the recipe as needed. |
| |
| .. note:: |
| |
| AUH uses much of ``devtool upgrade`` behind the scenes making AUH somewhat |
| of a "wrapper" application for ``devtool upgrade``. |
| |
| A typical scenario involves having used Git to clone an upstream |
| repository that you use during build operations. Because you have built the |
| recipe in the past, the layer is likely added to your |
| configuration already. If for some reason, the layer is not added, you |
| could add it easily using the |
| ":ref:`bitbake-layers <bsp-guide/bsp:creating a new bsp layer using the \`\`bitbake-layers\`\` script>`" |
| script. For example, suppose you use the ``nano.bb`` recipe from the |
| ``meta-oe`` layer in the ``meta-openembedded`` repository. For this |
| example, assume that the layer has been cloned into following area:: |
| |
| /home/scottrif/meta-openembedded |
| |
| The following command from your |
| :term:`Build Directory` adds the layer to |
| your build configuration (i.e. ``${BUILDDIR}/conf/bblayers.conf``):: |
| |
| $ bitbake-layers add-layer /home/scottrif/meta-openembedded/meta-oe |
| NOTE: Starting bitbake server... |
| Parsing recipes: 100% |##########################################| Time: 0:00:55 |
| Parsing of 1431 .bb files complete (0 cached, 1431 parsed). 2040 targets, 56 skipped, 0 masked, 0 errors. |
| Removing 12 recipes from the x86_64 sysroot: 100% |##############| Time: 0:00:00 |
| Removing 1 recipes from the x86_64_i586 sysroot: 100% |##########| Time: 0:00:00 |
| Removing 5 recipes from the i586 sysroot: 100% |#################| Time: 0:00:00 |
| Removing 5 recipes from the qemux86 sysroot: 100% |##############| Time: 0:00:00 |
| |
| For this example, assume that the ``nano.bb`` recipe that |
| is upstream has a 2.9.3 version number. However, the version in the |
| local repository is 2.7.4. The following command from your build |
| directory automatically upgrades the recipe for you: |
| |
| .. note:: |
| |
| Using the ``-V`` option is not necessary. Omitting the version number causes |
| ``devtool upgrade`` to upgrade the recipe to the most recent version. |
| |
| :: |
| |
| $ devtool upgrade nano -V 2.9.3 |
| NOTE: Starting bitbake server... |
| NOTE: Creating workspace layer in /home/scottrif/poky/build/workspace |
| Parsing recipes: 100% |##########################################| Time: 0:00:46 |
| Parsing of 1431 .bb files complete (0 cached, 1431 parsed). 2040 targets, 56 skipped, 0 masked, 0 errors. |
| NOTE: Extracting current version source... |
| NOTE: Resolving any missing task queue dependencies |
| . |
| . |
| . |
| NOTE: Executing SetScene Tasks |
| NOTE: Executing RunQueue Tasks |
| NOTE: Tasks Summary: Attempted 74 tasks of which 72 didn't need to be rerun and all succeeded. |
| Adding changed files: 100% |#####################################| Time: 0:00:00 |
| NOTE: Upgraded source extracted to /home/scottrif/poky/build/workspace/sources/nano |
| NOTE: New recipe is /home/scottrif/poky/build/workspace/recipes/nano/nano_2.9.3.bb |
| |
| Continuing with this example, you can use ``devtool build`` to build the |
| newly upgraded recipe:: |
| |
| $ devtool build nano |
| NOTE: Starting bitbake server... |
| Loading cache: 100% |################################################################################################| Time: 0:00:01 |
| Loaded 2040 entries from dependency cache. |
| Parsing recipes: 100% |##############################################################################################| Time: 0:00:00 |
| Parsing of 1432 .bb files complete (1431 cached, 1 parsed). 2041 targets, 56 skipped, 0 masked, 0 errors. |
| NOTE: Resolving any missing task queue dependencies |
| . |
| . |
| . |
| NOTE: Executing SetScene Tasks |
| NOTE: Executing RunQueue Tasks |
| NOTE: nano: compiling from external source tree /home/scottrif/poky/build/workspace/sources/nano |
| NOTE: Tasks Summary: Attempted 520 tasks of which 304 didn't need to be rerun and all succeeded. |
| |
| Within the ``devtool upgrade`` workflow, you can |
| deploy and test your rebuilt software. For this example, |
| however, running ``devtool finish`` cleans up the workspace once the |
| source in your workspace is clean. This usually means using Git to stage |
| and submit commits for the changes generated by the upgrade process. |
| |
| Once the tree is clean, you can clean things up in this example with the |
| following command from the ``${BUILDDIR}/workspace/sources/nano`` |
| directory:: |
| |
| $ devtool finish nano meta-oe |
| NOTE: Starting bitbake server... |
| Loading cache: 100% |################################################################################################| Time: 0:00:00 |
| Loaded 2040 entries from dependency cache. |
| Parsing recipes: 100% |##############################################################################################| Time: 0:00:01 |
| Parsing of 1432 .bb files complete (1431 cached, 1 parsed). 2041 targets, 56 skipped, 0 masked, 0 errors. |
| NOTE: Adding new patch 0001-nano.bb-Stuff-I-changed-when-upgrading-nano.bb.patch |
| NOTE: Updating recipe nano_2.9.3.bb |
| NOTE: Removing file /home/scottrif/meta-openembedded/meta-oe/recipes-support/nano/nano_2.7.4.bb |
| NOTE: Moving recipe file to /home/scottrif/meta-openembedded/meta-oe/recipes-support/nano |
| NOTE: Leaving source tree /home/scottrif/poky/build/workspace/sources/nano as-is; if you no longer need it then please delete it manually |
| |
| |
| Using the ``devtool finish`` command cleans up the workspace and creates a patch |
| file based on your commits. The tool puts all patch files back into the |
| source directory in a sub-directory named ``nano`` in this case. |
| |
| Manually Upgrading a Recipe |
| --------------------------- |
| |
| If for some reason you choose not to upgrade recipes using |
| :ref:`dev-manual/common-tasks:Using the Auto Upgrade Helper (AUH)` or |
| by :ref:`dev-manual/common-tasks:Using \`\`devtool upgrade\`\``, |
| you can manually edit the recipe files to upgrade the versions. |
| |
| .. note:: |
| |
| Manually updating multiple recipes scales poorly and involves many |
| steps. The recommendation to upgrade recipe versions is through AUH |
| or ``devtool upgrade``, both of which automate some steps and provide |
| guidance for others needed for the manual process. |
| |
| To manually upgrade recipe versions, follow these general steps: |
| |
| 1. *Change the Version:* Rename the recipe such that the version (i.e. |
| the :term:`PV` part of the recipe name) |
| changes appropriately. If the version is not part of the recipe name, |
| change the value as it is set for :term:`PV` within the recipe itself. |
| |
| 2. *Update* :term:`SRCREV` *if Needed*: If the source code your recipe builds |
| is fetched from Git or some other version control system, update |
| :term:`SRCREV` to point to the |
| commit hash that matches the new version. |
| |
| 3. *Build the Software:* Try to build the recipe using BitBake. Typical |
| build failures include the following: |
| |
| - License statements were updated for the new version. For this |
| case, you need to review any changes to the license and update the |
| values of :term:`LICENSE` and |
| :term:`LIC_FILES_CHKSUM` |
| as needed. |
| |
| .. note:: |
| |
| License changes are often inconsequential. For example, the |
| license text's copyright year might have changed. |
| |
| - Custom patches carried by the older version of the recipe might |
| fail to apply to the new version. For these cases, you need to |
| review the failures. Patches might not be necessary for the new |
| version of the software if the upgraded version has fixed those |
| issues. If a patch is necessary and failing, you need to rebase it |
| into the new version. |
| |
| 4. *Optionally Attempt to Build for Several Architectures:* Once you |
| successfully build the new software for a given architecture, you |
| could test the build for other architectures by changing the |
| :term:`MACHINE` variable and |
| rebuilding the software. This optional step is especially important |
| if the recipe is to be released publicly. |
| |
| 5. *Check the Upstream Change Log or Release Notes:* Checking both these |
| reveals if there are new features that could break |
| backwards-compatibility. If so, you need to take steps to mitigate or |
| eliminate that situation. |
| |
| 6. *Optionally Create a Bootable Image and Test:* If you want, you can |
| test the new software by booting it onto actual hardware. |
| |
| 7. *Create a Commit with the Change in the Layer Repository:* After all |
| builds work and any testing is successful, you can create commits for |
| any changes in the layer holding your upgraded recipe. |
| |
| Finding Temporary Source Code |
| ============================= |
| |
| You might find it helpful during development to modify the temporary |
| source code used by recipes to build packages. For example, suppose you |
| are developing a patch and you need to experiment a bit to figure out |
| your solution. After you have initially built the package, you can |
| iteratively tweak the source code, which is located in the |
| :term:`Build Directory`, and then you can |
| force a re-compile and quickly test your altered code. Once you settle |
| on a solution, you can then preserve your changes in the form of |
| patches. |
| |
| During a build, the unpacked temporary source code used by recipes to |
| build packages is available in the Build Directory as defined by the |
| :term:`S` variable. Below is the default |
| value for the :term:`S` variable as defined in the |
| ``meta/conf/bitbake.conf`` configuration file in the |
| :term:`Source Directory`:: |
| |
| S = "${WORKDIR}/${BP}" |
| |
| You should be aware that many recipes override the |
| :term:`S` variable. For example, recipes that fetch their source from Git |
| usually set :term:`S` to ``${WORKDIR}/git``. |
| |
| .. note:: |
| |
| The :term:`BP` represents the base recipe name, which consists of the name |
| and version:: |
| |
| BP = "${BPN}-${PV}" |
| |
| |
| The path to the work directory for the recipe |
| (:term:`WORKDIR`) is defined as |
| follows:: |
| |
| ${TMPDIR}/work/${MULTIMACH_TARGET_SYS}/${PN}/${EXTENDPE}${PV}-${PR} |
| |
| The actual directory depends on several things: |
| |
| - :term:`TMPDIR`: The top-level build |
| output directory. |
| |
| - :term:`MULTIMACH_TARGET_SYS`: |
| The target system identifier. |
| |
| - :term:`PN`: The recipe name. |
| |
| - :term:`EXTENDPE`: The epoch - (if |
| :term:`PE` is not specified, which is |
| usually the case for most recipes, then :term:`EXTENDPE` is blank). |
| |
| - :term:`PV`: The recipe version. |
| |
| - :term:`PR`: The recipe revision. |
| |
| As an example, assume a Source Directory top-level folder named |
| ``poky``, a default Build Directory at ``poky/build``, and a |
| ``qemux86-poky-linux`` machine target system. Furthermore, suppose your |
| recipe is named ``foo_1.3.0.bb``. In this case, the work directory the |
| build system uses to build the package would be as follows:: |
| |
| poky/build/tmp/work/qemux86-poky-linux/foo/1.3.0-r0 |
| |
| Using Quilt in Your Workflow |
| ============================ |
| |
| `Quilt <https://savannah.nongnu.org/projects/quilt>`__ is a powerful tool |
| that allows you to capture source code changes without having a clean |
| source tree. This section outlines the typical workflow you can use to |
| modify source code, test changes, and then preserve the changes in the |
| form of a patch all using Quilt. |
| |
| .. note:: |
| |
| With regard to preserving changes to source files, if you clean a |
| recipe or have ``rm_work`` enabled, the |
| :ref:`devtool workflow <sdk-manual/extensible:using \`\`devtool\`\` in your sdk workflow>` |
| as described in the Yocto Project Application Development and the |
| Extensible Software Development Kit (eSDK) manual is a safer |
| development flow than the flow that uses Quilt. |
| |
| Follow these general steps: |
| |
| 1. *Find the Source Code:* Temporary source code used by the |
| OpenEmbedded build system is kept in the |
| :term:`Build Directory`. See the |
| ":ref:`dev-manual/common-tasks:finding temporary source code`" section to |
| learn how to locate the directory that has the temporary source code for a |
| particular package. |
| |
| 2. *Change Your Working Directory:* You need to be in the directory that |
| has the temporary source code. That directory is defined by the |
| :term:`S` variable. |
| |
| 3. *Create a New Patch:* Before modifying source code, you need to |
| create a new patch. To create a new patch file, use ``quilt new`` as |
| below:: |
| |
| $ quilt new my_changes.patch |
| |
| 4. *Notify Quilt and Add Files:* After creating the patch, you need to |
| notify Quilt about the files you plan to edit. You notify Quilt by |
| adding the files to the patch you just created:: |
| |
| $ quilt add file1.c file2.c file3.c |
| |
| 5. *Edit the Files:* Make your changes in the source code to the files |
| you added to the patch. |
| |
| 6. *Test Your Changes:* Once you have modified the source code, the |
| easiest way to test your changes is by calling the ``do_compile`` |
| task as shown in the following example:: |
| |
| $ bitbake -c compile -f package |
| |
| The ``-f`` or ``--force`` option forces the specified task to |
| execute. If you find problems with your code, you can just keep |
| editing and re-testing iteratively until things work as expected. |
| |
| .. note:: |
| |
| All the modifications you make to the temporary source code disappear |
| once you run the ``do_clean`` or ``do_cleanall`` tasks using BitBake |
| (i.e. ``bitbake -c clean package`` and ``bitbake -c cleanall package``). |
| Modifications will also disappear if you use the ``rm_work`` feature as |
| described in the |
| ":ref:`dev-manual/common-tasks:conserving disk space during builds`" |
| section. |
| |
| 7. *Generate the Patch:* Once your changes work as expected, you need to |
| use Quilt to generate the final patch that contains all your |
| modifications. |
| :: |
| |
| $ quilt refresh |
| |
| At this point, the |
| ``my_changes.patch`` file has all your edits made to the ``file1.c``, |
| ``file2.c``, and ``file3.c`` files. |
| |
| You can find the resulting patch file in the ``patches/`` |
| subdirectory of the source (:term:`S`) directory. |
| |
| 8. *Copy the Patch File:* For simplicity, copy the patch file into a |
| directory named ``files``, which you can create in the same directory |
| that holds the recipe (``.bb``) file or the append (``.bbappend``) |
| file. Placing the patch here guarantees that the OpenEmbedded build |
| system will find the patch. Next, add the patch into the :term:`SRC_URI` |
| of the recipe. Here is an example:: |
| |
| SRC_URI += "file://my_changes.patch" |
| |
| Using a Development Shell |
| ========================= |
| |
| When debugging certain commands or even when just editing packages, |
| ``devshell`` can be a useful tool. When you invoke ``devshell``, all |
| tasks up to and including |
| :ref:`ref-tasks-patch` are run for the |
| specified target. Then, a new terminal is opened and you are placed in |
| ``${``\ :term:`S`\ ``}``, the source |
| directory. In the new terminal, all the OpenEmbedded build-related |
| environment variables are still defined so you can use commands such as |
| ``configure`` and ``make``. The commands execute just as if the |
| OpenEmbedded build system were executing them. Consequently, working |
| this way can be helpful when debugging a build or preparing software to |
| be used with the OpenEmbedded build system. |
| |
| Following is an example that uses ``devshell`` on a target named |
| ``matchbox-desktop``:: |
| |
| $ bitbake matchbox-desktop -c devshell |
| |
| This command spawns a terminal with a shell prompt within the |
| OpenEmbedded build environment. The |
| :term:`OE_TERMINAL` variable |
| controls what type of shell is opened. |
| |
| For spawned terminals, the following occurs: |
| |
| - The ``PATH`` variable includes the cross-toolchain. |
| |
| - The ``pkgconfig`` variables find the correct ``.pc`` files. |
| |
| - The ``configure`` command finds the Yocto Project site files as well |
| as any other necessary files. |
| |
| Within this environment, you can run configure or compile commands as if |
| they were being run by the OpenEmbedded build system itself. As noted |
| earlier, the working directory also automatically changes to the Source |
| Directory (:term:`S`). |
| |
| To manually run a specific task using ``devshell``, run the |
| corresponding ``run.*`` script in the |
| ``${``\ :term:`WORKDIR`\ ``}/temp`` |
| directory (e.g., ``run.do_configure.``\ `pid`). If a task's script does |
| not exist, which would be the case if the task was skipped by way of the |
| sstate cache, you can create the task by first running it outside of the |
| ``devshell``:: |
| |
| $ bitbake -c task |
| |
| .. note:: |
| |
| - Execution of a task's ``run.*`` script and BitBake's execution of |
| a task are identical. In other words, running the script re-runs |
| the task just as it would be run using the ``bitbake -c`` command. |
| |
| - Any ``run.*`` file that does not have a ``.pid`` extension is a |
| symbolic link (symlink) to the most recent version of that file. |
| |
| Remember, that the ``devshell`` is a mechanism that allows you to get |
| into the BitBake task execution environment. And as such, all commands |
| must be called just as BitBake would call them. That means you need to |
| provide the appropriate options for cross-compilation and so forth as |
| applicable. |
| |
| When you are finished using ``devshell``, exit the shell or close the |
| terminal window. |
| |
| .. note:: |
| |
| - It is worth remembering that when using ``devshell`` you need to |
| use the full compiler name such as ``arm-poky-linux-gnueabi-gcc`` |
| instead of just using ``gcc``. The same applies to other |
| applications such as ``binutils``, ``libtool`` and so forth. |
| BitBake sets up environment variables such as :term:`CC` to assist |
| applications, such as ``make`` to find the correct tools. |
| |
| - It is also worth noting that ``devshell`` still works over X11 |
| forwarding and similar situations. |
| |
| Using a Python Development Shell |
| ================================ |
| |
| Similar to working within a development shell as described in the |
| previous section, you can also spawn and work within an interactive |
| Python development shell. When debugging certain commands or even when |
| just editing packages, ``pydevshell`` can be a useful tool. When you |
| invoke the ``pydevshell`` task, all tasks up to and including |
| :ref:`ref-tasks-patch` are run for the |
| specified target. Then a new terminal is opened. Additionally, key |
| Python objects and code are available in the same way they are to |
| BitBake tasks, in particular, the data store 'd'. So, commands such as |
| the following are useful when exploring the data store and running |
| functions:: |
| |
| pydevshell> d.getVar("STAGING_DIR") |
| '/media/build1/poky/build/tmp/sysroots' |
| pydevshell> d.getVar("STAGING_DIR", False) |
| '${TMPDIR}/sysroots' |
| pydevshell> d.setVar("FOO", "bar") |
| pydevshell> d.getVar("FOO") |
| 'bar' |
| pydevshell> d.delVar("FOO") |
| pydevshell> d.getVar("FOO") |
| pydevshell> bb.build.exec_func("do_unpack", d) |
| pydevshell> |
| |
| The commands execute just as if the OpenEmbedded build |
| system were executing them. Consequently, working this way can be |
| helpful when debugging a build or preparing software to be used with the |
| OpenEmbedded build system. |
| |
| Following is an example that uses ``pydevshell`` on a target named |
| ``matchbox-desktop``:: |
| |
| $ bitbake matchbox-desktop -c pydevshell |
| |
| This command spawns a terminal and places you in an interactive Python |
| interpreter within the OpenEmbedded build environment. The |
| :term:`OE_TERMINAL` variable |
| controls what type of shell is opened. |
| |
| When you are finished using ``pydevshell``, you can exit the shell |
| either by using Ctrl+d or closing the terminal window. |
| |
| Building |
| ======== |
| |
| This section describes various build procedures, such as the steps |
| needed for a simple build, building a target for multiple configurations, |
| generating an image for more than one machine, and so forth. |
| |
| Building a Simple Image |
| ----------------------- |
| |
| In the development environment, you need to build an image whenever you |
| change hardware support, add or change system libraries, or add or |
| change services that have dependencies. There are several methods that allow |
| you to build an image within the Yocto Project. This section presents |
| the basic steps you need to build a simple image using BitBake from a |
| build host running Linux. |
| |
| .. note:: |
| |
| - For information on how to build an image using |
| :term:`Toaster`, see the |
| :doc:`/toaster-manual/index`. |
| |
| - For information on how to use ``devtool`` to build images, see the |
| ":ref:`sdk-manual/extensible:using \`\`devtool\`\` in your sdk workflow`" |
| section in the Yocto Project Application Development and the |
| Extensible Software Development Kit (eSDK) manual. |
| |
| - For a quick example on how to build an image using the |
| OpenEmbedded build system, see the |
| :doc:`/brief-yoctoprojectqs/index` document. |
| |
| The build process creates an entire Linux distribution from source and |
| places it in your :term:`Build Directory` under |
| ``tmp/deploy/images``. For detailed information on the build process |
| using BitBake, see the ":ref:`overview-manual/concepts:images`" section in the |
| Yocto Project Overview and Concepts Manual. |
| |
| The following figure and list overviews the build process: |
| |
| .. image:: figures/bitbake-build-flow.png |
| :align: center |
| |
| 1. *Set up Your Host Development System to Support Development Using the |
| Yocto Project*: See the ":doc:`start`" section for options on how to get a |
| build host ready to use the Yocto Project. |
| |
| 2. *Initialize the Build Environment:* Initialize the build environment |
| by sourcing the build environment script (i.e. |
| :ref:`structure-core-script`):: |
| |
| $ source oe-init-build-env [build_dir] |
| |
| When you use the initialization script, the OpenEmbedded build system |
| uses ``build`` as the default :term:`Build Directory` in your current work |
| directory. You can use a `build_dir` argument with the script to |
| specify a different build directory. |
| |
| .. note:: |
| |
| A common practice is to use a different Build Directory for |
| different targets; for example, ``~/build/x86`` for a ``qemux86`` |
| target, and ``~/build/arm`` for a ``qemuarm`` target. In any |
| event, it's typically cleaner to locate the build directory |
| somewhere outside of your source directory. |
| |
| 3. *Make Sure Your* ``local.conf`` *File is Correct*: Ensure the |
| ``conf/local.conf`` configuration file, which is found in the Build |
| Directory, is set up how you want it. This file defines many aspects |
| of the build environment including the target machine architecture |
| through the :term:`MACHINE` variable, the packaging format used during |
| the build |
| (:term:`PACKAGE_CLASSES`), |
| and a centralized tarball download directory through the |
| :term:`DL_DIR` variable. |
| |
| 4. *Build the Image:* Build the image using the ``bitbake`` command:: |
| |
| $ bitbake target |
| |
| .. note:: |
| |
| For information on BitBake, see the :doc:`bitbake:index`. |
| |
| The target is the name of the recipe you want to build. Common |
| targets are the images in ``meta/recipes-core/images``, |
| ``meta/recipes-sato/images``, and so forth all found in the |
| :term:`Source Directory`. Alternatively, the target |
| can be the name of a recipe for a specific piece of software such as |
| BusyBox. For more details about the images the OpenEmbedded build |
| system supports, see the |
| ":ref:`ref-manual/images:Images`" chapter in the Yocto |
| Project Reference Manual. |
| |
| As an example, the following command builds the |
| ``core-image-minimal`` image:: |
| |
| $ bitbake core-image-minimal |
| |
| Once an |
| image has been built, it often needs to be installed. The images and |
| kernels built by the OpenEmbedded build system are placed in the |
| Build Directory in ``tmp/deploy/images``. For information on how to |
| run pre-built images such as ``qemux86`` and ``qemuarm``, see the |
| :doc:`/sdk-manual/index` manual. For |
| information about how to install these images, see the documentation |
| for your particular board or machine. |
| |
| Building Images for Multiple Targets Using Multiple Configurations |
| ------------------------------------------------------------------ |
| |
| You can use a single ``bitbake`` command to build multiple images or |
| packages for different targets where each image or package requires a |
| different configuration (multiple configuration builds). The builds, in |
| this scenario, are sometimes referred to as "multiconfigs", and this |
| section uses that term throughout. |
| |
| This section describes how to set up for multiple configuration builds |
| and how to account for cross-build dependencies between the |
| multiconfigs. |
| |
| Setting Up and Running a Multiple Configuration Build |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| To accomplish a multiple configuration build, you must define each |
| target's configuration separately using a parallel configuration file in |
| the :term:`Build Directory`, and you |
| must follow a required file hierarchy. Additionally, you must enable the |
| multiple configuration builds in your ``local.conf`` file. |
| |
| Follow these steps to set up and execute multiple configuration builds: |
| |
| - *Create Separate Configuration Files*: You need to create a single |
| configuration file for each build target (each multiconfig). |
| Minimally, each configuration file must define the machine and the |
| temporary directory BitBake uses for the build. Suggested practice |
| dictates that you do not overlap the temporary directories used |
| during the builds. However, it is possible that you can share the |
| temporary directory |
| (:term:`TMPDIR`). For example, |
| consider a scenario with two different multiconfigs for the same |
| :term:`MACHINE`: "qemux86" built |
| for two distributions such as "poky" and "poky-lsb". In this case, |
| you might want to use the same :term:`TMPDIR`. |
| |
| Here is an example showing the minimal statements needed in a |
| configuration file for a "qemux86" target whose temporary build |
| directory is ``tmpmultix86``:: |
| |
| MACHINE = "qemux86" |
| TMPDIR = "${TOPDIR}/tmpmultix86" |
| |
| The location for these multiconfig configuration files is specific. |
| They must reside in the current build directory in a sub-directory of |
| ``conf`` named ``multiconfig``. Following is an example that defines |
| two configuration files for the "x86" and "arm" multiconfigs: |
| |
| .. image:: figures/multiconfig_files.png |
| :align: center |
| |
| The reason for this required file hierarchy is because the :term:`BBPATH` |
| variable is not constructed until the layers are parsed. |
| Consequently, using the configuration file as a pre-configuration |
| file is not possible unless it is located in the current working |
| directory. |
| |
| - *Add the BitBake Multi-configuration Variable to the Local |
| Configuration File*: Use the |
| :term:`BBMULTICONFIG` |
| variable in your ``conf/local.conf`` configuration file to specify |
| each multiconfig. Continuing with the example from the previous |
| figure, the :term:`BBMULTICONFIG` variable needs to enable two |
| multiconfigs: "x86" and "arm" by specifying each configuration file:: |
| |
| BBMULTICONFIG = "x86 arm" |
| |
| .. note:: |
| |
| A "default" configuration already exists by definition. This |
| configuration is named: "" (i.e. empty string) and is defined by |
| the variables coming from your ``local.conf`` |
| file. Consequently, the previous example actually adds two |
| additional configurations to your build: "arm" and "x86" along |
| with "". |
| |
| - *Launch BitBake*: Use the following BitBake command form to launch |
| the multiple configuration build:: |
| |
| $ bitbake [mc:multiconfigname:]target [[[mc:multiconfigname:]target] ... ] |
| |
| For the example in this section, the following command applies:: |
| |
| $ bitbake mc:x86:core-image-minimal mc:arm:core-image-sato mc::core-image-base |
| |
| The previous BitBake command builds a ``core-image-minimal`` image |
| that is configured through the ``x86.conf`` configuration file, a |
| ``core-image-sato`` image that is configured through the ``arm.conf`` |
| configuration file and a ``core-image-base`` that is configured |
| through your ``local.conf`` configuration file. |
| |
| .. note:: |
| |
| Support for multiple configuration builds in the Yocto Project &DISTRO; |
| (&DISTRO_NAME;) Release does not include Shared State (sstate) |
| optimizations. Consequently, if a build uses the same object twice |
| in, for example, two different :term:`TMPDIR` |
| directories, the build either loads from an existing sstate cache for |
| that build at the start or builds the object fresh. |
| |
| Enabling Multiple Configuration Build Dependencies |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| Sometimes dependencies can exist between targets (multiconfigs) in a |
| multiple configuration build. For example, suppose that in order to |
| build a ``core-image-sato`` image for an "x86" multiconfig, the root |
| filesystem of an "arm" multiconfig must exist. This dependency is |
| essentially that the |
| :ref:`ref-tasks-image` task in the |
| ``core-image-sato`` recipe depends on the completion of the |
| :ref:`ref-tasks-rootfs` task of the |
| ``core-image-minimal`` recipe. |
| |
| To enable dependencies in a multiple configuration build, you must |
| declare the dependencies in the recipe using the following statement |
| form:: |
| |
| task_or_package[mcdepends] = "mc:from_multiconfig:to_multiconfig:recipe_name:task_on_which_to_depend" |
| |
| To better show how to use this statement, consider the example scenario |
| from the first paragraph of this section. The following statement needs |
| to be added to the recipe that builds the ``core-image-sato`` image:: |
| |
| do_image[mcdepends] = "mc:x86:arm:core-image-minimal:do_rootfs" |
| |
| In this example, the `from_multiconfig` is "x86". The `to_multiconfig` is "arm". The |
| task on which the ``do_image`` task in the recipe depends is the |
| ``do_rootfs`` task from the ``core-image-minimal`` recipe associated |
| with the "arm" multiconfig. |
| |
| Once you set up this dependency, you can build the "x86" multiconfig |
| using a BitBake command as follows:: |
| |
| $ bitbake mc:x86:core-image-sato |
| |
| This command executes all the tasks needed to create the |
| ``core-image-sato`` image for the "x86" multiconfig. Because of the |
| dependency, BitBake also executes through the ``do_rootfs`` task for the |
| "arm" multiconfig build. |
| |
| Having a recipe depend on the root filesystem of another build might not |
| seem that useful. Consider this change to the statement in the |
| ``core-image-sato`` recipe:: |
| |
| do_image[mcdepends] = "mc:x86:arm:core-image-minimal:do_image" |
| |
| In this case, BitBake must |
| create the ``core-image-minimal`` image for the "arm" build since the |
| "x86" build depends on it. |
| |
| Because "x86" and "arm" are enabled for multiple configuration builds |
| and have separate configuration files, BitBake places the artifacts for |
| each build in the respective temporary build directories (i.e. |
| :term:`TMPDIR`). |
| |
| Building an Initial RAM Filesystem (initramfs) Image |
| ---------------------------------------------------- |
| |
| An initial RAM filesystem (initramfs) image provides a temporary root |
| filesystem used for early system initialization (e.g. loading of modules |
| needed to locate and mount the "real" root filesystem). |
| |
| .. note:: |
| |
| The initramfs image is the successor of initial RAM disk (initrd). It |
| is a "copy in and out" (cpio) archive of the initial filesystem that |
| gets loaded into memory during the Linux startup process. Because |
| Linux uses the contents of the archive during initialization, the |
| initramfs image needs to contain all of the device drivers and tools |
| needed to mount the final root filesystem. |
| |
| Follow these steps to create an initramfs image: |
| |
| 1. *Create the initramfs Image Recipe:* You can reference the |
| ``core-image-minimal-initramfs.bb`` recipe found in the |
| ``meta/recipes-core`` directory of the :term:`Source Directory` |
| as an example |
| from which to work. |
| |
| 2. *Decide if You Need to Bundle the initramfs Image Into the Kernel |
| Image:* If you want the initramfs image that is built to be bundled |
| in with the kernel image, set the |
| :term:`INITRAMFS_IMAGE_BUNDLE` |
| variable to "1" in your ``local.conf`` configuration file and set the |
| :term:`INITRAMFS_IMAGE` |
| variable in the recipe that builds the kernel image. |
| |
| .. note:: |
| |
| It is recommended that you bundle the initramfs image with the |
| kernel image to avoid circular dependencies between the kernel |
| recipe and the initramfs recipe should the initramfs image include |
| kernel modules. |
| |
| Setting the :term:`INITRAMFS_IMAGE_BUNDLE` flag causes the initramfs |
| image to be unpacked into the ``${B}/usr/`` directory. The unpacked |
| initramfs image is then passed to the kernel's ``Makefile`` using the |
| :term:`CONFIG_INITRAMFS_SOURCE` |
| variable, allowing the initramfs image to be built into the kernel |
| normally. |
| |
| .. note:: |
| |
| Bundling the initramfs with the kernel conflates the code in the initramfs |
| with the GPLv2 licensed Linux kernel binary. Thus only GPLv2 compatible |
| software may be part of a bundled initramfs. |
| |
| .. note:: |
| |
| If you choose to not bundle the initramfs image with the kernel |
| image, you are essentially using an |
| `Initial RAM Disk (initrd) <https://en.wikipedia.org/wiki/Initrd>`__. |
| Creating an initrd is handled primarily through the :term:`INITRD_IMAGE`, |
| ``INITRD_LIVE``, and ``INITRD_IMAGE_LIVE`` variables. For more |
| information, see the :ref:`ref-classes-image-live` file. |
| |
| 3. *Optionally Add Items to the initramfs Image Through the initramfs |
| Image Recipe:* If you add items to the initramfs image by way of its |
| recipe, you should use |
| :term:`PACKAGE_INSTALL` |
| rather than |
| :term:`IMAGE_INSTALL`. |
| :term:`PACKAGE_INSTALL` gives more direct control of what is added to the |
| image as compared to the defaults you might not necessarily want that |
| are set by the :ref:`image <ref-classes-image>` |
| or :ref:`core-image <ref-classes-core-image>` |
| classes. |
| |
| 4. *Build the Kernel Image and the initramfs Image:* Build your kernel |
| image using BitBake. Because the initramfs image recipe is a |
| dependency of the kernel image, the initramfs image is built as well |
| and bundled with the kernel image if you used the |
| :term:`INITRAMFS_IMAGE_BUNDLE` |
| variable described earlier. |
| |
| Building a Tiny System |
| ---------------------- |
| |
| Very small distributions have some significant advantages such as |
| requiring less on-die or in-package memory (cheaper), better performance |
| through efficient cache usage, lower power requirements due to less |
| memory, faster boot times, and reduced development overhead. Some |
| real-world examples where a very small distribution gives you distinct |
| advantages are digital cameras, medical devices, and small headless |
| systems. |
| |
| This section presents information that shows you how you can trim your |
| distribution to even smaller sizes than the ``poky-tiny`` distribution, |
| which is around 5 Mbytes, that can be built out-of-the-box using the |
| Yocto Project. |
| |
| Tiny System Overview |
| ~~~~~~~~~~~~~~~~~~~~ |
| |
| The following list presents the overall steps you need to consider and |
| perform to create distributions with smaller root filesystems, achieve |
| faster boot times, maintain your critical functionality, and avoid |
| initial RAM disks: |
| |
| - :ref:`Determine your goals and guiding principles |
| <dev-manual/common-tasks:goals and guiding principles>` |
| |
| - :ref:`dev-manual/common-tasks:understand what contributes to your image size` |
| |
| - :ref:`Reduce the size of the root filesystem |
| <dev-manual/common-tasks:trim the root filesystem>` |
| |
| - :ref:`Reduce the size of the kernel <dev-manual/common-tasks:trim the kernel>` |
| |
| - :ref:`dev-manual/common-tasks:remove package management requirements` |
| |
| - :ref:`dev-manual/common-tasks:look for other ways to minimize size` |
| |
| - :ref:`dev-manual/common-tasks:iterate on the process` |
| |
| Goals and Guiding Principles |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| Before you can reach your destination, you need to know where you are |
| going. Here is an example list that you can use as a guide when creating |
| very small distributions: |
| |
| - Determine how much space you need (e.g. a kernel that is 1 Mbyte or |
| less and a root filesystem that is 3 Mbytes or less). |
| |
| - Find the areas that are currently taking 90% of the space and |
| concentrate on reducing those areas. |
| |
| - Do not create any difficult "hacks" to achieve your goals. |
| |
| - Leverage the device-specific options. |
| |
| - Work in a separate layer so that you keep changes isolated. For |
| information on how to create layers, see the |
| ":ref:`dev-manual/common-tasks:understanding and creating layers`" section. |
| |
| Understand What Contributes to Your Image Size |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| It is easiest to have something to start with when creating your own |
| distribution. You can use the Yocto Project out-of-the-box to create the |
| ``poky-tiny`` distribution. Ultimately, you will want to make changes in |
| your own distribution that are likely modeled after ``poky-tiny``. |
| |
| .. note:: |
| |
| To use ``poky-tiny`` in your build, set the :term:`DISTRO` variable in your |
| ``local.conf`` file to "poky-tiny" as described in the |
| ":ref:`dev-manual/common-tasks:creating your own distribution`" |
| section. |
| |
| Understanding some memory concepts will help you reduce the system size. |
| Memory consists of static, dynamic, and temporary memory. Static memory |
| is the TEXT (code), DATA (initialized data in the code), and BSS |
| (uninitialized data) sections. Dynamic memory represents memory that is |
| allocated at runtime: stacks, hash tables, and so forth. Temporary |
| memory is recovered after the boot process. This memory consists of |
| memory used for decompressing the kernel and for the ``__init__`` |
| functions. |
| |
| To help you see where you currently are with kernel and root filesystem |
| sizes, you can use two tools found in the :term:`Source Directory` |
| in the |
| ``scripts/tiny/`` directory: |
| |
| - ``ksize.py``: Reports component sizes for the kernel build objects. |
| |
| - ``dirsize.py``: Reports component sizes for the root filesystem. |
| |
| This next tool and command help you organize configuration fragments and |
| view file dependencies in a human-readable form: |
| |
| - ``merge_config.sh``: Helps you manage configuration files and |
| fragments within the kernel. With this tool, you can merge individual |
| configuration fragments together. The tool allows you to make |
| overrides and warns you of any missing configuration options. The |
| tool is ideal for allowing you to iterate on configurations, create |
| minimal configurations, and create configuration files for different |
| machines without having to duplicate your process. |
| |
| The ``merge_config.sh`` script is part of the Linux Yocto kernel Git |
| repositories (i.e. ``linux-yocto-3.14``, ``linux-yocto-3.10``, |
| ``linux-yocto-3.8``, and so forth) in the ``scripts/kconfig`` |
| directory. |
| |
| For more information on configuration fragments, see the |
| ":ref:`kernel-dev/common:creating configuration fragments`" |
| section in the Yocto Project Linux Kernel Development Manual. |
| |
| - ``bitbake -u taskexp -g bitbake_target``: Using the BitBake command |
| with these options brings up a Dependency Explorer from which you can |
| view file dependencies. Understanding these dependencies allows you |
| to make informed decisions when cutting out various pieces of the |
| kernel and root filesystem. |
| |
| Trim the Root Filesystem |
| ~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| The root filesystem is made up of packages for booting, libraries, and |
| applications. To change things, you can configure how the packaging |
| happens, which changes the way you build them. You can also modify the |
| filesystem itself or select a different filesystem. |
| |
| First, find out what is hogging your root filesystem by running the |
| ``dirsize.py`` script from your root directory:: |
| |
| $ cd root-directory-of-image |
| $ dirsize.py 100000 > dirsize-100k.log |
| $ cat dirsize-100k.log |
| |
| You can apply a filter to the script to ignore files |
| under a certain size. The previous example filters out any files below |
| 100 Kbytes. The sizes reported by the tool are uncompressed, and thus |
| will be smaller by a relatively constant factor in a compressed root |
| filesystem. When you examine your log file, you can focus on areas of |
| the root filesystem that take up large amounts of memory. |
| |
| You need to be sure that what you eliminate does not cripple the |
| functionality you need. One way to see how packages relate to each other |
| is by using the Dependency Explorer UI with the BitBake command:: |
| |
| $ cd image-directory |
| $ bitbake -u taskexp -g image |
| |
| Use the interface to |
| select potential packages you wish to eliminate and see their dependency |
| relationships. |
| |
| When deciding how to reduce the size, get rid of packages that result in |
| minimal impact on the feature set. For example, you might not need a VGA |
| display. Or, you might be able to get by with ``devtmpfs`` and ``mdev`` |
| instead of ``udev``. |
| |
| Use your ``local.conf`` file to make changes. For example, to eliminate |
| ``udev`` and ``glib``, set the following in the local configuration |
| file:: |
| |
| VIRTUAL-RUNTIME_dev_manager = "" |
| |
| Finally, you should consider exactly the type of root filesystem you |
| need to meet your needs while also reducing its size. For example, |
| consider ``cramfs``, ``squashfs``, ``ubifs``, ``ext2``, or an |
| ``initramfs`` using ``initramfs``. Be aware that ``ext3`` requires a 1 |
| Mbyte journal. If you are okay with running read-only, you do not need |
| this journal. |
| |
| .. note:: |
| |
| After each round of elimination, you need to rebuild your system and |
| then use the tools to see the effects of your reductions. |
| |
| Trim the Kernel |
| ~~~~~~~~~~~~~~~ |
| |
| The kernel is built by including policies for hardware-independent |
| aspects. What subsystems do you enable? For what architecture are you |
| building? Which drivers do you build by default? |
| |
| .. note:: |
| |
| You can modify the kernel source if you want to help with boot time. |
| |
| Run the ``ksize.py`` script from the top-level Linux build directory to |
| get an idea of what is making up the kernel:: |
| |
| $ cd top-level-linux-build-directory |
| $ ksize.py > ksize.log |
| $ cat ksize.log |
| |
| When you examine the log, you will see how much space is taken up with |
| the built-in ``.o`` files for drivers, networking, core kernel files, |
| filesystem, sound, and so forth. The sizes reported by the tool are |
| uncompressed, and thus will be smaller by a relatively constant factor |
| in a compressed kernel image. Look to reduce the areas that are large |
| and taking up around the "90% rule." |
| |
| To examine, or drill down, into any particular area, use the ``-d`` |
| option with the script:: |
| |
| $ ksize.py -d > ksize.log |
| |
| Using this option |
| breaks out the individual file information for each area of the kernel |
| (e.g. drivers, networking, and so forth). |
| |
| Use your log file to see what you can eliminate from the kernel based on |
| features you can let go. For example, if you are not going to need |
| sound, you do not need any drivers that support sound. |
| |
| After figuring out what to eliminate, you need to reconfigure the kernel |
| to reflect those changes during the next build. You could run |
| ``menuconfig`` and make all your changes at once. However, that makes it |
| difficult to see the effects of your individual eliminations and also |
| makes it difficult to replicate the changes for perhaps another target |
| device. A better method is to start with no configurations using |
| ``allnoconfig``, create configuration fragments for individual changes, |
| and then manage the fragments into a single configuration file using |
| ``merge_config.sh``. The tool makes it easy for you to iterate using the |
| configuration change and build cycle. |
| |
| Each time you make configuration changes, you need to rebuild the kernel |
| and check to see what impact your changes had on the overall size. |
| |
| Remove Package Management Requirements |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| Packaging requirements add size to the image. One way to reduce the size |
| of the image is to remove all the packaging requirements from the image. |
| This reduction includes both removing the package manager and its unique |
| dependencies as well as removing the package management data itself. |
| |
| To eliminate all the packaging requirements for an image, be sure that |
| "package-management" is not part of your |
| :term:`IMAGE_FEATURES` |
| statement for the image. When you remove this feature, you are removing |
| the package manager as well as its dependencies from the root |
| filesystem. |
| |
| Look for Other Ways to Minimize Size |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| Depending on your particular circumstances, other areas that you can |
| trim likely exist. The key to finding these areas is through tools and |
| methods described here combined with experimentation and iteration. Here |
| are a couple of areas to experiment with: |
| |
| - ``glibc``: In general, follow this process: |
| |
| 1. Remove ``glibc`` features from |
| :term:`DISTRO_FEATURES` |
| that you think you do not need. |
| |
| 2. Build your distribution. |
| |
| 3. If the build fails due to missing symbols in a package, determine |
| if you can reconfigure the package to not need those features. For |
| example, change the configuration to not support wide character |
| support as is done for ``ncurses``. Or, if support for those |
| characters is needed, determine what ``glibc`` features provide |
| the support and restore the configuration. |
| |
| 4. Rebuild and repeat the process. |
| |
| - ``busybox``: For BusyBox, use a process similar as described for |
| ``glibc``. A difference is you will need to boot the resulting system |
| to see if you are able to do everything you expect from the running |
| system. You need to be sure to integrate configuration fragments into |
| Busybox because BusyBox handles its own core features and then allows |
| you to add configuration fragments on top. |
| |
| Iterate on the Process |
| ~~~~~~~~~~~~~~~~~~~~~~ |
| |
| If you have not reached your goals on system size, you need to iterate |
| on the process. The process is the same. Use the tools and see just what |
| is taking up 90% of the root filesystem and the kernel. Decide what you |
| can eliminate without limiting your device beyond what you need. |
| |
| Depending on your system, a good place to look might be Busybox, which |
| provides a stripped down version of Unix tools in a single, executable |
| file. You might be able to drop virtual terminal services or perhaps |
| ipv6. |
| |
| Building Images for More than One Machine |
| ----------------------------------------- |
| |
| A common scenario developers face is creating images for several |
| different machines that use the same software environment. In this |
| situation, it is tempting to set the tunings and optimization flags for |
| each build specifically for the targeted hardware (i.e. "maxing out" the |
| tunings). Doing so can considerably add to build times and package feed |
| maintenance collectively for the machines. For example, selecting tunes |
| that are extremely specific to a CPU core used in a system might enable |
| some micro optimizations in GCC for that particular system but would |
| otherwise not gain you much of a performance difference across the other |
| systems as compared to using a more general tuning across all the builds |
| (e.g. setting :term:`DEFAULTTUNE` |
| specifically for each machine's build). Rather than "max out" each |
| build's tunings, you can take steps that cause the OpenEmbedded build |
| system to reuse software across the various machines where it makes |
| sense. |
| |
| If build speed and package feed maintenance are considerations, you |
| should consider the points in this section that can help you optimize |
| your tunings to best consider build times and package feed maintenance. |
| |
| - *Share the Build Directory:* If at all possible, share the |
| :term:`TMPDIR` across builds. The |
| Yocto Project supports switching between different |
| :term:`MACHINE` values in the same |
| :term:`TMPDIR`. This practice is well supported and regularly used by |
| developers when building for multiple machines. When you use the same |
| :term:`TMPDIR` for multiple machine builds, the OpenEmbedded build system |
| can reuse the existing native and often cross-recipes for multiple |
| machines. Thus, build time decreases. |
| |
| .. note:: |
| |
| If :term:`DISTRO` settings change or fundamental configuration settings |
| such as the filesystem layout, you need to work with a clean :term:`TMPDIR`. |
| Sharing :term:`TMPDIR` under these circumstances might work but since it is |
| not guaranteed, you should use a clean :term:`TMPDIR`. |
| |
| - *Enable the Appropriate Package Architecture:* By default, the |
| OpenEmbedded build system enables three levels of package |
| architectures: "all", "tune" or "package", and "machine". Any given |
| recipe usually selects one of these package architectures (types) for |
| its output. Depending for what a given recipe creates packages, |
| making sure you enable the appropriate package architecture can |
| directly impact the build time. |
| |
| A recipe that just generates scripts can enable "all" architecture |
| because there are no binaries to build. To specifically enable "all" |
| architecture, be sure your recipe inherits the |
| :ref:`allarch <ref-classes-allarch>` class. |
| This class is useful for "all" architectures because it configures |
| many variables so packages can be used across multiple architectures. |
| |
| If your recipe needs to generate packages that are machine-specific |
| or when one of the build or runtime dependencies is already |
| machine-architecture dependent, which makes your recipe also |
| machine-architecture dependent, make sure your recipe enables the |
| "machine" package architecture through the |
| :term:`MACHINE_ARCH` |
| variable:: |
| |
| PACKAGE_ARCH = "${MACHINE_ARCH}" |
| |
| When you do not |
| specifically enable a package architecture through the |
| :term:`PACKAGE_ARCH`, The |
| OpenEmbedded build system defaults to the |
| :term:`TUNE_PKGARCH` setting:: |
| |
| PACKAGE_ARCH = "${TUNE_PKGARCH}" |
| |
| - *Choose a Generic Tuning File if Possible:* Some tunes are more |
| generic and can run on multiple targets (e.g. an ``armv5`` set of |
| packages could run on ``armv6`` and ``armv7`` processors in most |
| cases). Similarly, ``i486`` binaries could work on ``i586`` and |
| higher processors. You should realize, however, that advances on |
| newer processor versions would not be used. |
| |
| If you select the same tune for several different machines, the |
| OpenEmbedded build system reuses software previously built, thus |
| speeding up the overall build time. Realize that even though a new |
| sysroot for each machine is generated, the software is not recompiled |
| and only one package feed exists. |
| |
| - *Manage Granular Level Packaging:* Sometimes there are cases where |
| injecting another level of package architecture beyond the three |
| higher levels noted earlier can be useful. For example, consider how |
| NXP (formerly Freescale) allows for the easy reuse of binary packages |
| in their layer |
| :yocto_git:`meta-freescale </meta-freescale/>`. |
| In this example, the |
| :yocto_git:`fsl-dynamic-packagearch </meta-freescale/tree/classes/fsl-dynamic-packagearch.bbclass>` |
| class shares GPU packages for i.MX53 boards because all boards share |
| the AMD GPU. The i.MX6-based boards can do the same because all |
| boards share the Vivante GPU. This class inspects the BitBake |
| datastore to identify if the package provides or depends on one of |
| the sub-architecture values. If so, the class sets the |
| :term:`PACKAGE_ARCH` value |
| based on the ``MACHINE_SUBARCH`` value. If the package does not |
| provide or depend on one of the sub-architecture values but it |
| matches a value in the machine-specific filter, it sets |
| :term:`MACHINE_ARCH`. This |
| behavior reduces the number of packages built and saves build time by |
| reusing binaries. |
| |
| - *Use Tools to Debug Issues:* Sometimes you can run into situations |
| where software is being rebuilt when you think it should not be. For |
| example, the OpenEmbedded build system might not be using shared |
| state between machines when you think it should be. These types of |
| situations are usually due to references to machine-specific |
| variables such as :term:`MACHINE`, |
| :term:`SERIAL_CONSOLES`, |
| :term:`XSERVER`, |
| :term:`MACHINE_FEATURES`, |
| and so forth in code that is supposed to only be tune-specific or |
| when the recipe depends |
| (:term:`DEPENDS`, |
| :term:`RDEPENDS`, |
| :term:`RRECOMMENDS`, |
| :term:`RSUGGESTS`, and so forth) |
| on some other recipe that already has |
| :term:`PACKAGE_ARCH` defined |
| as "${MACHINE_ARCH}". |
| |
| .. note:: |
| |
| Patches to fix any issues identified are most welcome as these |
| issues occasionally do occur. |
| |
| For such cases, you can use some tools to help you sort out the |
| situation: |
| |
| - ``state-diff-machines.sh``*:* You can find this tool in the |
| ``scripts`` directory of the Source Repositories. See the comments |
| in the script for information on how to use the tool. |
| |
| - *BitBake's "-S printdiff" Option:* Using this option causes |
| BitBake to try to establish the closest signature match it can |
| (e.g. in the shared state cache) and then run ``bitbake-diffsigs`` |
| over the matches to determine the stamps and delta where these two |
| stamp trees diverge. |
| |
| Building Software from an External Source |
| ----------------------------------------- |
| |
| By default, the OpenEmbedded build system uses the |
| :term:`Build Directory` when building source |
| code. The build process involves fetching the source files, unpacking |
| them, and then patching them if necessary before the build takes place. |
| |
| There are situations where you might want to build software from source |
| files that are external to and thus outside of the OpenEmbedded build |
| system. For example, suppose you have a project that includes a new BSP |
| with a heavily customized kernel. And, you want to minimize exposing the |
| build system to the development team so that they can focus on their |
| project and maintain everyone's workflow as much as possible. In this |
| case, you want a kernel source directory on the development machine |
| where the development occurs. You want the recipe's |
| :term:`SRC_URI` variable to point to |
| the external directory and use it as is, not copy it. |
| |
| To build from software that comes from an external source, all you need |
| to do is inherit the |
| :ref:`externalsrc <ref-classes-externalsrc>` class |
| and then set the |
| :term:`EXTERNALSRC` variable to |
| point to your external source code. Here are the statements to put in |
| your ``local.conf`` file:: |
| |
| INHERIT += "externalsrc" |
| EXTERNALSRC:pn-myrecipe = "path-to-your-source-tree" |
| |
| This next example shows how to accomplish the same thing by setting |
| :term:`EXTERNALSRC` in the recipe itself or in the recipe's append file:: |
| |
| EXTERNALSRC = "path" |
| EXTERNALSRC_BUILD = "path" |
| |
| .. note:: |
| |
| In order for these settings to take effect, you must globally or |
| locally inherit the :ref:`externalsrc <ref-classes-externalsrc>` |
| class. |
| |
| By default, ``externalsrc.bbclass`` builds the source code in a |
| directory separate from the external source directory as specified by |
| :term:`EXTERNALSRC`. If you need |
| to have the source built in the same directory in which it resides, or |
| some other nominated directory, you can set |
| :term:`EXTERNALSRC_BUILD` |
| to point to that directory:: |
| |
| EXTERNALSRC_BUILD:pn-myrecipe = "path-to-your-source-tree" |
| |
| Replicating a Build Offline |
| --------------------------- |
| |
| It can be useful to take a "snapshot" of upstream sources used in a |
| build and then use that "snapshot" later to replicate the build offline. |
| To do so, you need to first prepare and populate your downloads |
| directory your "snapshot" of files. Once your downloads directory is |
| ready, you can use it at any time and from any machine to replicate your |
| build. |
| |
| Follow these steps to populate your Downloads directory: |
| |
| 1. *Create a Clean Downloads Directory:* Start with an empty downloads |
| directory (:term:`DL_DIR`). You |
| start with an empty downloads directory by either removing the files |
| in the existing directory or by setting :term:`DL_DIR` to point to either |
| an empty location or one that does not yet exist. |
| |
| 2. *Generate Tarballs of the Source Git Repositories:* Edit your |
| ``local.conf`` configuration file as follows:: |
| |
| DL_DIR = "/home/your-download-dir/" |
| BB_GENERATE_MIRROR_TARBALLS = "1" |
| |
| During |
| the fetch process in the next step, BitBake gathers the source files |
| and creates tarballs in the directory pointed to by :term:`DL_DIR`. See |
| the |
| :term:`BB_GENERATE_MIRROR_TARBALLS` |
| variable for more information. |
| |
| 3. *Populate Your Downloads Directory Without Building:* Use BitBake to |
| fetch your sources but inhibit the build:: |
| |
| $ bitbake target --runonly=fetch |
| |
| The downloads directory (i.e. ``${DL_DIR}``) now has |
| a "snapshot" of the source files in the form of tarballs, which can |
| be used for the build. |
| |
| 4. *Optionally Remove Any Git or other SCM Subdirectories From the |
| Downloads Directory:* If you want, you can clean up your downloads |
| directory by removing any Git or other Source Control Management |
| (SCM) subdirectories such as ``${DL_DIR}/git2/*``. The tarballs |
| already contain these subdirectories. |
| |
| Once your downloads directory has everything it needs regarding source |
| files, you can create your "own-mirror" and build your target. |
| Understand that you can use the files to build the target offline from |
| any machine and at any time. |
| |
| Follow these steps to build your target using the files in the downloads |
| directory: |
| |
| 1. *Using Local Files Only:* Inside your ``local.conf`` file, add the |
| :term:`SOURCE_MIRROR_URL` variable, inherit the |
| :ref:`own-mirrors <ref-classes-own-mirrors>` class, and use the |
| :term:`BB_NO_NETWORK` variable to your ``local.conf``. |
| :: |
| |
| SOURCE_MIRROR_URL ?= "file:///home/your-download-dir/" |
| INHERIT += "own-mirrors" |
| BB_NO_NETWORK = "1" |
| |
| The :term:`SOURCE_MIRROR_URL` and :ref:`own-mirrors <ref-classes-own-mirrors>` |
| class set up the system to use the downloads directory as your "own |
| mirror". Using the :term:`BB_NO_NETWORK` variable makes sure that |
| BitBake's fetching process in step 3 stays local, which means files |
| from your "own-mirror" are used. |
| |
| 2. *Start With a Clean Build:* You can start with a clean build by |
| removing the |
| ``${``\ :term:`TMPDIR`\ ``}`` |
| directory or using a new :term:`Build Directory`. |
| |
| 3. *Build Your Target:* Use BitBake to build your target:: |
| |
| $ bitbake target |
| |
| The build completes using the known local "snapshot" of source |
| files from your mirror. The resulting tarballs for your "snapshot" of |
| source files are in the downloads directory. |
| |
| .. note:: |
| |
| The offline build does not work if recipes attempt to find the |
| latest version of software by setting |
| :term:`SRCREV` to |
| ``${``\ :term:`AUTOREV`\ ``}``:: |
| |
| SRCREV = "${AUTOREV}" |
| |
| When a recipe sets :term:`SRCREV` to |
| ``${``\ :term:`AUTOREV`\ ``}``, the build system accesses the network in an |
| attempt to determine the latest version of software from the SCM. |
| Typically, recipes that use :term:`AUTOREV` are custom or modified |
| recipes. Recipes that reside in public repositories usually do not |
| use :term:`AUTOREV`. |
| |
| If you do have recipes that use :term:`AUTOREV`, you can take steps to |
| still use the recipes in an offline build. Do the following: |
| |
| 1. Use a configuration generated by enabling :ref:`build |
| history <dev-manual/common-tasks:maintaining build output quality>`. |
| |
| 2. Use the ``buildhistory-collect-srcrevs`` command to collect the |
| stored :term:`SRCREV` values from the build's history. For more |
| information on collecting these values, see the |
| ":ref:`dev-manual/common-tasks:build history package information`" |
| section. |
| |
| 3. Once you have the correct source revisions, you can modify |
| those recipes to set :term:`SRCREV` to specific versions of the |
| software. |
| |
| Speeding Up a Build |
| =================== |
| |
| Build time can be an issue. By default, the build system uses simple |
| controls to try and maximize build efficiency. In general, the default |
| settings for all the following variables result in the most efficient |
| build times when dealing with single socket systems (i.e. a single CPU). |
| If you have multiple CPUs, you might try increasing the default values |
| to gain more speed. See the descriptions in the glossary for each |
| variable for more information: |
| |
| - :term:`BB_NUMBER_THREADS`: |
| The maximum number of threads BitBake simultaneously executes. |
| |
| - :term:`BB_NUMBER_PARSE_THREADS`: |
| The number of threads BitBake uses during parsing. |
| |
| - :term:`PARALLEL_MAKE`: Extra |
| options passed to the ``make`` command during the |
| :ref:`ref-tasks-compile` task in |
| order to specify parallel compilation on the local build host. |
| |
| - :term:`PARALLEL_MAKEINST`: |
| Extra options passed to the ``make`` command during the |
| :ref:`ref-tasks-install` task in |
| order to specify parallel installation on the local build host. |
| |
| As mentioned, these variables all scale to the number of processor cores |
| available on the build system. For single socket systems, this |
| auto-scaling ensures that the build system fundamentally takes advantage |
| of potential parallel operations during the build based on the build |
| machine's capabilities. |
| |
| Following are additional factors that can affect build speed: |
| |
| - File system type: The file system type that the build is being |
| performed on can also influence performance. Using ``ext4`` is |
| recommended as compared to ``ext2`` and ``ext3`` due to ``ext4`` |
| improved features such as extents. |
| |
| - Disabling the updating of access time using ``noatime``: The |
| ``noatime`` mount option prevents the build system from updating file |
| and directory access times. |
| |
| - Setting a longer commit: Using the "commit=" mount option increases |
| the interval in seconds between disk cache writes. Changing this |
| interval from the five second default to something longer increases |
| the risk of data loss but decreases the need to write to the disk, |
| thus increasing the build performance. |
| |
| - Choosing the packaging backend: Of the available packaging backends, |
| IPK is the fastest. Additionally, selecting a singular packaging |
| backend also helps. |
| |
| - Using ``tmpfs`` for :term:`TMPDIR` |
| as a temporary file system: While this can help speed up the build, |
| the benefits are limited due to the compiler using ``-pipe``. The |
| build system goes to some lengths to avoid ``sync()`` calls into the |
| file system on the principle that if there was a significant failure, |
| the :term:`Build Directory` |
| contents could easily be rebuilt. |
| |
| - Inheriting the |
| :ref:`rm_work <ref-classes-rm-work>` class: |
| Inheriting this class has shown to speed up builds due to |
| significantly lower amounts of data stored in the data cache as well |
| as on disk. Inheriting this class also makes cleanup of |
| :term:`TMPDIR` faster, at the |
| expense of being easily able to dive into the source code. File |
| system maintainers have recommended that the fastest way to clean up |
| large numbers of files is to reformat partitions rather than delete |
| files due to the linear nature of partitions. This, of course, |
| assumes you structure the disk partitions and file systems in a way |
| that this is practical. |
| |
| Aside from the previous list, you should keep some trade offs in mind |
| that can help you speed up the build: |
| |
| - Remove items from |
| :term:`DISTRO_FEATURES` |
| that you might not need. |
| |
| - Exclude debug symbols and other debug information: If you do not need |
| these symbols and other debug information, disabling the ``*-dbg`` |
| package generation can speed up the build. You can disable this |
| generation by setting the |
| :term:`INHIBIT_PACKAGE_DEBUG_SPLIT` |
| variable to "1". |
| |
| - Disable static library generation for recipes derived from |
| ``autoconf`` or ``libtool``: Following is an example showing how to |
| disable static libraries and still provide an override to handle |
| exceptions:: |
| |
| STATICLIBCONF = "--disable-static" |
| STATICLIBCONF:sqlite3-native = "" |
| EXTRA_OECONF += "${STATICLIBCONF}" |
| |
| .. note:: |
| |
| - Some recipes need static libraries in order to work correctly |
| (e.g. ``pseudo-native`` needs ``sqlite3-native``). Overrides, |
| as in the previous example, account for these kinds of |
| exceptions. |
| |
| - Some packages have packaging code that assumes the presence of |
| the static libraries. If so, you might need to exclude them as |
| well. |
| |
| Working With Libraries |
| ====================== |
| |
| Libraries are an integral part of your system. This section describes |
| some common practices you might find helpful when working with libraries |
| to build your system: |
| |
| - :ref:`How to include static library files |
| <dev-manual/common-tasks:including static library files>` |
| |
| - :ref:`How to use the Multilib feature to combine multiple versions of |
| library files into a single image |
| <dev-manual/common-tasks:combining multiple versions of library files into one image>` |
| |
| - :ref:`How to install multiple versions of the same library in parallel on |
| the same system |
| <dev-manual/common-tasks:installing multiple versions of the same library>` |
| |
| Including Static Library Files |
| ------------------------------ |
| |
| If you are building a library and the library offers static linking, you |
| can control which static library files (``*.a`` files) get included in |
| the built library. |
| |
| The :term:`PACKAGES` and |
| :term:`FILES:* <FILES>` variables in the |
| ``meta/conf/bitbake.conf`` configuration file define how files installed |
| by the ``do_install`` task are packaged. By default, the :term:`PACKAGES` |
| variable includes ``${PN}-staticdev``, which represents all static |
| library files. |
| |
| .. note:: |
| |
| Some previously released versions of the Yocto Project defined the |
| static library files through ``${PN}-dev``. |
| |
| Following is part of the BitBake configuration file, where you can see |
| how the static library files are defined:: |
| |
| PACKAGE_BEFORE_PN ?= "" |
| PACKAGES = "${PN}-src ${PN}-dbg ${PN}-staticdev ${PN}-dev ${PN}-doc ${PN}-locale ${PACKAGE_BEFORE_PN} ${PN}" |
| PACKAGES_DYNAMIC = "^${PN}-locale-.*" |
| FILES = "" |
| |
| FILES:${PN} = "${bindir}/* ${sbindir}/* ${libexecdir}/* ${libdir}/lib*${SOLIBS} \ |
| ${sysconfdir} ${sharedstatedir} ${localstatedir} \ |
| ${base_bindir}/* ${base_sbindir}/* \ |
| ${base_libdir}/*${SOLIBS} \ |
| ${base_prefix}/lib/udev ${prefix}/lib/udev \ |
| ${base_libdir}/udev ${libdir}/udev \ |
| ${datadir}/${BPN} ${libdir}/${BPN}/* \ |
| ${datadir}/pixmaps ${datadir}/applications \ |
| ${datadir}/idl ${datadir}/omf ${datadir}/sounds \ |
| ${libdir}/bonobo/servers" |
| |
| FILES:${PN}-bin = "${bindir}/* ${sbindir}/*" |
| |
| FILES:${PN}-doc = "${docdir} ${mandir} ${infodir} ${datadir}/gtk-doc \ |
| ${datadir}/gnome/help" |
| SECTION:${PN}-doc = "doc" |
| |
| FILES_SOLIBSDEV ?= "${base_libdir}/lib*${SOLIBSDEV} ${libdir}/lib*${SOLIBSDEV}" |
| FILES:${PN}-dev = "${includedir} ${FILES_SOLIBSDEV} ${libdir}/*.la \ |
| ${libdir}/*.o ${libdir}/pkgconfig ${datadir}/pkgconfig \ |
| ${datadir}/aclocal ${base_libdir}/*.o \ |
| ${libdir}/${BPN}/*.la ${base_libdir}/*.la \ |
| ${libdir}/cmake ${datadir}/cmake" |
| SECTION:${PN}-dev = "devel" |
| ALLOW_EMPTY:${PN}-dev = "1" |
| RDEPENDS:${PN}-dev = "${PN} (= ${EXTENDPKGV})" |
| |
| FILES:${PN}-staticdev = "${libdir}/*.a ${base_libdir}/*.a ${libdir}/${BPN}/*.a" |
| SECTION:${PN}-staticdev = "devel" |
| RDEPENDS:${PN}-staticdev = "${PN}-dev (= ${EXTENDPKGV})" |
| |
| Combining Multiple Versions of Library Files into One Image |
| ----------------------------------------------------------- |
| |
| The build system offers the ability to build libraries with different |
| target optimizations or architecture formats and combine these together |
| into one system image. You can link different binaries in the image |
| against the different libraries as needed for specific use cases. This |
| feature is called "Multilib". |
| |
| An example would be where you have most of a system compiled in 32-bit |
| mode using 32-bit libraries, but you have something large, like a |
| database engine, that needs to be a 64-bit application and uses 64-bit |
| libraries. Multilib allows you to get the best of both 32-bit and 64-bit |
| libraries. |
| |
| While the Multilib feature is most commonly used for 32 and 64-bit |
| differences, the approach the build system uses facilitates different |
| target optimizations. You could compile some binaries to use one set of |
| libraries and other binaries to use a different set of libraries. The |
| libraries could differ in architecture, compiler options, or other |
| optimizations. |
| |
| There are several examples in the ``meta-skeleton`` layer found in the |
| :term:`Source Directory`: |
| |
| - :oe_git:`conf/multilib-example.conf </openembedded-core/tree/meta-skeleton/conf/multilib-example.conf>` |
| configuration file. |
| |
| - :oe_git:`conf/multilib-example2.conf </openembedded-core/tree/meta-skeleton/conf/multilib-example2.conf>` |
| configuration file. |
| |
| - :oe_git:`recipes-multilib/images/core-image-multilib-example.bb </openembedded-core/tree/meta-skeleton/recipes-multilib/images/core-image-multilib-example.bb>` |
| recipe |
| |
| Preparing to Use Multilib |
| ~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| User-specific requirements drive the Multilib feature. Consequently, |
| there is no one "out-of-the-box" configuration that would |
| meet your needs. |
| |
| In order to enable Multilib, you first need to ensure your recipe is |
| extended to support multiple libraries. Many standard recipes are |
| already extended and support multiple libraries. You can check in the |
| ``meta/conf/multilib.conf`` configuration file in the |
| :term:`Source Directory` to see how this is |
| done using the |
| :term:`BBCLASSEXTEND` variable. |
| Eventually, all recipes will be covered and this list will not be |
| needed. |
| |
| For the most part, the :ref:`Multilib <ref-classes-multilib*>` |
| class extension works automatically to |
| extend the package name from ``${PN}`` to ``${MLPREFIX}${PN}``, where |
| :term:`MLPREFIX` is the particular multilib (e.g. "lib32-" or "lib64-"). |
| Standard variables such as |
| :term:`DEPENDS`, |
| :term:`RDEPENDS`, |
| :term:`RPROVIDES`, |
| :term:`RRECOMMENDS`, |
| :term:`PACKAGES`, and |
| :term:`PACKAGES_DYNAMIC` are |
| automatically extended by the system. If you are extending any manual |
| code in the recipe, you can use the ``${MLPREFIX}`` variable to ensure |
| those names are extended correctly. |
| |
| Using Multilib |
| ~~~~~~~~~~~~~~ |
| |
| After you have set up the recipes, you need to define the actual |
| combination of multiple libraries you want to build. You accomplish this |
| through your ``local.conf`` configuration file in the |
| :term:`Build Directory`. An example |
| configuration would be as follows:: |
| |
| MACHINE = "qemux86-64" |
| require conf/multilib.conf |
| MULTILIBS = "multilib:lib32" |
| DEFAULTTUNE:virtclass-multilib-lib32 = "x86" |
| IMAGE_INSTALL:append = "lib32-glib-2.0" |
| |
| This example enables an additional library named |
| ``lib32`` alongside the normal target packages. When combining these |
| "lib32" alternatives, the example uses "x86" for tuning. For information |
| on this particular tuning, see |
| ``meta/conf/machine/include/ia32/arch-ia32.inc``. |
| |
| The example then includes ``lib32-glib-2.0`` in all the images, which |
| illustrates one method of including a multiple library dependency. You |
| can use a normal image build to include this dependency, for example:: |
| |
| $ bitbake core-image-sato |
| |
| You can also build Multilib packages |
| specifically with a command like this:: |
| |
| $ bitbake lib32-glib-2.0 |
| |
| Additional Implementation Details |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| There are generic implementation details as well as details that are specific to |
| package management systems. Following are implementation details |
| that exist regardless of the package management system: |
| |
| - The typical convention used for the class extension code as used by |
| Multilib assumes that all package names specified in |
| :term:`PACKAGES` that contain |
| ``${PN}`` have ``${PN}`` at the start of the name. When that |
| convention is not followed and ``${PN}`` appears at the middle or the |
| end of a name, problems occur. |
| |
| - The :term:`TARGET_VENDOR` |
| value under Multilib will be extended to "-vendormlmultilib" (e.g. |
| "-pokymllib32" for a "lib32" Multilib with Poky). The reason for this |
| slightly unwieldy contraction is that any "-" characters in the |
| vendor string presently break Autoconf's ``config.sub``, and other |
| separators are problematic for different reasons. |
| |
| Here are the implementation details for the RPM Package Management System: |
| |
| - A unique architecture is defined for the Multilib packages, along |
| with creating a unique deploy folder under ``tmp/deploy/rpm`` in the |
| :term:`Build Directory`. For |
| example, consider ``lib32`` in a ``qemux86-64`` image. The possible |
| architectures in the system are "all", "qemux86_64", |
| "lib32:qemux86_64", and "lib32:x86". |
| |
| - The ``${MLPREFIX}`` variable is stripped from ``${PN}`` during RPM |
| packaging. The naming for a normal RPM package and a Multilib RPM |
| package in a ``qemux86-64`` system resolves to something similar to |
| ``bash-4.1-r2.x86_64.rpm`` and ``bash-4.1.r2.lib32_x86.rpm``, |
| respectively. |
| |
| - When installing a Multilib image, the RPM backend first installs the |
| base image and then installs the Multilib libraries. |
| |
| - The build system relies on RPM to resolve the identical files in the |
| two (or more) Multilib packages. |
| |
| Here are the implementation details for the IPK Package Management System: |
| |
| - The ``${MLPREFIX}`` is not stripped from ``${PN}`` during IPK |
| packaging. The naming for a normal RPM package and a Multilib IPK |
| package in a ``qemux86-64`` system resolves to something like |
| ``bash_4.1-r2.x86_64.ipk`` and ``lib32-bash_4.1-rw:x86.ipk``, |
| respectively. |
| |
| - The IPK deploy folder is not modified with ``${MLPREFIX}`` because |
| packages with and without the Multilib feature can exist in the same |
| folder due to the ``${PN}`` differences. |
| |
| - IPK defines a sanity check for Multilib installation using certain |
| rules for file comparison, overridden, etc. |
| |
| Installing Multiple Versions of the Same Library |
| ------------------------------------------------ |
| |
| There are be situations where you need to install and use multiple versions |
| of the same library on the same system at the same time. This |
| almost always happens when a library API changes and you have |
| multiple pieces of software that depend on the separate versions of the |
| library. To accommodate these situations, you can install multiple |
| versions of the same library in parallel on the same system. |
| |
| The process is straightforward as long as the libraries use proper |
| versioning. With properly versioned libraries, all you need to do to |
| individually specify the libraries is create separate, appropriately |
| named recipes where the :term:`PN` part of |
| the name includes a portion that differentiates each library version |
| (e.g. the major part of the version number). Thus, instead of having a |
| single recipe that loads one version of a library (e.g. ``clutter``), |
| you provide multiple recipes that result in different versions of the |
| libraries you want. As an example, the following two recipes would allow |
| the two separate versions of the ``clutter`` library to co-exist on the |
| same system: |
| |
| .. code-block:: none |
| |
| clutter-1.6_1.6.20.bb |
| clutter-1.8_1.8.4.bb |
| |
| Additionally, if |
| you have other recipes that depend on a given library, you need to use |
| the :term:`DEPENDS` variable to |
| create the dependency. Continuing with the same example, if you want to |
| have a recipe depend on the 1.8 version of the ``clutter`` library, use |
| the following in your recipe:: |
| |
| DEPENDS = "clutter-1.8" |
| |
| Using x32 psABI |
| =============== |
| |
| x32 processor-specific Application Binary Interface (`x32 |
| psABI <https://software.intel.com/en-us/node/628948>`__) is a native |
| 32-bit processor-specific ABI for Intel 64 (x86-64) architectures. An |
| ABI defines the calling conventions between functions in a processing |
| environment. The interface determines what registers are used and what |
| the sizes are for various C data types. |
| |
| Some processing environments prefer using 32-bit applications even when |
| running on Intel 64-bit platforms. Consider the i386 psABI, which is a |
| very old 32-bit ABI for Intel 64-bit platforms. The i386 psABI does not |
| provide efficient use and access of the Intel 64-bit processor |
| resources, leaving the system underutilized. Now consider the x86_64 |
| psABI. This ABI is newer and uses 64-bits for data sizes and program |
| pointers. The extra bits increase the footprint size of the programs, |
| libraries, and also increases the memory and file system size |
| requirements. Executing under the x32 psABI enables user programs to |
| utilize CPU and system resources more efficiently while keeping the |
| memory footprint of the applications low. Extra bits are used for |
| registers but not for addressing mechanisms. |
| |
| The Yocto Project supports the final specifications of x32 psABI as |
| follows: |
| |
| - You can create packages and images in x32 psABI format on x86_64 |
| architecture targets. |
| |
| - You can successfully build recipes with the x32 toolchain. |
| |
| - You can create and boot ``core-image-minimal`` and |
| ``core-image-sato`` images. |
| |
| - There is RPM Package Manager (RPM) support for x32 binaries. |
| |
| - There is support for large images. |
| |
| To use the x32 psABI, you need to edit your ``conf/local.conf`` |
| configuration file as follows:: |
| |
| MACHINE = "qemux86-64" |
| DEFAULTTUNE = "x86-64-x32" |
| baselib = "${@d.getVar('BASE_LIB:tune-' + (d.getVar('DEFAULTTUNE') \ |
| or 'INVALID')) or 'lib'}" |
| |
| Once you have set |
| up your configuration file, use BitBake to build an image that supports |
| the x32 psABI. Here is an example:: |
| |
| $ bitbake core-image-sato |
| |
| Enabling GObject Introspection Support |
| ====================================== |
| |
| `GObject introspection <https://gi.readthedocs.io/en/latest/>`__ |
| is the standard mechanism for accessing GObject-based software from |
| runtime environments. GObject is a feature of the GLib library that |
| provides an object framework for the GNOME desktop and related software. |
| GObject Introspection adds information to GObject that allows objects |
| created within it to be represented across different programming |
| languages. If you want to construct GStreamer pipelines using Python, or |
| control UPnP infrastructure using Javascript and GUPnP, GObject |
| introspection is the only way to do it. |
| |
| This section describes the Yocto Project support for generating and |
| packaging GObject introspection data. GObject introspection data is a |
| description of the API provided by libraries built on top of the GLib |
| framework, and, in particular, that framework's GObject mechanism. |
| GObject Introspection Repository (GIR) files go to ``-dev`` packages, |
| ``typelib`` files go to main packages as they are packaged together with |
| libraries that are introspected. |
| |
| The data is generated when building such a library, by linking the |
| library with a small executable binary that asks the library to describe |
| itself, and then executing the binary and processing its output. |
| |
| Generating this data in a cross-compilation environment is difficult |
| because the library is produced for the target architecture, but its |
| code needs to be executed on the build host. This problem is solved with |
| the OpenEmbedded build system by running the code through QEMU, which |
| allows precisely that. Unfortunately, QEMU does not always work |
| perfectly as mentioned in the ":ref:`dev-manual/common-tasks:known issues`" |
| section. |
| |
| Enabling the Generation of Introspection Data |
| --------------------------------------------- |
| |
| Enabling the generation of introspection data (GIR files) in your |
| library package involves the following: |
| |
| 1. Inherit the |
| :ref:`gobject-introspection <ref-classes-gobject-introspection>` |
| class. |
| |
| 2. Make sure introspection is not disabled anywhere in the recipe or |
| from anything the recipe includes. Also, make sure that |
| "gobject-introspection-data" is not in |
| :term:`DISTRO_FEATURES_BACKFILL_CONSIDERED` |
| and that "qemu-usermode" is not in |
| :term:`MACHINE_FEATURES_BACKFILL_CONSIDERED`. |
| In either of these conditions, nothing will happen. |
| |
| 3. Try to build the recipe. If you encounter build errors that look like |
| something is unable to find ``.so`` libraries, check where these |
| libraries are located in the source tree and add the following to the |
| recipe:: |
| |
| GIR_EXTRA_LIBS_PATH = "${B}/something/.libs" |
| |
| .. note:: |
| |
| See recipes in the ``oe-core`` repository that use that |
| :term:`GIR_EXTRA_LIBS_PATH` variable as an example. |
| |
| 4. Look for any other errors, which probably mean that introspection |
| support in a package is not entirely standard, and thus breaks down |
| in a cross-compilation environment. For such cases, custom-made fixes |
| are needed. A good place to ask and receive help in these cases is |
| the :ref:`Yocto Project mailing |
| lists <resources-mailinglist>`. |
| |
| .. note:: |
| |
| Using a library that no longer builds against the latest Yocto |
| Project release and prints introspection related errors is a good |
| candidate for the previous procedure. |
| |
| Disabling the Generation of Introspection Data |
| ---------------------------------------------- |
| |
| You might find that you do not want to generate introspection data. Or, |
| perhaps QEMU does not work on your build host and target architecture |
| combination. If so, you can use either of the following methods to |
| disable GIR file generations: |
| |
| - Add the following to your distro configuration:: |
| |
| DISTRO_FEATURES_BACKFILL_CONSIDERED = "gobject-introspection-data" |
| |
| Adding this statement disables generating introspection data using |
| QEMU but will still enable building introspection tools and libraries |
| (i.e. building them does not require the use of QEMU). |
| |
| - Add the following to your machine configuration:: |
| |
| MACHINE_FEATURES_BACKFILL_CONSIDERED = "qemu-usermode" |
| |
| Adding this statement disables the use of QEMU when building packages for your |
| machine. Currently, this feature is used only by introspection |
| recipes and has the same effect as the previously described option. |
| |
| .. note:: |
| |
| Future releases of the Yocto Project might have other features |
| affected by this option. |
| |
| If you disable introspection data, you can still obtain it through other |
| means such as copying the data from a suitable sysroot, or by generating |
| it on the target hardware. The OpenEmbedded build system does not |
| currently provide specific support for these techniques. |
| |
| Testing that Introspection Works in an Image |
| -------------------------------------------- |
| |
| Use the following procedure to test if generating introspection data is |
| working in an image: |
| |
| 1. Make sure that "gobject-introspection-data" is not in |
| :term:`DISTRO_FEATURES_BACKFILL_CONSIDERED` |
| and that "qemu-usermode" is not in |
| :term:`MACHINE_FEATURES_BACKFILL_CONSIDERED`. |
| |
| 2. Build ``core-image-sato``. |
| |
| 3. Launch a Terminal and then start Python in the terminal. |
| |
| 4. Enter the following in the terminal:: |
| |
| >>> from gi.repository import GLib |
| >>> GLib.get_host_name() |
| |
| 5. For something a little more advanced, enter the following see: |
| https://python-gtk-3-tutorial.readthedocs.io/en/latest/introduction.html |
| |
| Known Issues |
| ------------ |
| |
| Here are know issues in GObject Introspection Support: |
| |
| - ``qemu-ppc64`` immediately crashes. Consequently, you cannot build |
| introspection data on that architecture. |
| |
| - x32 is not supported by QEMU. Consequently, introspection data is |
| disabled. |
| |
| - musl causes transient GLib binaries to crash on assertion failures. |
| Consequently, generating introspection data is disabled. |
| |
| - Because QEMU is not able to run the binaries correctly, introspection |
| is disabled for some specific packages under specific architectures |
| (e.g. ``gcr``, ``libsecret``, and ``webkit``). |
| |
| - QEMU usermode might not work properly when running 64-bit binaries |
| under 32-bit host machines. In particular, "qemumips64" is known to |
| not work under i686. |
| |
| Optionally Using an External Toolchain |
| ====================================== |
| |
| You might want to use an external toolchain as part of your development. |
| If this is the case, the fundamental steps you need to accomplish are as |
| follows: |
| |
| - Understand where the installed toolchain resides. For cases where you |
| need to build the external toolchain, you would need to take separate |
| steps to build and install the toolchain. |
| |
| - Make sure you add the layer that contains the toolchain to your |
| ``bblayers.conf`` file through the |
| :term:`BBLAYERS` variable. |
| |
| - Set the ``EXTERNAL_TOOLCHAIN`` variable in your ``local.conf`` file |
| to the location in which you installed the toolchain. |
| |
| A good example of an external toolchain used with the Yocto Project is |
| Mentor Graphics Sourcery G++ Toolchain. You can see information on how |
| to use that particular layer in the ``README`` file at |
| https://github.com/MentorEmbedded/meta-sourcery/. You can find |
| further information by reading about the |
| :term:`TCMODE` variable in the Yocto |
| Project Reference Manual's variable glossary. |
| |
| Creating Partitioned Images Using Wic |
| ===================================== |
| |
| Creating an image for a particular hardware target using the |
| OpenEmbedded build system does not necessarily mean you can boot that |
| image as is on your device. Physical devices accept and boot images in |
| various ways depending on the specifics of the device. Usually, |
| information about the hardware can tell you what image format the device |
| requires. Should your device require multiple partitions on an SD card, |
| flash, or an HDD, you can use the OpenEmbedded Image Creator, Wic, to |
| create the properly partitioned image. |
| |
| The ``wic`` command generates partitioned images from existing |
| OpenEmbedded build artifacts. Image generation is driven by partitioning |
| commands contained in an Openembedded kickstart file (``.wks``) |
| specified either directly on the command line or as one of a selection |
| of canned kickstart files as shown with the ``wic list images`` command |
| in the |
| ":ref:`dev-manual/common-tasks:generate an image using an existing kickstart file`" |
| section. When you apply the command to a given set of build artifacts, the |
| result is an image or set of images that can be directly written onto media and |
| used on a particular system. |
| |
| .. note:: |
| |
| For a kickstart file reference, see the |
| ":ref:`ref-manual/kickstart:openembedded kickstart (\`\`.wks\`\`) reference`" |
| Chapter in the Yocto Project Reference Manual. |
| |
| The ``wic`` command and the infrastructure it is based on is by |
| definition incomplete. The purpose of the command is to allow the |
| generation of customized images, and as such, was designed to be |
| completely extensible through a plugin interface. See the |
| ":ref:`dev-manual/common-tasks:using the wic plugin interface`" section |
| for information on these plugins. |
| |
| This section provides some background information on Wic, describes what |
| you need to have in place to run the tool, provides instruction on how |
| to use the Wic utility, provides information on using the Wic plugins |
| interface, and provides several examples that show how to use Wic. |
| |
| Background |
| ---------- |
| |
| This section provides some background on the Wic utility. While none of |
| this information is required to use Wic, you might find it interesting. |
| |
| - The name "Wic" is derived from OpenEmbedded Image Creator (oeic). The |
| "oe" diphthong in "oeic" was promoted to the letter "w", because |
| "oeic" is both difficult to remember and to pronounce. |
| |
| - Wic is loosely based on the Meego Image Creator (``mic``) framework. |
| The Wic implementation has been heavily modified to make direct use |
| of OpenEmbedded build artifacts instead of package installation and |
| configuration, which are already incorporated within the OpenEmbedded |
| artifacts. |
| |
| - Wic is a completely independent standalone utility that initially |
| provides easier-to-use and more flexible replacements for an existing |
| functionality in OE-Core's |
| :ref:`image-live <ref-classes-image-live>` |
| class. The difference between Wic and those examples is that with Wic |
| the functionality of those scripts is implemented by a |
| general-purpose partitioning language, which is based on Redhat |
| kickstart syntax. |
| |
| Requirements |
| ------------ |
| |
| In order to use the Wic utility with the OpenEmbedded Build system, your |
| system needs to meet the following requirements: |
| |
| - The Linux distribution on your development host must support the |
| Yocto Project. See the ":ref:`detailed-supported-distros`" |
| section in the Yocto Project Reference Manual for the list of |
| distributions that support the Yocto Project. |
| |
| - The standard system utilities, such as ``cp``, must be installed on |
| your development host system. |
| |
| - You must have sourced the build environment setup script (i.e. |
| :ref:`structure-core-script`) found in the |
| :term:`Build Directory`. |
| |
| - You need to have the build artifacts already available, which |
| typically means that you must have already created an image using the |
| Openembedded build system (e.g. ``core-image-minimal``). While it |
| might seem redundant to generate an image in order to create an image |
| using Wic, the current version of Wic requires the artifacts in the |
| form generated by the OpenEmbedded build system. |
| |
| - You must build several native tools, which are built to run on the |
| build system:: |
| |
| $ bitbake parted-native dosfstools-native mtools-native |
| |
| - Include "wic" as part of the |
| :term:`IMAGE_FSTYPES` |
| variable. |
| |
| - Include the name of the :ref:`wic kickstart file <openembedded-kickstart-wks-reference>` |
| as part of the :term:`WKS_FILE` variable |
| |
| Getting Help |
| ------------ |
| |
| You can get general help for the ``wic`` command by entering the ``wic`` |
| command by itself or by entering the command with a help argument as |
| follows:: |
| |
| $ wic -h |
| $ wic --help |
| $ wic help |
| |
| Currently, Wic supports seven commands: ``cp``, ``create``, ``help``, |
| ``list``, ``ls``, ``rm``, and ``write``. You can get help for all these |
| commands except "help" by using the following form:: |
| |
| $ wic help command |
| |
| For example, the following command returns help for the ``write`` |
| command:: |
| |
| $ wic help write |
| |
| Wic supports help for three topics: ``overview``, ``plugins``, and |
| ``kickstart``. You can get help for any topic using the following form:: |
| |
| $ wic help topic |
| |
| For example, the following returns overview help for Wic:: |
| |
| $ wic help overview |
| |
| There is one additional level of help for Wic. You can get help on |
| individual images through the ``list`` command. You can use the ``list`` |
| command to return the available Wic images as follows:: |
| |
| $ wic list images |
| genericx86 Create an EFI disk image for genericx86* |
| edgerouter Create SD card image for Edgerouter |
| beaglebone-yocto Create SD card image for Beaglebone |
| qemux86-directdisk Create a qemu machine 'pcbios' direct disk image |
| systemd-bootdisk Create an EFI disk image with systemd-boot |
| mkhybridiso Create a hybrid ISO image |
| mkefidisk Create an EFI disk image |
| sdimage-bootpart Create SD card image with a boot partition |
| directdisk-multi-rootfs Create multi rootfs image using rootfs plugin |
| directdisk Create a 'pcbios' direct disk image |
| directdisk-bootloader-config Create a 'pcbios' direct disk image with custom bootloader config |
| qemuriscv Create qcow2 image for RISC-V QEMU machines |
| directdisk-gpt Create a 'pcbios' direct disk image |
| efi-bootdisk |
| |
| Once you know the list of available |
| Wic images, you can use ``help`` with the command to get help on a |
| particular image. For example, the following command returns help on the |
| "beaglebone-yocto" image:: |
| |
| $ wic list beaglebone-yocto help |
| |
| Creates a partitioned SD card image for Beaglebone. |
| Boot files are located in the first vfat partition. |
| |
| Operational Modes |
| ----------------- |
| |
| You can use Wic in two different modes, depending on how much control |
| you need for specifying the Openembedded build artifacts that are used |
| for creating the image: Raw and Cooked: |
| |
| - *Raw Mode:* You explicitly specify build artifacts through Wic |
| command-line arguments. |
| |
| - *Cooked Mode:* The current |
| :term:`MACHINE` setting and image |
| name are used to automatically locate and provide the build |
| artifacts. You just supply a kickstart file and the name of the image |
| from which to use artifacts. |
| |
| Regardless of the mode you use, you need to have the build artifacts |
| ready and available. |
| |
| Raw Mode |
| ~~~~~~~~ |
| |
| Running Wic in raw mode allows you to specify all the partitions through |
| the ``wic`` command line. The primary use for raw mode is if you have |
| built your kernel outside of the Yocto Project |
| :term:`Build Directory`. In other words, you |
| can point to arbitrary kernel, root filesystem locations, and so forth. |
| Contrast this behavior with cooked mode where Wic looks in the Build |
| Directory (e.g. ``tmp/deploy/images/``\ machine). |
| |
| The general form of the ``wic`` command in raw mode is:: |
| |
| $ wic create wks_file options ... |
| |
| Where: |
| |
| wks_file: |
| An OpenEmbedded kickstart file. You can provide |
| your own custom file or use a file from a set of |
| existing files as described by further options. |
| |
| optional arguments: |
| -h, --help show this help message and exit |
| -o OUTDIR, --outdir OUTDIR |
| name of directory to create image in |
| -e IMAGE_NAME, --image-name IMAGE_NAME |
| name of the image to use the artifacts from e.g. core- |
| image-sato |
| -r ROOTFS_DIR, --rootfs-dir ROOTFS_DIR |
| path to the /rootfs dir to use as the .wks rootfs |
| source |
| -b BOOTIMG_DIR, --bootimg-dir BOOTIMG_DIR |
| path to the dir containing the boot artifacts (e.g. |
| /EFI or /syslinux dirs) to use as the .wks bootimg |
| source |
| -k KERNEL_DIR, --kernel-dir KERNEL_DIR |
| path to the dir containing the kernel to use in the |
| .wks bootimg |
| -n NATIVE_SYSROOT, --native-sysroot NATIVE_SYSROOT |
| path to the native sysroot containing the tools to use |
| to build the image |
| -s, --skip-build-check |
| skip the build check |
| -f, --build-rootfs build rootfs |
| -c {gzip,bzip2,xz}, --compress-with {gzip,bzip2,xz} |
| compress image with specified compressor |
| -m, --bmap generate .bmap |
| --no-fstab-update Do not change fstab file. |
| -v VARS_DIR, --vars VARS_DIR |
| directory with <image>.env files that store bitbake |
| variables |
| -D, --debug output debug information |
| |
| .. note:: |
| |
| You do not need root privileges to run Wic. In fact, you should not |
| run as root when using the utility. |
| |
| Cooked Mode |
| ~~~~~~~~~~~ |
| |
| Running Wic in cooked mode leverages off artifacts in the Build |
| Directory. In other words, you do not have to specify kernel or root |
| filesystem locations as part of the command. All you need to provide is |
| a kickstart file and the name of the image from which to use artifacts |
| by using the "-e" option. Wic looks in the Build Directory (e.g. |
| ``tmp/deploy/images/``\ machine) for artifacts. |
| |
| The general form of the ``wic`` command using Cooked Mode is as follows:: |
| |
| $ wic create wks_file -e IMAGE_NAME |
| |
| Where: |
| |
| wks_file: |
| An OpenEmbedded kickstart file. You can provide |
| your own custom file or use a file from a set of |
| existing files provided with the Yocto Project |
| release. |
| |
| required argument: |
| -e IMAGE_NAME, --image-name IMAGE_NAME |
| name of the image to use the artifacts from e.g. core- |
| image-sato |
| |
| Using an Existing Kickstart File |
| -------------------------------- |
| |
| If you do not want to create your own kickstart file, you can use an |
| existing file provided by the Wic installation. As shipped, kickstart |
| files can be found in the :ref:`overview-manual/development-environment:yocto project source repositories` in the |
| following two locations:: |
| |
| poky/meta-yocto-bsp/wic |
| poky/scripts/lib/wic/canned-wks |
| |
| Use the following command to list the available kickstart files:: |
| |
| $ wic list images |
| genericx86 Create an EFI disk image for genericx86* |
| beaglebone-yocto Create SD card image for Beaglebone |
| edgerouter Create SD card image for Edgerouter |
| qemux86-directdisk Create a QEMU machine 'pcbios' direct disk image |
| directdisk-gpt Create a 'pcbios' direct disk image |
| mkefidisk Create an EFI disk image |
| directdisk Create a 'pcbios' direct disk image |
| systemd-bootdisk Create an EFI disk image with systemd-boot |
| mkhybridiso Create a hybrid ISO image |
| sdimage-bootpart Create SD card image with a boot partition |
| directdisk-multi-rootfs Create multi rootfs image using rootfs plugin |
| directdisk-bootloader-config Create a 'pcbios' direct disk image with custom bootloader config |
| |
| When you use an existing file, you |
| do not have to use the ``.wks`` extension. Here is an example in Raw |
| Mode that uses the ``directdisk`` file:: |
| |
| $ wic create directdisk -r rootfs_dir -b bootimg_dir \ |
| -k kernel_dir -n native_sysroot |
| |
| Here are the actual partition language commands used in the |
| ``genericx86.wks`` file to generate an image:: |
| |
| # short-description: Create an EFI disk image for genericx86* |
| # long-description: Creates a partitioned EFI disk image for genericx86* machines |
| part /boot --source bootimg-efi --sourceparams="loader=grub-efi" --ondisk sda --label msdos --active --align 1024 |
| part / --source rootfs --ondisk sda --fstype=ext4 --label platform --align 1024 --use-uuid |
| part swap --ondisk sda --size 44 --label swap1 --fstype=swap |
| |
| bootloader --ptable gpt --timeout=5 --append="rootfstype=ext4 console=ttyS0,115200 console=tty0" |
| |
| Using the Wic Plugin Interface |
| ------------------------------ |
| |
| You can extend and specialize Wic functionality by using Wic plugins. |
| This section explains the Wic plugin interface. |
| |
| .. note:: |
| |
| Wic plugins consist of "source" and "imager" plugins. Imager plugins |
| are beyond the scope of this section. |
| |
| Source plugins provide a mechanism to customize partition content during |
| the Wic image generation process. You can use source plugins to map |
| values that you specify using ``--source`` commands in kickstart files |
| (i.e. ``*.wks``) to a plugin implementation used to populate a given |
| partition. |
| |
| .. note:: |
| |
| If you use plugins that have build-time dependencies (e.g. native |
| tools, bootloaders, and so forth) when building a Wic image, you need |
| to specify those dependencies using the :term:`WKS_FILE_DEPENDS` |
| variable. |
| |
| Source plugins are subclasses defined in plugin files. As shipped, the |
| Yocto Project provides several plugin files. You can see the source |
| plugin files that ship with the Yocto Project |
| :yocto_git:`here </poky/tree/scripts/lib/wic/plugins/source>`. |
| Each of these plugin files contains source plugins that are designed to |
| populate a specific Wic image partition. |
| |
| Source plugins are subclasses of the ``SourcePlugin`` class, which is |
| defined in the ``poky/scripts/lib/wic/pluginbase.py`` file. For example, |
| the ``BootimgEFIPlugin`` source plugin found in the ``bootimg-efi.py`` |
| file is a subclass of the ``SourcePlugin`` class, which is found in the |
| ``pluginbase.py`` file. |
| |
| You can also implement source plugins in a layer outside of the Source |
| Repositories (external layer). To do so, be sure that your plugin files |
| are located in a directory whose path is |
| ``scripts/lib/wic/plugins/source/`` within your external layer. When the |
| plugin files are located there, the source plugins they contain are made |
| available to Wic. |
| |
| When the Wic implementation needs to invoke a partition-specific |
| implementation, it looks for the plugin with the same name as the |
| ``--source`` parameter used in the kickstart file given to that |
| partition. For example, if the partition is set up using the following |
| command in a kickstart file:: |
| |
| part /boot --source bootimg-pcbios --ondisk sda --label boot --active --align 1024 |
| |
| The methods defined as class |
| members of the matching source plugin (i.e. ``bootimg-pcbios``) in the |
| ``bootimg-pcbios.py`` plugin file are used. |
| |
| To be more concrete, here is the corresponding plugin definition from |
| the ``bootimg-pcbios.py`` file for the previous command along with an |
| example method called by the Wic implementation when it needs to prepare |
| a partition using an implementation-specific function:: |
| |
| . |
| . |
| . |
| class BootimgPcbiosPlugin(SourcePlugin): |
| """ |
| Create MBR boot partition and install syslinux on it. |
| """ |
| |
| name = 'bootimg-pcbios' |
| . |
| . |
| . |
| @classmethod |
| def do_prepare_partition(cls, part, source_params, creator, cr_workdir, |
| oe_builddir, bootimg_dir, kernel_dir, |
| rootfs_dir, native_sysroot): |
| """ |
| Called to do the actual content population for a partition i.e. it |
| 'prepares' the partition to be incorporated into the image. |
| In this case, prepare content for legacy bios boot partition. |
| """ |
| . |
| . |
| . |
| |
| If a |
| subclass (plugin) itself does not implement a particular function, Wic |
| locates and uses the default version in the superclass. It is for this |
| reason that all source plugins are derived from the ``SourcePlugin`` |
| class. |
| |
| The ``SourcePlugin`` class defined in the ``pluginbase.py`` file defines |
| a set of methods that source plugins can implement or override. Any |
| plugins (subclass of ``SourcePlugin``) that do not implement a |
| particular method inherit the implementation of the method from the |
| ``SourcePlugin`` class. For more information, see the ``SourcePlugin`` |
| class in the ``pluginbase.py`` file for details: |
| |
| The following list describes the methods implemented in the |
| ``SourcePlugin`` class: |
| |
| - ``do_prepare_partition()``: Called to populate a partition with |
| actual content. In other words, the method prepares the final |
| partition image that is incorporated into the disk image. |
| |
| - ``do_configure_partition()``: Called before |
| ``do_prepare_partition()`` to create custom configuration files for a |
| partition (e.g. syslinux or grub configuration files). |
| |
| - ``do_install_disk()``: Called after all partitions have been |
| prepared and assembled into a disk image. This method provides a hook |
| to allow finalization of a disk image (e.g. writing an MBR). |
| |
| - ``do_stage_partition()``: Special content-staging hook called |
| before ``do_prepare_partition()``. This method is normally empty. |
| |
| Typically, a partition just uses the passed-in parameters (e.g. the |
| unmodified value of ``bootimg_dir``). However, in some cases, things |
| might need to be more tailored. As an example, certain files might |
| additionally need to be taken from ``bootimg_dir + /boot``. This hook |
| allows those files to be staged in a customized fashion. |
| |
| .. note:: |
| |
| ``get_bitbake_var()`` allows you to access non-standard variables that |
| you might want to use for this behavior. |
| |
| You can extend the source plugin mechanism. To add more hooks, create |
| more source plugin methods within ``SourcePlugin`` and the corresponding |
| derived subclasses. The code that calls the plugin methods uses the |
| ``plugin.get_source_plugin_methods()`` function to find the method or |
| methods needed by the call. Retrieval of those methods is accomplished |
| by filling up a dict with keys that contain the method names of |
| interest. On success, these will be filled in with the actual methods. |
| See the Wic implementation for examples and details. |
| |
| Wic Examples |
| ------------ |
| |
| This section provides several examples that show how to use the Wic |
| utility. All the examples assume the list of requirements in the |
| ":ref:`dev-manual/common-tasks:requirements`" section have been met. The |
| examples assume the previously generated image is |
| ``core-image-minimal``. |
| |
| Generate an Image using an Existing Kickstart File |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| This example runs in Cooked Mode and uses the ``mkefidisk`` kickstart |
| file:: |
| |
| $ wic create mkefidisk -e core-image-minimal |
| INFO: Building wic-tools... |
| . |
| . |
| . |
| INFO: The new image(s) can be found here: |
| ./mkefidisk-201804191017-sda.direct |
| |
| The following build artifacts were used to create the image(s): |
| ROOTFS_DIR: /home/stephano/yocto/build/tmp-glibc/work/qemux86-oe-linux/core-image-minimal/1.0-r0/rootfs |
| BOOTIMG_DIR: /home/stephano/yocto/build/tmp-glibc/work/qemux86-oe-linux/core-image-minimal/1.0-r0/recipe-sysroot/usr/share |
| KERNEL_DIR: /home/stephano/yocto/build/tmp-glibc/deploy/images/qemux86 |
| NATIVE_SYSROOT: /home/stephano/yocto/build/tmp-glibc/work/i586-oe-linux/wic-tools/1.0-r0/recipe-sysroot-native |
| |
| INFO: The image(s) were created using OE kickstart file: |
| /home/stephano/yocto/openembedded-core/scripts/lib/wic/canned-wks/mkefidisk.wks |
| |
| The previous example shows the easiest way to create an image by running |
| in cooked mode and supplying a kickstart file and the "-e" option to |
| point to the existing build artifacts. Your ``local.conf`` file needs to |
| have the :term:`MACHINE` variable set |
| to the machine you are using, which is "qemux86" in this example. |
| |
| Once the image builds, the output provides image location, artifact use, |
| and kickstart file information. |
| |
| .. note:: |
| |
| You should always verify the details provided in the output to make |
| sure that the image was indeed created exactly as expected. |
| |
| Continuing with the example, you can now write the image from the Build |
| Directory onto a USB stick, or whatever media for which you built your |
| image, and boot from the media. You can write the image by using |
| ``bmaptool`` or ``dd``:: |
| |
| $ oe-run-native bmaptool copy mkefidisk-201804191017-sda.direct /dev/sdX |
| |
| or :: |
| |
| $ sudo dd if=mkefidisk-201804191017-sda.direct of=/dev/sdX |
| |
| .. note:: |
| |
| For more information on how to use the ``bmaptool`` |
| to flash a device with an image, see the |
| ":ref:`dev-manual/common-tasks:flashing images using \`\`bmaptool\`\``" |
| section. |
| |
| Using a Modified Kickstart File |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| Because partitioned image creation is driven by the kickstart file, it |
| is easy to affect image creation by changing the parameters in the file. |
| This next example demonstrates that through modification of the |
| ``directdisk-gpt`` kickstart file. |
| |
| As mentioned earlier, you can use the command ``wic list images`` to |
| show the list of existing kickstart files. The directory in which the |
| ``directdisk-gpt.wks`` file resides is |
| ``scripts/lib/image/canned-wks/``, which is located in the |
| :term:`Source Directory` (e.g. ``poky``). |
| Because available files reside in this directory, you can create and add |
| your own custom files to the directory. Subsequent use of the |
| ``wic list images`` command would then include your kickstart files. |
| |
| In this example, the existing ``directdisk-gpt`` file already does most |
| of what is needed. However, for the hardware in this example, the image |
| will need to boot from ``sdb`` instead of ``sda``, which is what the |
| ``directdisk-gpt`` kickstart file uses. |
| |
| The example begins by making a copy of the ``directdisk-gpt.wks`` file |
| in the ``scripts/lib/image/canned-wks`` directory and then by changing |
| the lines that specify the target disk from which to boot. |
| :: |
| |
| $ cp /home/stephano/yocto/poky/scripts/lib/wic/canned-wks/directdisk-gpt.wks \ |
| /home/stephano/yocto/poky/scripts/lib/wic/canned-wks/directdisksdb-gpt.wks |
| |
| Next, the example modifies the ``directdisksdb-gpt.wks`` file and |
| changes all instances of "``--ondisk sda``" to "``--ondisk sdb``". The |
| example changes the following two lines and leaves the remaining lines |
| untouched:: |
| |
| part /boot --source bootimg-pcbios --ondisk sdb --label boot --active --align 1024 |
| part / --source rootfs --ondisk sdb --fstype=ext4 --label platform --align 1024 --use-uuid |
| |
| Once the lines are changed, the |
| example generates the ``directdisksdb-gpt`` image. The command points |
| the process at the ``core-image-minimal`` artifacts for the Next Unit of |
| Computing (nuc) :term:`MACHINE` the |
| ``local.conf``. |
| :: |
| |
| $ wic create directdisksdb-gpt -e core-image-minimal |
| INFO: Building wic-tools... |
| . |
| . |
| . |
| Initialising tasks: 100% |#######################################| Time: 0:00:01 |
| NOTE: Executing SetScene Tasks |
| NOTE: Executing RunQueue Tasks |
| NOTE: Tasks Summary: Attempted 1161 tasks of which 1157 didn't need to be rerun and all succeeded. |
| INFO: Creating image(s)... |
| |
| INFO: The new image(s) can be found here: |
| ./directdisksdb-gpt-201710090938-sdb.direct |
| |
| The following build artifacts were used to create the image(s): |
| ROOTFS_DIR: /home/stephano/yocto/build/tmp-glibc/work/qemux86-oe-linux/core-image-minimal/1.0-r0/rootfs |
| BOOTIMG_DIR: /home/stephano/yocto/build/tmp-glibc/work/qemux86-oe-linux/core-image-minimal/1.0-r0/recipe-sysroot/usr/share |
| KERNEL_DIR: /home/stephano/yocto/build/tmp-glibc/deploy/images/qemux86 |
| NATIVE_SYSROOT: /home/stephano/yocto/build/tmp-glibc/work/i586-oe-linux/wic-tools/1.0-r0/recipe-sysroot-native |
| |
| INFO: The image(s) were created using OE kickstart file: |
| /home/stephano/yocto/poky/scripts/lib/wic/canned-wks/directdisksdb-gpt.wks |
| |
| Continuing with the example, you can now directly ``dd`` the image to a |
| USB stick, or whatever media for which you built your image, and boot |
| the resulting media:: |
| |
| $ sudo dd if=directdisksdb-gpt-201710090938-sdb.direct of=/dev/sdb |
| 140966+0 records in |
| 140966+0 records out |
| 72174592 bytes (72 MB, 69 MiB) copied, 78.0282 s, 925 kB/s |
| $ sudo eject /dev/sdb |
| |
| Using a Modified Kickstart File and Running in Raw Mode |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| This next example manually specifies each build artifact (runs in Raw |
| Mode) and uses a modified kickstart file. The example also uses the |
| ``-o`` option to cause Wic to create the output somewhere other than the |
| default output directory, which is the current directory:: |
| |
| $ wic create test.wks -o /home/stephano/testwic \ |
| --rootfs-dir /home/stephano/yocto/build/tmp/work/qemux86-poky-linux/core-image-minimal/1.0-r0/rootfs \ |
| --bootimg-dir /home/stephano/yocto/build/tmp/work/qemux86-poky-linux/core-image-minimal/1.0-r0/recipe-sysroot/usr/share \ |
| --kernel-dir /home/stephano/yocto/build/tmp/deploy/images/qemux86 \ |
| --native-sysroot /home/stephano/yocto/build/tmp/work/i586-poky-linux/wic-tools/1.0-r0/recipe-sysroot-native |
| |
| INFO: Creating image(s)... |
| |
| INFO: The new image(s) can be found here: |
| /home/stephano/testwic/test-201710091445-sdb.direct |
| |
| The following build artifacts were used to create the image(s): |
| ROOTFS_DIR: /home/stephano/yocto/build/tmp-glibc/work/qemux86-oe-linux/core-image-minimal/1.0-r0/rootfs |
| BOOTIMG_DIR: /home/stephano/yocto/build/tmp-glibc/work/qemux86-oe-linux/core-image-minimal/1.0-r0/recipe-sysroot/usr/share |
| KERNEL_DIR: /home/stephano/yocto/build/tmp-glibc/deploy/images/qemux86 |
| NATIVE_SYSROOT: /home/stephano/yocto/build/tmp-glibc/work/i586-oe-linux/wic-tools/1.0-r0/recipe-sysroot-native |
| |
| INFO: The image(s) were created using OE kickstart file: |
| test.wks |
| |
| For this example, |
| :term:`MACHINE` did not have to be |
| specified in the ``local.conf`` file since the artifact is manually |
| specified. |
| |
| Using Wic to Manipulate an Image |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| Wic image manipulation allows you to shorten turnaround time during |
| image development. For example, you can use Wic to delete the kernel |
| partition of a Wic image and then insert a newly built kernel. This |
| saves you time from having to rebuild the entire image each time you |
| modify the kernel. |
| |
| .. note:: |
| |
| In order to use Wic to manipulate a Wic image as in this example, |
| your development machine must have the ``mtools`` package installed. |
| |
| The following example examines the contents of the Wic image, deletes |
| the existing kernel, and then inserts a new kernel: |
| |
| 1. *List the Partitions:* Use the ``wic ls`` command to list all the |
| partitions in the Wic image:: |
| |
| $ wic ls tmp/deploy/images/qemux86/core-image-minimal-qemux86.wic |
| Num Start End Size Fstype |
| 1 1048576 25041919 23993344 fat16 |
| 2 25165824 72157183 46991360 ext4 |
| |
| The previous output shows two partitions in the |
| ``core-image-minimal-qemux86.wic`` image. |
| |
| 2. *Examine a Particular Partition:* Use the ``wic ls`` command again |
| but in a different form to examine a particular partition. |
| |
| .. note:: |
| |
| You can get command usage on any Wic command using the following |
| form:: |
| |
| $ wic help command |
| |
| |
| For example, the following command shows you the various ways to |
| use the |
| wic ls |
| command:: |
| |
| $ wic help ls |
| |
| |
| The following command shows what is in partition one:: |
| |
| $ wic ls tmp/deploy/images/qemux86/core-image-minimal-qemux86.wic:1 |
| Volume in drive : is boot |
| Volume Serial Number is E894-1809 |
| Directory for ::/ |
| |
| libcom32 c32 186500 2017-10-09 16:06 |
| libutil c32 24148 2017-10-09 16:06 |
| syslinux cfg 220 2017-10-09 16:06 |
| vesamenu c32 27104 2017-10-09 16:06 |
| vmlinuz 6904608 2017-10-09 16:06 |
| 5 files 7 142 580 bytes |
| 16 582 656 bytes free |
| |
| The previous output shows five files, with the |
| ``vmlinuz`` being the kernel. |
| |
| .. note:: |
| |
| If you see the following error, you need to update or create a |
| ``~/.mtoolsrc`` file and be sure to have the line "mtools_skip_check=1" |
| in the file. Then, run the Wic command again:: |
| |
| ERROR: _exec_cmd: /usr/bin/mdir -i /tmp/wic-parttfokuwra ::/ returned '1' instead of 0 |
| output: Total number of sectors (47824) not a multiple of sectors per track (32)! |
| Add mtools_skip_check=1 to your .mtoolsrc file to skip this test |
| |
| |
| 3. *Remove the Old Kernel:* Use the ``wic rm`` command to remove the |
| ``vmlinuz`` file (kernel):: |
| |
| $ wic rm tmp/deploy/images/qemux86/core-image-minimal-qemux86.wic:1/vmlinuz |
| |
| 4. *Add In the New Kernel:* Use the ``wic cp`` command to add the |
| updated kernel to the Wic image. Depending on how you built your |
| kernel, it could be in different places. If you used ``devtool`` and |
| an SDK to build your kernel, it resides in the ``tmp/work`` directory |
| of the extensible SDK. If you used ``make`` to build the kernel, the |
| kernel will be in the ``workspace/sources`` area. |
| |
| The following example assumes ``devtool`` was used to build the |
| kernel:: |
| |
| $ wic cp poky_sdk/tmp/work/qemux86-poky-linux/linux-yocto/4.12.12+git999-r0/linux-yocto-4.12.12+git999/arch/x86/boot/bzImage \ |
| poky/build/tmp/deploy/images/qemux86/core-image-minimal-qemux86.wic:1/vmlinuz |
| |
| Once the new kernel is added back into the image, you can use the |
| ``dd`` command or :ref:`bmaptool |
| <dev-manual/common-tasks:flashing images using \`\`bmaptool\`\`>` |
| to flash your wic image onto an SD card or USB stick and test your |
| target. |
| |
| .. note:: |
| |
| Using ``bmaptool`` is generally 10 to 20 times faster than using ``dd``. |
| |
| Flashing Images Using ``bmaptool`` |
| ================================== |
| |
| A fast and easy way to flash an image to a bootable device is to use |
| Bmaptool, which is integrated into the OpenEmbedded build system. |
| Bmaptool is a generic tool that creates a file's block map (bmap) and |
| then uses that map to copy the file. As compared to traditional tools |
| such as dd or cp, Bmaptool can copy (or flash) large files like raw |
| system image files much faster. |
| |
| .. note:: |
| |
| - If you are using Ubuntu or Debian distributions, you can install |
| the ``bmap-tools`` package using the following command and then |
| use the tool without specifying ``PATH`` even from the root |
| account:: |
| |
| $ sudo apt install bmap-tools |
| |
| - If you are unable to install the ``bmap-tools`` package, you will |
| need to build Bmaptool before using it. Use the following command:: |
| |
| $ bitbake bmap-tools-native |
| |
| Following, is an example that shows how to flash a Wic image. Realize |
| that while this example uses a Wic image, you can use Bmaptool to flash |
| any type of image. Use these steps to flash an image using Bmaptool: |
| |
| 1. *Update your local.conf File:* You need to have the following set |
| in your ``local.conf`` file before building your image:: |
| |
| IMAGE_FSTYPES += "wic wic.bmap" |
| |
| 2. *Get Your Image:* Either have your image ready (pre-built with the |
| :term:`IMAGE_FSTYPES` |
| setting previously mentioned) or take the step to build the image:: |
| |
| $ bitbake image |
| |
| 3. *Flash the Device:* Flash the device with the image by using Bmaptool |
| depending on your particular setup. The following commands assume the |
| image resides in the Build Directory's ``deploy/images/`` area: |
| |
| - If you have write access to the media, use this command form:: |
| |
| $ oe-run-native bmap-tools-native bmaptool copy build-directory/tmp/deploy/images/machine/image.wic /dev/sdX |
| |
| - If you do not have write access to the media, set your permissions |
| first and then use the same command form:: |
| |
| $ sudo chmod 666 /dev/sdX |
| $ oe-run-native bmap-tools-native bmaptool copy build-directory/tmp/deploy/images/machine/image.wic /dev/sdX |
| |
| For help on the ``bmaptool`` command, use the following command:: |
| |
| $ bmaptool --help |
| |
| Making Images More Secure |
| ========================= |
| |
| Security is of increasing concern for embedded devices. Consider the |
| issues and problems discussed in just this sampling of work found across |
| the Internet: |
| |
| - *"*\ `Security Risks of Embedded |
| Systems <https://www.schneier.com/blog/archives/2014/01/security_risks_9.html>`__\ *"* |
| by Bruce Schneier |
| |
| - *"*\ `Internet Census |
| 2012 <http://census2012.sourceforge.net/paper.html>`__\ *"* by Carna |
| Botnet |
| |
| - *"*\ `Security Issues for Embedded |
| Devices <https://elinux.org/images/6/6f/Security-issues.pdf>`__\ *"* |
| by Jake Edge |
| |
| When securing your image is of concern, there are steps, tools, and |
| variables that you can consider to help you reach the security goals you |
| need for your particular device. Not all situations are identical when |
| it comes to making an image secure. Consequently, this section provides |
| some guidance and suggestions for consideration when you want to make |
| your image more secure. |
| |
| .. note:: |
| |
| Because the security requirements and risks are different for every |
| type of device, this section cannot provide a complete reference on |
| securing your custom OS. It is strongly recommended that you also |
| consult other sources of information on embedded Linux system |
| hardening and on security. |
| |
| General Considerations |
| ---------------------- |
| |
| There are general considerations that help you create more secure images. |
| You should consider the following suggestions to make your device |
| more secure: |
| |
| - Scan additional code you are adding to the system (e.g. application |
| code) by using static analysis tools. Look for buffer overflows and |
| other potential security problems. |
| |
| - Pay particular attention to the security for any web-based |
| administration interface. |
| |
| Web interfaces typically need to perform administrative functions and |
| tend to need to run with elevated privileges. Thus, the consequences |
| resulting from the interface's security becoming compromised can be |
| serious. Look for common web vulnerabilities such as |
| cross-site-scripting (XSS), unvalidated inputs, and so forth. |
| |
| As with system passwords, the default credentials for accessing a |
| web-based interface should not be the same across all devices. This |
| is particularly true if the interface is enabled by default as it can |
| be assumed that many end-users will not change the credentials. |
| |
| - Ensure you can update the software on the device to mitigate |
| vulnerabilities discovered in the future. This consideration |
| especially applies when your device is network-enabled. |
| |
| - Ensure you remove or disable debugging functionality before producing |
| the final image. For information on how to do this, see the |
| ":ref:`dev-manual/common-tasks:considerations specific to the openembedded build system`" |
| section. |
| |
| - Ensure you have no network services listening that are not needed. |
| |
| - Remove any software from the image that is not needed. |
| |
| - Enable hardware support for secure boot functionality when your |
| device supports this functionality. |
| |
| Security Flags |
| -------------- |
| |
| The Yocto Project has security flags that you can enable that help make |
| your build output more secure. The security flags are in the |
| ``meta/conf/distro/include/security_flags.inc`` file in your |
| :term:`Source Directory` (e.g. ``poky``). |
| |
| .. note:: |
| |
| Depending on the recipe, certain security flags are enabled and |
| disabled by default. |
| |
| Use the following line in your ``local.conf`` file or in your custom |
| distribution configuration file to enable the security compiler and |
| linker flags for your build:: |
| |
| require conf/distro/include/security_flags.inc |
| |
| Considerations Specific to the OpenEmbedded Build System |
| -------------------------------------------------------- |
| |
| You can take some steps that are specific to the OpenEmbedded build |
| system to make your images more secure: |
| |
| - Ensure "debug-tweaks" is not one of your selected |
| :term:`IMAGE_FEATURES`. |
| When creating a new project, the default is to provide you with an |
| initial ``local.conf`` file that enables this feature using the |
| :term:`EXTRA_IMAGE_FEATURES` |
| variable with the line:: |
| |
| EXTRA_IMAGE_FEATURES = "debug-tweaks" |
| |
| To disable that feature, simply comment out that line in your |
| ``local.conf`` file, or make sure :term:`IMAGE_FEATURES` does not contain |
| "debug-tweaks" before producing your final image. Among other things, |
| leaving this in place sets the root password as blank, which makes |
| logging in for debugging or inspection easy during development but |
| also means anyone can easily log in during production. |
| |
| - It is possible to set a root password for the image and also to set |
| passwords for any extra users you might add (e.g. administrative or |
| service type users). When you set up passwords for multiple images or |
| users, you should not duplicate passwords. |
| |
| To set up passwords, use the |
| :ref:`extrausers <ref-classes-extrausers>` |
| class, which is the preferred method. For an example on how to set up |
| both root and user passwords, see the |
| ":ref:`extrausers.bbclass <ref-classes-extrausers>`" |
| section. |
| |
| .. note:: |
| |
| When adding extra user accounts or setting a root password, be |
| cautious about setting the same password on every device. If you |
| do this, and the password you have set is exposed, then every |
| device is now potentially compromised. If you need this access but |
| want to ensure security, consider setting a different, random |
| password for each device. Typically, you do this as a separate |
| step after you deploy the image onto the device. |
| |
| - Consider enabling a Mandatory Access Control (MAC) framework such as |
| SMACK or SELinux and tuning it appropriately for your device's usage. |
| You can find more information in the |
| :yocto_git:`meta-selinux </meta-selinux/>` layer. |
| |
| Tools for Hardening Your Image |
| ------------------------------ |
| |
| The Yocto Project provides tools for making your image more secure. You |
| can find these tools in the ``meta-security`` layer of the |
| :yocto_git:`Yocto Project Source Repositories <>`. |
| |
| Creating Your Own Distribution |
| ============================== |
| |
| When you build an image using the Yocto Project and do not alter any |
| distribution :term:`Metadata`, you are |
| creating a Poky distribution. If you wish to gain more control over |
| package alternative selections, compile-time options, and other |
| low-level configurations, you can create your own distribution. |
| |
| To create your own distribution, the basic steps consist of creating |
| your own distribution layer, creating your own distribution |
| configuration file, and then adding any needed code and Metadata to the |
| layer. The following steps provide some more detail: |
| |
| - *Create a layer for your new distro:* Create your distribution layer |
| so that you can keep your Metadata and code for the distribution |
| separate. It is strongly recommended that you create and use your own |
| layer for configuration and code. Using your own layer as compared to |
| just placing configurations in a ``local.conf`` configuration file |
| makes it easier to reproduce the same build configuration when using |
| multiple build machines. See the |
| ":ref:`dev-manual/common-tasks:creating a general layer using the \`\`bitbake-layers\`\` script`" |
| section for information on how to quickly set up a layer. |
| |
| - *Create the distribution configuration file:* The distribution |
| configuration file needs to be created in the ``conf/distro`` |
| directory of your layer. You need to name it using your distribution |
| name (e.g. ``mydistro.conf``). |
| |
| .. note:: |
| |
| The :term:`DISTRO` variable in your ``local.conf`` file determines the |
| name of your distribution. |
| |
| You can split out parts of your configuration file into include files |
| and then "require" them from within your distribution configuration |
| file. Be sure to place the include files in the |
| ``conf/distro/include`` directory of your layer. A common example |
| usage of include files would be to separate out the selection of |
| desired version and revisions for individual recipes. |
| |
| Your configuration file needs to set the following required |
| variables: |
| |
| - :term:`DISTRO_NAME` |
| |
| - :term:`DISTRO_VERSION` |
| |
| These following variables are optional and you typically set them |
| from the distribution configuration file: |
| |
| - :term:`DISTRO_FEATURES` |
| |
| - :term:`DISTRO_EXTRA_RDEPENDS` |
| |
| - :term:`DISTRO_EXTRA_RRECOMMENDS` |
| |
| - :term:`TCLIBC` |
| |
| .. tip:: |
| |
| If you want to base your distribution configuration file on the |
| very basic configuration from OE-Core, you can use |
| ``conf/distro/defaultsetup.conf`` as a reference and just include |
| variables that differ as compared to ``defaultsetup.conf``. |
| Alternatively, you can create a distribution configuration file |
| from scratch using the ``defaultsetup.conf`` file or configuration files |
| from other distributions such as Poky or Angstrom as references. |
| |
| - *Provide miscellaneous variables:* Be sure to define any other |
| variables for which you want to create a default or enforce as part |
| of the distribution configuration. You can include nearly any |
| variable from the ``local.conf`` file. The variables you use are not |
| limited to the list in the previous bulleted item. |
| |
| - *Point to Your distribution configuration file:* In your |
| ``local.conf`` file in the :term:`Build Directory`, |
| set your |
| :term:`DISTRO` variable to point to |
| your distribution's configuration file. For example, if your |
| distribution's configuration file is named ``mydistro.conf``, then |
| you point to it as follows:: |
| |
| DISTRO = "mydistro" |
| |
| - *Add more to the layer if necessary:* Use your layer to hold other |
| information needed for the distribution: |
| |
| - Add recipes for installing distro-specific configuration files |
| that are not already installed by another recipe. If you have |
| distro-specific configuration files that are included by an |
| existing recipe, you should add an append file (``.bbappend``) for |
| those. For general information and recommendations on how to add |
| recipes to your layer, see the |
| ":ref:`dev-manual/common-tasks:creating your own layer`" and |
| ":ref:`dev-manual/common-tasks:following best practices when creating layers`" |
| sections. |
| |
| - Add any image recipes that are specific to your distribution. |
| |
| - Add a ``psplash`` append file for a branded splash screen. For |
| information on append files, see the |
| ":ref:`dev-manual/common-tasks:appending other layers metadata with your layer`" |
| section. |
| |
| - Add any other append files to make custom changes that are |
| specific to individual recipes. |
| |
| Creating a Custom Template Configuration Directory |
| ================================================== |
| |
| If you are producing your own customized version of the build system for |
| use by other users, you might want to customize the message shown by the |
| setup script or you might want to change the template configuration |
| files (i.e. ``local.conf`` and ``bblayers.conf``) that are created in a |
| new build directory. |
| |
| The OpenEmbedded build system uses the environment variable |
| ``TEMPLATECONF`` to locate the directory from which it gathers |
| configuration information that ultimately ends up in the |
| :term:`Build Directory` ``conf`` directory. |
| By default, ``TEMPLATECONF`` is set as follows in the ``poky`` |
| repository:: |
| |
| TEMPLATECONF=${TEMPLATECONF:-meta-poky/conf} |
| |
| This is the |
| directory used by the build system to find templates from which to build |
| some key configuration files. If you look at this directory, you will |
| see the ``bblayers.conf.sample``, ``local.conf.sample``, and |
| ``conf-notes.txt`` files. The build system uses these files to form the |
| respective ``bblayers.conf`` file, ``local.conf`` file, and display the |
| list of BitBake targets when running the setup script. |
| |
| To override these default configuration files with configurations you |
| want used within every new Build Directory, simply set the |
| ``TEMPLATECONF`` variable to your directory. The ``TEMPLATECONF`` |
| variable is set in the ``.templateconf`` file, which is in the top-level |
| :term:`Source Directory` folder |
| (e.g. ``poky``). Edit the ``.templateconf`` so that it can locate your |
| directory. |
| |
| Best practices dictate that you should keep your template configuration |
| directory in your custom distribution layer. For example, suppose you |
| have a layer named ``meta-mylayer`` located in your home directory and |
| you want your template configuration directory named ``myconf``. |
| Changing the ``.templateconf`` as follows causes the OpenEmbedded build |
| system to look in your directory and base its configuration files on the |
| ``*.sample`` configuration files it finds. The final configuration files |
| (i.e. ``local.conf`` and ``bblayers.conf`` ultimately still end up in |
| your Build Directory, but they are based on your ``*.sample`` files. |
| :: |
| |
| TEMPLATECONF=${TEMPLATECONF:-meta-mylayer/myconf} |
| |
| Aside from the ``*.sample`` configuration files, the ``conf-notes.txt`` |
| also resides in the default ``meta-poky/conf`` directory. The script |
| that sets up the build environment (i.e. |
| :ref:`structure-core-script`) uses this file to |
| display BitBake targets as part of the script output. Customizing this |
| ``conf-notes.txt`` file is a good way to make sure your list of custom |
| targets appears as part of the script's output. |
| |
| Here is the default list of targets displayed as a result of running |
| either of the setup scripts:: |
| |
| You can now run 'bitbake <target>' |
| |
| Common targets are: |
| core-image-minimal |
| core-image-sato |
| meta-toolchain |
| meta-ide-support |
| |
| Changing the listed common targets is as easy as editing your version of |
| ``conf-notes.txt`` in your custom template configuration directory and |
| making sure you have ``TEMPLATECONF`` set to your directory. |
| |
| Conserving Disk Space |
| ===================== |
| |
| Conserving Disk Space During Builds |
| ----------------------------------- |
| |
| To help conserve disk space during builds, you can add the following |
| statement to your project's ``local.conf`` configuration file found in |
| the :term:`Build Directory`:: |
| |
| INHERIT += "rm_work" |
| |
| Adding this statement deletes the work directory used for |
| building a recipe once the recipe is built. For more information on |
| "rm_work", see the |
| :ref:`rm_work <ref-classes-rm-work>` class in the |
| Yocto Project Reference Manual. |
| |
| Purging Duplicate Shared State Cache Files |
| ------------------------------------------- |
| |
| After multiple build iterations, the Shared State (sstate) cache can contain |
| duplicate cache files for a given package, while only the most recent one |
| is likely to be reusable. The following command purges all but the |
| newest sstate cache file for each package:: |
| |
| sstate-cache-management.sh --remove-duplicated --cache-dir=build/sstate-cache |
| |
| This command will ask you to confirm the deletions it identifies. |
| |
| Note:: |
| |
| The duplicated sstate cache files of one package must have the same |
| architecture, which means that sstate cache files with multiple |
| architectures are not considered as duplicate. |
| |
| Run ``sstate-cache-management.sh`` for more details about this script. |
| |
| Working with Packages |
| ===================== |
| |
| This section describes a few tasks that involve packages: |
| |
| - :ref:`dev-manual/common-tasks:excluding packages from an image` |
| |
| - :ref:`dev-manual/common-tasks:incrementing a package version` |
| |
| - :ref:`dev-manual/common-tasks:handling optional module packaging` |
| |
| - :ref:`dev-manual/common-tasks:using runtime package management` |
| |
| - :ref:`dev-manual/common-tasks:generating and using signed packages` |
| |
| - :ref:`Setting up and running package test |
| (ptest) <dev-manual/common-tasks:testing packages with ptest>` |
| |
| - :ref:`dev-manual/common-tasks:creating node package manager (npm) packages` |
| |
| - :ref:`dev-manual/common-tasks:adding custom metadata to packages` |
| |
| Excluding Packages from an Image |
| -------------------------------- |
| |
| You might find it necessary to prevent specific packages from being |
| installed into an image. If so, you can use several variables to direct |
| the build system to essentially ignore installing recommended packages |
| or to not install a package at all. |
| |
| The following list introduces variables you can use to prevent packages |
| from being installed into your image. Each of these variables only works |
| with IPK and RPM package types, not for Debian packages. |
| Also, you can use these variables from your ``local.conf`` file |
| or attach them to a specific image recipe by using a recipe name |
| override. For more detail on the variables, see the descriptions in the |
| Yocto Project Reference Manual's glossary chapter. |
| |
| - :term:`BAD_RECOMMENDATIONS`: |
| Use this variable to specify "recommended-only" packages that you do |
| not want installed. |
| |
| - :term:`NO_RECOMMENDATIONS`: |
| Use this variable to prevent all "recommended-only" packages from |
| being installed. |
| |
| - :term:`PACKAGE_EXCLUDE`: |
| Use this variable to prevent specific packages from being installed |
| regardless of whether they are "recommended-only" or not. You need to |
| realize that the build process could fail with an error when you |
| prevent the installation of a package whose presence is required by |
| an installed package. |
| |
| Incrementing a Package Version |
| ------------------------------ |
| |
| This section provides some background on how binary package versioning |
| is accomplished and presents some of the services, variables, and |
| terminology involved. |
| |
| In order to understand binary package versioning, you need to consider |
| the following: |
| |
| - Binary Package: The binary package that is eventually built and |
| installed into an image. |
| |
| - Binary Package Version: The binary package version is composed of two |
| components - a version and a revision. |
| |
| .. note:: |
| |
| Technically, a third component, the "epoch" (i.e. :term:`PE`) is involved |
| but this discussion for the most part ignores :term:`PE`. |
| |
| The version and revision are taken from the |
| :term:`PV` and |
| :term:`PR` variables, respectively. |
| |
| - :term:`PV`: The recipe version. :term:`PV` represents the version of the |
| software being packaged. Do not confuse :term:`PV` with the binary |
| package version. |
| |
| - :term:`PR`: The recipe revision. |
| |
| - :term:`SRCPV`: The OpenEmbedded |
| build system uses this string to help define the value of :term:`PV` when |
| the source code revision needs to be included in it. |
| |
| - :yocto_wiki:`PR Service </PR_Service>`: A |
| network-based service that helps automate keeping package feeds |
| compatible with existing package manager applications such as RPM, |
| APT, and OPKG. |
| |
| Whenever the binary package content changes, the binary package version |
| must change. Changing the binary package version is accomplished by |
| changing or "bumping" the :term:`PR` and/or :term:`PV` values. Increasing these |
| values occurs one of two ways: |
| |
| - Automatically using a Package Revision Service (PR Service). |
| |
| - Manually incrementing the :term:`PR` and/or :term:`PV` variables. |
| |
| Given a primary challenge of any build system and its users is how to |
| maintain a package feed that is compatible with existing package manager |
| applications such as RPM, APT, and OPKG, using an automated system is |
| much preferred over a manual system. In either system, the main |
| requirement is that binary package version numbering increases in a |
| linear fashion and that there is a number of version components that |
| support that linear progression. For information on how to ensure |
| package revisioning remains linear, see the |
| ":ref:`dev-manual/common-tasks:automatically incrementing a package version number`" |
| section. |
| |
| The following three sections provide related information on the PR |
| Service, the manual method for "bumping" :term:`PR` and/or :term:`PV`, and on |
| how to ensure binary package revisioning remains linear. |
| |
| Working With a PR Service |
| ~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| As mentioned, attempting to maintain revision numbers in the |
| :term:`Metadata` is error prone, inaccurate, |
| and causes problems for people submitting recipes. Conversely, the PR |
| Service automatically generates increasing numbers, particularly the |
| revision field, which removes the human element. |
| |
| .. note:: |
| |
| For additional information on using a PR Service, you can see the |
| :yocto_wiki:`PR Service </PR_Service>` wiki page. |
| |
| The Yocto Project uses variables in order of decreasing priority to |
| facilitate revision numbering (i.e. |
| :term:`PE`, |
| :term:`PV`, and |
| :term:`PR` for epoch, version, and |
| revision, respectively). The values are highly dependent on the policies |
| and procedures of a given distribution and package feed. |
| |
| Because the OpenEmbedded build system uses |
| ":ref:`signatures <overview-manual/concepts:checksums (signatures)>`", which are |
| unique to a given build, the build system knows when to rebuild |
| packages. All the inputs into a given task are represented by a |
| signature, which can trigger a rebuild when different. Thus, the build |
| system itself does not rely on the :term:`PR`, :term:`PV`, and :term:`PE` numbers to |
| trigger a rebuild. The signatures, however, can be used to generate |
| these values. |
| |
| The PR Service works with both ``OEBasic`` and ``OEBasicHash`` |
| generators. The value of :term:`PR` bumps when the checksum changes and the |
| different generator mechanisms change signatures under different |
| circumstances. |
| |
| As implemented, the build system includes values from the PR Service |
| into the :term:`PR` field as an addition using the form "``.x``" so ``r0`` |
| becomes ``r0.1``, ``r0.2`` and so forth. This scheme allows existing |
| :term:`PR` values to be used for whatever reasons, which include manual |
| :term:`PR` bumps, should it be necessary. |
| |
| By default, the PR Service is not enabled or running. Thus, the packages |
| generated are just "self consistent". The build system adds and removes |
| packages and there are no guarantees about upgrade paths but images will |
| be consistent and correct with the latest changes. |
| |
| The simplest form for a PR Service is for a single host |
| development system that builds the package feed (building system). For |
| this scenario, you can enable a local PR Service by setting |
| :term:`PRSERV_HOST` in your |
| ``local.conf`` file in the :term:`Build Directory`:: |
| |
| PRSERV_HOST = "localhost:0" |
| |
| Once the service is started, packages will automatically |
| get increasing :term:`PR` values and BitBake takes care of starting and |
| stopping the server. |
| |
| If you have a more complex setup where multiple host development systems |
| work against a common, shared package feed, you have a single PR Service |
| running and it is connected to each building system. For this scenario, |
| you need to start the PR Service using the ``bitbake-prserv`` command:: |
| |
| bitbake-prserv --host ip --port port --start |
| |
| In addition to |
| hand-starting the service, you need to update the ``local.conf`` file of |
| each building system as described earlier so each system points to the |
| server and port. |
| |
| It is also recommended you use build history, which adds some sanity |
| checks to binary package versions, in conjunction with the server that |
| is running the PR Service. To enable build history, add the following to |
| each building system's ``local.conf`` file:: |
| |
| # It is recommended to activate "buildhistory" for testing the PR service |
| INHERIT += "buildhistory" |
| BUILDHISTORY_COMMIT = "1" |
| |
| For information on build |
| history, see the |
| ":ref:`dev-manual/common-tasks:maintaining build output quality`" section. |
| |
| .. note:: |
| |
| The OpenEmbedded build system does not maintain :term:`PR` information as |
| part of the shared state (sstate) packages. If you maintain an sstate |
| feed, it's expected that either all your building systems that |
| contribute to the sstate feed use a shared PR Service, or you do not |
| run a PR Service on any of your building systems. Having some systems |
| use a PR Service while others do not leads to obvious problems. |
| |
| For more information on shared state, see the |
| ":ref:`overview-manual/concepts:shared state cache`" |
| section in the Yocto Project Overview and Concepts Manual. |
| |
| Manually Bumping PR |
| ~~~~~~~~~~~~~~~~~~~ |
| |
| The alternative to setting up a PR Service is to manually "bump" the |
| :term:`PR` variable. |
| |
| If a committed change results in changing the package output, then the |
| value of the PR variable needs to be increased (or "bumped") as part of |
| that commit. For new recipes you should add the :term:`PR` variable and set |
| its initial value equal to "r0", which is the default. Even though the |
| default value is "r0", the practice of adding it to a new recipe makes |
| it harder to forget to bump the variable when you make changes to the |
| recipe in future. |
| |
| If you are sharing a common ``.inc`` file with multiple recipes, you can |
| also use the :term:`INC_PR` variable to ensure that the recipes sharing the |
| ``.inc`` file are rebuilt when the ``.inc`` file itself is changed. The |
| ``.inc`` file must set :term:`INC_PR` (initially to "r0"), and all recipes |
| referring to it should set :term:`PR` to "${INC_PR}.0" initially, |
| incrementing the last number when the recipe is changed. If the ``.inc`` |
| file is changed then its :term:`INC_PR` should be incremented. |
| |
| When upgrading the version of a binary package, assuming the :term:`PV` |
| changes, the :term:`PR` variable should be reset to "r0" (or "${INC_PR}.0" |
| if you are using :term:`INC_PR`). |
| |
| Usually, version increases occur only to binary packages. However, if |
| for some reason :term:`PV` changes but does not increase, you can increase |
| the :term:`PE` variable (Package Epoch). The :term:`PE` variable defaults to |
| "0". |
| |
| Binary package version numbering strives to follow the `Debian Version |
| Field Policy |
| Guidelines <https://www.debian.org/doc/debian-policy/ch-controlfields.html>`__. |
| These guidelines define how versions are compared and what "increasing" |
| a version means. |
| |
| Automatically Incrementing a Package Version Number |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| When fetching a repository, BitBake uses the |
| :term:`SRCREV` variable to determine |
| the specific source code revision from which to build. You set the |
| :term:`SRCREV` variable to |
| :term:`AUTOREV` to cause the |
| OpenEmbedded build system to automatically use the latest revision of |
| the software:: |
| |
| SRCREV = "${AUTOREV}" |
| |
| Furthermore, you need to reference :term:`SRCPV` in :term:`PV` in order to |
| automatically update the version whenever the revision of the source |
| code changes. Here is an example:: |
| |
| PV = "1.0+git${SRCPV}" |
| |
| The OpenEmbedded build system substitutes :term:`SRCPV` with the following: |
| |
| .. code-block:: none |
| |
| AUTOINC+source_code_revision |
| |
| The build system replaces the ``AUTOINC`` |
| with a number. The number used depends on the state of the PR Service: |
| |
| - If PR Service is enabled, the build system increments the number, |
| which is similar to the behavior of |
| :term:`PR`. This behavior results in |
| linearly increasing package versions, which is desirable. Here is an |
| example: |
| |
| .. code-block:: none |
| |
| hello-world-git_0.0+git0+b6558dd387-r0.0_armv7a-neon.ipk |
| hello-world-git_0.0+git1+dd2f5c3565-r0.0_armv7a-neon.ipk |
| |
| - If PR Service is not enabled, the build system replaces the |
| ``AUTOINC`` placeholder with zero (i.e. "0"). This results in |
| changing the package version since the source revision is included. |
| However, package versions are not increased linearly. Here is an |
| example: |
| |
| .. code-block:: none |
| |
| hello-world-git_0.0+git0+b6558dd387-r0.0_armv7a-neon.ipk |
| hello-world-git_0.0+git0+dd2f5c3565-r0.0_armv7a-neon.ipk |
| |
| In summary, the OpenEmbedded build system does not track the history of |
| binary package versions for this purpose. ``AUTOINC``, in this case, is |
| comparable to :term:`PR`. If PR server is not enabled, ``AUTOINC`` in the |
| package version is simply replaced by "0". If PR server is enabled, the |
| build system keeps track of the package versions and bumps the number |
| when the package revision changes. |
| |
| Handling Optional Module Packaging |
| ---------------------------------- |
| |
| Many pieces of software split functionality into optional modules (or |
| plugins) and the plugins that are built might depend on configuration |
| options. To avoid having to duplicate the logic that determines what |
| modules are available in your recipe or to avoid having to package each |
| module by hand, the OpenEmbedded build system provides functionality to |
| handle module packaging dynamically. |
| |
| To handle optional module packaging, you need to do two things: |
| |
| - Ensure the module packaging is actually done. |
| |
| - Ensure that any dependencies on optional modules from other recipes |
| are satisfied by your recipe. |
| |
| Making Sure the Packaging is Done |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| To ensure the module packaging actually gets done, you use the |
| ``do_split_packages`` function within the ``populate_packages`` Python |
| function in your recipe. The ``do_split_packages`` function searches for |
| a pattern of files or directories under a specified path and creates a |
| package for each one it finds by appending to the |
| :term:`PACKAGES` variable and |
| setting the appropriate values for ``FILES:packagename``, |
| ``RDEPENDS:packagename``, ``DESCRIPTION:packagename``, and so forth. |
| Here is an example from the ``lighttpd`` recipe:: |
| |
| python populate_packages:prepend () { |
| lighttpd_libdir = d.expand('${libdir}') |
| do_split_packages(d, lighttpd_libdir, '^mod_(.*).so$', |
| 'lighttpd-module-%s', 'Lighttpd module for %s', |
| extra_depends='') |
| } |
| |
| The previous example specifies a number of things in the call to |
| ``do_split_packages``. |
| |
| - A directory within the files installed by your recipe through |
| ``do_install`` in which to search. |
| |
| - A regular expression used to match module files in that directory. In |
| the example, note the parentheses () that mark the part of the |
| expression from which the module name should be derived. |
| |
| - A pattern to use for the package names. |
| |
| - A description for each package. |
| |
| - An empty string for ``extra_depends``, which disables the default |
| dependency on the main ``lighttpd`` package. Thus, if a file in |
| ``${libdir}`` called ``mod_alias.so`` is found, a package called |
| ``lighttpd-module-alias`` is created for it and the |
| :term:`DESCRIPTION` is set to |
| "Lighttpd module for alias". |
| |
| Often, packaging modules is as simple as the previous example. However, |
| there are more advanced options that you can use within |
| ``do_split_packages`` to modify its behavior. And, if you need to, you |
| can add more logic by specifying a hook function that is called for each |
| package. It is also perfectly acceptable to call ``do_split_packages`` |
| multiple times if you have more than one set of modules to package. |
| |
| For more examples that show how to use ``do_split_packages``, see the |
| ``connman.inc`` file in the ``meta/recipes-connectivity/connman/`` |
| directory of the ``poky`` :ref:`source repository <overview-manual/development-environment:yocto project source repositories>`. You can |
| also find examples in ``meta/classes/kernel.bbclass``. |
| |
| Following is a reference that shows ``do_split_packages`` mandatory and |
| optional arguments:: |
| |
| Mandatory arguments |
| |
| root |
| The path in which to search |
| file_regex |
| Regular expression to match searched files. |
| Use parentheses () to mark the part of this |
| expression that should be used to derive the |
| module name (to be substituted where %s is |
| used in other function arguments as noted below) |
| output_pattern |
| Pattern to use for the package names. Must |
| include %s. |
| description |
| Description to set for each package. Must |
| include %s. |
| |
| Optional arguments |
| |
| postinst |
| Postinstall script to use for all packages |
| (as a string) |
| recursive |
| True to perform a recursive search - default |
| False |
| hook |
| A hook function to be called for every match. |
| The function will be called with the following |
| arguments (in the order listed): |
| |
| f |
| Full path to the file/directory match |
| pkg |
| The package name |
| file_regex |
| As above |
| output_pattern |
| As above |
| modulename |
| The module name derived using file_regex |
| extra_depends |
| Extra runtime dependencies (RDEPENDS) to be |
| set for all packages. The default value of None |
| causes a dependency on the main package |
| (${PN}) - if you do not want this, pass empty |
| string '' for this parameter. |
| aux_files_pattern |
| Extra item(s) to be added to FILES for each |
| package. Can be a single string item or a list |
| of strings for multiple items. Must include %s. |
| postrm |
| postrm script to use for all packages (as a |
| string) |
| allow_dirs |
| True to allow directories to be matched - |
| default False |
| prepend |
| If True, prepend created packages to PACKAGES |
| instead of the default False which appends them |
| match_path |
| match file_regex on the whole relative path to |
| the root rather than just the filename |
| aux_files_pattern_verbatim |
| Extra item(s) to be added to FILES for each |
| package, using the actual derived module name |
| rather than converting it to something legal |
| for a package name. Can be a single string item |
| or a list of strings for multiple items. Must |
| include %s. |
| allow_links |
| True to allow symlinks to be matched - default |
| False |
| summary |
| Summary to set for each package. Must include %s; |
| defaults to description if not set. |
| |
| |
| |
| Satisfying Dependencies |
| ~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| The second part for handling optional module packaging is to ensure that |
| any dependencies on optional modules from other recipes are satisfied by |
| your recipe. You can be sure these dependencies are satisfied by using |
| the :term:`PACKAGES_DYNAMIC` |
| variable. Here is an example that continues with the ``lighttpd`` recipe |
| shown earlier:: |
| |
| PACKAGES_DYNAMIC = "lighttpd-module-.*" |
| |
| The name |
| specified in the regular expression can of course be anything. In this |
| example, it is ``lighttpd-module-`` and is specified as the prefix to |
| ensure that any :term:`RDEPENDS` and |
| :term:`RRECOMMENDS` on a package |
| name starting with the prefix are satisfied during build time. If you |
| are using ``do_split_packages`` as described in the previous section, |
| the value you put in :term:`PACKAGES_DYNAMIC` should correspond to the name |
| pattern specified in the call to ``do_split_packages``. |
| |
| Using Runtime Package Management |
| -------------------------------- |
| |
| During a build, BitBake always transforms a recipe into one or more |
| packages. For example, BitBake takes the ``bash`` recipe and produces a |
| number of packages (e.g. ``bash``, ``bash-bashbug``, |
| ``bash-completion``, ``bash-completion-dbg``, ``bash-completion-dev``, |
| ``bash-completion-extra``, ``bash-dbg``, and so forth). Not all |
| generated packages are included in an image. |
| |
| In several situations, you might need to update, add, remove, or query |
| the packages on a target device at runtime (i.e. without having to |
| generate a new image). Examples of such situations include: |
| |
| - You want to provide in-the-field updates to deployed devices (e.g. |
| security updates). |
| |
| - You want to have a fast turn-around development cycle for one or more |
| applications that run on your device. |
| |
| - You want to temporarily install the "debug" packages of various |
| applications on your device so that debugging can be greatly improved |
| by allowing access to symbols and source debugging. |
| |
| - You want to deploy a more minimal package selection of your device |
| but allow in-the-field updates to add a larger selection for |
| customization. |
| |
| In all these situations, you have something similar to a more |
| traditional Linux distribution in that in-field devices are able to |
| receive pre-compiled packages from a server for installation or update. |
| Being able to install these packages on a running, in-field device is |
| what is termed "runtime package management". |
| |
| In order to use runtime package management, you need a host or server |
| machine that serves up the pre-compiled packages plus the required |
| metadata. You also need package manipulation tools on the target. The |
| build machine is a likely candidate to act as the server. However, that |
| machine does not necessarily have to be the package server. The build |
| machine could push its artifacts to another machine that acts as the |
| server (e.g. Internet-facing). In fact, doing so is advantageous for a |
| production environment as getting the packages away from the development |
| system's build directory prevents accidental overwrites. |
| |
| A simple build that targets just one device produces more than one |
| package database. In other words, the packages produced by a build are |
| separated out into a couple of different package groupings based on |
| criteria such as the target's CPU architecture, the target board, or the |
| C library used on the target. For example, a build targeting the |
| ``qemux86`` device produces the following three package databases: |
| ``noarch``, ``i586``, and ``qemux86``. If you wanted your ``qemux86`` |
| device to be aware of all the packages that were available to it, you |
| would need to point it to each of these databases individually. In a |
| similar way, a traditional Linux distribution usually is configured to |
| be aware of a number of software repositories from which it retrieves |
| packages. |
| |
| Using runtime package management is completely optional and not required |
| for a successful build or deployment in any way. But if you want to make |
| use of runtime package management, you need to do a couple things above |
| and beyond the basics. The remainder of this section describes what you |
| need to do. |
| |
| Build Considerations |
| ~~~~~~~~~~~~~~~~~~~~ |
| |
| This section describes build considerations of which you need to be |
| aware in order to provide support for runtime package management. |
| |
| When BitBake generates packages, it needs to know what format or formats |
| to use. In your configuration, you use the |
| :term:`PACKAGE_CLASSES` |
| variable to specify the format: |
| |
| 1. Open the ``local.conf`` file inside your |
| :term:`Build Directory` (e.g. |
| ``poky/build/conf/local.conf``). |
| |
| 2. Select the desired package format as follows:: |
| |
| PACKAGE_CLASSES ?= "package_packageformat" |
| |
| where packageformat can be "ipk", "rpm", |
| "deb", or "tar" which are the supported package formats. |
| |
| .. note:: |
| |
| Because the Yocto Project supports four different package formats, |
| you can set the variable with more than one argument. However, the |
| OpenEmbedded build system only uses the first argument when |
| creating an image or Software Development Kit (SDK). |
| |
| If you would like your image to start off with a basic package database |
| containing the packages in your current build as well as to have the |
| relevant tools available on the target for runtime package management, |
| you can include "package-management" in the |
| :term:`IMAGE_FEATURES` |
| variable. Including "package-management" in this configuration variable |
| ensures that when the image is assembled for your target, the image |
| includes the currently-known package databases as well as the |
| target-specific tools required for runtime package management to be |
| performed on the target. However, this is not strictly necessary. You |
| could start your image off without any databases but only include the |
| required on-target package tool(s). As an example, you could include |
| "opkg" in your |
| :term:`IMAGE_INSTALL` variable |
| if you are using the IPK package format. You can then initialize your |
| target's package database(s) later once your image is up and running. |
| |
| Whenever you perform any sort of build step that can potentially |
| generate a package or modify existing package, it is always a good idea |
| to re-generate the package index after the build by using the following |
| command:: |
| |
| $ bitbake package-index |
| |
| It might be tempting to build the |
| package and the package index at the same time with a command such as |
| the following:: |
| |
| $ bitbake some-package package-index |
| |
| Do not do this as |
| BitBake does not schedule the package index for after the completion of |
| the package you are building. Consequently, you cannot be sure of the |
| package index including information for the package you just built. |
| Thus, be sure to run the package update step separately after building |
| any packages. |
| |
| You can use the |
| :term:`PACKAGE_FEED_ARCHS`, |
| :term:`PACKAGE_FEED_BASE_PATHS`, |
| and |
| :term:`PACKAGE_FEED_URIS` |
| variables to pre-configure target images to use a package feed. If you |
| do not define these variables, then manual steps as described in the |
| subsequent sections are necessary to configure the target. You should |
| set these variables before building the image in order to produce a |
| correctly configured image. |
| |
| When your build is complete, your packages reside in the |
| ``${TMPDIR}/deploy/packageformat`` directory. For example, if |
| ``${``\ :term:`TMPDIR`\ ``}`` is |
| ``tmp`` and your selected package type is RPM, then your RPM packages |
| are available in ``tmp/deploy/rpm``. |
| |
| Host or Server Machine Setup |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| Although other protocols are possible, a server using HTTP typically |
| serves packages. If you want to use HTTP, then set up and configure a |
| web server such as Apache 2, lighttpd, or Python web server on the |
| machine serving the packages. |
| |
| To keep things simple, this section describes how to set up a |
| Python web server to share package feeds from the developer's |
| machine. Although this server might not be the best for a production |
| environment, the setup is simple and straight forward. Should you want |
| to use a different server more suited for production (e.g. Apache 2, |
| Lighttpd, or Nginx), take the appropriate steps to do so. |
| |
| From within the build directory where you have built an image based on |
| your packaging choice (i.e. the |
| :term:`PACKAGE_CLASSES` |
| setting), simply start the server. The following example assumes a build |
| directory of ``poky/build/tmp/deploy/rpm`` and a :term:`PACKAGE_CLASSES` |
| setting of "package_rpm":: |
| |
| $ cd poky/build/tmp/deploy/rpm |
| $ python3 -m http.server |
| |
| Target Setup |
| ~~~~~~~~~~~~ |
| |
| Setting up the target differs depending on the package management |
| system. This section provides information for RPM, IPK, and DEB. |
| |
| Using RPM |
| ^^^^^^^^^ |
| |
| The `Dandified Packaging |
| Tool <https://en.wikipedia.org/wiki/DNF_(software)>`__ (DNF) performs |
| runtime package management of RPM packages. In order to use DNF for |
| runtime package management, you must perform an initial setup on the |
| target machine for cases where the ``PACKAGE_FEED_*`` variables were not |
| set as part of the image that is running on the target. This means if |
| you built your image and did not use these variables as part of the |
| build and your image is now running on the target, you need to perform |
| the steps in this section if you want to use runtime package management. |
| |
| .. note:: |
| |
| For information on the ``PACKAGE_FEED_*`` variables, see |
| :term:`PACKAGE_FEED_ARCHS`, :term:`PACKAGE_FEED_BASE_PATHS`, and |
| :term:`PACKAGE_FEED_URIS` in the Yocto Project Reference Manual variables |
| glossary. |
| |
| On the target, you must inform DNF that package databases are available. |
| You do this by creating a file named |
| ``/etc/yum.repos.d/oe-packages.repo`` and defining the ``oe-packages``. |
| |
| As an example, assume the target is able to use the following package |
| databases: ``all``, ``i586``, and ``qemux86`` from a server named |
| ``my.server``. The specifics for setting up the web server are up to |
| you. The critical requirement is that the URIs in the target repository |
| configuration point to the correct remote location for the feeds. |
| |
| .. note:: |
| |
| For development purposes, you can point the web server to the build |
| system's ``deploy`` directory. However, for production use, it is better to |
| copy the package directories to a location outside of the build area and use |
| that location. Doing so avoids situations where the build system |
| overwrites or changes the ``deploy`` directory. |
| |
| When telling DNF where to look for the package databases, you must |
| declare individual locations per architecture or a single location used |
| for all architectures. You cannot do both: |
| |
| - *Create an Explicit List of Architectures:* Define individual base |
| URLs to identify where each package database is located: |
| |
| .. code-block:: none |
| |
| [oe-packages] |
| baseurl=http://my.server/rpm/i586 http://my.server/rpm/qemux86 http://my.server/rpm/all |
| |
| This example |
| informs DNF about individual package databases for all three |
| architectures. |
| |
| - *Create a Single (Full) Package Index:* Define a single base URL that |
| identifies where a full package database is located:: |
| |
| [oe-packages] |
| baseurl=http://my.server/rpm |
| |
| This example informs DNF about a single |
| package database that contains all the package index information for |
| all supported architectures. |
| |
| Once you have informed DNF where to find the package databases, you need |
| to fetch them: |
| |
| .. code-block:: none |
| |
| # dnf makecache |
| |
| DNF is now able to find, install, and |
| upgrade packages from the specified repository or repositories. |
| |
| .. note:: |
| |
| See the `DNF documentation <https://dnf.readthedocs.io/en/latest/>`__ for |
| additional information. |
| |
| Using IPK |
| ^^^^^^^^^ |
| |
| The ``opkg`` application performs runtime package management of IPK |
| packages. You must perform an initial setup for ``opkg`` on the target |
| machine if the |
| :term:`PACKAGE_FEED_ARCHS`, |
| :term:`PACKAGE_FEED_BASE_PATHS`, |
| and |
| :term:`PACKAGE_FEED_URIS` |
| variables have not been set or the target image was built before the |
| variables were set. |
| |
| The ``opkg`` application uses configuration files to find available |
| package databases. Thus, you need to create a configuration file inside |
| the ``/etc/opkg/`` direction, which informs ``opkg`` of any repository |
| you want to use. |
| |
| As an example, suppose you are serving packages from a ``ipk/`` |
| directory containing the ``i586``, ``all``, and ``qemux86`` databases |
| through an HTTP server named ``my.server``. On the target, create a |
| configuration file (e.g. ``my_repo.conf``) inside the ``/etc/opkg/`` |
| directory containing the following: |
| |
| .. code-block:: none |
| |
| src/gz all http://my.server/ipk/all |
| src/gz i586 http://my.server/ipk/i586 |
| src/gz qemux86 http://my.server/ipk/qemux86 |
| |
| Next, instruct ``opkg`` to fetch the |
| repository information: |
| |
| .. code-block:: none |
| |
| # opkg update |
| |
| The ``opkg`` application is now able to find, install, and upgrade packages |
| from the specified repository. |
| |
| Using DEB |
| ^^^^^^^^^ |
| |
| The ``apt`` application performs runtime package management of DEB |
| packages. This application uses a source list file to find available |
| package databases. You must perform an initial setup for ``apt`` on the |
| target machine if the |
| :term:`PACKAGE_FEED_ARCHS`, |
| :term:`PACKAGE_FEED_BASE_PATHS`, |
| and |
| :term:`PACKAGE_FEED_URIS` |
| variables have not been set or the target image was built before the |
| variables were set. |
| |
| To inform ``apt`` of the repository you want to use, you might create a |
| list file (e.g. ``my_repo.list``) inside the |
| ``/etc/apt/sources.list.d/`` directory. As an example, suppose you are |
| serving packages from a ``deb/`` directory containing the ``i586``, |
| ``all``, and ``qemux86`` databases through an HTTP server named |
| ``my.server``. The list file should contain: |
| |
| .. code-block:: none |
| |
| deb http://my.server/deb/all ./ |
| deb http://my.server/deb/i586 ./ |
| deb http://my.server/deb/qemux86 ./ |
| |
| Next, instruct the ``apt`` application |
| to fetch the repository information: |
| |
| .. code-block:: none |
| |
| $ sudo apt update |
| |
| After this step, |
| ``apt`` is able to find, install, and upgrade packages from the |
| specified repository. |
| |
| Generating and Using Signed Packages |
| ------------------------------------ |
| |
| In order to add security to RPM packages used during a build, you can |
| take steps to securely sign them. Once a signature is verified, the |
| OpenEmbedded build system can use the package in the build. If security |
| fails for a signed package, the build system stops the build. |
| |
| This section describes how to sign RPM packages during a build and how |
| to use signed package feeds (repositories) when doing a build. |
| |
| Signing RPM Packages |
| ~~~~~~~~~~~~~~~~~~~~ |
| |
| To enable signing RPM packages, you must set up the following |
| configurations in either your ``local.config`` or ``distro.config`` |
| file:: |
| |
| # Inherit sign_rpm.bbclass to enable signing functionality |
| INHERIT += " sign_rpm" |
| # Define the GPG key that will be used for signing. |
| RPM_GPG_NAME = "key_name" |
| # Provide passphrase for the key |
| RPM_GPG_PASSPHRASE = "passphrase" |
| |
| .. note:: |
| |
| Be sure to supply appropriate values for both `key_name` and |
| `passphrase`. |
| |
| Aside from the ``RPM_GPG_NAME`` and ``RPM_GPG_PASSPHRASE`` variables in |
| the previous example, two optional variables related to signing are available: |
| |
| - *GPG_BIN:* Specifies a ``gpg`` binary/wrapper that is executed |
| when the package is signed. |
| |
| - *GPG_PATH:* Specifies the ``gpg`` home directory used when the |
| package is signed. |
| |
| Processing Package Feeds |
| ~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| In addition to being able to sign RPM packages, you can also enable |
| signed package feeds for IPK and RPM packages. |
| |
| The steps you need to take to enable signed package feed use are similar |
| to the steps used to sign RPM packages. You must define the following in |
| your ``local.config`` or ``distro.config`` file:: |
| |
| INHERIT += "sign_package_feed" |
| PACKAGE_FEED_GPG_NAME = "key_name" |
| PACKAGE_FEED_GPG_PASSPHRASE_FILE = "path_to_file_containing_passphrase" |
| |
| For signed package feeds, the passphrase must be specified in a separate file, |
| which is pointed to by the ``PACKAGE_FEED_GPG_PASSPHRASE_FILE`` |
| variable. Regarding security, keeping a plain text passphrase out of the |
| configuration is more secure. |
| |
| Aside from the ``PACKAGE_FEED_GPG_NAME`` and |
| ``PACKAGE_FEED_GPG_PASSPHRASE_FILE`` variables, three optional variables |
| related to signed package feeds are available: |
| |
| - *GPG_BIN* Specifies a ``gpg`` binary/wrapper that is executed |
| when the package is signed. |
| |
| - *GPG_PATH:* Specifies the ``gpg`` home directory used when the |
| package is signed. |
| |
| - *PACKAGE_FEED_GPG_SIGNATURE_TYPE:* Specifies the type of ``gpg`` |
| signature. This variable applies only to RPM and IPK package feeds. |
| Allowable values for the ``PACKAGE_FEED_GPG_SIGNATURE_TYPE`` are |
| "ASC", which is the default and specifies ascii armored, and "BIN", |
| which specifies binary. |
| |
| Testing Packages With ptest |
| --------------------------- |
| |
| A Package Test (ptest) runs tests against packages built by the |
| OpenEmbedded build system on the target machine. A ptest contains at |
| least two items: the actual test, and a shell script (``run-ptest``) |
| that starts the test. The shell script that starts the test must not |
| contain the actual test - the script only starts the test. On the other |
| hand, the test can be anything from a simple shell script that runs a |
| binary and checks the output to an elaborate system of test binaries and |
| data files. |
| |
| The test generates output in the format used by Automake:: |
| |
| result: testname |
| |
| where the result can be ``PASS``, ``FAIL``, or ``SKIP``, and |
| the testname can be any identifying string. |
| |
| For a list of Yocto Project recipes that are already enabled with ptest, |
| see the :yocto_wiki:`Ptest </Ptest>` wiki page. |
| |
| .. note:: |
| |
| A recipe is "ptest-enabled" if it inherits the |
| :ref:`ptest <ref-classes-ptest>` class. |
| |
| Adding ptest to Your Build |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| To add package testing to your build, add the |
| :term:`DISTRO_FEATURES` and |
| :term:`EXTRA_IMAGE_FEATURES` |
| variables to your ``local.conf`` file, which is found in the |
| :term:`Build Directory`:: |
| |
| DISTRO_FEATURES:append = " ptest" |
| EXTRA_IMAGE_FEATURES += "ptest-pkgs" |
| |
| Once your build is complete, the ptest files are installed into the |
| ``/usr/lib/package/ptest`` directory within the image, where ``package`` |
| is the name of the package. |
| |
| Running ptest |
| ~~~~~~~~~~~~~ |
| |
| The ``ptest-runner`` package installs a shell script that loops through |
| all installed ptest test suites and runs them in sequence. Consequently, |
| you might want to add this package to your image. |
| |
| Getting Your Package Ready |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| In order to enable a recipe to run installed ptests on target hardware, |
| you need to prepare the recipes that build the packages you want to |
| test. Here is what you have to do for each recipe: |
| |
| - *Be sure the recipe inherits |
| the* :ref:`ptest <ref-classes-ptest>` *class:* |
| Include the following line in each recipe:: |
| |
| inherit ptest |
| |
| - *Create run-ptest:* This script starts your test. Locate the |
| script where you will refer to it using |
| :term:`SRC_URI`. Here is an |
| example that starts a test for ``dbus``:: |
| |
| #!/bin/sh |
| cd test |
| make -k runtest-TESTS |
| |
| - *Ensure dependencies are met:* If the test adds build or runtime |
| dependencies that normally do not exist for the package (such as |
| requiring "make" to run the test suite), use the |
| :term:`DEPENDS` and |
| :term:`RDEPENDS` variables in |
| your recipe in order for the package to meet the dependencies. Here |
| is an example where the package has a runtime dependency on "make":: |
| |
| RDEPENDS:${PN}-ptest += "make" |
| |
| - *Add a function to build the test suite:* Not many packages support |
| cross-compilation of their test suites. Consequently, you usually |
| need to add a cross-compilation function to the package. |
| |
| Many packages based on Automake compile and run the test suite by |
| using a single command such as ``make check``. However, the host |
| ``make check`` builds and runs on the same computer, while |
| cross-compiling requires that the package is built on the host but |
| executed for the target architecture (though often, as in the case |
| for ptest, the execution occurs on the host). The built version of |
| Automake that ships with the Yocto Project includes a patch that |
| separates building and execution. Consequently, packages that use the |
| unaltered, patched version of ``make check`` automatically |
| cross-compiles. |
| |
| Regardless, you still must add a ``do_compile_ptest`` function to |
| build the test suite. Add a function similar to the following to your |
| recipe:: |
| |
| do_compile_ptest() { |
| oe_runmake buildtest-TESTS |
| } |
| |
| - *Ensure special configurations are set:* If the package requires |
| special configurations prior to compiling the test code, you must |
| insert a ``do_configure_ptest`` function into the recipe. |
| |
| - *Install the test suite:* The ``ptest`` class automatically copies |
| the file ``run-ptest`` to the target and then runs make |
| ``install-ptest`` to run the tests. If this is not enough, you need |
| to create a ``do_install_ptest`` function and make sure it gets |
| called after the "make install-ptest" completes. |
| |
| Creating Node Package Manager (NPM) Packages |
| -------------------------------------------- |
| |
| `NPM <https://en.wikipedia.org/wiki/Npm_(software)>`__ is a package |
| manager for the JavaScript programming language. The Yocto Project |
| supports the NPM :ref:`fetcher <bitbake:bitbake-user-manual/bitbake-user-manual-fetching:fetchers>`. You can |
| use this fetcher in combination with |
| :doc:`devtool </ref-manual/devtool-reference>` to create |
| recipes that produce NPM packages. |
| |
| There are two workflows that allow you to create NPM packages using |
| ``devtool``: the NPM registry modules method and the NPM project code |
| method. |
| |
| .. note:: |
| |
| While it is possible to create NPM recipes manually, using |
| ``devtool`` is far simpler. |
| |
| Additionally, some requirements and caveats exist. |
| |
| Requirements and Caveats |
| ~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| You need to be aware of the following before using ``devtool`` to create |
| NPM packages: |
| |
| - Of the two methods that you can use ``devtool`` to create NPM |
| packages, the registry approach is slightly simpler. However, you |
| might consider the project approach because you do not have to |
| publish your module in the NPM registry |
| (`npm-registry <https://docs.npmjs.com/misc/registry>`_), which |
| is NPM's public registry. |
| |
| - Be familiar with |
| :doc:`devtool </ref-manual/devtool-reference>`. |
| |
| - The NPM host tools need the native ``nodejs-npm`` package, which is |
| part of the OpenEmbedded environment. You need to get the package by |
| cloning the https://github.com/openembedded/meta-openembedded |
| repository out of GitHub. Be sure to add the path to your local copy |
| to your ``bblayers.conf`` file. |
| |
| - ``devtool`` cannot detect native libraries in module dependencies. |
| Consequently, you must manually add packages to your recipe. |
| |
| - While deploying NPM packages, ``devtool`` cannot determine which |
| dependent packages are missing on the target (e.g. the node runtime |
| ``nodejs``). Consequently, you need to find out what files are |
| missing and be sure they are on the target. |
| |
| - Although you might not need NPM to run your node package, it is |
| useful to have NPM on your target. The NPM package name is |
| ``nodejs-npm``. |
| |
| Using the Registry Modules Method |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| This section presents an example that uses the ``cute-files`` module, |
| which is a file browser web application. |
| |
| .. note:: |
| |
| You must know the ``cute-files`` module version. |
| |
| The first thing you need to do is use ``devtool`` and the NPM fetcher to |
| create the recipe:: |
| |
| $ devtool add "npm://registry.npmjs.org;package=cute-files;version=1.0.2" |
| |
| The |
| ``devtool add`` command runs ``recipetool create`` and uses the same |
| fetch URI to download each dependency and capture license details where |
| possible. The result is a generated recipe. |
| |
| The recipe file is fairly simple and contains every license that |
| ``recipetool`` finds and includes the licenses in the recipe's |
| :term:`LIC_FILES_CHKSUM` |
| variables. You need to examine the variables and look for those with |
| "unknown" in the :term:`LICENSE` |
| field. You need to track down the license information for "unknown" |
| modules and manually add the information to the recipe. |
| |
| ``recipetool`` creates a "shrinkwrap" file for your recipe. Shrinkwrap |
| files capture the version of all dependent modules. Many packages do not |
| provide shrinkwrap files. ``recipetool`` create a shrinkwrap file as it |
| runs. |
| |
| .. note:: |
| |
| A package is created for each sub-module. This policy is the only |
| practical way to have the licenses for all of the dependencies |
| represented in the license manifest of the image. |
| |
| The ``devtool edit-recipe`` command lets you take a look at the recipe:: |
| |
| $ devtool edit-recipe cute-files |
| SUMMARY = "Turn any folder on your computer into a cute file browser, available on the local network." |
| LICENSE = "MIT & ISC & Unknown" |
| LIC_FILES_CHKSUM = "file://LICENSE;md5=71d98c0a1db42956787b1909c74a86ca \ |
| file://node_modules/toidentifier/LICENSE;md5=1a261071a044d02eb6f2bb47f51a3502 \ |
| file://node_modules/debug/LICENSE;md5=ddd815a475e7338b0be7a14d8ee35a99 \ |
| ... |
| SRC_URI = " \ |
| npm://registry.npmjs.org/;package=cute-files;version=${PV} \ |
| npmsw://${THISDIR}/${BPN}/npm-shrinkwrap.json \ |
| " |
| S = "${WORKDIR}/npm" |
| inherit npm |
| LICENSE:${PN} = "MIT" |
| LICENSE:${PN}-accepts = "MIT" |
| LICENSE:${PN}-array-flatten = "MIT" |
| ... |
| LICENSE:${PN}-vary = "MIT" |
| |
| Here are three key points in the previous example: |
| |
| - :term:`SRC_URI` uses the NPM |
| scheme so that the NPM fetcher is used. |
| |
| - ``recipetool`` collects all the license information. If a |
| sub-module's license is unavailable, the sub-module's name appears in |
| the comments. |
| |
| - The ``inherit npm`` statement causes the |
| :ref:`npm <ref-classes-npm>` class to package |
| up all the modules. |
| |
| You can run the following command to build the ``cute-files`` package:: |
| |
| $ devtool build cute-files |
| |
| Remember that ``nodejs`` must be installed on |
| the target before your package. |
| |
| Assuming 192.168.7.2 for the target's IP address, use the following |
| command to deploy your package:: |
| |
| $ devtool deploy-target -s cute-files root@192.168.7.2 |
| |
| Once the package is installed on the target, you can |
| test the application: |
| |
| .. note:: |
| |
| Because of a known issue, you cannot simply run ``cute-files`` as you would |
| if you had run ``npm install``. |
| |
| :: |
| |
| $ cd /usr/lib/node_modules/cute-files |
| $ node cute-files.js |
| |
| On a browser, |
| go to ``http://192.168.7.2:3000`` and you see the following: |
| |
| .. image:: figures/cute-files-npm-example.png |
| :align: center |
| |
| You can find the recipe in ``workspace/recipes/cute-files``. You can use |
| the recipe in any layer you choose. |
| |
| Using the NPM Projects Code Method |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| Although it is useful to package modules already in the NPM registry, |
| adding ``node.js`` projects under development is a more common developer |
| use case. |
| |
| This section covers the NPM projects code method, which is very similar |
| to the "registry" approach described in the previous section. In the NPM |
| projects method, you provide ``devtool`` with an URL that points to the |
| source files. |
| |
| Replicating the same example, (i.e. ``cute-files``) use the following |
| command:: |
| |
| $ devtool add https://github.com/martinaglv/cute-files.git |
| |
| The |
| recipe this command generates is very similar to the recipe created in |
| the previous section. However, the :term:`SRC_URI` looks like the following:: |
| |
| SRC_URI = " \ |
| git://github.com/martinaglv/cute-files.git;protocol=https \ |
| npmsw://${THISDIR}/${BPN}/npm-shrinkwrap.json \ |
| " |
| |
| In this example, |
| the main module is taken from the Git repository and dependencies are |
| taken from the NPM registry. Other than those differences, the recipe is |
| basically the same between the two methods. You can build and deploy the |
| package exactly as described in the previous section that uses the |
| registry modules method. |
| |
| Adding custom metadata to packages |
| ---------------------------------- |
| |
| The variable |
| :term:`PACKAGE_ADD_METADATA` |
| can be used to add additional metadata to packages. This is reflected in |
| the package control/spec file. To take the ipk format for example, the |
| CONTROL file stored inside would contain the additional metadata as |
| additional lines. |
| |
| The variable can be used in multiple ways, including using suffixes to |
| set it for a specific package type and/or package. Note that the order |
| of precedence is the same as this list: |
| |
| - ``PACKAGE_ADD_METADATA_<PKGTYPE>:<PN>`` |
| |
| - ``PACKAGE_ADD_METADATA_<PKGTYPE>`` |
| |
| - ``PACKAGE_ADD_METADATA:<PN>`` |
| |
| - :term:`PACKAGE_ADD_METADATA` |
| |
| `<PKGTYPE>` is a parameter and expected to be a distinct name of specific |
| package type: |
| |
| - IPK for .ipk packages |
| |
| - DEB for .deb packages |
| |
| - RPM for .rpm packages |
| |
| `<PN>` is a parameter and expected to be a package name. |
| |
| The variable can contain multiple [one-line] metadata fields separated |
| by the literal sequence '\\n'. The separator can be redefined using the |
| variable flag ``separator``. |
| |
| Here is an example that adds two custom fields for ipk |
| packages:: |
| |
| PACKAGE_ADD_METADATA_IPK = "Vendor: CustomIpk\nGroup:Applications/Spreadsheets" |
| |
| Efficiently Fetching Source Files During a Build |
| ================================================ |
| |
| The OpenEmbedded build system works with source files located through |
| the :term:`SRC_URI` variable. When |
| you build something using BitBake, a big part of the operation is |
| locating and downloading all the source tarballs. For images, |
| downloading all the source for various packages can take a significant |
| amount of time. |
| |
| This section shows you how you can use mirrors to speed up fetching |
| source files and how you can pre-fetch files all of which leads to more |
| efficient use of resources and time. |
| |
| Setting up Effective Mirrors |
| ---------------------------- |
| |
| A good deal that goes into a Yocto Project build is simply downloading |
| all of the source tarballs. Maybe you have been working with another |
| build system (OpenEmbedded or Angstrom) for which you have built up a |
| sizable directory of source tarballs. Or, perhaps someone else has such |
| a directory for which you have read access. If so, you can save time by |
| adding statements to your configuration file so that the build process |
| checks local directories first for existing tarballs before checking the |
| Internet. |
| |
| Here is an efficient way to set it up in your ``local.conf`` file:: |
| |
| SOURCE_MIRROR_URL ?= "file:///home/you/your-download-dir/" |
| INHERIT += "own-mirrors" |
| BB_GENERATE_MIRROR_TARBALLS = "1" |
| # BB_NO_NETWORK = "1" |
| |
| In the previous example, the |
| :term:`BB_GENERATE_MIRROR_TARBALLS` |
| variable causes the OpenEmbedded build system to generate tarballs of |
| the Git repositories and store them in the |
| :term:`DL_DIR` directory. Due to |
| performance reasons, generating and storing these tarballs is not the |
| build system's default behavior. |
| |
| You can also use the |
| :term:`PREMIRRORS` variable. For |
| an example, see the variable's glossary entry in the Yocto Project |
| Reference Manual. |
| |
| Getting Source Files and Suppressing the Build |
| ---------------------------------------------- |
| |
| Another technique you can use to ready yourself for a successive string |
| of build operations, is to pre-fetch all the source files without |
| actually starting a build. This technique lets you work through any |
| download issues and ultimately gathers all the source files into your |
| download directory :ref:`structure-build-downloads`, |
| which is located with :term:`DL_DIR`. |
| |
| Use the following BitBake command form to fetch all the necessary |
| sources without starting the build:: |
| |
| $ bitbake target --runall=fetch |
| |
| This |
| variation of the BitBake command guarantees that you have all the |
| sources for that BitBake target should you disconnect from the Internet |
| and want to do the build later offline. |
| |
| Selecting an Initialization Manager |
| =================================== |
| |
| By default, the Yocto Project uses SysVinit as the initialization |
| manager. However, there is also support for systemd, which is a full |
| replacement for init with parallel starting of services, reduced shell |
| overhead and other features that are used by many distributions. |
| |
| Within the system, SysVinit treats system components as services. These |
| services are maintained as shell scripts stored in the ``/etc/init.d/`` |
| directory. Services organize into different run levels. This |
| organization is maintained by putting links to the services in the |
| ``/etc/rcN.d/`` directories, where `N/` is one of the following options: |
| "S", "0", "1", "2", "3", "4", "5", or "6". |
| |
| .. note:: |
| |
| Each runlevel has a dependency on the previous runlevel. This |
| dependency allows the services to work properly. |
| |
| In comparison, systemd treats components as units. Using units is a |
| broader concept as compared to using a service. A unit includes several |
| different types of entities. Service is one of the types of entities. |
| The runlevel concept in SysVinit corresponds to the concept of a target |
| in systemd, where target is also a type of supported unit. |
| |
| In a SysVinit-based system, services load sequentially (i.e. one by one) |
| during init and parallelization is not supported. With systemd, services |
| start in parallel. Needless to say, the method can have an impact on |
| system startup performance. |
| |
| If you want to use SysVinit, you do not have to do anything. But, if you |
| want to use systemd, you must take some steps as described in the |
| following sections. |
| |
| Using systemd Exclusively |
| ------------------------- |
| |
| Set these variables in your distribution configuration file as follows:: |
| |
| DISTRO_FEATURES:append = " systemd" |
| VIRTUAL-RUNTIME_init_manager = "systemd" |
| |
| You can also prevent the SysVinit distribution feature from |
| being automatically enabled as follows:: |
| |
| DISTRO_FEATURES_BACKFILL_CONSIDERED = "sysvinit" |
| |
| Doing so removes any |
| redundant SysVinit scripts. |
| |
| To remove initscripts from your image altogether, set this variable |
| also:: |
| |
| VIRTUAL-RUNTIME_initscripts = "" |
| |
| For information on the backfill variable, see |
| :term:`DISTRO_FEATURES_BACKFILL_CONSIDERED`. |
| |
| Using systemd for the Main Image and Using SysVinit for the Rescue Image |
| ------------------------------------------------------------------------ |
| |
| Set these variables in your distribution configuration file as follows:: |
| |
| DISTRO_FEATURES:append = " systemd" |
| VIRTUAL-RUNTIME_init_manager = "systemd" |
| |
| Doing so causes your main image to use the |
| ``packagegroup-core-boot.bb`` recipe and systemd. The rescue/minimal |
| image cannot use this package group. However, it can install SysVinit |
| and the appropriate packages will have support for both systemd and |
| SysVinit. |
| |
| Selecting a Device Manager |
| ========================== |
| |
| The Yocto Project provides multiple ways to manage the device manager |
| (``/dev``): |
| |
| - Persistent and Pre-Populated ``/dev``: For this case, the ``/dev`` |
| directory is persistent and the required device nodes are created |
| during the build. |
| |
| - Use ``devtmpfs`` with a Device Manager: For this case, the ``/dev`` |
| directory is provided by the kernel as an in-memory file system and |
| is automatically populated by the kernel at runtime. Additional |
| configuration of device nodes is done in user space by a device |
| manager like ``udev`` or ``busybox-mdev``. |
| |
| Using Persistent and Pre-Populated ``/dev`` |
| -------------------------------------------- |
| |
| To use the static method for device population, you need to set the |
| :term:`USE_DEVFS` variable to "0" |
| as follows:: |
| |
| USE_DEVFS = "0" |
| |
| The content of the resulting ``/dev`` directory is defined in a Device |
| Table file. The |
| :term:`IMAGE_DEVICE_TABLES` |
| variable defines the Device Table to use and should be set in the |
| machine or distro configuration file. Alternatively, you can set this |
| variable in your ``local.conf`` configuration file. |
| |
| If you do not define the :term:`IMAGE_DEVICE_TABLES` variable, the default |
| ``device_table-minimal.txt`` is used:: |
| |
| IMAGE_DEVICE_TABLES = "device_table-mymachine.txt" |
| |
| The population is handled by the ``makedevs`` utility during image |
| creation: |
| |
| Using ``devtmpfs`` and a Device Manager |
| --------------------------------------- |
| |
| To use the dynamic method for device population, you need to use (or be |
| sure to set) the :term:`USE_DEVFS` |
| variable to "1", which is the default:: |
| |
| USE_DEVFS = "1" |
| |
| With this |
| setting, the resulting ``/dev`` directory is populated by the kernel |
| using ``devtmpfs``. Make sure the corresponding kernel configuration |
| variable ``CONFIG_DEVTMPFS`` is set when building you build a Linux |
| kernel. |
| |
| All devices created by ``devtmpfs`` will be owned by ``root`` and have |
| permissions ``0600``. |
| |
| To have more control over the device nodes, you can use a device manager |
| like ``udev`` or ``busybox-mdev``. You choose the device manager by |
| defining the ``VIRTUAL-RUNTIME_dev_manager`` variable in your machine or |
| distro configuration file. Alternatively, you can set this variable in |
| your ``local.conf`` configuration file:: |
| |
| VIRTUAL-RUNTIME_dev_manager = "udev" |
| |
| # Some alternative values |
| # VIRTUAL-RUNTIME_dev_manager = "busybox-mdev" |
| # VIRTUAL-RUNTIME_dev_manager = "systemd" |
| |
| Using an External SCM |
| ===================== |
| |
| If you're working on a recipe that pulls from an external Source Code |
| Manager (SCM), it is possible to have the OpenEmbedded build system |
| notice new recipe changes added to the SCM and then build the resulting |
| packages that depend on the new recipes by using the latest versions. |
| This only works for SCMs from which it is possible to get a sensible |
| revision number for changes. Currently, you can do this with Apache |
| Subversion (SVN), Git, and Bazaar (BZR) repositories. |
| |
| To enable this behavior, the :term:`PV` of |
| the recipe needs to reference |
| :term:`SRCPV`. Here is an example:: |
| |
| PV = "1.2.3+git${SRCPV}" |
| |
| Then, you can add the following to your |
| ``local.conf``:: |
| |
| SRCREV:pn-PN = "${AUTOREV}" |
| |
| :term:`PN` is the name of the recipe for |
| which you want to enable automatic source revision updating. |
| |
| If you do not want to update your local configuration file, you can add |
| the following directly to the recipe to finish enabling the feature:: |
| |
| SRCREV = "${AUTOREV}" |
| |
| The Yocto Project provides a distribution named ``poky-bleeding``, whose |
| configuration file contains the line:: |
| |
| require conf/distro/include/poky-floating-revisions.inc |
| |
| This line pulls in the |
| listed include file that contains numerous lines of exactly that form:: |
| |
| #SRCREV:pn-opkg-native ?= "${AUTOREV}" |
| #SRCREV:pn-opkg-sdk ?= "${AUTOREV}" |
| #SRCREV:pn-opkg ?= "${AUTOREV}" |
| #SRCREV:pn-opkg-utils-native ?= "${AUTOREV}" |
| #SRCREV:pn-opkg-utils ?= "${AUTOREV}" |
| SRCREV:pn-gconf-dbus ?= "${AUTOREV}" |
| SRCREV:pn-matchbox-common ?= "${AUTOREV}" |
| SRCREV:pn-matchbox-config-gtk ?= "${AUTOREV}" |
| SRCREV:pn-matchbox-desktop ?= "${AUTOREV}" |
| SRCREV:pn-matchbox-keyboard ?= "${AUTOREV}" |
| SRCREV:pn-matchbox-panel-2 ?= "${AUTOREV}" |
| SRCREV:pn-matchbox-themes-extra ?= "${AUTOREV}" |
| SRCREV:pn-matchbox-terminal ?= "${AUTOREV}" |
| SRCREV:pn-matchbox-wm ?= "${AUTOREV}" |
| SRCREV:pn-settings-daemon ?= "${AUTOREV}" |
| SRCREV:pn-screenshot ?= "${AUTOREV}" |
| . . . |
| |
| These lines allow you to |
| experiment with building a distribution that tracks the latest |
| development source for numerous packages. |
| |
| .. note:: |
| |
| The ``poky-bleeding`` distribution is not tested on a regular basis. Keep |
| this in mind if you use it. |
| |
| Creating a Read-Only Root Filesystem |
| ==================================== |
| |
| Suppose, for security reasons, you need to disable your target device's |
| root filesystem's write permissions (i.e. you need a read-only root |
| filesystem). Or, perhaps you are running the device's operating system |
| from a read-only storage device. For either case, you can customize your |
| image for that behavior. |
| |
| .. note:: |
| |
| Supporting a read-only root filesystem requires that the system and |
| applications do not try to write to the root filesystem. You must |
| configure all parts of the target system to write elsewhere, or to |
| gracefully fail in the event of attempting to write to the root |
| filesystem. |
| |
| Creating the Root Filesystem |
| ---------------------------- |
| |
| To create the read-only root filesystem, simply add the |
| "read-only-rootfs" feature to your image, normally in one of two ways. |
| The first way is to add the "read-only-rootfs" image feature in the |
| image's recipe file via the :term:`IMAGE_FEATURES` variable:: |
| |
| IMAGE_FEATURES += "read-only-rootfs" |
| |
| As an alternative, you can add the same feature |
| from within your build directory's ``local.conf`` file with the |
| associated :term:`EXTRA_IMAGE_FEATURES` variable, as in:: |
| |
| EXTRA_IMAGE_FEATURES = "read-only-rootfs" |
| |
| For more information on how to use these variables, see the |
| ":ref:`dev-manual/common-tasks:Customizing Images Using Custom \`\`IMAGE_FEATURES\`\` and \`\`EXTRA_IMAGE_FEATURES\`\``" |
| section. For information on the variables, see |
| :term:`IMAGE_FEATURES` and |
| :term:`EXTRA_IMAGE_FEATURES`. |
| |
| Post-Installation Scripts and Read-Only Root Filesystem |
| ------------------------------------------------------- |
| |
| It is very important that you make sure all post-Installation |
| (``pkg_postinst``) scripts for packages that are installed into the |
| image can be run at the time when the root filesystem is created during |
| the build on the host system. These scripts cannot attempt to run during |
| the first boot on the target device. With the "read-only-rootfs" feature |
| enabled, the build system makes sure that all post-installation scripts |
| succeed at file system creation time. If any of these scripts |
| still need to be run after the root filesystem is created, the build |
| immediately fails. These build-time checks ensure that the build fails |
| rather than the target device fails later during its initial boot |
| operation. |
| |
| Most of the common post-installation scripts generated by the build |
| system for the out-of-the-box Yocto Project are engineered so that they |
| can run during root filesystem creation (e.g. post-installation scripts |
| for caching fonts). However, if you create and add custom scripts, you |
| need to be sure they can be run during this file system creation. |
| |
| Here are some common problems that prevent post-installation scripts |
| from running during root filesystem creation: |
| |
| - *Not using $D in front of absolute paths:* The build system defines |
| ``$``\ :term:`D` when the root |
| filesystem is created. Furthermore, ``$D`` is blank when the script |
| is run on the target device. This implies two purposes for ``$D``: |
| ensuring paths are valid in both the host and target environments, |
| and checking to determine which environment is being used as a method |
| for taking appropriate actions. |
| |
| - *Attempting to run processes that are specific to or dependent on the |
| target architecture:* You can work around these attempts by using |
| native tools, which run on the host system, to accomplish the same |
| tasks, or by alternatively running the processes under QEMU, which |
| has the ``qemu_run_binary`` function. For more information, see the |
| :ref:`qemu <ref-classes-qemu>` class. |
| |
| Areas With Write Access |
| ----------------------- |
| |
| With the "read-only-rootfs" feature enabled, any attempt by the target |
| to write to the root filesystem at runtime fails. Consequently, you must |
| make sure that you configure processes and applications that attempt |
| these types of writes do so to directories with write access (e.g. |
| ``/tmp`` or ``/var/run``). |
| |
| Maintaining Build Output Quality |
| ================================ |
| |
| Many factors can influence the quality of a build. For example, if you |
| upgrade a recipe to use a new version of an upstream software package or |
| you experiment with some new configuration options, subtle changes can |
| occur that you might not detect until later. Consider the case where |
| your recipe is using a newer version of an upstream package. In this |
| case, a new version of a piece of software might introduce an optional |
| dependency on another library, which is auto-detected. If that library |
| has already been built when the software is building, the software will |
| link to the built library and that library will be pulled into your |
| image along with the new software even if you did not want the library. |
| |
| The :ref:`buildhistory <ref-classes-buildhistory>` |
| class helps you maintain the quality of your build output. You |
| can use the class to highlight unexpected and possibly unwanted changes |
| in the build output. When you enable build history, it records |
| information about the contents of each package and image and then |
| commits that information to a local Git repository where you can examine |
| the information. |
| |
| The remainder of this section describes the following: |
| |
| - :ref:`How you can enable and disable build history <dev-manual/common-tasks:enabling and disabling build history>` |
| |
| - :ref:`How to understand what the build history contains <dev-manual/common-tasks:understanding what the build history contains>` |
| |
| - :ref:`How to limit the information used for build history <dev-manual/common-tasks:using build history to gather image information only>` |
| |
| - :ref:`How to examine the build history from both a command-line and web interface <dev-manual/common-tasks:examining build history information>` |
| |
| Enabling and Disabling Build History |
| ------------------------------------ |
| |
| Build history is disabled by default. To enable it, add the following |
| :term:`INHERIT` statement and set the |
| :term:`BUILDHISTORY_COMMIT` |
| variable to "1" at the end of your ``conf/local.conf`` file found in the |
| :term:`Build Directory`:: |
| |
| INHERIT += "buildhistory" |
| BUILDHISTORY_COMMIT = "1" |
| |
| Enabling build history as |
| previously described causes the OpenEmbedded build system to collect |
| build output information and commit it as a single commit to a local |
| :ref:`overview-manual/development-environment:git` repository. |
| |
| .. note:: |
| |
| Enabling build history increases your build times slightly, |
| particularly for images, and increases the amount of disk space used |
| during the build. |
| |
| You can disable build history by removing the previous statements from |
| your ``conf/local.conf`` file. |
| |
| Understanding What the Build History Contains |
| --------------------------------------------- |
| |
| Build history information is kept in |
| ``${``\ :term:`TOPDIR`\ ``}/buildhistory`` |
| in the Build Directory as defined by the |
| :term:`BUILDHISTORY_DIR` |
| variable. Here is an example abbreviated listing: |
| |
| .. image:: figures/buildhistory.png |
| :align: center |
| |
| At the top level, there is a ``metadata-revs`` file that lists the |
| revisions of the repositories for the enabled layers when the build was |
| produced. The rest of the data splits into separate ``packages``, |
| ``images`` and ``sdk`` directories, the contents of which are described |
| as follows. |
| |
| Build History Package Information |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| The history for each package contains a text file that has name-value |
| pairs with information about the package. For example, |
| ``buildhistory/packages/i586-poky-linux/busybox/busybox/latest`` |
| contains the following: |
| |
| .. code-block:: none |
| |
| PV = 1.22.1 |
| PR = r32 |
| RPROVIDES = |
| RDEPENDS = glibc (>= 2.20) update-alternatives-opkg |
| RRECOMMENDS = busybox-syslog busybox-udhcpc update-rc.d |
| PKGSIZE = 540168 |
| FILES = /usr/bin/* /usr/sbin/* /usr/lib/busybox/* /usr/lib/lib*.so.* \ |
| /etc /com /var /bin/* /sbin/* /lib/*.so.* /lib/udev/rules.d \ |
| /usr/lib/udev/rules.d /usr/share/busybox /usr/lib/busybox/* \ |
| /usr/share/pixmaps /usr/share/applications /usr/share/idl \ |
| /usr/share/omf /usr/share/sounds /usr/lib/bonobo/servers |
| FILELIST = /bin/busybox /bin/busybox.nosuid /bin/busybox.suid /bin/sh \ |
| /etc/busybox.links.nosuid /etc/busybox.links.suid |
| |
| Most of these |
| name-value pairs correspond to variables used to produce the package. |
| The exceptions are ``FILELIST``, which is the actual list of files in |
| the package, and ``PKGSIZE``, which is the total size of files in the |
| package in bytes. |
| |
| There is also a file that corresponds to the recipe from which the package |
| came (e.g. ``buildhistory/packages/i586-poky-linux/busybox/latest``): |
| |
| .. code-block:: none |
| |
| PV = 1.22.1 |
| PR = r32 |
| DEPENDS = initscripts kern-tools-native update-rc.d-native \ |
| virtual/i586-poky-linux-compilerlibs virtual/i586-poky-linux-gcc \ |
| virtual/libc virtual/update-alternatives |
| PACKAGES = busybox-ptest busybox-httpd busybox-udhcpd busybox-udhcpc \ |
| busybox-syslog busybox-mdev busybox-hwclock busybox-dbg \ |
| busybox-staticdev busybox-dev busybox-doc busybox-locale busybox |
| |
| Finally, for those recipes fetched from a version control system (e.g., |
| Git), there is a file that lists source revisions that are specified in |
| the recipe and the actual revisions used during the build. Listed |
| and actual revisions might differ when |
| :term:`SRCREV` is set to |
| ${:term:`AUTOREV`}. Here is an |
| example assuming |
| ``buildhistory/packages/qemux86-poky-linux/linux-yocto/latest_srcrev``):: |
| |
| # SRCREV_machine = "38cd560d5022ed2dbd1ab0dca9642e47c98a0aa1" |
| SRCREV_machine = "38cd560d5022ed2dbd1ab0dca9642e47c98a0aa1" |
| # SRCREV_meta = "a227f20eff056e511d504b2e490f3774ab260d6f" |
| SRCREV_meta ="a227f20eff056e511d504b2e490f3774ab260d6f" |
| |
| You can use the |
| ``buildhistory-collect-srcrevs`` command with the ``-a`` option to |
| collect the stored :term:`SRCREV` values from build history and report them |
| in a format suitable for use in global configuration (e.g., |
| ``local.conf`` or a distro include file) to override floating |
| :term:`AUTOREV` values to a fixed set of revisions. Here is some example |
| output from this command:: |
| |
| $ buildhistory-collect-srcrevs -a |
| # i586-poky-linux |
| SRCREV:pn-glibc = "b8079dd0d360648e4e8de48656c5c38972621072" |
| SRCREV:pn-glibc-initial = "b8079dd0d360648e4e8de48656c5c38972621072" |
| SRCREV:pn-opkg-utils = "53274f087565fd45d8452c5367997ba6a682a37a" |
| SRCREV:pn-kmod = "fd56638aed3fe147015bfa10ed4a5f7491303cb4" |
| # x86_64-linux |
| SRCREV:pn-gtk-doc-stub-native = "1dea266593edb766d6d898c79451ef193eb17cfa" |
| SRCREV:pn-dtc-native = "65cc4d2748a2c2e6f27f1cf39e07a5dbabd80ebf" |
| SRCREV:pn-update-rc.d-native = "eca680ddf28d024954895f59a241a622dd575c11" |
| SRCREV_glibc:pn-cross-localedef-native = "b8079dd0d360648e4e8de48656c5c38972621072" |
| SRCREV_localedef:pn-cross-localedef-native = "c833367348d39dad7ba018990bfdaffaec8e9ed3" |
| SRCREV:pn-prelink-native = "faa069deec99bf61418d0bab831c83d7c1b797ca" |
| SRCREV:pn-opkg-utils-native = "53274f087565fd45d8452c5367997ba6a682a37a" |
| SRCREV:pn-kern-tools-native = "23345b8846fe4bd167efdf1bd8a1224b2ba9a5ff" |
| SRCREV:pn-kmod-native = "fd56638aed3fe147015bfa10ed4a5f7491303cb4" |
| # qemux86-poky-linux |
| SRCREV_machine:pn-linux-yocto = "38cd560d5022ed2dbd1ab0dca9642e47c98a0aa1" |
| SRCREV_meta:pn-linux-yocto = "a227f20eff056e511d504b2e490f3774ab260d6f" |
| # all-poky-linux |
| SRCREV:pn-update-rc.d = "eca680ddf28d024954895f59a241a622dd575c11" |
| |
| .. note:: |
| |
| Here are some notes on using the ``buildhistory-collect-srcrevs`` command: |
| |
| - By default, only values where the :term:`SRCREV` was not hardcoded |
| (usually when :term:`AUTOREV` is used) are reported. Use the ``-a`` |
| option to see all :term:`SRCREV` values. |
| |
| - The output statements might not have any effect if overrides are |
| applied elsewhere in the build system configuration. Use the |
| ``-f`` option to add the ``forcevariable`` override to each output |
| line if you need to work around this restriction. |
| |
| - The script does apply special handling when building for multiple |
| machines. However, the script does place a comment before each set |
| of values that specifies which triplet to which they belong as |
| previously shown (e.g., ``i586-poky-linux``). |
| |
| Build History Image Information |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| The files produced for each image are as follows: |
| |
| - ``image-files:`` A directory containing selected files from the root |
| filesystem. The files are defined by |
| :term:`BUILDHISTORY_IMAGE_FILES`. |
| |
| - ``build-id.txt:`` Human-readable information about the build |
| configuration and metadata source revisions. This file contains the |
| full build header as printed by BitBake. |
| |
| - ``*.dot:`` Dependency graphs for the image that are compatible with |
| ``graphviz``. |
| |
| - ``files-in-image.txt:`` A list of files in the image with |
| permissions, owner, group, size, and symlink information. |
| |
| - ``image-info.txt:`` A text file containing name-value pairs with |
| information about the image. See the following listing example for |
| more information. |
| |
| - ``installed-package-names.txt:`` A list of installed packages by name |
| only. |
| |
| - ``installed-package-sizes.txt:`` A list of installed packages ordered |
| by size. |
| |
| - ``installed-packages.txt:`` A list of installed packages with full |
| package filenames. |
| |
| .. note:: |
| |
| Installed package information is able to be gathered and produced |
| even if package management is disabled for the final image. |
| |
| Here is an example of ``image-info.txt``: |
| |
| .. code-block:: none |
| |
| DISTRO = poky |
| DISTRO_VERSION = 1.7 |
| USER_CLASSES = buildstats image-prelink |
| IMAGE_CLASSES = image_types |
| IMAGE_FEATURES = debug-tweaks |
| IMAGE_LINGUAS = |
| IMAGE_INSTALL = packagegroup-core-boot run-postinsts |
| BAD_RECOMMENDATIONS = |
| NO_RECOMMENDATIONS = |
| PACKAGE_EXCLUDE = |
| ROOTFS_POSTPROCESS_COMMAND = write_package_manifest; license_create_manifest; \ |
| write_image_manifest ; buildhistory_list_installed_image ; \ |
| buildhistory_get_image_installed ; ssh_allow_empty_password; \ |
| postinst_enable_logging; rootfs_update_timestamp ; ssh_disable_dns_lookup ; |
| IMAGE_POSTPROCESS_COMMAND = buildhistory_get_imageinfo ; |
| IMAGESIZE = 6900 |
| |
| Other than ``IMAGESIZE``, |
| which is the total size of the files in the image in Kbytes, the |
| name-value pairs are variables that may have influenced the content of |
| the image. This information is often useful when you are trying to |
| determine why a change in the package or file listings has occurred. |
| |
| Using Build History to Gather Image Information Only |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| As you can see, build history produces image information, including |
| dependency graphs, so you can see why something was pulled into the |
| image. If you are just interested in this information and not interested |
| in collecting specific package or SDK information, you can enable |
| writing only image information without any history by adding the |
| following to your ``conf/local.conf`` file found in the |
| :term:`Build Directory`:: |
| |
| INHERIT += "buildhistory" |
| BUILDHISTORY_COMMIT = "0" |
| BUILDHISTORY_FEATURES = "image" |
| |
| Here, you set the |
| :term:`BUILDHISTORY_FEATURES` |
| variable to use the image feature only. |
| |
| Build History SDK Information |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| Build history collects similar information on the contents of SDKs (e.g. |
| ``bitbake -c populate_sdk imagename``) as compared to information it |
| collects for images. Furthermore, this information differs depending on |
| whether an extensible or standard SDK is being produced. |
| |
| The following list shows the files produced for SDKs: |
| |
| - ``files-in-sdk.txt:`` A list of files in the SDK with permissions, |
| owner, group, size, and symlink information. This list includes both |
| the host and target parts of the SDK. |
| |
| - ``sdk-info.txt:`` A text file containing name-value pairs with |
| information about the SDK. See the following listing example for more |
| information. |
| |
| - ``sstate-task-sizes.txt:`` A text file containing name-value pairs |
| with information about task group sizes (e.g. ``do_populate_sysroot`` |
| tasks have a total size). The ``sstate-task-sizes.txt`` file exists |
| only when an extensible SDK is created. |
| |
| - ``sstate-package-sizes.txt:`` A text file containing name-value pairs |
| with information for the shared-state packages and sizes in the SDK. |
| The ``sstate-package-sizes.txt`` file exists only when an extensible |
| SDK is created. |
| |
| - ``sdk-files:`` A folder that contains copies of the files mentioned |
| in ``BUILDHISTORY_SDK_FILES`` if the files are present in the output. |
| Additionally, the default value of ``BUILDHISTORY_SDK_FILES`` is |
| specific to the extensible SDK although you can set it differently if |
| you would like to pull in specific files from the standard SDK. |
| |
| The default files are ``conf/local.conf``, ``conf/bblayers.conf``, |
| ``conf/auto.conf``, ``conf/locked-sigs.inc``, and |
| ``conf/devtool.conf``. Thus, for an extensible SDK, these files get |
| copied into the ``sdk-files`` directory. |
| |
| - The following information appears under each of the ``host`` and |
| ``target`` directories for the portions of the SDK that run on the |
| host and on the target, respectively: |
| |
| .. note:: |
| |
| The following files for the most part are empty when producing an |
| extensible SDK because this type of SDK is not constructed from |
| packages as is the standard SDK. |
| |
| - ``depends.dot:`` Dependency graph for the SDK that is compatible |
| with ``graphviz``. |
| |
| - ``installed-package-names.txt:`` A list of installed packages by |
| name only. |
| |
| - ``installed-package-sizes.txt:`` A list of installed packages |
| ordered by size. |
| |
| - ``installed-packages.txt:`` A list of installed packages with full |
| package filenames. |
| |
| Here is an example of ``sdk-info.txt``: |
| |
| .. code-block:: none |
| |
| DISTRO = poky |
| DISTRO_VERSION = 1.3+snapshot-20130327 |
| SDK_NAME = poky-glibc-i686-arm |
| SDK_VERSION = 1.3+snapshot |
| SDKMACHINE = |
| SDKIMAGE_FEATURES = dev-pkgs dbg-pkgs |
| BAD_RECOMMENDATIONS = |
| SDKSIZE = 352712 |
| |
| Other than ``SDKSIZE``, which is |
| the total size of the files in the SDK in Kbytes, the name-value pairs |
| are variables that might have influenced the content of the SDK. This |
| information is often useful when you are trying to determine why a |
| change in the package or file listings has occurred. |
| |
| Examining Build History Information |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| You can examine build history output from the command line or from a web |
| interface. |
| |
| To see any changes that have occurred (assuming you have |
| :term:`BUILDHISTORY_COMMIT` = "1"), |
| you can simply use any Git command that allows you to view the history |
| of a repository. Here is one method:: |
| |
| $ git log -p |
| |
| You need to realize, |
| however, that this method does show changes that are not significant |
| (e.g. a package's size changing by a few bytes). |
| |
| There is a command-line tool called ``buildhistory-diff``, though, |
| that queries the Git repository and prints just the differences that |
| might be significant in human-readable form. Here is an example:: |
| |
| $ poky/poky/scripts/buildhistory-diff . HEAD^ |
| Changes to images/qemux86_64/glibc/core-image-minimal (files-in-image.txt): |
| /etc/anotherpkg.conf was added |
| /sbin/anotherpkg was added |
| * (installed-package-names.txt): |
| * anotherpkg was added |
| Changes to images/qemux86_64/glibc/core-image-minimal (installed-package-names.txt): |
| anotherpkg was added |
| packages/qemux86_64-poky-linux/v86d: PACKAGES: added "v86d-extras" |
| * PR changed from "r0" to "r1" |
| * PV changed from "0.1.10" to "0.1.12" |
| packages/qemux86_64-poky-linux/v86d/v86d: PKGSIZE changed from 110579 to 144381 (+30%) |
| * PR changed from "r0" to "r1" |
| * PV changed from "0.1.10" to "0.1.12" |
| |
| .. note:: |
| |
| The ``buildhistory-diff`` tool requires the ``GitPython`` |
| package. Be sure to install it using Pip3 as follows:: |
| |
| $ pip3 install GitPython --user |
| |
| |
| Alternatively, you can install ``python3-git`` using the appropriate |
| distribution package manager (e.g. ``apt``, ``dnf``, or ``zipper``). |
| |
| To see changes to the build history using a web interface, follow the |
| instruction in the ``README`` file |
| :yocto_git:`here </buildhistory-web/>`. |
| |
| Here is a sample screenshot of the interface: |
| |
| .. image:: figures/buildhistory-web.png |
| :align: center |
| |
| Performing Automated Runtime Testing |
| ==================================== |
| |
| The OpenEmbedded build system makes available a series of automated |
| tests for images to verify runtime functionality. You can run these |
| tests on either QEMU or actual target hardware. Tests are written in |
| Python making use of the ``unittest`` module, and the majority of them |
| run commands on the target system over SSH. This section describes how |
| you set up the environment to use these tests, run available tests, and |
| write and add your own tests. |
| |
| For information on the test and QA infrastructure available within the |
| Yocto Project, see the ":ref:`ref-manual/release-process:testing and quality assurance`" |
| section in the Yocto Project Reference Manual. |
| |
| Enabling Tests |
| -------------- |
| |
| Depending on whether you are planning to run tests using QEMU or on the |
| hardware, you have to take different steps to enable the tests. See the |
| following subsections for information on how to enable both types of |
| tests. |
| |
| Enabling Runtime Tests on QEMU |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| In order to run tests, you need to do the following: |
| |
| - *Set up to avoid interaction with sudo for networking:* To |
| accomplish this, you must do one of the following: |
| |
| - Add ``NOPASSWD`` for your user in ``/etc/sudoers`` either for all |
| commands or just for ``runqemu-ifup``. You must provide the full |
| path as that can change if you are using multiple clones of the |
| source repository. |
| |
| .. note:: |
| |
| On some distributions, you also need to comment out "Defaults |
| requiretty" in ``/etc/sudoers``. |
| |
| - Manually configure a tap interface for your system. |
| |
| - Run as root the script in ``scripts/runqemu-gen-tapdevs``, which |
| should generate a list of tap devices. This is the option |
| typically chosen for Autobuilder-type environments. |
| |
| .. note:: |
| |
| - Be sure to use an absolute path when calling this script |
| with sudo. |
| |
| - The package recipe ``qemu-helper-native`` is required to run |
| this script. Build the package using the following command:: |
| |
| $ bitbake qemu-helper-native |
| |
| - *Set the DISPLAY variable:* You need to set this variable so that |
| you have an X server available (e.g. start ``vncserver`` for a |
| headless machine). |
| |
| - *Be sure your host's firewall accepts incoming connections from |
| 192.168.7.0/24:* Some of the tests (in particular DNF tests) start an |
| HTTP server on a random high number port, which is used to serve |
| files to the target. The DNF module serves |
| ``${WORKDIR}/oe-rootfs-repo`` so it can run DNF channel commands. |
| That means your host's firewall must accept incoming connections from |
| 192.168.7.0/24, which is the default IP range used for tap devices by |
| ``runqemu``. |
| |
| - *Be sure your host has the correct packages installed:* Depending |
| your host's distribution, you need to have the following packages |
| installed: |
| |
| - Ubuntu and Debian: ``sysstat`` and ``iproute2`` |
| |
| - openSUSE: ``sysstat`` and ``iproute2`` |
| |
| - Fedora: ``sysstat`` and ``iproute`` |
| |
| - CentOS: ``sysstat`` and ``iproute`` |
| |
| Once you start running the tests, the following happens: |
| |
| 1. A copy of the root filesystem is written to ``${WORKDIR}/testimage``. |
| |
| 2. The image is booted under QEMU using the standard ``runqemu`` script. |
| |
| 3. A default timeout of 500 seconds occurs to allow for the boot process |
| to reach the login prompt. You can change the timeout period by |
| setting |
| :term:`TEST_QEMUBOOT_TIMEOUT` |
| in the ``local.conf`` file. |
| |
| 4. Once the boot process is reached and the login prompt appears, the |
| tests run. The full boot log is written to |
| ``${WORKDIR}/testimage/qemu_boot_log``. |
| |
| 5. Each test module loads in the order found in :term:`TEST_SUITES`. You can |
| find the full output of the commands run over SSH in |
| ``${WORKDIR}/testimgage/ssh_target_log``. |
| |
| 6. If no failures occur, the task running the tests ends successfully. |
| You can find the output from the ``unittest`` in the task log at |
| ``${WORKDIR}/temp/log.do_testimage``. |
| |
| Enabling Runtime Tests on Hardware |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| The OpenEmbedded build system can run tests on real hardware, and for |
| certain devices it can also deploy the image to be tested onto the |
| device beforehand. |
| |
| For automated deployment, a "controller image" is installed onto the |
| hardware once as part of setup. Then, each time tests are to be run, the |
| following occurs: |
| |
| 1. The controller image is booted into and used to write the image to be |
| tested to a second partition. |
| |
| 2. The device is then rebooted using an external script that you need to |
| provide. |
| |
| 3. The device boots into the image to be tested. |
| |
| When running tests (independent of whether the image has been deployed |
| automatically or not), the device is expected to be connected to a |
| network on a pre-determined IP address. You can either use static IP |
| addresses written into the image, or set the image to use DHCP and have |
| your DHCP server on the test network assign a known IP address based on |
| the MAC address of the device. |
| |
| In order to run tests on hardware, you need to set :term:`TEST_TARGET` to an |
| appropriate value. For QEMU, you do not have to change anything, the |
| default value is "qemu". For running tests on hardware, the following |
| options are available: |
| |
| - *"simpleremote":* Choose "simpleremote" if you are going to run tests |
| on a target system that is already running the image to be tested and |
| is available on the network. You can use "simpleremote" in |
| conjunction with either real hardware or an image running within a |
| separately started QEMU or any other virtual machine manager. |
| |
| - *"SystemdbootTarget":* Choose "SystemdbootTarget" if your hardware is |
| an EFI-based machine with ``systemd-boot`` as bootloader and |
| ``core-image-testmaster`` (or something similar) is installed. Also, |
| your hardware under test must be in a DHCP-enabled network that gives |
| it the same IP address for each reboot. |
| |
| If you choose "SystemdbootTarget", there are additional requirements |
| and considerations. See the |
| ":ref:`dev-manual/common-tasks:selecting systemdboottarget`" section, which |
| follows, for more information. |
| |
| - *"BeagleBoneTarget":* Choose "BeagleBoneTarget" if you are deploying |
| images and running tests on the BeagleBone "Black" or original |
| "White" hardware. For information on how to use these tests, see the |
| comments at the top of the BeagleBoneTarget |
| ``meta-yocto-bsp/lib/oeqa/controllers/beaglebonetarget.py`` file. |
| |
| - *"EdgeRouterTarget":* Choose "EdgeRouterTarget" if you are deploying |
| images and running tests on the Ubiquiti Networks EdgeRouter Lite. |
| For information on how to use these tests, see the comments at the |
| top of the EdgeRouterTarget |
| ``meta-yocto-bsp/lib/oeqa/controllers/edgeroutertarget.py`` file. |
| |
| - *"GrubTarget":* Choose "GrubTarget" if you are deploying images and running |
| tests on any generic PC that boots using GRUB. For information on how |
| to use these tests, see the comments at the top of the GrubTarget |
| ``meta-yocto-bsp/lib/oeqa/controllers/grubtarget.py`` file. |
| |
| - *"your-target":* Create your own custom target if you want to run |
| tests when you are deploying images and running tests on a custom |
| machine within your BSP layer. To do this, you need to add a Python |
| unit that defines the target class under ``lib/oeqa/controllers/`` |
| within your layer. You must also provide an empty ``__init__.py``. |
| For examples, see files in ``meta-yocto-bsp/lib/oeqa/controllers/``. |
| |
| Selecting SystemdbootTarget |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| If you did not set :term:`TEST_TARGET` to "SystemdbootTarget", then you do |
| not need any information in this section. You can skip down to the |
| ":ref:`dev-manual/common-tasks:running tests`" section. |
| |
| If you did set :term:`TEST_TARGET` to "SystemdbootTarget", you also need to |
| perform a one-time setup of your controller image by doing the following: |
| |
| 1. *Set EFI_PROVIDER:* Be sure that :term:`EFI_PROVIDER` is as follows:: |
| |
| EFI_PROVIDER = "systemd-boot" |
| |
| 2. *Build the controller image:* Build the ``core-image-testmaster`` image. |
| The ``core-image-testmaster`` recipe is provided as an example for a |
| "controller" image and you can customize the image recipe as you would |
| any other recipe. |
| |
| Here are the image recipe requirements: |
| |
| - Inherits ``core-image`` so that kernel modules are installed. |
| |
| - Installs normal linux utilities not BusyBox ones (e.g. ``bash``, |
| ``coreutils``, ``tar``, ``gzip``, and ``kmod``). |
| |
| - Uses a custom Initial RAM Disk (initramfs) image with a custom |
| installer. A normal image that you can install usually creates a |
| single root filesystem partition. This image uses another installer that |
| creates a specific partition layout. Not all Board Support |
| Packages (BSPs) can use an installer. For such cases, you need to |
| manually create the following partition layout on the target: |
| |
| - First partition mounted under ``/boot``, labeled "boot". |
| |
| - The main root filesystem partition where this image gets installed, |
| which is mounted under ``/``. |
| |
| - Another partition labeled "testrootfs" where test images get |
| deployed. |
| |
| 3. *Install image:* Install the image that you just built on the target |
| system. |
| |
| The final thing you need to do when setting :term:`TEST_TARGET` to |
| "SystemdbootTarget" is to set up the test image: |
| |
| 1. *Set up your local.conf file:* Make sure you have the following |
| statements in your ``local.conf`` file:: |
| |
| IMAGE_FSTYPES += "tar.gz" |
| INHERIT += "testimage" |
| TEST_TARGET = "SystemdbootTarget" |
| TEST_TARGET_IP = "192.168.2.3" |
| |
| 2. *Build your test image:* Use BitBake to build the image:: |
| |
| $ bitbake core-image-sato |
| |
| Power Control |
| ~~~~~~~~~~~~~ |
| |
| For most hardware targets other than "simpleremote", you can control |
| power: |
| |
| - You can use :term:`TEST_POWERCONTROL_CMD` together with |
| :term:`TEST_POWERCONTROL_EXTRA_ARGS` as a command that runs on the host |
| and does power cycling. The test code passes one argument to that |
| command: off, on or cycle (off then on). Here is an example that |
| could appear in your ``local.conf`` file:: |
| |
| TEST_POWERCONTROL_CMD = "powercontrol.exp test 10.11.12.1 nuc1" |
| |
| In this example, the expect |
| script does the following: |
| |
| .. code-block:: shell |
| |
| ssh test@10.11.12.1 "pyctl nuc1 arg" |
| |
| It then runs a Python script that controls power for a label called |
| ``nuc1``. |
| |
| .. note:: |
| |
| You need to customize :term:`TEST_POWERCONTROL_CMD` and |
| :term:`TEST_POWERCONTROL_EXTRA_ARGS` for your own setup. The one requirement |
| is that it accepts "on", "off", and "cycle" as the last argument. |
| |
| - When no command is defined, it connects to the device over SSH and |
| uses the classic reboot command to reboot the device. Classic reboot |
| is fine as long as the machine actually reboots (i.e. the SSH test |
| has not failed). It is useful for scenarios where you have a simple |
| setup, typically with a single board, and where some manual |
| interaction is okay from time to time. |
| |
| If you have no hardware to automatically perform power control but still |
| wish to experiment with automated hardware testing, you can use the |
| ``dialog-power-control`` script that shows a dialog prompting you to perform |
| the required power action. This script requires either KDialog or Zenity |
| to be installed. To use this script, set the |
| :term:`TEST_POWERCONTROL_CMD` |
| variable as follows:: |
| |
| TEST_POWERCONTROL_CMD = "${COREBASE}/scripts/contrib/dialog-power-control" |
| |
| Serial Console Connection |
| ~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| For test target classes requiring a serial console to interact with the |
| bootloader (e.g. BeagleBoneTarget, EdgeRouterTarget, and GrubTarget), |
| you need to specify a command to use to connect to the serial console of |
| the target machine by using the |
| :term:`TEST_SERIALCONTROL_CMD` |
| variable and optionally the |
| :term:`TEST_SERIALCONTROL_EXTRA_ARGS` |
| variable. |
| |
| These cases could be a serial terminal program if the machine is |
| connected to a local serial port, or a ``telnet`` or ``ssh`` command |
| connecting to a remote console server. Regardless of the case, the |
| command simply needs to connect to the serial console and forward that |
| connection to standard input and output as any normal terminal program |
| does. For example, to use the picocom terminal program on serial device |
| ``/dev/ttyUSB0`` at 115200bps, you would set the variable as follows:: |
| |
| TEST_SERIALCONTROL_CMD = "picocom /dev/ttyUSB0 -b 115200" |
| |
| For local |
| devices where the serial port device disappears when the device reboots, |
| an additional "serdevtry" wrapper script is provided. To use this |
| wrapper, simply prefix the terminal command with |
| ``${COREBASE}/scripts/contrib/serdevtry``:: |
| |
| TEST_SERIALCONTROL_CMD = "${COREBASE}/scripts/contrib/serdevtry picocom -b 115200 /dev/ttyUSB0" |
| |
| Running Tests |
| ------------- |
| |
| You can start the tests automatically or manually: |
| |
| - *Automatically running tests:* To run the tests automatically after |
| the OpenEmbedded build system successfully creates an image, first |
| set the |
| :term:`TESTIMAGE_AUTO` |
| variable to "1" in your ``local.conf`` file in the |
| :term:`Build Directory`:: |
| |
| TESTIMAGE_AUTO = "1" |
| |
| Next, build your image. If the image successfully builds, the |
| tests run:: |
| |
| bitbake core-image-sato |
| |
| - *Manually running tests:* To manually run the tests, first globally |
| inherit the |
| :ref:`testimage <ref-classes-testimage*>` class |
| by editing your ``local.conf`` file:: |
| |
| INHERIT += "testimage" |
| |
| Next, use BitBake to run the tests:: |
| |
| bitbake -c testimage image |
| |
| All test files reside in ``meta/lib/oeqa/runtime`` in the |
| :term:`Source Directory`. A test name maps |
| directly to a Python module. Each test module may contain a number of |
| individual tests. Tests are usually grouped together by the area tested |
| (e.g tests for systemd reside in ``meta/lib/oeqa/runtime/systemd.py``). |
| |
| You can add tests to any layer provided you place them in the proper |
| area and you extend :term:`BBPATH` in |
| the ``local.conf`` file as normal. Be sure that tests reside in |
| ``layer/lib/oeqa/runtime``. |
| |
| .. note:: |
| |
| Be sure that module names do not collide with module names used in |
| the default set of test modules in ``meta/lib/oeqa/runtime``. |
| |
| You can change the set of tests run by appending or overriding |
| :term:`TEST_SUITES` variable in |
| ``local.conf``. Each name in :term:`TEST_SUITES` represents a required test |
| for the image. Test modules named within :term:`TEST_SUITES` cannot be |
| skipped even if a test is not suitable for an image (e.g. running the |
| RPM tests on an image without ``rpm``). Appending "auto" to |
| :term:`TEST_SUITES` causes the build system to try to run all tests that are |
| suitable for the image (i.e. each test module may elect to skip itself). |
| |
| The order you list tests in :term:`TEST_SUITES` is important and influences |
| test dependencies. Consequently, tests that depend on other tests should |
| be added after the test on which they depend. For example, since the |
| ``ssh`` test depends on the ``ping`` test, "ssh" needs to come after |
| "ping" in the list. The test class provides no re-ordering or dependency |
| handling. |
| |
| .. note:: |
| |
| Each module can have multiple classes with multiple test methods. |
| And, Python ``unittest`` rules apply. |
| |
| Here are some things to keep in mind when running tests: |
| |
| - The default tests for the image are defined as:: |
| |
| DEFAULT_TEST_SUITES:pn-image = "ping ssh df connman syslog xorg scp vnc date rpm dnf dmesg" |
| |
| - Add your own test to the list of the by using the following:: |
| |
| TEST_SUITES:append = " mytest" |
| |
| - Run a specific list of tests as follows:: |
| |
| TEST_SUITES = "test1 test2 test3" |
| |
| Remember, order is important. Be sure to place a test that is |
| dependent on another test later in the order. |
| |
| Exporting Tests |
| --------------- |
| |
| You can export tests so that they can run independently of the build |
| system. Exporting tests is required if you want to be able to hand the |
| test execution off to a scheduler. You can only export tests that are |
| defined in :term:`TEST_SUITES`. |
| |
| If your image is already built, make sure the following are set in your |
| ``local.conf`` file:: |
| |
| INHERIT += "testexport" |
| TEST_TARGET_IP = "IP-address-for-the-test-target" |
| TEST_SERVER_IP = "IP-address-for-the-test-server" |
| |
| You can then export the tests with the |
| following BitBake command form:: |
| |
| $ bitbake image -c testexport |
| |
| Exporting the tests places them in the |
| :term:`Build Directory` in |
| ``tmp/testexport/``\ image, which is controlled by the |
| :term:`TEST_EXPORT_DIR` variable. |
| |
| You can now run the tests outside of the build environment:: |
| |
| $ cd tmp/testexport/image |
| $ ./runexported.py testdata.json |
| |
| Here is a complete example that shows IP addresses and uses the |
| ``core-image-sato`` image:: |
| |
| INHERIT += "testexport" |
| TEST_TARGET_IP = "192.168.7.2" |
| TEST_SERVER_IP = "192.168.7.1" |
| |
| Use BitBake to export the tests:: |
| |
| $ bitbake core-image-sato -c testexport |
| |
| Run the tests outside of |
| the build environment using the following:: |
| |
| $ cd tmp/testexport/core-image-sato |
| $ ./runexported.py testdata.json |
| |
| Writing New Tests |
| ----------------- |
| |
| As mentioned previously, all new test files need to be in the proper |
| place for the build system to find them. New tests for additional |
| functionality outside of the core should be added to the layer that adds |
| the functionality, in ``layer/lib/oeqa/runtime`` (as long as |
| :term:`BBPATH` is extended in the |
| layer's ``layer.conf`` file as normal). Just remember the following: |
| |
| - Filenames need to map directly to test (module) names. |
| |
| - Do not use module names that collide with existing core tests. |
| |
| - Minimally, an empty ``__init__.py`` file must be present in the runtime |
| directory. |
| |
| To create a new test, start by copying an existing module (e.g. |
| ``syslog.py`` or ``gcc.py`` are good ones to use). Test modules can use |
| code from ``meta/lib/oeqa/utils``, which are helper classes. |
| |
| .. note:: |
| |
| Structure shell commands such that you rely on them and they return a |
| single code for success. Be aware that sometimes you will need to |
| parse the output. See the ``df.py`` and ``date.py`` modules for examples. |
| |
| You will notice that all test classes inherit ``oeRuntimeTest``, which |
| is found in ``meta/lib/oetest.py``. This base class offers some helper |
| attributes, which are described in the following sections: |
| |
| Class Methods |
| ~~~~~~~~~~~~~ |
| |
| Class methods are as follows: |
| |
| - *hasPackage(pkg):* Returns "True" if ``pkg`` is in the installed |
| package list of the image, which is based on the manifest file that |
| is generated during the ``do_rootfs`` task. |
| |
| - *hasFeature(feature):* Returns "True" if the feature is in |
| :term:`IMAGE_FEATURES` or |
| :term:`DISTRO_FEATURES`. |
| |
| Class Attributes |
| ~~~~~~~~~~~~~~~~ |
| |
| Class attributes are as follows: |
| |
| - *pscmd:* Equals "ps -ef" if ``procps`` is installed in the image. |
| Otherwise, ``pscmd`` equals "ps" (busybox). |
| |
| - *tc:* The called test context, which gives access to the |
| following attributes: |
| |
| - *d:* The BitBake datastore, which allows you to use stuff such |
| as ``oeRuntimeTest.tc.d.getVar("VIRTUAL-RUNTIME_init_manager")``. |
| |
| - *testslist and testsrequired:* Used internally. The tests |
| do not need these. |
| |
| - *filesdir:* The absolute path to |
| ``meta/lib/oeqa/runtime/files``, which contains helper files for |
| tests meant for copying on the target such as small files written |
| in C for compilation. |
| |
| - *target:* The target controller object used to deploy and |
| start an image on a particular target (e.g. Qemu, SimpleRemote, |
| and SystemdbootTarget). Tests usually use the following: |
| |
| - *ip:* The target's IP address. |
| |
| - *server_ip:* The host's IP address, which is usually used |
| by the DNF test suite. |
| |
| - *run(cmd, timeout=None):* The single, most used method. |
| This command is a wrapper for: ``ssh root@host "cmd"``. The |
| command returns a tuple: (status, output), which are what their |
| names imply - the return code of "cmd" and whatever output it |
| produces. The optional timeout argument represents the number |
| of seconds the test should wait for "cmd" to return. If the |
| argument is "None", the test uses the default instance's |
| timeout period, which is 300 seconds. If the argument is "0", |
| the test runs until the command returns. |
| |
| - *copy_to(localpath, remotepath):* |
| ``scp localpath root@ip:remotepath``. |
| |
| - *copy_from(remotepath, localpath):* |
| ``scp root@host:remotepath localpath``. |
| |
| Instance Attributes |
| ~~~~~~~~~~~~~~~~~~~ |
| |
| There is a single instance attribute, which is ``target``. The ``target`` |
| instance attribute is identical to the class attribute of the same name, |
| which is described in the previous section. This attribute exists as |
| both an instance and class attribute so tests can use |
| ``self.target.run(cmd)`` in instance methods instead of |
| ``oeRuntimeTest.tc.target.run(cmd)``. |
| |
| Installing Packages in the DUT Without the Package Manager |
| ---------------------------------------------------------- |
| |
| When a test requires a package built by BitBake, it is possible to |
| install that package. Installing the package does not require a package |
| manager be installed in the device under test (DUT). It does, however, |
| require an SSH connection and the target must be using the |
| ``sshcontrol`` class. |
| |
| .. note:: |
| |
| This method uses ``scp`` to copy files from the host to the target, which |
| causes permissions and special attributes to be lost. |
| |
| A JSON file is used to define the packages needed by a test. This file |
| must be in the same path as the file used to define the tests. |
| Furthermore, the filename must map directly to the test module name with |
| a ``.json`` extension. |
| |
| The JSON file must include an object with the test name as keys of an |
| object or an array. This object (or array of objects) uses the following |
| data: |
| |
| - "pkg" - A mandatory string that is the name of the package to be |
| installed. |
| |
| - "rm" - An optional boolean, which defaults to "false", that specifies |
| to remove the package after the test. |
| |
| - "extract" - An optional boolean, which defaults to "false", that |
| specifies if the package must be extracted from the package format. |
| When set to "true", the package is not automatically installed into |
| the DUT. |
| |
| Following is an example JSON file that handles test "foo" installing |
| package "bar" and test "foobar" installing packages "foo" and "bar". |
| Once the test is complete, the packages are removed from the DUT. |
| :: |
| |
| { |
| "foo": { |
| "pkg": "bar" |
| }, |
| "foobar": [ |
| { |
| "pkg": "foo", |
| "rm": true |
| }, |
| { |
| "pkg": "bar", |
| "rm": true |
| } |
| ] |
| } |
| |
| Debugging Tools and Techniques |
| ============================== |
| |
| The exact method for debugging build failures depends on the nature of |
| the problem and on the system's area from which the bug originates. |
| Standard debugging practices such as comparison against the last known |
| working version with examination of the changes and the re-application |
| of steps to identify the one causing the problem are valid for the Yocto |
| Project just as they are for any other system. Even though it is |
| impossible to detail every possible potential failure, this section |
| provides some general tips to aid in debugging given a variety of |
| situations. |
| |
| .. note:: |
| |
| A useful feature for debugging is the error reporting tool. |
| Configuring the Yocto Project to use this tool causes the |
| OpenEmbedded build system to produce error reporting commands as part |
| of the console output. You can enter the commands after the build |
| completes to log error information into a common database, that can |
| help you figure out what might be going wrong. For information on how |
| to enable and use this feature, see the |
| ":ref:`dev-manual/common-tasks:using the error reporting tool`" |
| section. |
| |
| The following list shows the debugging topics in the remainder of this |
| section: |
| |
| - ":ref:`dev-manual/common-tasks:viewing logs from failed tasks`" describes |
| how to find and view logs from tasks that failed during the build |
| process. |
| |
| - ":ref:`dev-manual/common-tasks:viewing variable values`" describes how to |
| use the BitBake ``-e`` option to examine variable values after a |
| recipe has been parsed. |
| |
| - ":ref:`dev-manual/common-tasks:viewing package information with \`\`oe-pkgdata-util\`\``" |
| describes how to use the ``oe-pkgdata-util`` utility to query |
| :term:`PKGDATA_DIR` and |
| display package-related information for built packages. |
| |
| - ":ref:`dev-manual/common-tasks:viewing dependencies between recipes and tasks`" |
| describes how to use the BitBake ``-g`` option to display recipe |
| dependency information used during the build. |
| |
| - ":ref:`dev-manual/common-tasks:viewing task variable dependencies`" describes |
| how to use the ``bitbake-dumpsig`` command in conjunction with key |
| subdirectories in the |
| :term:`Build Directory` to determine |
| variable dependencies. |
| |
| - ":ref:`dev-manual/common-tasks:running specific tasks`" describes |
| how to use several BitBake options (e.g. ``-c``, ``-C``, and ``-f``) |
| to run specific tasks in the build chain. It can be useful to run |
| tasks "out-of-order" when trying isolate build issues. |
| |
| - ":ref:`dev-manual/common-tasks:general bitbake problems`" describes how |
| to use BitBake's ``-D`` debug output option to reveal more about what |
| BitBake is doing during the build. |
| |
| - ":ref:`dev-manual/common-tasks:building with no dependencies`" |
| describes how to use the BitBake ``-b`` option to build a recipe |
| while ignoring dependencies. |
| |
| - ":ref:`dev-manual/common-tasks:recipe logging mechanisms`" |
| describes how to use the many recipe logging functions to produce |
| debugging output and report errors and warnings. |
| |
| - ":ref:`dev-manual/common-tasks:debugging parallel make races`" |
| describes how to debug situations where the build consists of several |
| parts that are run simultaneously and when the output or result of |
| one part is not ready for use with a different part of the build that |
| depends on that output. |
| |
| - ":ref:`dev-manual/common-tasks:debugging with the gnu project debugger (gdb) remotely`" |
| describes how to use GDB to allow you to examine running programs, which can |
| help you fix problems. |
| |
| - ":ref:`dev-manual/common-tasks:debugging with the gnu project debugger (gdb) on the target`" |
| describes how to use GDB directly on target hardware for debugging. |
| |
| - ":ref:`dev-manual/common-tasks:other debugging tips`" describes |
| miscellaneous debugging tips that can be useful. |
| |
| Viewing Logs from Failed Tasks |
| ------------------------------ |
| |
| You can find the log for a task in the file |
| ``${``\ :term:`WORKDIR`\ ``}/temp/log.do_``\ `taskname`. |
| For example, the log for the |
| :ref:`ref-tasks-compile` task of the |
| QEMU minimal image for the x86 machine (``qemux86``) might be in |
| ``tmp/work/qemux86-poky-linux/core-image-minimal/1.0-r0/temp/log.do_compile``. |
| To see the commands :term:`BitBake` ran |
| to generate a log, look at the corresponding ``run.do_``\ `taskname` file |
| in the same directory. |
| |
| ``log.do_``\ `taskname` and ``run.do_``\ `taskname` are actually symbolic |
| links to ``log.do_``\ `taskname`\ ``.``\ `pid` and |
| ``log.run_``\ `taskname`\ ``.``\ `pid`, where `pid` is the PID the task had |
| when it ran. The symlinks always point to the files corresponding to the |
| most recent run. |
| |
| Viewing Variable Values |
| ----------------------- |
| |
| Sometimes you need to know the value of a variable as a result of |
| BitBake's parsing step. This could be because some unexpected behavior |
| occurred in your project. Perhaps an attempt to :ref:`modify a variable |
| <bitbake:bitbake-user-manual/bitbake-user-manual-metadata:modifying existing |
| variables>` did not work out as expected. |
| |
| BitBake's ``-e`` option is used to display variable values after |
| parsing. The following command displays the variable values after the |
| configuration files (i.e. ``local.conf``, ``bblayers.conf``, |
| ``bitbake.conf`` and so forth) have been parsed:: |
| |
| $ bitbake -e |
| |
| The following command displays variable values after a specific recipe has |
| been parsed. The variables include those from the configuration as well:: |
| |
| $ bitbake -e recipename |
| |
| .. note:: |
| |
| Each recipe has its own private set of variables (datastore). |
| Internally, after parsing the configuration, a copy of the resulting |
| datastore is made prior to parsing each recipe. This copying implies |
| that variables set in one recipe will not be visible to other |
| recipes. |
| |
| Likewise, each task within a recipe gets a private datastore based on |
| the recipe datastore, which means that variables set within one task |
| will not be visible to other tasks. |
| |
| In the output of ``bitbake -e``, each variable is preceded by a |
| description of how the variable got its value, including temporary |
| values that were later overridden. This description also includes |
| variable flags (varflags) set on the variable. The output can be very |
| helpful during debugging. |
| |
| Variables that are exported to the environment are preceded by |
| ``export`` in the output of ``bitbake -e``. See the following example:: |
| |
| export CC="i586-poky-linux-gcc -m32 -march=i586 --sysroot=/home/ulf/poky/build/tmp/sysroots/qemux86" |
| |
| In addition to variable values, the output of the ``bitbake -e`` and |
| ``bitbake -e`` recipe commands includes the following information: |
| |
| - The output starts with a tree listing all configuration files and |
| classes included globally, recursively listing the files they include |
| or inherit in turn. Much of the behavior of the OpenEmbedded build |
| system (including the behavior of the :ref:`ref-manual/tasks:normal recipe build tasks`) is |
| implemented in the |
| :ref:`base <ref-classes-base>` class and the |
| classes it inherits, rather than being built into BitBake itself. |
| |
| - After the variable values, all functions appear in the output. For |
| shell functions, variables referenced within the function body are |
| expanded. If a function has been modified using overrides or using |
| override-style operators like ``:append`` and ``:prepend``, then the |
| final assembled function body appears in the output. |
| |
| Viewing Package Information with ``oe-pkgdata-util`` |
| ---------------------------------------------------- |
| |
| You can use the ``oe-pkgdata-util`` command-line utility to query |
| :term:`PKGDATA_DIR` and display |
| various package-related information. When you use the utility, you must |
| use it to view information on packages that have already been built. |
| |
| Following are a few of the available ``oe-pkgdata-util`` subcommands. |
| |
| .. note:: |
| |
| You can use the standard \* and ? globbing wildcards as part of |
| package names and paths. |
| |
| - ``oe-pkgdata-util list-pkgs [pattern]``: Lists all packages |
| that have been built, optionally limiting the match to packages that |
| match pattern. |
| |
| - ``oe-pkgdata-util list-pkg-files package ...``: Lists the |
| files and directories contained in the given packages. |
| |
| .. note:: |
| |
| A different way to view the contents of a package is to look at |
| the |
| ``${``\ :term:`WORKDIR`\ ``}/packages-split`` |
| directory of the recipe that generates the package. This directory |
| is created by the |
| :ref:`ref-tasks-package` task |
| and has one subdirectory for each package the recipe generates, |
| which contains the files stored in that package. |
| |
| If you want to inspect the ``${WORKDIR}/packages-split`` |
| directory, make sure that |
| :ref:`rm_work <ref-classes-rm-work>` is not |
| enabled when you build the recipe. |
| |
| - ``oe-pkgdata-util find-path path ...``: Lists the names of |
| the packages that contain the given paths. For example, the following |
| tells us that ``/usr/share/man/man1/make.1`` is contained in the |
| ``make-doc`` package:: |
| |
| $ oe-pkgdata-util find-path /usr/share/man/man1/make.1 |
| make-doc: /usr/share/man/man1/make.1 |
| |
| - ``oe-pkgdata-util lookup-recipe package ...``: Lists the name |
| of the recipes that produce the given packages. |
| |
| For more information on the ``oe-pkgdata-util`` command, use the help |
| facility:: |
| |
| $ oe-pkgdata-util --help |
| $ oe-pkgdata-util subcommand --help |
| |
| Viewing Dependencies Between Recipes and Tasks |
| ---------------------------------------------- |
| |
| Sometimes it can be hard to see why BitBake wants to build other recipes |
| before the one you have specified. Dependency information can help you |
| understand why a recipe is built. |
| |
| To generate dependency information for a recipe, run the following |
| command:: |
| |
| $ bitbake -g recipename |
| |
| This command writes the following files in the current directory: |
| |
| - ``pn-buildlist``: A list of recipes/targets involved in building |
| `recipename`. "Involved" here means that at least one task from the |
| recipe needs to run when building `recipename` from scratch. Targets |
| that are in |
| :term:`ASSUME_PROVIDED` |
| are not listed. |
| |
| - ``task-depends.dot``: A graph showing dependencies between tasks. |
| |
| The graphs are in |
| `DOT <https://en.wikipedia.org/wiki/DOT_%28graph_description_language%29>`__ |
| format and can be converted to images (e.g. using the ``dot`` tool from |
| `Graphviz <https://www.graphviz.org/>`__). |
| |
| .. note:: |
| |
| - DOT files use a plain text format. The graphs generated using the |
| ``bitbake -g`` command are often so large as to be difficult to |
| read without special pruning (e.g. with Bitbake's ``-I`` option) |
| and processing. Despite the form and size of the graphs, the |
| corresponding ``.dot`` files can still be possible to read and |
| provide useful information. |
| |
| As an example, the ``task-depends.dot`` file contains lines such |
| as the following:: |
| |
| "libxslt.do_configure" -> "libxml2.do_populate_sysroot" |
| |
| The above example line reveals that the |
| :ref:`ref-tasks-configure` |
| task in ``libxslt`` depends on the |
| :ref:`ref-tasks-populate_sysroot` |
| task in ``libxml2``, which is a normal |
| :term:`DEPENDS` dependency |
| between the two recipes. |
| |
| - For an example of how ``.dot`` files can be processed, see the |
| ``scripts/contrib/graph-tool`` Python script, which finds and |
| displays paths between graph nodes. |
| |
| You can use a different method to view dependency information by using |
| the following command:: |
| |
| $ bitbake -g -u taskexp recipename |
| |
| This command |
| displays a GUI window from which you can view build-time and runtime |
| dependencies for the recipes involved in building recipename. |
| |
| Viewing Task Variable Dependencies |
| ---------------------------------- |
| |
| As mentioned in the |
| ":ref:`bitbake:bitbake-user-manual/bitbake-user-manual-execution:checksums (signatures)`" section of the BitBake |
| User Manual, BitBake tries to automatically determine what variables a |
| task depends on so that it can rerun the task if any values of the |
| variables change. This determination is usually reliable. However, if |
| you do things like construct variable names at runtime, then you might |
| have to manually declare dependencies on those variables using |
| ``vardeps`` as described in the |
| ":ref:`bitbake:bitbake-user-manual/bitbake-user-manual-metadata:variable flags`" section of the BitBake |
| User Manual. |
| |
| If you are unsure whether a variable dependency is being picked up |
| automatically for a given task, you can list the variable dependencies |
| BitBake has determined by doing the following: |
| |
| 1. Build the recipe containing the task:: |
| |
| $ bitbake recipename |
| |
| 2. Inside the :term:`STAMPS_DIR` |
| directory, find the signature data (``sigdata``) file that |
| corresponds to the task. The ``sigdata`` files contain a pickled |
| Python database of all the metadata that went into creating the input |
| checksum for the task. As an example, for the |
| :ref:`ref-tasks-fetch` task of the |
| ``db`` recipe, the ``sigdata`` file might be found in the following |
| location:: |
| |
| ${BUILDDIR}/tmp/stamps/i586-poky-linux/db/6.0.30-r1.do_fetch.sigdata.7c048c18222b16ff0bcee2000ef648b1 |
| |
| For tasks that are accelerated through the shared state |
| (:ref:`sstate <overview-manual/concepts:shared state cache>`) cache, an |
| additional ``siginfo`` file is written into |
| :term:`SSTATE_DIR` along with |
| the cached task output. The ``siginfo`` files contain exactly the |
| same information as ``sigdata`` files. |
| |
| 3. Run ``bitbake-dumpsig`` on the ``sigdata`` or ``siginfo`` file. Here |
| is an example:: |
| |
| $ bitbake-dumpsig ${BUILDDIR}/tmp/stamps/i586-poky-linux/db/6.0.30-r1.do_fetch.sigdata.7c048c18222b16ff0bcee2000ef648b1 |
| |
| In the output of the above command, you will find a line like the |
| following, which lists all the (inferred) variable dependencies for |
| the task. This list also includes indirect dependencies from |
| variables depending on other variables, recursively. |
| :: |
| |
| Task dependencies: ['PV', 'SRCREV', 'SRC_URI', 'SRC_URI[md5sum]', 'SRC_URI[sha256sum]', 'base_do_fetch'] |
| |
| .. note:: |
| |
| Functions (e.g. ``base_do_fetch``) also count as variable dependencies. |
| These functions in turn depend on the variables they reference. |
| |
| The output of ``bitbake-dumpsig`` also includes the value each |
| variable had, a list of dependencies for each variable, and |
| :term:`BB_HASHBASE_WHITELIST` |
| information. |
| |
| There is also a ``bitbake-diffsigs`` command for comparing two |
| ``siginfo`` or ``sigdata`` files. This command can be helpful when |
| trying to figure out what changed between two versions of a task. If you |
| call ``bitbake-diffsigs`` with just one file, the command behaves like |
| ``bitbake-dumpsig``. |
| |
| You can also use BitBake to dump out the signature construction |
| information without executing tasks by using either of the following |
| BitBake command-line options:: |
| |
| ‐‐dump-signatures=SIGNATURE_HANDLER |
| -S SIGNATURE_HANDLER |
| |
| |
| .. note:: |
| |
| Two common values for `SIGNATURE_HANDLER` are "none" and "printdiff", which |
| dump only the signature or compare the dumped signature with the cached one, |
| respectively. |
| |
| Using BitBake with either of these options causes BitBake to dump out |
| ``sigdata`` files in the ``stamps`` directory for every task it would |
| have executed instead of building the specified target package. |
| |
| Viewing Metadata Used to Create the Input Signature of a Shared State Task |
| -------------------------------------------------------------------------- |
| |
| Seeing what metadata went into creating the input signature of a shared |
| state (sstate) task can be a useful debugging aid. This information is |
| available in signature information (``siginfo``) files in |
| :term:`SSTATE_DIR`. For |
| information on how to view and interpret information in ``siginfo`` |
| files, see the |
| ":ref:`dev-manual/common-tasks:viewing task variable dependencies`" section. |
| |
| For conceptual information on shared state, see the |
| ":ref:`overview-manual/concepts:shared state`" |
| section in the Yocto Project Overview and Concepts Manual. |
| |
| Invalidating Shared State to Force a Task to Run |
| ------------------------------------------------ |
| |
| The OpenEmbedded build system uses |
| :ref:`checksums <overview-manual/concepts:checksums (signatures)>` and |
| :ref:`overview-manual/concepts:shared state` cache to avoid unnecessarily |
| rebuilding tasks. Collectively, this scheme is known as "shared state |
| code". |
| |
| As with all schemes, this one has some drawbacks. It is possible that |
| you could make implicit changes to your code that the checksum |
| calculations do not take into account. These implicit changes affect a |
| task's output but do not trigger the shared state code into rebuilding a |
| recipe. Consider an example during which a tool changes its output. |
| Assume that the output of ``rpmdeps`` changes. The result of the change |
| should be that all the ``package`` and ``package_write_rpm`` shared |
| state cache items become invalid. However, because the change to the |
| output is external to the code and therefore implicit, the associated |
| shared state cache items do not become invalidated. In this case, the |
| build process uses the cached items rather than running the task again. |
| Obviously, these types of implicit changes can cause problems. |
| |
| To avoid these problems during the build, you need to understand the |
| effects of any changes you make. Realize that changes you make directly |
| to a function are automatically factored into the checksum calculation. |
| Thus, these explicit changes invalidate the associated area of shared |
| state cache. However, you need to be aware of any implicit changes that |
| are not obvious changes to the code and could affect the output of a |
| given task. |
| |
| When you identify an implicit change, you can easily take steps to |
| invalidate the cache and force the tasks to run. The steps you can take |
| are as simple as changing a function's comments in the source code. For |
| example, to invalidate package shared state files, change the comment |
| statements of |
| :ref:`ref-tasks-package` or the |
| comments of one of the functions it calls. Even though the change is |
| purely cosmetic, it causes the checksum to be recalculated and forces |
| the build system to run the task again. |
| |
| .. note:: |
| |
| For an example of a commit that makes a cosmetic change to invalidate |
| shared state, see this |
| :yocto_git:`commit </poky/commit/meta/classes/package.bbclass?id=737f8bbb4f27b4837047cb9b4fbfe01dfde36d54>`. |
| |
| Running Specific Tasks |
| ---------------------- |
| |
| Any given recipe consists of a set of tasks. The standard BitBake |
| behavior in most cases is: ``do_fetch``, ``do_unpack``, ``do_patch``, |
| ``do_configure``, ``do_compile``, ``do_install``, ``do_package``, |
| ``do_package_write_*``, and ``do_build``. The default task is |
| ``do_build`` and any tasks on which it depends build first. Some tasks, |
| such as ``do_devshell``, are not part of the default build chain. If you |
| wish to run a task that is not part of the default build chain, you can |
| use the ``-c`` option in BitBake. Here is an example:: |
| |
| $ bitbake matchbox-desktop -c devshell |
| |
| The ``-c`` option respects task dependencies, which means that all other |
| tasks (including tasks from other recipes) that the specified task |
| depends on will be run before the task. Even when you manually specify a |
| task to run with ``-c``, BitBake will only run the task if it considers |
| it "out of date". See the |
| ":ref:`overview-manual/concepts:stamp files and the rerunning of tasks`" |
| section in the Yocto Project Overview and Concepts Manual for how |
| BitBake determines whether a task is "out of date". |
| |
| If you want to force an up-to-date task to be rerun (e.g. because you |
| made manual modifications to the recipe's |
| :term:`WORKDIR` that you want to try |
| out), then you can use the ``-f`` option. |
| |
| .. note:: |
| |
| The reason ``-f`` is never required when running the |
| :ref:`ref-tasks-devshell` task is because the |
| [\ :ref:`nostamp <bitbake:bitbake-user-manual/bitbake-user-manual-metadata:variable flags>`\ ] |
| variable flag is already set for the task. |
| |
| The following example shows one way you can use the ``-f`` option:: |
| |
| $ bitbake matchbox-desktop |
| . |
| . |
| make some changes to the source code in the work directory |
| . |
| . |
| $ bitbake matchbox-desktop -c compile -f |
| $ bitbake matchbox-desktop |
| |
| This sequence first builds and then recompiles ``matchbox-desktop``. The |
| last command reruns all tasks (basically the packaging tasks) after the |
| compile. BitBake recognizes that the ``do_compile`` task was rerun and |
| therefore understands that the other tasks also need to be run again. |
| |
| Another, shorter way to rerun a task and all |
| :ref:`ref-manual/tasks:normal recipe build tasks` |
| that depend on it is to use the ``-C`` option. |
| |
| .. note:: |
| |
| This option is upper-cased and is separate from the ``-c`` |
| option, which is lower-cased. |
| |
| Using this option invalidates the given task and then runs the |
| :ref:`ref-tasks-build` task, which is |
| the default task if no task is given, and the tasks on which it depends. |
| You could replace the final two commands in the previous example with |
| the following single command:: |
| |
| $ bitbake matchbox-desktop -C compile |
| |
| Internally, the ``-f`` and ``-C`` options work by tainting (modifying) |
| the input checksum of the specified task. This tainting indirectly |
| causes the task and its dependent tasks to be rerun through the normal |
| task dependency mechanisms. |
| |
| .. note:: |
| |
| BitBake explicitly keeps track of which tasks have been tainted in |
| this fashion, and will print warnings such as the following for |
| builds involving such tasks: |
| |
| .. code-block:: none |
| |
| WARNING: /home/ulf/poky/meta/recipes-sato/matchbox-desktop/matchbox-desktop_2.1.bb.do_compile is tainted from a forced run |
| |
| |
| The purpose of the warning is to let you know that the work directory |
| and build output might not be in the clean state they would be in for |
| a "normal" build, depending on what actions you took. To get rid of |
| such warnings, you can remove the work directory and rebuild the |
| recipe, as follows:: |
| |
| $ bitbake matchbox-desktop -c clean |
| $ bitbake matchbox-desktop |
| |
| |
| You can view a list of tasks in a given package by running the |
| ``do_listtasks`` task as follows:: |
| |
| $ bitbake matchbox-desktop -c listtasks |
| |
| The results appear as output to the console and are also in |
| the file ``${WORKDIR}/temp/log.do_listtasks``. |
| |
| General BitBake Problems |
| ------------------------ |
| |
| You can see debug output from BitBake by using the ``-D`` option. The |
| debug output gives more information about what BitBake is doing and the |
| reason behind it. Each ``-D`` option you use increases the logging |
| level. The most common usage is ``-DDD``. |
| |
| The output from ``bitbake -DDD -v targetname`` can reveal why BitBake |
| chose a certain version of a package or why BitBake picked a certain |
| provider. This command could also help you in a situation where you |
| think BitBake did something unexpected. |
| |
| Building with No Dependencies |
| ----------------------------- |
| |
| To build a specific recipe (``.bb`` file), you can use the following |
| command form:: |
| |
| $ bitbake -b somepath/somerecipe.bb |
| |
| This command form does |
| not check for dependencies. Consequently, you should use it only when |
| you know existing dependencies have been met. |
| |
| .. note:: |
| |
| You can also specify fragments of the filename. In this case, BitBake |
| checks for a unique match. |
| |
| Recipe Logging Mechanisms |
| ------------------------- |
| |
| The Yocto Project provides several logging functions for producing |
| debugging output and reporting errors and warnings. For Python |
| functions, the following logging functions are available. All of these functions |
| log to ``${T}/log.do_``\ `task`, and can also log to standard output |
| (stdout) with the right settings: |
| |
| - ``bb.plain(msg)``: Writes msg as is to the log while also |
| logging to stdout. |
| |
| - ``bb.note(msg)``: Writes "NOTE: msg" to the log. Also logs to |
| stdout if BitBake is called with "-v". |
| |
| - ``bb.debug(level, msg)``: Writes "DEBUG: msg" to the |
| log. Also logs to stdout if the log level is greater than or equal to |
| level. See the ":ref:`bitbake:bitbake-user-manual/bitbake-user-manual-intro:usage and syntax`" option |
| in the BitBake User Manual for more information. |
| |
| - ``bb.warn(msg)``: Writes "WARNING: msg" to the log while also |
| logging to stdout. |
| |
| - ``bb.error(msg)``: Writes "ERROR: msg" to the log while also |
| logging to standard out (stdout). |
| |
| .. note:: |
| |
| Calling this function does not cause the task to fail. |
| |
| - ``bb.fatal(msg)``: This logging function is similar to |
| ``bb.error(msg)`` but also causes the calling task to fail. |
| |
| .. note:: |
| |
| ``bb.fatal()`` raises an exception, which means you do not need to put a |
| "return" statement after the function. |
| |
| The same logging functions are also available in shell functions, under |
| the names ``bbplain``, ``bbnote``, ``bbdebug``, ``bbwarn``, ``bberror``, |
| and ``bbfatal``. The |
| :ref:`logging <ref-classes-logging>` class |
| implements these functions. See that class in the ``meta/classes`` |
| folder of the :term:`Source Directory` for information. |
| |
| Logging With Python |
| ~~~~~~~~~~~~~~~~~~~ |
| |
| When creating recipes using Python and inserting code that handles build |
| logs, keep in mind the goal is to have informative logs while keeping |
| the console as "silent" as possible. Also, if you want status messages |
| in the log, use the "debug" loglevel. |
| |
| Following is an example written in Python. The code handles logging for |
| a function that determines the number of tasks needed to be run. See the |
| ":ref:`ref-tasks-listtasks`" |
| section for additional information:: |
| |
| python do_listtasks() { |
| bb.debug(2, "Starting to figure out the task list") |
| if noteworthy_condition: |
| bb.note("There are 47 tasks to run") |
| bb.debug(2, "Got to point xyz") |
| if warning_trigger: |
| bb.warn("Detected warning_trigger, this might be a problem later.") |
| if recoverable_error: |
| bb.error("Hit recoverable_error, you really need to fix this!") |
| if fatal_error: |
| bb.fatal("fatal_error detected, unable to print the task list") |
| bb.plain("The tasks present are abc") |
| bb.debug(2, "Finished figuring out the tasklist") |
| } |
| |
| Logging With Bash |
| ~~~~~~~~~~~~~~~~~ |
| |
| When creating recipes using Bash and inserting code that handles build |
| logs, you have the same goals - informative with minimal console output. |
| The syntax you use for recipes written in Bash is similar to that of |
| recipes written in Python described in the previous section. |
| |
| Following is an example written in Bash. The code logs the progress of |
| the ``do_my_function`` function. |
| :: |
| |
| do_my_function() { |
| bbdebug 2 "Running do_my_function" |
| if [ exceptional_condition ]; then |
| bbnote "Hit exceptional_condition" |
| fi |
| bbdebug 2 "Got to point xyz" |
| if [ warning_trigger ]; then |
| bbwarn "Detected warning_trigger, this might cause a problem later." |
| fi |
| if [ recoverable_error ]; then |
| bberror "Hit recoverable_error, correcting" |
| fi |
| if [ fatal_error ]; then |
| bbfatal "fatal_error detected" |
| fi |
| bbdebug 2 "Completed do_my_function" |
| } |
| |
| |
| Debugging Parallel Make Races |
| ----------------------------- |
| |
| A parallel ``make`` race occurs when the build consists of several parts |
| that are run simultaneously and a situation occurs when the output or |
| result of one part is not ready for use with a different part of the |
| build that depends on that output. Parallel make races are annoying and |
| can sometimes be difficult to reproduce and fix. However, there are some simple |
| tips and tricks that can help you debug and fix them. This section |
| presents a real-world example of an error encountered on the Yocto |
| Project autobuilder and the process used to fix it. |
| |
| .. note:: |
| |
| If you cannot properly fix a ``make`` race condition, you can work around it |
| by clearing either the :term:`PARALLEL_MAKE` or :term:`PARALLEL_MAKEINST` |
| variables. |
| |
| The Failure |
| ~~~~~~~~~~~ |
| |
| For this example, assume that you are building an image that depends on |
| the "neard" package. And, during the build, BitBake runs into problems |
| and creates the following output. |
| |
| .. note:: |
| |
| This example log file has longer lines artificially broken to make |
| the listing easier to read. |
| |
| If you examine the output or the log file, you see the failure during |
| ``make``: |
| |
| .. code-block:: none |
| |
| | DEBUG: SITE files ['endian-little', 'bit-32', 'ix86-common', 'common-linux', 'common-glibc', 'i586-linux', 'common'] |
| | DEBUG: Executing shell function do_compile |
| | NOTE: make -j 16 |
| | make --no-print-directory all-am |
| | /bin/mkdir -p include/near |
| | /bin/mkdir -p include/near |
| | /bin/mkdir -p include/near |
| | ln -s /home/pokybuild/yocto-autobuilder/nightly-x86/build/build/tmp/work/i586-poky-linux/neard/ |
| 0.14-r0/neard-0.14/include/types.h include/near/types.h |
| | ln -s /home/pokybuild/yocto-autobuilder/nightly-x86/build/build/tmp/work/i586-poky-linux/neard/ |
| 0.14-r0/neard-0.14/include/log.h include/near/log.h |
| | ln -s /home/pokybuild/yocto-autobuilder/nightly-x86/build/build/tmp/work/i586-poky-linux/neard/ |
| 0.14-r0/neard-0.14/include/plugin.h include/near/plugin.h |
| | /bin/mkdir -p include/near |
| | /bin/mkdir -p include/near |
| | /bin/mkdir -p include/near |
| | ln -s /home/pokybuild/yocto-autobuilder/nightly-x86/build/build/tmp/work/i586-poky-linux/neard/ |
| 0.14-r0/neard-0.14/include/tag.h include/near/tag.h |
| | /bin/mkdir -p include/near |
| | ln -s /home/pokybuild/yocto-autobuilder/nightly-x86/build/build/tmp/work/i586-poky-linux/neard/ |
| 0.14-r0/neard-0.14/include/adapter.h include/near/adapter.h |
| | /bin/mkdir -p include/near |
| | ln -s /home/pokybuild/yocto-autobuilder/nightly-x86/build/build/tmp/work/i586-poky-linux/neard/ |
| 0.14-r0/neard-0.14/include/ndef.h include/near/ndef.h |
| | ln -s /home/pokybuild/yocto-autobuilder/nightly-x86/build/build/tmp/work/i586-poky-linux/neard/ |
| 0.14-r0/neard-0.14/include/tlv.h include/near/tlv.h |
| | /bin/mkdir -p include/near |
| | /bin/mkdir -p include/near |
| | ln -s /home/pokybuild/yocto-autobuilder/nightly-x86/build/build/tmp/work/i586-poky-linux/neard/ |
| 0.14-r0/neard-0.14/include/setting.h include/near/setting.h |
| | /bin/mkdir -p include/near |
| | /bin/mkdir -p include/near |
| | /bin/mkdir -p include/near |
| | ln -s /home/pokybuild/yocto-autobuilder/nightly-x86/build/build/tmp/work/i586-poky-linux/neard/ |
| 0.14-r0/neard-0.14/include/device.h include/near/device.h |
| | ln -s /home/pokybuild/yocto-autobuilder/nightly-x86/build/build/tmp/work/i586-poky-linux/neard/ |
| 0.14-r0/neard-0.14/include/nfc_copy.h include/near/nfc_copy.h |
| | ln -s /home/pokybuild/yocto-autobuilder/nightly-x86/build/build/tmp/work/i586-poky-linux/neard/ |
| 0.14-r0/neard-0.14/include/snep.h include/near/snep.h |
| | ln -s /home/pokybuild/yocto-autobuilder/nightly-x86/build/build/tmp/work/i586-poky-linux/neard/ |
| 0.14-r0/neard-0.14/include/version.h include/near/version.h |
| | ln -s /home/pokybuild/yocto-autobuilder/nightly-x86/build/build/tmp/work/i586-poky-linux/neard/ |
| 0.14-r0/neard-0.14/include/dbus.h include/near/dbus.h |
| | ./src/genbuiltin nfctype1 nfctype2 nfctype3 nfctype4 p2p > src/builtin.h |
| | i586-poky-linux-gcc -m32 -march=i586 --sysroot=/home/pokybuild/yocto-autobuilder/nightly-x86/ |
| build/build/tmp/sysroots/qemux86 -DHAVE_CONFIG_H -I. -I./include -I./src -I./gdbus -I/home/pokybuild/ |
| yocto-autobuilder/nightly-x86/build/build/tmp/sysroots/qemux86/usr/include/glib-2.0 |
| -I/home/pokybuild/yocto-autobuilder/nightly-x86/build/build/tmp/sysroots/qemux86/usr/ |
| lib/glib-2.0/include -I/home/pokybuild/yocto-autobuilder/nightly-x86/build/build/ |
| tmp/sysroots/qemux86/usr/include/dbus-1.0 -I/home/pokybuild/yocto-autobuilder/ |
| nightly-x86/build/build/tmp/sysroots/qemux86/usr/lib/dbus-1.0/include -I/home/pokybuild/yocto-autobuilder/ |
| nightly-x86/build/build/tmp/sysroots/qemux86/usr/include/libnl3 |
| -DNEAR_PLUGIN_BUILTIN -DPLUGINDIR=\""/usr/lib/near/plugins"\" |
| -DCONFIGDIR=\""/etc/neard\"" -O2 -pipe -g -feliminate-unused-debug-types -c |
| -o tools/snep-send.o tools/snep-send.c |
| | In file included from tools/snep-send.c:16:0: |
| | tools/../src/near.h:41:23: fatal error: near/dbus.h: No such file or directory |
| | #include <near/dbus.h> |
| | ^ |
| | compilation terminated. |
| | make[1]: *** [tools/snep-send.o] Error 1 |
| | make[1]: *** Waiting for unfinished jobs.... |
| | make: *** [all] Error 2 |
| | ERROR: oe_runmake failed |
| |
| Reproducing the Error |
| ~~~~~~~~~~~~~~~~~~~~~ |
| |
| Because race conditions are intermittent, they do not manifest |
| themselves every time you do the build. In fact, most times the build |
| will complete without problems even though the potential race condition |
| exists. Thus, once the error surfaces, you need a way to reproduce it. |
| |
| In this example, compiling the "neard" package is causing the problem. |
| So the first thing to do is build "neard" locally. Before you start the |
| build, set the |
| :term:`PARALLEL_MAKE` variable |
| in your ``local.conf`` file to a high number (e.g. "-j 20"). Using a |
| high value for :term:`PARALLEL_MAKE` increases the chances of the race |
| condition showing up:: |
| |
| $ bitbake neard |
| |
| Once the local build for "neard" completes, start a ``devshell`` build:: |
| |
| $ bitbake neard -c devshell |
| |
| For information on how to use a ``devshell``, see the |
| ":ref:`dev-manual/common-tasks:using a development shell`" section. |
| |
| In the ``devshell``, do the following:: |
| |
| $ make clean |
| $ make tools/snep-send.o |
| |
| The ``devshell`` commands cause the failure to clearly |
| be visible. In this case, there is a missing dependency for the ``neard`` |
| Makefile target. Here is some abbreviated, sample output with the |
| missing dependency clearly visible at the end:: |
| |
| i586-poky-linux-gcc -m32 -march=i586 --sysroot=/home/scott-lenovo/...... |
| . |
| . |
| . |
| tools/snep-send.c |
| In file included from tools/snep-send.c:16:0: |
| tools/../src/near.h:41:23: fatal error: near/dbus.h: No such file or directory |
| #include <near/dbus.h> |
| ^ |
| compilation terminated. |
| make: *** [tools/snep-send.o] Error 1 |
| $ |
| |
| |
| Creating a Patch for the Fix |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| Because there is a missing dependency for the Makefile target, you need |
| to patch the ``Makefile.am`` file, which is generated from |
| ``Makefile.in``. You can use Quilt to create the patch:: |
| |
| $ quilt new parallelmake.patch |
| Patch patches/parallelmake.patch is now on top |
| $ quilt add Makefile.am |
| File Makefile.am added to patch patches/parallelmake.patch |
| |
| For more information on using Quilt, see the |
| ":ref:`dev-manual/common-tasks:using quilt in your workflow`" section. |
| |
| At this point you need to make the edits to ``Makefile.am`` to add the |
| missing dependency. For our example, you have to add the following line |
| to the file:: |
| |
| tools/snep-send.$(OBJEXT): include/near/dbus.h |
| |
| Once you have edited the file, use the ``refresh`` command to create the |
| patch:: |
| |
| $ quilt refresh |
| Refreshed patch patches/parallelmake.patch |
| |
| Once the patch file is created, you need to add it back to the originating |
| recipe folder. Here is an example assuming a top-level |
| :term:`Source Directory` named ``poky``:: |
| |
| $ cp patches/parallelmake.patch poky/meta/recipes-connectivity/neard/neard |
| |
| The final thing you need to do to implement the fix in the build is to |
| update the "neard" recipe (i.e. ``neard-0.14.bb``) so that the |
| :term:`SRC_URI` statement includes |
| the patch file. The recipe file is in the folder above the patch. Here |
| is what the edited :term:`SRC_URI` statement would look like:: |
| |
| SRC_URI = "${KERNELORG_MIRROR}/linux/network/nfc/${BPN}-${PV}.tar.xz \ |
| file://neard.in \ |
| file://neard.service.in \ |
| file://parallelmake.patch \ |
| " |
| |
| With the patch complete and moved to the correct folder and the |
| :term:`SRC_URI` statement updated, you can exit the ``devshell``:: |
| |
| $ exit |
| |
| Testing the Build |
| ~~~~~~~~~~~~~~~~~ |
| |
| With everything in place, you can get back to trying the build again |
| locally:: |
| |
| $ bitbake neard |
| |
| This build should succeed. |
| |
| Now you can open up a ``devshell`` again and repeat the clean and make |
| operations as follows:: |
| |
| $ bitbake neard -c devshell |
| $ make clean |
| $ make tools/snep-send.o |
| |
| The build should work without issue. |
| |
| As with all solved problems, if they originated upstream, you need to |
| submit the fix for the recipe in OE-Core and upstream so that the |
| problem is taken care of at its source. See the |
| ":ref:`dev-manual/common-tasks:submitting a change to the yocto project`" |
| section for more information. |
| |
| Debugging With the GNU Project Debugger (GDB) Remotely |
| ------------------------------------------------------ |
| |
| GDB allows you to examine running programs, which in turn helps you to |
| understand and fix problems. It also allows you to perform post-mortem |
| style analysis of program crashes. GDB is available as a package within |
| the Yocto Project and is installed in SDK images by default. See the |
| ":ref:`ref-manual/images:Images`" chapter in the Yocto |
| Project Reference Manual for a description of these images. You can find |
| information on GDB at https://sourceware.org/gdb/. |
| |
| .. note:: |
| |
| For best results, install debug (``-dbg``) packages for the applications you |
| are going to debug. Doing so makes extra debug symbols available that give |
| you more meaningful output. |
| |
| Sometimes, due to memory or disk space constraints, it is not possible |
| to use GDB directly on the remote target to debug applications. These |
| constraints arise because GDB needs to load the debugging information |
| and the binaries of the process being debugged. Additionally, GDB needs |
| to perform many computations to locate information such as function |
| names, variable names and values, stack traces and so forth - even |
| before starting the debugging process. These extra computations place |
| more load on the target system and can alter the characteristics of the |
| program being debugged. |
| |
| To help get past the previously mentioned constraints, there are two |
| methods you can use: running a debuginfod server and using gdbserver. |
| |
| Using the debuginfod server method |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| ``debuginfod`` from ``elfutils`` is a way to distribute ``debuginfo`` files. |
| Running a ``debuginfod`` server makes debug symbols readily available, |
| which means you don't need to download debugging information |
| and the binaries of the process being debugged. You can just fetch |
| debug symbols from the server. |
| |
| To run a ``debuginfod`` server, you need to do the following: |
| |
| - Ensure that ``debuginfod`` is present in :term:`DISTRO_FEATURES` |
| (it already is in ``OpenEmbedded-core`` defaults and ``poky`` reference distribution). |
| If not, set in your distro config file or in ``local.conf``:: |
| |
| DISTRO_FEATURES:append = " debuginfod" |
| |
| This distro feature enables the server and client library in ``elfutils``, |
| and enables ``debuginfod`` support in clients (at the moment, ``gdb`` and ``binutils``). |
| |
| - Run the following commands to launch the ``debuginfod`` server on the host:: |
| |
| $ oe-debuginfod |
| |
| - To use ``debuginfod`` on the target, you need to know the ip:port where |
| ``debuginfod`` is listening on the host (port defaults to 8002), and export |
| that into the shell environment, for example in ``qemu``:: |
| |
| root@qemux86-64:~# export DEBUGINFOD_URLS="http://192.168.7.1:8002/" |
| |
| - Then debug info fetching should simply work when running the target ``gdb``, |
| ``readelf`` or ``objdump``, for example:: |
| |
| root@qemux86-64:~# gdb /bin/cat |
| ... |
| Reading symbols from /bin/cat... |
| Downloading separate debug info for /bin/cat... |
| Reading symbols from /home/root/.cache/debuginfod_client/923dc4780cfbc545850c616bffa884b6b5eaf322/debuginfo... |
| |
| - It's also possible to use ``debuginfod-find`` to just query the server:: |
| |
| root@qemux86-64:~# debuginfod-find debuginfo /bin/ls |
| /home/root/.cache/debuginfod_client/356edc585f7f82d46f94fcb87a86a3fe2d2e60bd/debuginfo |
| |
| |
| Using the gdbserver method |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| gdbserver, which runs on the remote target and does not load any |
| debugging information from the debugged process. Instead, a GDB instance |
| processes the debugging information that is run on a remote computer - |
| the host GDB. The host GDB then sends control commands to gdbserver to |
| make it stop or start the debugged program, as well as read or write |
| memory regions of that debugged program. All the debugging information |
| loaded and processed as well as all the heavy debugging is done by the |
| host GDB. Offloading these processes gives the gdbserver running on the |
| target a chance to remain small and fast. |
| |
| Because the host GDB is responsible for loading the debugging |
| information and for doing the necessary processing to make actual |
| debugging happen, you have to make sure the host can access the |
| unstripped binaries complete with their debugging information and also |
| be sure the target is compiled with no optimizations. The host GDB must |
| also have local access to all the libraries used by the debugged |
| program. Because gdbserver does not need any local debugging |
| information, the binaries on the remote target can remain stripped. |
| However, the binaries must also be compiled without optimization so they |
| match the host's binaries. |
| |
| To remain consistent with GDB documentation and terminology, the binary |
| being debugged on the remote target machine is referred to as the |
| "inferior" binary. For documentation on GDB see the `GDB |
| site <https://sourceware.org/gdb/documentation/>`__. |
| |
| The following steps show you how to debug using the GNU project |
| debugger. |
| |
| 1. *Configure your build system to construct the companion debug |
| filesystem:* |
| |
| In your ``local.conf`` file, set the following:: |
| |
| IMAGE_GEN_DEBUGFS = "1" |
| IMAGE_FSTYPES_DEBUGFS = "tar.bz2" |
| |
| These options cause the |
| OpenEmbedded build system to generate a special companion filesystem |
| fragment, which contains the matching source and debug symbols to |
| your deployable filesystem. The build system does this by looking at |
| what is in the deployed filesystem, and pulling the corresponding |
| ``-dbg`` packages. |
| |
| The companion debug filesystem is not a complete filesystem, but only |
| contains the debug fragments. This filesystem must be combined with |
| the full filesystem for debugging. Subsequent steps in this procedure |
| show how to combine the partial filesystem with the full filesystem. |
| |
| 2. *Configure the system to include gdbserver in the target filesystem:* |
| |
| Make the following addition in either your ``local.conf`` file or in |
| an image recipe:: |
| |
| IMAGE_INSTALL:append = " gdbserver" |
| |
| The change makes |
| sure the ``gdbserver`` package is included. |
| |
| 3. *Build the environment:* |
| |
| Use the following command to construct the image and the companion |
| Debug Filesystem:: |
| |
| $ bitbake image |
| |
| Build the cross GDB component and |
| make it available for debugging. Build the SDK that matches the |
| image. Building the SDK is best for a production build that can be |
| used later for debugging, especially during long term maintenance:: |
| |
| $ bitbake -c populate_sdk image |
| |
| Alternatively, you can build the minimal toolchain components that |
| match the target. Doing so creates a smaller than typical SDK and |
| only contains a minimal set of components with which to build simple |
| test applications, as well as run the debugger:: |
| |
| $ bitbake meta-toolchain |
| |
| A final method is to build Gdb itself within the build system:: |
| |
| $ bitbake gdb-cross-<architecture> |
| |
| Doing so produces a temporary copy of |
| ``cross-gdb`` you can use for debugging during development. While |
| this is the quickest approach, the two previous methods in this step |
| are better when considering long-term maintenance strategies. |
| |
| .. note:: |
| |
| If you run ``bitbake gdb-cross``, the OpenEmbedded build system suggests |
| the actual image (e.g. ``gdb-cross-i586``). The suggestion is usually the |
| actual name you want to use. |
| |
| 4. *Set up the* ``debugfs``\ *:* |
| |
| Run the following commands to set up the ``debugfs``:: |
| |
| $ mkdir debugfs |
| $ cd debugfs |
| $ tar xvfj build-dir/tmp-glibc/deploy/images/machine/image.rootfs.tar.bz2 |
| $ tar xvfj build-dir/tmp-glibc/deploy/images/machine/image-dbg.rootfs.tar.bz2 |
| |
| 5. *Set up GDB:* |
| |
| Install the SDK (if you built one) and then source the correct |
| environment file. Sourcing the environment file puts the SDK in your |
| ``PATH`` environment variable. |
| |
| If you are using the build system, Gdb is located in |
| `build-dir`\ ``/tmp/sysroots/``\ `host`\ ``/usr/bin/``\ `architecture`\ ``/``\ `architecture`\ ``-gdb`` |
| |
| 6. *Boot the target:* |
| |
| For information on how to run QEMU, see the `QEMU |
| Documentation <https://wiki.qemu.org/Documentation/GettingStartedDevelopers>`__. |
| |
| .. note:: |
| |
| Be sure to verify that your host can access the target via TCP. |
| |
| 7. *Debug a program:* |
| |
| Debugging a program involves running gdbserver on the target and then |
| running Gdb on the host. The example in this step debugs ``gzip``: |
| |
| .. code-block:: shell |
| |
| root@qemux86:~# gdbserver localhost:1234 /bin/gzip —help |
| |
| For |
| additional gdbserver options, see the `GDB Server |
| Documentation <https://www.gnu.org/software/gdb/documentation/>`__. |
| |
| After running gdbserver on the target, you need to run Gdb on the |
| host and configure it and connect to the target. Use these commands:: |
| |
| $ cd directory-holding-the-debugfs-directory |
| $ arch-gdb |
| (gdb) set sysroot debugfs |
| (gdb) set substitute-path /usr/src/debug debugfs/usr/src/debug |
| (gdb) target remote IP-of-target:1234 |
| |
| At this |
| point, everything should automatically load (i.e. matching binaries, |
| symbols and headers). |
| |
| .. note:: |
| |
| The Gdb ``set`` commands in the previous example can be placed into the |
| users ``~/.gdbinit`` file. Upon starting, Gdb automatically runs whatever |
| commands are in that file. |
| |
| 8. *Deploying without a full image rebuild:* |
| |
| In many cases, during development you want a quick method to deploy a |
| new binary to the target and debug it, without waiting for a full |
| image build. |
| |
| One approach to solving this situation is to just build the component |
| you want to debug. Once you have built the component, copy the |
| executable directly to both the target and the host ``debugfs``. |
| |
| If the binary is processed through the debug splitting in |
| OpenEmbedded, you should also copy the debug items (i.e. ``.debug`` |
| contents and corresponding ``/usr/src/debug`` files) from the work |
| directory. Here is an example:: |
| |
| $ bitbake bash |
| $ bitbake -c devshell bash |
| $ cd .. |
| $ scp packages-split/bash/bin/bash target:/bin/bash |
| $ cp -a packages-split/bash-dbg/\* path/debugfs |
| |
| Debugging with the GNU Project Debugger (GDB) on the Target |
| ----------------------------------------------------------- |
| |
| The previous section addressed using GDB remotely for debugging |
| purposes, which is the most usual case due to the inherent hardware |
| limitations on many embedded devices. However, debugging in the target |
| hardware itself is also possible with more powerful devices. This |
| section describes what you need to do in order to support using GDB to |
| debug on the target hardware. |
| |
| To support this kind of debugging, you need do the following: |
| |
| - Ensure that GDB is on the target. You can do this by adding "gdb" to |
| :term:`IMAGE_INSTALL`:: |
| |
| IMAGE_INSTALL:append = " gdb" |
| |
| Alternatively, you can add "tools-debug" to :term:`IMAGE_FEATURES`:: |
| |
| IMAGE_FEATURES:append = " tools-debug" |
| |
| - Ensure that debug symbols are present. You can make sure these |
| symbols are present by installing ``-dbg``:: |
| |
| IMAGE_INSTALL:append = "packagename-dbg" |
| |
| Alternatively, you can do the following to include |
| all the debug symbols:: |
| |
| IMAGE_FEATURES:append = " dbg-pkgs" |
| |
| .. note:: |
| |
| To improve the debug information accuracy, you can reduce the level |
| of optimization used by the compiler. For example, when adding the |
| following line to your ``local.conf`` file, you will reduce optimization |
| from :term:`FULL_OPTIMIZATION` of "-O2" to :term:`DEBUG_OPTIMIZATION` |
| of "-O -fno-omit-frame-pointer":: |
| |
| DEBUG_BUILD = "1" |
| |
| Consider that this will reduce the application's performance and is |
| recommended only for debugging purposes. |
| |
| Other Debugging Tips |
| -------------------- |
| |
| Here are some other tips that you might find useful: |
| |
| - When adding new packages, it is worth watching for undesirable items |
| making their way into compiler command lines. For example, you do not |
| want references to local system files like ``/usr/lib/`` or |
| ``/usr/include/``. |
| |
| - If you want to remove the ``psplash`` boot splashscreen, add |
| ``psplash=false`` to the kernel command line. Doing so prevents |
| ``psplash`` from loading and thus allows you to see the console. It |
| is also possible to switch out of the splashscreen by switching the |
| virtual console (e.g. Fn+Left or Fn+Right on a Zaurus). |
| |
| - Removing :term:`TMPDIR` (usually |
| ``tmp/``, within the |
| :term:`Build Directory`) can often fix |
| temporary build issues. Removing :term:`TMPDIR` is usually a relatively |
| cheap operation, because task output will be cached in |
| :term:`SSTATE_DIR` (usually |
| ``sstate-cache/``, which is also in the Build Directory). |
| |
| .. note:: |
| |
| Removing :term:`TMPDIR` might be a workaround rather than a fix. |
| Consequently, trying to determine the underlying cause of an issue before |
| removing the directory is a good idea. |
| |
| - Understanding how a feature is used in practice within existing |
| recipes can be very helpful. It is recommended that you configure |
| some method that allows you to quickly search through files. |
| |
| Using GNU Grep, you can use the following shell function to |
| recursively search through common recipe-related files, skipping |
| binary files, ``.git`` directories, and the Build Directory (assuming |
| its name starts with "build"):: |
| |
| g() { |
| grep -Ir \ |
| --exclude-dir=.git \ |
| --exclude-dir='build*' \ |
| --include='*.bb*' \ |
| --include='*.inc*' \ |
| --include='*.conf*' \ |
| --include='*.py*' \ |
| "$@" |
| } |
| |
| Following are some usage examples:: |
| |
| $ g FOO # Search recursively for "FOO" |
| $ g -i foo # Search recursively for "foo", ignoring case |
| $ g -w FOO # Search recursively for "FOO" as a word, ignoring e.g. "FOOBAR" |
| |
| If figuring |
| out how some feature works requires a lot of searching, it might |
| indicate that the documentation should be extended or improved. In |
| such cases, consider filing a documentation bug using the Yocto |
| Project implementation of |
| :yocto_bugs:`Bugzilla <>`. For information on |
| how to submit a bug against the Yocto Project, see the Yocto Project |
| Bugzilla :yocto_wiki:`wiki page </Bugzilla_Configuration_and_Bug_Tracking>` |
| and the |
| ":ref:`dev-manual/common-tasks:submitting a defect against the yocto project`" |
| section. |
| |
| .. note:: |
| |
| The manuals might not be the right place to document variables |
| that are purely internal and have a limited scope (e.g. internal |
| variables used to implement a single ``.bbclass`` file). |
| |
| Making Changes to the Yocto Project |
| =================================== |
| |
| Because the Yocto Project is an open-source, community-based project, |
| you can effect changes to the project. This section presents procedures |
| that show you how to submit a defect against the project and how to |
| submit a change. |
| |
| Submitting a Defect Against the Yocto Project |
| --------------------------------------------- |
| |
| Use the Yocto Project implementation of |
| `Bugzilla <https://www.bugzilla.org/about/>`__ to submit a defect (bug) |
| against the Yocto Project. For additional information on this |
| implementation of Bugzilla see the ":ref:`Yocto Project |
| Bugzilla <resources-bugtracker>`" section in the |
| Yocto Project Reference Manual. For more detail on any of the following |
| steps, see the Yocto Project |
| :yocto_wiki:`Bugzilla wiki page </Bugzilla_Configuration_and_Bug_Tracking>`. |
| |
| Use the following general steps to submit a bug: |
| |
| 1. Open the Yocto Project implementation of :yocto_bugs:`Bugzilla <>`. |
| |
| 2. Click "File a Bug" to enter a new bug. |
| |
| 3. Choose the appropriate "Classification", "Product", and "Component" |
| for which the bug was found. Bugs for the Yocto Project fall into |
| one of several classifications, which in turn break down into |
| several products and components. For example, for a bug against the |
| ``meta-intel`` layer, you would choose "Build System, Metadata & |
| Runtime", "BSPs", and "bsps-meta-intel", respectively. |
| |
| 4. Choose the "Version" of the Yocto Project for which you found the |
| bug (e.g. &DISTRO;). |
| |
| 5. Determine and select the "Severity" of the bug. The severity |
| indicates how the bug impacted your work. |
| |
| 6. Choose the "Hardware" that the bug impacts. |
| |
| 7. Choose the "Architecture" that the bug impacts. |
| |
| 8. Choose a "Documentation change" item for the bug. Fixing a bug might |
| or might not affect the Yocto Project documentation. If you are |
| unsure of the impact to the documentation, select "Don't Know". |
| |
| 9. Provide a brief "Summary" of the bug. Try to limit your summary to |
| just a line or two and be sure to capture the essence of the bug. |
| |
| 10. Provide a detailed "Description" of the bug. You should provide as |
| much detail as you can about the context, behavior, output, and so |
| forth that surrounds the bug. You can even attach supporting files |
| for output from logs by using the "Add an attachment" button. |
| |
| 11. Click the "Submit Bug" button submit the bug. A new Bugzilla number |
| is assigned to the bug and the defect is logged in the bug tracking |
| system. |
| |
| Once you file a bug, the bug is processed by the Yocto Project Bug |
| Triage Team and further details concerning the bug are assigned (e.g. |
| priority and owner). You are the "Submitter" of the bug and any further |
| categorization, progress, or comments on the bug result in Bugzilla |
| sending you an automated email concerning the particular change or |
| progress to the bug. |
| |
| Submitting a Change to the Yocto Project |
| ---------------------------------------- |
| |
| Contributions to the Yocto Project and OpenEmbedded are very welcome. |
| Because the system is extremely configurable and flexible, we recognize |
| that developers will want to extend, configure or optimize it for their |
| specific uses. |
| |
| The Yocto Project uses a mailing list and a patch-based workflow that is |
| similar to the Linux kernel but contains important differences. In |
| general, there is a mailing list through which you can submit patches. You |
| should send patches to the appropriate mailing list so that they can be |
| reviewed and merged by the appropriate maintainer. The specific mailing |
| list you need to use depends on the location of the code you are |
| changing. Each component (e.g. layer) should have a ``README`` file that |
| indicates where to send the changes and which process to follow. |
| |
| You can send the patch to the mailing list using whichever approach you |
| feel comfortable with to generate the patch. Once sent, the patch is |
| usually reviewed by the community at large. If somebody has concerns |
| with the patch, they will usually voice their concern over the mailing |
| list. If a patch does not receive any negative reviews, the maintainer |
| of the affected layer typically takes the patch, tests it, and then |
| based on successful testing, merges the patch. |
| |
| The "poky" repository, which is the Yocto Project's reference build |
| environment, is a hybrid repository that contains several individual |
| pieces (e.g. BitBake, Metadata, documentation, and so forth) built using |
| the combo-layer tool. The upstream location used for submitting changes |
| varies by component: |
| |
| - *Core Metadata:* Send your patch to the |
| :oe_lists:`openembedded-core </g/openembedded-core>` |
| mailing list. For example, a change to anything under the ``meta`` or |
| ``scripts`` directories should be sent to this mailing list. |
| |
| - *BitBake:* For changes to BitBake (i.e. anything under the |
| ``bitbake`` directory), send your patch to the |
| :oe_lists:`bitbake-devel </g/bitbake-devel>` |
| mailing list. |
| |
| - *"meta-\*" trees:* These trees contain Metadata. Use the |
| :yocto_lists:`poky </g/poky>` mailing list. |
| |
| - *Documentation*: For changes to the Yocto Project documentation, use the |
| :yocto_lists:`docs </g/docs>` mailing list. |
| |
| For changes to other layers hosted in the Yocto Project source |
| repositories (i.e. ``yoctoproject.org``) and tools use the |
| :yocto_lists:`Yocto Project </g/yocto/>` general mailing list. |
| |
| .. note:: |
| |
| Sometimes a layer's documentation specifies to use a particular |
| mailing list. If so, use that list. |
| |
| For additional recipes that do not fit into the core Metadata, you |
| should determine which layer the recipe should go into and submit the |
| change in the manner recommended by the documentation (e.g. the |
| ``README`` file) supplied with the layer. If in doubt, please ask on the |
| Yocto general mailing list or on the openembedded-devel mailing list. |
| |
| You can also push a change upstream and request a maintainer to pull the |
| change into the component's upstream repository. You do this by pushing |
| to a contribution repository that is upstream. See the |
| ":ref:`overview-manual/development-environment:git workflows and the yocto project`" |
| section in the Yocto Project Overview and Concepts Manual for additional |
| concepts on working in the Yocto Project development environment. |
| |
| Maintainers commonly use ``-next`` branches to test submissions prior to |
| merging patches. Thus, you can get an idea of the status of a patch based on |
| whether the patch has been merged into one of these branches. The commonly |
| used testing branches for OpenEmbedded-Core are as follows: |
| |
| - *openembedded-core "master-next" branch:* This branch is part of the |
| :oe_git:`openembedded-core </openembedded-core/>` repository and contains |
| proposed changes to the core metadata. |
| |
| - *poky "master-next" branch:* This branch is part of the |
| :yocto_git:`poky </poky/>` repository and combines proposed |
| changes to bitbake, the core metadata and the poky distro. |
| |
| Similarly, stable branches maintained by the project may have corresponding |
| ``-next`` branches which collect proposed changes. For example, |
| ``&DISTRO_NAME_NO_CAP;-next`` and ``&DISTRO_NAME_NO_CAP_MINUS_ONE;-next`` |
| branches in both the "openembdedded-core" and "poky" repositories. |
| |
| Other layers may have similar testing branches but there is no formal |
| requirement or standard for these so please check the documentation for the |
| layers you are contributing to. |
| |
| The following sections provide procedures for submitting a change. |
| |
| Preparing Changes for Submission |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| 1. *Make Your Changes Locally:* Make your changes in your local Git |
| repository. You should make small, controlled, isolated changes. |
| Keeping changes small and isolated aids review, makes |
| merging/rebasing easier and keeps the change history clean should |
| anyone need to refer to it in future. |
| |
| 2. *Stage Your Changes:* Stage your changes by using the ``git add`` |
| command on each file you changed. |
| |
| 3. *Commit Your Changes:* Commit the change by using the ``git commit`` |
| command. Make sure your commit information follows standards by |
| following these accepted conventions: |
| |
| - Be sure to include a "Signed-off-by:" line in the same style as |
| required by the Linux kernel. Adding this line signifies that you, |
| the submitter, have agreed to the Developer's Certificate of |
| Origin 1.1 as follows: |
| |
| .. code-block:: none |
| |
| Developer's Certificate of Origin 1.1 |
| |
| By making a contribution to this project, I certify that: |
| |
| (a) The contribution was created in whole or in part by me and I |
| have the right to submit it under the open source license |
| indicated in the file; or |
| |
| (b) The contribution is based upon previous work that, to the best |
| of my knowledge, is covered under an appropriate open source |
| license and I have the right under that license to submit that |
| work with modifications, whether created in whole or in part |
| by me, under the same open source license (unless I am |
| permitted to submit under a different license), as indicated |
| in the file; or |
| |
| (c) The contribution was provided directly to me by some other |
| person who certified (a), (b) or (c) and I have not modified |
| it. |
| |
| (d) I understand and agree that this project and the contribution |
| are public and that a record of the contribution (including all |
| personal information I submit with it, including my sign-off) is |
| maintained indefinitely and may be redistributed consistent with |
| this project or the open source license(s) involved. |
| |
| - Provide a single-line summary of the change and, if more |
| explanation is needed, provide more detail in the body of the |
| commit. This summary is typically viewable in the "shortlist" of |
| changes. Thus, providing something short and descriptive that |
| gives the reader a summary of the change is useful when viewing a |
| list of many commits. You should prefix this short description |
| with the recipe name (if changing a recipe), or else with the |
| short form path to the file being changed. |
| |
| - For the body of the commit message, provide detailed information |
| that describes what you changed, why you made the change, and the |
| approach you used. It might also be helpful if you mention how you |
| tested the change. Provide as much detail as you can in the body |
| of the commit message. |
| |
| .. note:: |
| |
| You do not need to provide a more detailed explanation of a |
| change if the change is minor to the point of the single line |
| summary providing all the information. |
| |
| - If the change addresses a specific bug or issue that is associated |
| with a bug-tracking ID, include a reference to that ID in your |
| detailed description. For example, the Yocto Project uses a |
| specific convention for bug references - any commit that addresses |
| a specific bug should use the following form for the detailed |
| description. Be sure to use the actual bug-tracking ID from |
| Bugzilla for bug-id:: |
| |
| Fixes [YOCTO #bug-id] |
| |
| detailed description of change |
| |
| Using Email to Submit a Patch |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| Depending on the components changed, you need to submit the email to a |
| specific mailing list. For some guidance on which mailing list to use, |
| see the |
| :ref:`list <dev-manual/common-tasks:submitting a change to the yocto project>` |
| at the beginning of this section. For a description of all the available |
| mailing lists, see the ":ref:`Mailing Lists <resources-mailinglist>`" section in the |
| Yocto Project Reference Manual. |
| |
| Here is the general procedure on how to submit a patch through email |
| without using the scripts once the steps in |
| :ref:`dev-manual/common-tasks:preparing changes for submission` have been followed: |
| |
| 1. *Format the Commit:* Format the commit into an email message. To |
| format commits, use the ``git format-patch`` command. When you |
| provide the command, you must include a revision list or a number of |
| patches as part of the command. For example, either of these two |
| commands takes your most recent single commit and formats it as an |
| email message in the current directory:: |
| |
| $ git format-patch -1 |
| |
| or :: |
| |
| $ git format-patch HEAD~ |
| |
| After the command is run, the current directory contains a numbered |
| ``.patch`` file for the commit. |
| |
| If you provide several commits as part of the command, the |
| ``git format-patch`` command produces a series of numbered files in |
| the current directory – one for each commit. If you have more than |
| one patch, you should also use the ``--cover`` option with the |
| command, which generates a cover letter as the first "patch" in the |
| series. You can then edit the cover letter to provide a description |
| for the series of patches. For information on the |
| ``git format-patch`` command, see ``GIT_FORMAT_PATCH(1)`` displayed |
| using the ``man git-format-patch`` command. |
| |
| .. note:: |
| |
| If you are or will be a frequent contributor to the Yocto Project |
| or to OpenEmbedded, you might consider requesting a contrib area |
| and the necessary associated rights. |
| |
| 2. *Send the patches via email:* Send the patches to the recipients and |
| relevant mailing lists by using the ``git send-email`` command. |
| |
| .. note:: |
| |
| In order to use ``git send-email``, you must have the proper Git packages |
| installed on your host. |
| For Ubuntu, Debian, and Fedora the package is ``git-email``. |
| |
| The ``git send-email`` command sends email by using a local or remote |
| Mail Transport Agent (MTA) such as ``msmtp``, ``sendmail``, or |
| through a direct ``smtp`` configuration in your Git ``~/.gitconfig`` |
| file. If you are submitting patches through email only, it is very |
| important that you submit them without any whitespace or HTML |
| formatting that either you or your mailer introduces. The maintainer |
| that receives your patches needs to be able to save and apply them |
| directly from your emails. A good way to verify that what you are |
| sending will be applicable by the maintainer is to do a dry run and |
| send them to yourself and then save and apply them as the maintainer |
| would. |
| |
| The ``git send-email`` command is the preferred method for sending |
| your patches using email since there is no risk of compromising |
| whitespace in the body of the message, which can occur when you use |
| your own mail client. The command also has several options that let |
| you specify recipients and perform further editing of the email |
| message. For information on how to use the ``git send-email`` |
| command, see ``GIT-SEND-EMAIL(1)`` displayed using the |
| ``man git-send-email`` command. |
| |
| The Yocto Project uses a `Patchwork instance <https://patchwork.openembedded.org/>`__ |
| to track the status of patches submitted to the various mailing lists and to |
| support automated patch testing. Each submitted patch is checked for common |
| mistakes and deviations from the expected patch format and submitters are |
| notified by patchtest if such mistakes are found. This process helps to |
| reduce the burden of patch review on maintainers. |
| |
| .. note:: |
| |
| This system is imperfect and changes can sometimes get lost in the flow. |
| Asking about the status of a patch or change is reasonable if the change |
| has been idle for a while with no feedback. |
| |
| Using Scripts to Push a Change Upstream and Request a Pull |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| For larger patch series it is preferable to send a pull request which not |
| only includes the patch but also a pointer to a branch that can be pulled |
| from. This involves making a local branch for your changes, pushing this |
| branch to an accessible repository and then using the ``create-pull-request`` |
| and ``send-pull-request`` scripts from openembedded-core to create and send a |
| patch series with a link to the branch for review. |
| |
| Follow this procedure to push a change to an upstream "contrib" Git |
| repository once the steps in :ref:`dev-manual/common-tasks:preparing changes for submission` have |
| been followed: |
| |
| .. note:: |
| |
| You can find general Git information on how to push a change upstream |
| in the |
| `Git Community Book <https://git-scm.com/book/en/v2/Distributed-Git-Distributed-Workflows>`__. |
| |
| 1. *Push Your Commits to a "Contrib" Upstream:* If you have arranged for |
| permissions to push to an upstream contrib repository, push the |
| change to that repository:: |
| |
| $ git push upstream_remote_repo local_branch_name |
| |
| For example, suppose you have permissions to push |
| into the upstream ``meta-intel-contrib`` repository and you are |
| working in a local branch named `your_name`\ ``/README``. The following |
| command pushes your local commits to the ``meta-intel-contrib`` |
| upstream repository and puts the commit in a branch named |
| `your_name`\ ``/README``:: |
| |
| $ git push meta-intel-contrib your_name/README |
| |
| 2. *Determine Who to Notify:* Determine the maintainer or the mailing |
| list that you need to notify for the change. |
| |
| Before submitting any change, you need to be sure who the maintainer |
| is or what mailing list that you need to notify. Use either these |
| methods to find out: |
| |
| - *Maintenance File:* Examine the ``maintainers.inc`` file, which is |
| located in the :term:`Source Directory` at |
| ``meta/conf/distro/include``, to see who is responsible for code. |
| |
| - *Search by File:* Using :ref:`overview-manual/development-environment:git`, you can |
| enter the following command to bring up a short list of all |
| commits against a specific file:: |
| |
| git shortlog -- filename |
| |
| Just provide the name of the file for which you are interested. The |
| information returned is not ordered by history but does include a |
| list of everyone who has committed grouped by name. From the list, |
| you can see who is responsible for the bulk of the changes against |
| the file. |
| |
| - *Examine the List of Mailing Lists:* For a list of the Yocto |
| Project and related mailing lists, see the ":ref:`Mailing |
| lists <resources-mailinglist>`" section in |
| the Yocto Project Reference Manual. |
| |
| 3. *Make a Pull Request:* Notify the maintainer or the mailing list that |
| you have pushed a change by making a pull request. |
| |
| The Yocto Project provides two scripts that conveniently let you |
| generate and send pull requests to the Yocto Project. These scripts |
| are ``create-pull-request`` and ``send-pull-request``. You can find |
| these scripts in the ``scripts`` directory within the |
| :term:`Source Directory` (e.g. |
| ``poky/scripts``). |
| |
| Using these scripts correctly formats the requests without |
| introducing any whitespace or HTML formatting. The maintainer that |
| receives your patches either directly or through the mailing list |
| needs to be able to save and apply them directly from your emails. |
| Using these scripts is the preferred method for sending patches. |
| |
| First, create the pull request. For example, the following command |
| runs the script, specifies the upstream repository in the contrib |
| directory into which you pushed the change, and provides a subject |
| line in the created patch files:: |
| |
| $ poky/scripts/create-pull-request -u meta-intel-contrib -s "Updated Manual Section Reference in README" |
| |
| Running this script forms ``*.patch`` files in a folder named |
| ``pull-``\ `PID` in the current directory. One of the patch files is a |
| cover letter. |
| |
| Before running the ``send-pull-request`` script, you must edit the |
| cover letter patch to insert information about your change. After |
| editing the cover letter, send the pull request. For example, the |
| following command runs the script and specifies the patch directory |
| and email address. In this example, the email address is a mailing |
| list:: |
| |
| $ poky/scripts/send-pull-request -p ~/meta-intel/pull-10565 -t meta-intel@lists.yoctoproject.org |
| |
| You need to follow the prompts as the script is interactive. |
| |
| .. note:: |
| |
| For help on using these scripts, simply provide the ``-h`` |
| argument as follows:: |
| |
| $ poky/scripts/create-pull-request -h |
| $ poky/scripts/send-pull-request -h |
| |
| Responding to Patch Review |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| You may get feedback on your submitted patches from other community members |
| or from the automated patchtest service. If issues are identified in your |
| patch then it is usually necessary to address these before the patch will be |
| accepted into the project. In this case you should amend the patch according |
| to the feedback and submit an updated version to the relevant mailing list, |
| copying in the reviewers who provided feedback to the previous version of the |
| patch. |
| |
| The patch should be amended using ``git commit --amend`` or perhaps ``git |
| rebase`` for more expert git users. You should also modify the ``[PATCH]`` |
| tag in the email subject line when sending the revised patch to mark the new |
| iteration as ``[PATCH v2]``, ``[PATCH v3]``, etc as appropriate. This can be |
| done by passing the ``-v`` argument to ``git format-patch`` with a version |
| number. |
| |
| Lastly please ensure that you also test your revised changes. In particular |
| please don't just edit the patch file written out by ``git format-patch`` and |
| resend it. |
| |
| Submitting Changes to Stable Release Branches |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| The process for proposing changes to a Yocto Project stable branch differs |
| from the steps described above. Changes to a stable branch must address |
| identified bugs or CVEs and should be made carefully in order to avoid the |
| risk of introducing new bugs or breaking backwards compatibility. Typically |
| bug fixes must already be accepted into the master branch before they can be |
| backported to a stable branch unless the bug in question does not affect the |
| master branch or the fix on the master branch is unsuitable for backporting. |
| |
| The list of stable branches along with the status and maintainer for each |
| branch can be obtained from the |
| :yocto_wiki:`Releases wiki page </Releases>`. |
| |
| .. note:: |
| |
| Changes will not typically be accepted for branches which are marked as |
| End-Of-Life (EOL). |
| |
| With this in mind, the steps to submit a change for a stable branch are as |
| follows: |
| |
| 1. *Identify the bug or CVE to be fixed:* This information should be |
| collected so that it can be included in your submission. |
| |
| See :ref:`dev-manual/common-tasks:checking for vulnerabilities` |
| for details about CVE tracking. |
| |
| 2. *Check if the fix is already present in the master branch:* This will |
| result in the most straightforward path into the stable branch for the |
| fix. |
| |
| a. *If the fix is present in the master branch - Submit a backport request |
| by email:* You should send an email to the relevant stable branch |
| maintainer and the mailing list with details of the bug or CVE to be |
| fixed, the commit hash on the master branch that fixes the issue and |
| the stable branches which you would like this fix to be backported to. |
| |
| b. *If the fix is not present in the master branch - Submit the fix to the |
| master branch first:* This will ensure that the fix passes through the |
| project's usual patch review and test processes before being accepted. |
| It will also ensure that bugs are not left unresolved in the master |
| branch itself. Once the fix is accepted in the master branch a backport |
| request can be submitted as above. |
| |
| c. *If the fix is unsuitable for the master branch - Submit a patch |
| directly for the stable branch:* This method should be considered as a |
| last resort. It is typically necessary when the master branch is using |
| a newer version of the software which includes an upstream fix for the |
| issue or when the issue has been fixed on the master branch in a way |
| that introduces backwards incompatible changes. In this case follow the |
| steps in :ref:`dev-manual/common-tasks:preparing changes for submission` and |
| :ref:`dev-manual/common-tasks:using email to submit a patch` but modify the subject header of your patch |
| email to include the name of the stable branch which you are |
| targetting. This can be done using the ``--subject-prefix`` argument to |
| ``git format-patch``, for example to submit a patch to the dunfell |
| branch use |
| ``git format-patch --subject-prefix='&DISTRO_NAME_NO_CAP_MINUS_ONE;][PATCH' ...``. |
| |
| Working With Licenses |
| ===================== |
| |
| As mentioned in the ":ref:`overview-manual/development-environment:licensing`" |
| section in the Yocto Project Overview and Concepts Manual, open source |
| projects are open to the public and they consequently have different |
| licensing structures in place. This section describes the mechanism by |
| which the :term:`OpenEmbedded Build System` |
| tracks changes to |
| licensing text and covers how to maintain open source license compliance |
| during your project's lifecycle. The section also describes how to |
| enable commercially licensed recipes, which by default are disabled. |
| |
| Tracking License Changes |
| ------------------------ |
| |
| The license of an upstream project might change in the future. In order |
| to prevent these changes going unnoticed, the |
| :term:`LIC_FILES_CHKSUM` |
| variable tracks changes to the license text. The checksums are validated |
| at the end of the configure step, and if the checksums do not match, the |
| build will fail. |
| |
| Specifying the ``LIC_FILES_CHKSUM`` Variable |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| The :term:`LIC_FILES_CHKSUM` variable contains checksums of the license text |
| in the source code for the recipe. Following is an example of how to |
| specify :term:`LIC_FILES_CHKSUM`:: |
| |
| LIC_FILES_CHKSUM = "file://COPYING;md5=xxxx \ |
| file://licfile1.txt;beginline=5;endline=29;md5=yyyy \ |
| file://licfile2.txt;endline=50;md5=zzzz \ |
| ..." |
| |
| .. note:: |
| |
| - When using "beginline" and "endline", realize that line numbering |
| begins with one and not zero. Also, the included lines are |
| inclusive (i.e. lines five through and including 29 in the |
| previous example for ``licfile1.txt``). |
| |
| - When a license check fails, the selected license text is included |
| as part of the QA message. Using this output, you can determine |
| the exact start and finish for the needed license text. |
| |
| The build system uses the :term:`S` |
| variable as the default directory when searching files listed in |
| :term:`LIC_FILES_CHKSUM`. The previous example employs the default |
| directory. |
| |
| Consider this next example:: |
| |
| LIC_FILES_CHKSUM = "file://src/ls.c;beginline=5;endline=16;\ |
| md5=bb14ed3c4cda583abc85401304b5cd4e" |
| LIC_FILES_CHKSUM = "file://${WORKDIR}/license.html;md5=5c94767cedb5d6987c902ac850ded2c6" |
| |
| The first line locates a file in ``${S}/src/ls.c`` and isolates lines |
| five through 16 as license text. The second line refers to a file in |
| :term:`WORKDIR`. |
| |
| Note that :term:`LIC_FILES_CHKSUM` variable is mandatory for all recipes, |
| unless the :term:`LICENSE` variable is set to "CLOSED". |
| |
| Explanation of Syntax |
| ~~~~~~~~~~~~~~~~~~~~~ |
| |
| As mentioned in the previous section, the :term:`LIC_FILES_CHKSUM` variable |
| lists all the important files that contain the license text for the |
| source code. It is possible to specify a checksum for an entire file, or |
| a specific section of a file (specified by beginning and ending line |
| numbers with the "beginline" and "endline" parameters, respectively). |
| The latter is useful for source files with a license notice header, |
| README documents, and so forth. If you do not use the "beginline" |
| parameter, then it is assumed that the text begins on the first line of |
| the file. Similarly, if you do not use the "endline" parameter, it is |
| assumed that the license text ends with the last line of the file. |
| |
| The "md5" parameter stores the md5 checksum of the license text. If the |
| license text changes in any way as compared to this parameter then a |
| mismatch occurs. This mismatch triggers a build failure and notifies the |
| developer. Notification allows the developer to review and address the |
| license text changes. Also note that if a mismatch occurs during the |
| build, the correct md5 checksum is placed in the build log and can be |
| easily copied to the recipe. |
| |
| There is no limit to how many files you can specify using the |
| :term:`LIC_FILES_CHKSUM` variable. Generally, however, every project |
| requires a few specifications for license tracking. Many projects have a |
| "COPYING" file that stores the license information for all the source |
| code files. This practice allows you to just track the "COPYING" file as |
| long as it is kept up to date. |
| |
| .. note:: |
| |
| - If you specify an empty or invalid "md5" parameter, |
| :term:`BitBake` returns an md5 |
| mis-match error and displays the correct "md5" parameter value |
| during the build. The correct parameter is also captured in the |
| build log. |
| |
| - If the whole file contains only license text, you do not need to |
| use the "beginline" and "endline" parameters. |
| |
| Enabling Commercially Licensed Recipes |
| -------------------------------------- |
| |
| By default, the OpenEmbedded build system disables components that have |
| commercial or other special licensing requirements. Such requirements |
| are defined on a recipe-by-recipe basis through the |
| :term:`LICENSE_FLAGS` variable |
| definition in the affected recipe. For instance, the |
| ``poky/meta/recipes-multimedia/gstreamer/gst-plugins-ugly`` recipe |
| contains the following statement:: |
| |
| LICENSE_FLAGS = "commercial" |
| |
| Here is a |
| slightly more complicated example that contains both an explicit recipe |
| name and version (after variable expansion):: |
| |
| LICENSE_FLAGS = "license_${PN}_${PV}" |
| |
| In order for a component restricted by a |
| :term:`LICENSE_FLAGS` definition to be enabled and included in an image, it |
| needs to have a matching entry in the global |
| :term:`LICENSE_FLAGS_WHITELIST` |
| variable, which is a variable typically defined in your ``local.conf`` |
| file. For example, to enable the |
| ``poky/meta/recipes-multimedia/gstreamer/gst-plugins-ugly`` package, you |
| could add either the string "commercial_gst-plugins-ugly" or the more |
| general string "commercial" to :term:`LICENSE_FLAGS_WHITELIST`. See the |
| ":ref:`dev-manual/common-tasks:license flag matching`" section for a full |
| explanation of how :term:`LICENSE_FLAGS` matching works. Here is the |
| example:: |
| |
| LICENSE_FLAGS_WHITELIST = "commercial_gst-plugins-ugly" |
| |
| Likewise, to additionally enable the package built from the recipe |
| containing ``LICENSE_FLAGS = "license_${PN}_${PV}"``, and assuming that |
| the actual recipe name was ``emgd_1.10.bb``, the following string would |
| enable that package as well as the original ``gst-plugins-ugly`` |
| package:: |
| |
| LICENSE_FLAGS_WHITELIST = "commercial_gst-plugins-ugly license_emgd_1.10" |
| |
| As a convenience, you do not need to specify the |
| complete license string for every package. You can use |
| an abbreviated form, which consists of just the first portion or |
| portions of the license string before the initial underscore character |
| or characters. A partial string will match any license that contains the |
| given string as the first portion of its license. For example, the |
| following value will also match both of the packages |
| previously mentioned as well as any other packages that have licenses |
| starting with "commercial" or "license". |
| :: |
| |
| LICENSE_FLAGS_WHITELIST = "commercial license" |
| |
| License Flag Matching |
| ~~~~~~~~~~~~~~~~~~~~~ |
| |
| License flag matching allows you to control what recipes the |
| OpenEmbedded build system includes in the build. Fundamentally, the |
| build system attempts to match :term:`LICENSE_FLAGS` strings found in |
| recipes against strings found in :term:`LICENSE_FLAGS_WHITELIST`. |
| A match causes the build system to include a recipe in the |
| build, while failure to find a match causes the build system to exclude |
| a recipe. |
| |
| In general, license flag matching is simple. However, understanding some |
| concepts will help you correctly and effectively use matching. |
| |
| Before a flag defined by a particular recipe is tested against the |
| entries of :term:`LICENSE_FLAGS_WHITELIST`, the expanded |
| string ``_${PN}`` is appended to the flag. This expansion makes each |
| :term:`LICENSE_FLAGS` value recipe-specific. After expansion, the |
| string is then matched against the entries. Thus, specifying |
| ``LICENSE_FLAGS = "commercial"`` in recipe "foo", for example, results |
| in the string ``"commercial_foo"``. And, to create a match, that string |
| must appear among the entries of :term:`LICENSE_FLAGS_WHITELIST`. |
| |
| Judicious use of the :term:`LICENSE_FLAGS` strings and the contents of the |
| :term:`LICENSE_FLAGS_WHITELIST` variable allows you a lot of flexibility for |
| including or excluding recipes based on licensing. For example, you can |
| broaden the matching capabilities by using license flags string subsets |
| in :term:`LICENSE_FLAGS_WHITELIST`. |
| |
| .. note:: |
| |
| When using a string subset, be sure to use the part of the expanded |
| string that precedes the appended underscore character (e.g. |
| ``usethispart_1.3``, ``usethispart_1.4``, and so forth). |
| |
| For example, simply specifying the string "commercial" in the |
| :term:`LICENSE_FLAGS_WHITELIST` variable matches any expanded |
| :term:`LICENSE_FLAGS` definition that starts with the string |
| "commercial" such as "commercial_foo" and "commercial_bar", which |
| are the strings the build system automatically generates for |
| hypothetical recipes named "foo" and "bar" assuming those recipes simply |
| specify the following:: |
| |
| LICENSE_FLAGS = "commercial" |
| |
| Thus, you can choose to exhaustively enumerate each license flag in the |
| list and allow only specific recipes into the image, or you can use a |
| string subset that causes a broader range of matches to allow a range of |
| recipes into the image. |
| |
| This scheme works even if the :term:`LICENSE_FLAGS` string already has |
| ``_${PN}`` appended. For example, the build system turns the license |
| flag "commercial_1.2_foo" into "commercial_1.2_foo_foo" and would match |
| both the general "commercial" and the specific "commercial_1.2_foo" |
| strings found in the :term:`LICENSE_FLAGS_WHITELIST` variable, as expected. |
| |
| Here are some other scenarios: |
| |
| - You can specify a versioned string in the recipe such as |
| "commercial_foo_1.2" in a "foo" recipe. The build system expands this |
| string to "commercial_foo_1.2_foo". Combine this license flag with a |
| :term:`LICENSE_FLAGS_WHITELIST` variable that has the string |
| "commercial" and you match the flag along with any other flag that |
| starts with the string "commercial". |
| |
| - Under the same circumstances, you can add "commercial_foo" in the |
| :term:`LICENSE_FLAGS_WHITELIST` variable and the build system not only |
| matches "commercial_foo_1.2" but also matches any license flag with |
| the string "commercial_foo", regardless of the version. |
| |
| - You can be very specific and use both the package and version parts |
| in the :term:`LICENSE_FLAGS_WHITELIST` list (e.g. |
| "commercial_foo_1.2") to specifically match a versioned recipe. |
| |
| Other Variables Related to Commercial Licenses |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| There are other helpful variables related to commercial license handling, |
| defined in the |
| ``poky/meta/conf/distro/include/default-distrovars.inc`` file:: |
| |
| COMMERCIAL_AUDIO_PLUGINS ?= "" |
| COMMERCIAL_VIDEO_PLUGINS ?= "" |
| |
| If you |
| want to enable these components, you can do so by making sure you have |
| statements similar to the following in your ``local.conf`` configuration |
| file:: |
| |
| COMMERCIAL_AUDIO_PLUGINS = "gst-plugins-ugly-mad \ |
| gst-plugins-ugly-mpegaudioparse" |
| COMMERCIAL_VIDEO_PLUGINS = "gst-plugins-ugly-mpeg2dec \ |
| gst-plugins-ugly-mpegstream gst-plugins-bad-mpegvideoparse" |
| LICENSE_FLAGS_WHITELIST = "commercial_gst-plugins-ugly commercial_gst-plugins-bad commercial_qmmp" |
| |
| |
| Of course, you could also create a matching list for those |
| components using the more general "commercial" in the |
| :term:`LICENSE_FLAGS_WHITELIST` variable, but that would also enable all |
| the other packages with :term:`LICENSE_FLAGS` |
| containing "commercial", which you may or may not want:: |
| |
| LICENSE_FLAGS_WHITELIST = "commercial" |
| |
| Specifying audio and video plugins as part of the |
| ``COMMERCIAL_AUDIO_PLUGINS`` and ``COMMERCIAL_VIDEO_PLUGINS`` statements |
| (along with the enabling :term:`LICENSE_FLAGS_WHITELIST`) includes the |
| plugins or components into built images, thus adding support for media |
| formats or components. |
| |
| Maintaining Open Source License Compliance During Your Product's Lifecycle |
| -------------------------------------------------------------------------- |
| |
| One of the concerns for a development organization using open source |
| software is how to maintain compliance with various open source |
| licensing during the lifecycle of the product. While this section does |
| not provide legal advice or comprehensively cover all scenarios, it does |
| present methods that you can use to assist you in meeting the compliance |
| requirements during a software release. |
| |
| With hundreds of different open source licenses that the Yocto Project |
| tracks, it is difficult to know the requirements of each and every |
| license. However, the requirements of the major FLOSS licenses can begin |
| to be covered by assuming that there are three main areas of concern: |
| |
| - Source code must be provided. |
| |
| - License text for the software must be provided. |
| |
| - Compilation scripts and modifications to the source code must be |
| provided. |
| |
| - spdx files can be provided. |
| |
| There are other requirements beyond the scope of these three and the |
| methods described in this section (e.g. the mechanism through which |
| source code is distributed). |
| |
| As different organizations have different methods of complying with open |
| source licensing, this section is not meant to imply that there is only |
| one single way to meet your compliance obligations, but rather to |
| describe one method of achieving compliance. The remainder of this |
| section describes methods supported to meet the previously mentioned |
| three requirements. Once you take steps to meet these requirements, and |
| prior to releasing images, sources, and the build system, you should |
| audit all artifacts to ensure completeness. |
| |
| .. note:: |
| |
| The Yocto Project generates a license manifest during image creation |
| that is located in ``${DEPLOY_DIR}/licenses/``\ `image_name`\ ``-``\ `datestamp` |
| to assist with any audits. |
| |
| Providing the Source Code |
| ~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| Compliance activities should begin before you generate the final image. |
| The first thing you should look at is the requirement that tops the list |
| for most compliance groups - providing the source. The Yocto Project has |
| a few ways of meeting this requirement. |
| |
| One of the easiest ways to meet this requirement is to provide the |
| entire :term:`DL_DIR` used by the |
| build. This method, however, has a few issues. The most obvious is the |
| size of the directory since it includes all sources used in the build |
| and not just the source used in the released image. It will include |
| toolchain source, and other artifacts, which you would not generally |
| release. However, the more serious issue for most companies is |
| accidental release of proprietary software. The Yocto Project provides |
| an :ref:`archiver <ref-classes-archiver>` class to |
| help avoid some of these concerns. |
| |
| Before you employ :term:`DL_DIR` or the :ref:`archiver <ref-classes-archiver>` class, you need to |
| decide how you choose to provide source. The source ``archiver`` class |
| can generate tarballs and SRPMs and can create them with various levels |
| of compliance in mind. |
| |
| One way of doing this (but certainly not the only way) is to release |
| just the source as a tarball. You can do this by adding the following to |
| the ``local.conf`` file found in the |
| :term:`Build Directory`:: |
| |
| INHERIT += "archiver" |
| ARCHIVER_MODE[src] = "original" |
| |
| During the creation of your |
| image, the source from all recipes that deploy packages to the image is |
| placed within subdirectories of ``DEPLOY_DIR/sources`` based on the |
| :term:`LICENSE` for each recipe. |
| Releasing the entire directory enables you to comply with requirements |
| concerning providing the unmodified source. It is important to note that |
| the size of the directory can get large. |
| |
| A way to help mitigate the size issue is to only release tarballs for |
| licenses that require the release of source. Let us assume you are only |
| concerned with GPL code as identified by running the following script: |
| |
| .. code-block:: shell |
| |
| # Script to archive a subset of packages matching specific license(s) |
| # Source and license files are copied into sub folders of package folder |
| # Must be run from build folder |
| #!/bin/bash |
| src_release_dir="source-release" |
| mkdir -p $src_release_dir |
| for a in tmp/deploy/sources/*; do |
| for d in $a/*; do |
| # Get package name from path |
| p=`basename $d` |
| p=${p%-*} |
| p=${p%-*} |
| # Only archive GPL packages (update *GPL* regex for your license check) |
| numfiles=`ls tmp/deploy/licenses/$p/*GPL* 2> /dev/null | wc -l` |
| if [ $numfiles -ge 1 ]; then |
| echo Archiving $p |
| mkdir -p $src_release_dir/$p/source |
| cp $d/* $src_release_dir/$p/source 2> /dev/null |
| mkdir -p $src_release_dir/$p/license |
| cp tmp/deploy/licenses/$p/* $src_release_dir/$p/license 2> /dev/null |
| fi |
| done |
| done |
| |
| At this point, you |
| could create a tarball from the ``gpl_source_release`` directory and |
| provide that to the end user. This method would be a step toward |
| achieving compliance with section 3a of GPLv2 and with section 6 of |
| GPLv3. |
| |
| Providing License Text |
| ~~~~~~~~~~~~~~~~~~~~~~ |
| |
| One requirement that is often overlooked is inclusion of license text. |
| This requirement also needs to be dealt with prior to generating the |
| final image. Some licenses require the license text to accompany the |
| binary. You can achieve this by adding the following to your |
| ``local.conf`` file:: |
| |
| COPY_LIC_MANIFEST = "1" |
| COPY_LIC_DIRS = "1" |
| LICENSE_CREATE_PACKAGE = "1" |
| |
| Adding these statements to the |
| configuration file ensures that the licenses collected during package |
| generation are included on your image. |
| |
| .. note:: |
| |
| Setting all three variables to "1" results in the image having two |
| copies of the same license file. One copy resides in |
| ``/usr/share/common-licenses`` and the other resides in |
| ``/usr/share/license``. |
| |
| The reason for this behavior is because |
| :term:`COPY_LIC_DIRS` and |
| :term:`COPY_LIC_MANIFEST` |
| add a copy of the license when the image is built but do not offer a |
| path for adding licenses for newly installed packages to an image. |
| :term:`LICENSE_CREATE_PACKAGE` |
| adds a separate package and an upgrade path for adding licenses to an |
| image. |
| |
| As the source ``archiver`` class has already archived the original |
| unmodified source that contains the license files, you would have |
| already met the requirements for inclusion of the license information |
| with source as defined by the GPL and other open source licenses. |
| |
| Providing Compilation Scripts and Source Code Modifications |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| At this point, we have addressed all we need to prior to generating the |
| image. The next two requirements are addressed during the final |
| packaging of the release. |
| |
| By releasing the version of the OpenEmbedded build system and the layers |
| used during the build, you will be providing both compilation scripts |
| and the source code modifications in one step. |
| |
| If the deployment team has a :ref:`overview-manual/concepts:bsp layer` |
| and a distro layer, and those |
| those layers are used to patch, compile, package, or modify (in any way) |
| any open source software included in your released images, you might be |
| required to release those layers under section 3 of GPLv2 or section 1 |
| of GPLv3. One way of doing that is with a clean checkout of the version |
| of the Yocto Project and layers used during your build. Here is an |
| example: |
| |
| .. code-block:: shell |
| |
| # We built using the dunfell branch of the poky repo |
| $ git clone -b dunfell git://git.yoctoproject.org/poky |
| $ cd poky |
| # We built using the release_branch for our layers |
| $ git clone -b release_branch git://git.mycompany.com/meta-my-bsp-layer |
| $ git clone -b release_branch git://git.mycompany.com/meta-my-software-layer |
| # clean up the .git repos |
| $ find . -name ".git" -type d -exec rm -rf {} \; |
| |
| One |
| thing a development organization might want to consider for end-user |
| convenience is to modify ``meta-poky/conf/bblayers.conf.sample`` to |
| ensure that when the end user utilizes the released build system to |
| build an image, the development organization's layers are included in |
| the ``bblayers.conf`` file automatically:: |
| |
| # POKY_BBLAYERS_CONF_VERSION is increased each time build/conf/bblayers.conf |
| # changes incompatibly |
| POKY_BBLAYERS_CONF_VERSION = "2" |
| |
| BBPATH = "${TOPDIR}" |
| BBFILES ?= "" |
| |
| BBLAYERS ?= " \ |
| ##OEROOT##/meta \ |
| ##OEROOT##/meta-poky \ |
| ##OEROOT##/meta-yocto-bsp \ |
| ##OEROOT##/meta-mylayer \ |
| " |
| |
| Creating and |
| providing an archive of the :term:`Metadata` |
| layers (recipes, configuration files, and so forth) enables you to meet |
| your requirements to include the scripts to control compilation as well |
| as any modifications to the original source. |
| |
| Providing spdx files |
| ~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| The spdx module has been integrated to a layer named meta-spdxscanner. |
| meta-spdxscanner provides several kinds of scanner. If you want to enable |
| this function, you have to follow the following steps: |
| |
| 1. Add meta-spdxscanner layer into ``bblayers.conf``. |
| |
| 2. Refer to the README in meta-spdxscanner to setup the environment (e.g, |
| setup a fossology server) needed for the scanner. |
| |
| 3. Meta-spdxscanner provides several methods within the bbclass to create spdx files. |
| Please choose one that you want to use and enable the spdx task. You have to |
| add some config options in ``local.conf`` file in your :term:`Build |
| Directory`. Here is an example showing how to generate spdx files |
| during bitbake using the fossology-python.bbclass:: |
| |
| # Select fossology-python.bbclass. |
| INHERIT += "fossology-python" |
| # For fossology-python.bbclass, TOKEN is necessary, so, after setup a |
| # Fossology server, you have to create a token. |
| TOKEN = "eyJ0eXAiO..." |
| # The fossology server is necessary for fossology-python.bbclass. |
| FOSSOLOGY_SERVER = "http://xx.xx.xx.xx:8081/repo" |
| # If you want to upload the source code to a special folder: |
| FOLDER_NAME = "xxxx" //Optional |
| # If you don't want to put spdx files in tmp/deploy/spdx, you can enable: |
| SPDX_DEPLOY_DIR = "${DEPLOY_DIR}" //Optional |
| |
| For more usage information refer to :yocto_git:`the meta-spdxscanner repository |
| </meta-spdxscanner/>`. |
| |
| Compliance Limitations with Executables Built from Static Libraries |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| When package A is added to an image via the :term:`RDEPENDS` or :term:`RRECOMMENDS` |
| mechanisms as well as explicitly included in the image recipe with |
| :term:`IMAGE_INSTALL`, and depends on a static linked library recipe B |
| (``DEPENDS += "B"``), package B will neither appear in the generated license |
| manifest nor in the generated source tarballs. This occurs as the |
| :ref:`license <ref-classes-license>` and :ref:`archiver <ref-classes-archiver>` |
| classes assume that only packages included via :term:`RDEPENDS` or :term:`RRECOMMENDS` |
| end up in the image. |
| |
| As a result, potential obligations regarding license compliance for package B |
| may not be met. |
| |
| The Yocto Project doesn't enable static libraries by default, in part because |
| of this issue. Before a solution to this limitation is found, you need to |
| keep in mind that if your root filesystem is built from static libraries, |
| you will need to manually ensure that your deliveries are compliant |
| with the licenses of these libraries. |
| |
| Copying Non Standard Licenses |
| ----------------------------- |
| |
| Some packages, such as the linux-firmware package, have many licenses |
| that are not in any way common. You can avoid adding a lot of these |
| types of common license files, which are only applicable to a specific |
| package, by using the |
| :term:`NO_GENERIC_LICENSE` |
| variable. Using this variable also avoids QA errors when you use a |
| non-common, non-CLOSED license in a recipe. |
| |
| Here is an example that uses the ``LICENSE.Abilis.txt`` file as |
| the license from the fetched source:: |
| |
| NO_GENERIC_LICENSE[Firmware-Abilis] = "LICENSE.Abilis.txt" |
| |
| Checking for Vulnerabilities |
| ============================ |
| |
| Vulnerabilities in images |
| ------------------------- |
| |
| The Yocto Project has an infrastructure to track and address unfixed |
| known security vulnerabilities, as tracked by the public |
| `Common Vulnerabilities and Exposures (CVE) <https://en.wikipedia.org/wiki/Common_Vulnerabilities_and_Exposures>`__ |
| database. |
| |
| To know which packages are vulnerable to known security vulnerabilities, |
| add the following setting to your configuration:: |
| |
| INHERIT += "cve-check" |
| |
| This way, at build time, BitBake will warn you about known CVEs |
| as in the example below:: |
| |
| WARNING: flex-2.6.4-r0 do_cve_check: Found unpatched CVE (CVE-2019-6293), for more information check /poky/build/tmp/work/core2-64-poky-linux/flex/2.6.4-r0/temp/cve.log |
| WARNING: libarchive-3.5.1-r0 do_cve_check: Found unpatched CVE (CVE-2021-36976), for more information check /poky/build/tmp/work/core2-64-poky-linux/libarchive/3.5.1-r0/temp/cve.log |
| |
| It is also possible to check the CVE status of individual packages as follows:: |
| |
| bitbake -c cve_check flex libarchive |
| |
| Note that OpenEmbedded-Core keeps a list of known unfixed CVE issues which can |
| be ignored. You can pass this list to the check as follows:: |
| |
| bitbake -c cve_check libarchive -R conf/distro/include/cve-extra-exclusions.inc |
| |
| Enabling vulnerabily tracking in recipes |
| ---------------------------------------- |
| |
| The :term:`CVE_PRODUCT` variable defines the name used to match the recipe name |
| against the name in the upstream `NIST CVE database <https://nvd.nist.gov/>`__. |
| |
| Editing recipes to fix vulnerabilities |
| -------------------------------------- |
| |
| To fix a given known vulnerability, you need to add a patch file to your recipe. Here's |
| an example from the :oe_layerindex:`ffmpeg recipe</layerindex/recipe/47350>`:: |
| |
| SRC_URI = "https://www.ffmpeg.org/releases/${BP}.tar.xz \ |
| file://0001-libavutil-include-assembly-with-full-path-from-sourc.patch \ |
| file://fix-CVE-2020-20446.patch \ |
| file://fix-CVE-2020-20453.patch \ |
| file://fix-CVE-2020-22015.patch \ |
| file://fix-CVE-2020-22021.patch \ |
| file://fix-CVE-2020-22033-CVE-2020-22019.patch \ |
| file://fix-CVE-2021-33815.patch \ |
| |
| The :ref:`cve-check <ref-classes-cve-check>` class defines two ways of |
| supplying a patch for a given CVE. The first |
| way is to use a patch filename that matches the below pattern:: |
| |
| cve_file_name_match = re.compile(".*([Cc][Vv][Ee]\-\d{4}\-\d+)") |
| |
| As shown in the example above, multiple CVE IDs can appear in a patch filename, |
| but the :ref:`cve-check <ref-classes-cve-check>` class will only consider |
| the last CVE ID in the filename as patched. |
| |
| The second way to recognize a patched CVE ID is when a line matching the |
| below pattern is found in any patch file provided by the recipe:: |
| |
| cve_match = re.compile("CVE:( CVE\-\d{4}\-\d+)+") |
| |
| This allows a single patch file to address multiple CVE IDs at the same time. |
| |
| Of course, another way to fix vulnerabilities is to upgrade to a version |
| of the package which is not impacted, typically a more recent one. |
| The NIST database knows which versions are vulnerable and which ones |
| are not. |
| |
| Last but not least, you can choose to ignore vulnerabilities through |
| the :term:`CVE_CHECK_PN_WHITELIST` and :term:`CVE_CHECK_WHITELIST` |
| variables. |
| |
| Implementation details |
| ---------------------- |
| |
| Here's what the :ref:`cve-check <ref-classes-cve-check>` class does to |
| find unpatched CVE IDs. |
| |
| First the code goes through each patch file provided by a recipe. If a valid CVE ID |
| is found in the name of the file, the corresponding CVE is considered as patched. |
| Don't forget that if multiple CVE IDs are found in the filename, only the last |
| one is considered. Then, the code looks for ``CVE: CVE-ID`` lines in the patch |
| file. The found CVE IDs are also considered as patched. |
| |
| Then, the code looks up all the CVE IDs in the NIST database for all the |
| products defined in :term:`CVE_PRODUCT`. Then, for each found CVE: |
| |
| - If the package name (:term:`PN`) is part of |
| :term:`CVE_CHECK_PN_WHITELIST`, it is considered as patched. |
| |
| - If the CVE ID is part of :term:`CVE_CHECK_WHITELIST`, it is |
| considered as patched too. |
| |
| - If the CVE ID is part of the patched CVE for the recipe, it is |
| already considered as patched. |
| |
| - Otherwise, the code checks whether the recipe version (:term:`PV`) |
| is within the range of versions impacted by the CVE. If so, the CVE |
| is considered as unpatched. |
| |
| The CVE database is stored in :term:`DL_DIR` and can be inspected using |
| ``sqlite3`` command as follows:: |
| |
| sqlite3 downloads/CVE_CHECK/nvdcve_1.1.db .dump | grep CVE-2021-37462 |
| |
| Using the Error Reporting Tool |
| ============================== |
| |
| The error reporting tool allows you to submit errors encountered during |
| builds to a central database. Outside of the build environment, you can |
| use a web interface to browse errors, view statistics, and query for |
| errors. The tool works using a client-server system where the client |
| portion is integrated with the installed Yocto Project |
| :term:`Source Directory` (e.g. ``poky``). |
| The server receives the information collected and saves it in a |
| database. |
| |
| There is a live instance of the error reporting server at |
| https://errors.yoctoproject.org. |
| When you want to get help with build failures, you can submit all of the |
| information on the failure easily and then point to the URL in your bug |
| report or send an email to the mailing list. |
| |
| .. note:: |
| |
| If you send error reports to this server, the reports become publicly |
| visible. |
| |
| Enabling and Using the Tool |
| --------------------------- |
| |
| By default, the error reporting tool is disabled. You can enable it by |
| inheriting the |
| :ref:`report-error <ref-classes-report-error>` |
| class by adding the following statement to the end of your |
| ``local.conf`` file in your |
| :term:`Build Directory`. |
| :: |
| |
| INHERIT += "report-error" |
| |
| By default, the error reporting feature stores information in |
| ``${``\ :term:`LOG_DIR`\ ``}/error-report``. |
| However, you can specify a directory to use by adding the following to |
| your ``local.conf`` file:: |
| |
| ERR_REPORT_DIR = "path" |
| |
| Enabling error |
| reporting causes the build process to collect the errors and store them |
| in a file as previously described. When the build system encounters an |
| error, it includes a command as part of the console output. You can run |
| the command to send the error file to the server. For example, the |
| following command sends the errors to an upstream server:: |
| |
| $ send-error-report /home/brandusa/project/poky/build/tmp/log/error-report/error_report_201403141617.txt |
| |
| In the previous example, the errors are sent to a public database |
| available at https://errors.yoctoproject.org, which is used by the |
| entire community. If you specify a particular server, you can send the |
| errors to a different database. Use the following command for more |
| information on available options:: |
| |
| $ send-error-report --help |
| |
| When sending the error file, you are prompted to review the data being |
| sent as well as to provide a name and optional email address. Once you |
| satisfy these prompts, the command returns a link from the server that |
| corresponds to your entry in the database. For example, here is a |
| typical link: https://errors.yoctoproject.org/Errors/Details/9522/ |
| |
| Following the link takes you to a web interface where you can browse, |
| query the errors, and view statistics. |
| |
| Disabling the Tool |
| ------------------ |
| |
| To disable the error reporting feature, simply remove or comment out the |
| following statement from the end of your ``local.conf`` file in your |
| :term:`Build Directory`. |
| :: |
| |
| INHERIT += "report-error" |
| |
| Setting Up Your Own Error Reporting Server |
| ------------------------------------------ |
| |
| If you want to set up your own error reporting server, you can obtain |
| the code from the Git repository at :yocto_git:`/error-report-web/`. |
| Instructions on how to set it up are in the README document. |
| |
| Using Wayland and Weston |
| ======================== |
| |
| `Wayland <https://en.wikipedia.org/wiki/Wayland_(display_server_protocol)>`__ |
| is a computer display server protocol that provides a method for |
| compositing window managers to communicate directly with applications |
| and video hardware and expects them to communicate with input hardware |
| using other libraries. Using Wayland with supporting targets can result |
| in better control over graphics frame rendering than an application |
| might otherwise achieve. |
| |
| The Yocto Project provides the Wayland protocol libraries and the |
| reference |
| `Weston <https://en.wikipedia.org/wiki/Wayland_(display_server_protocol)#Weston>`__ |
| compositor as part of its release. You can find the integrated packages |
| in the ``meta`` layer of the :term:`Source Directory`. |
| Specifically, you |
| can find the recipes that build both Wayland and Weston at |
| ``meta/recipes-graphics/wayland``. |
| |
| You can build both the Wayland and Weston packages for use only with |
| targets that accept the `Mesa 3D and Direct Rendering |
| Infrastructure <https://en.wikipedia.org/wiki/Mesa_(computer_graphics)>`__, |
| which is also known as Mesa DRI. This implies that you cannot build and |
| use the packages if your target uses, for example, the Intel Embedded |
| Media and Graphics Driver (Intel EMGD) that overrides Mesa DRI. |
| |
| .. note:: |
| |
| Due to lack of EGL support, Weston 1.0.3 will not run directly on the |
| emulated QEMU hardware. However, this version of Weston will run |
| under X emulation without issues. |
| |
| This section describes what you need to do to implement Wayland and use |
| the Weston compositor when building an image for a supporting target. |
| |
| Enabling Wayland in an Image |
| ---------------------------- |
| |
| To enable Wayland, you need to enable it to be built and enable it to be |
| included (installed) in the image. |
| |
| Building Wayland |
| ~~~~~~~~~~~~~~~~ |
| |
| To cause Mesa to build the ``wayland-egl`` platform and Weston to build |
| Wayland with Kernel Mode Setting |
| (`KMS <https://wiki.archlinux.org/index.php/Kernel_Mode_Setting>`__) |
| support, include the "wayland" flag in the |
| :term:`DISTRO_FEATURES` |
| statement in your ``local.conf`` file:: |
| |
| DISTRO_FEATURES:append = " wayland" |
| |
| .. note:: |
| |
| If X11 has been enabled elsewhere, Weston will build Wayland with X11 |
| support |
| |
| Installing Wayland and Weston |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| To install the Wayland feature into an image, you must include the |
| following |
| :term:`CORE_IMAGE_EXTRA_INSTALL` |
| statement in your ``local.conf`` file:: |
| |
| CORE_IMAGE_EXTRA_INSTALL += "wayland weston" |
| |
| Running Weston |
| -------------- |
| |
| To run Weston inside X11, enabling it as described earlier and building |
| a Sato image is sufficient. If you are running your image under Sato, a |
| Weston Launcher appears in the "Utility" category. |
| |
| Alternatively, you can run Weston through the command-line interpretor |
| (CLI), which is better suited for development work. To run Weston under |
| the CLI, you need to do the following after your image is built: |
| |
| 1. Run these commands to export ``XDG_RUNTIME_DIR``:: |
| |
| mkdir -p /tmp/$USER-weston |
| chmod 0700 /tmp/$USER-weston |
| export XDG_RUNTIME_DIR=/tmp/$USER-weston |
| |
| 2. Launch Weston in the shell:: |
| |
| weston |