5 Classes
Class files are used to abstract common functionality and share it
amongst multiple recipe (.bb
) files. To use a class file, you simply
make sure the recipe inherits the class. In most cases, when a recipe
inherits a class it is enough to enable its features. There are cases,
however, where in the recipe you might need to set variables or override
some default behavior.
Any Metadata usually found in a recipe can also be
placed in a class file. Class files are identified by the extension
.bbclass
and are usually placed in one of a set of subdirectories
beneath the meta*/
directory found in the Source Directory:
classes-recipe/
- classes intended to be inherited by recipes individually
classes-global/
- classes intended to be inherited globally
classes/
- classes whose usage context is not clearly defined
Class files can also be pointed to by
BUILDDIR (e.g. build/
) in the same way as
.conf
files in the conf
directory. Class files are searched for
in BBPATH using the same method by which .conf
files are searched.
This chapter discusses only the most useful and important classes. Other
classes do exist within the meta/classes*
directories in the Source
Directory. You can reference the .bbclass
files directly for more
information.
5.1 allarch
The allarch class is inherited by recipes that do not produce architecture-specific output. The class disables functionality that is normally needed for recipes that produce executable binaries (such as building the cross-compiler and a C library as pre-requisites, and splitting out of debug symbols during packaging).
Note
Unlike some distro recipes (e.g. Debian), OpenEmbedded recipes that produce packages that depend on tunings through use of the RDEPENDS and TUNE_PKGARCH variables, should never be configured for all architectures using allarch. This is the case even if the recipes do not produce architecture-specific output.
Configuring such recipes for all architectures causes the do_package_write_* tasks to have different signatures for the machines with different tunings. Additionally, unnecessary rebuilds occur every time an image for a different MACHINE is built even when the recipe never changes.
By default, all recipes inherit the base and package classes, which enable functionality needed for recipes that produce executable output. If your recipe, for example, only produces packages that contain configuration files, media files, or scripts (e.g. Python and Perl), then it should inherit the allarch class.
5.2 archiver
The archiver class supports releasing source code and other materials with the binaries.
For more details on the source archiver, see the “Maintaining Open Source License Compliance During Your Product’s Lifecycle” section in the Yocto Project Development Tasks Manual. You can also see the ARCHIVER_MODE variable for information about the variable flags (varflags) that help control archive creation.
5.3 autotools*
The autotools* classes support packages built with the GNU Autotools.
The autoconf
, automake
, and libtool
packages bring
standardization. This class defines a set of tasks (e.g. configure
,
compile
and so forth) that work for all Autotooled packages. It
should usually be enough to define a few standard variables and then
simply inherit autotools
. These classes can also work with software
that emulates Autotools. For more information, see the
“Building an Autotooled Package” section
in the Yocto Project Development Tasks Manual.
By default, the autotools* classes use out-of-tree builds (i.e.
autotools.bbclass
building with B != S
).
If the software being built by a recipe does not support using out-of-tree builds, you should have the recipe inherit the autotools-brokensep class. The autotools-brokensep class behaves the same as the autotools* class but builds with B == S. This method is useful when out-of-tree build support is either not present or is broken.
Note
It is recommended that out-of-tree support be fixed and used if at all possible.
It’s useful to have some idea of how the tasks defined by the autotools* classes work and what they do behind the scenes.
do_configure — regenerates the configure script (using
autoreconf
) and then launches it with a standard set of arguments used during cross-compilation. You can pass additional parameters toconfigure
through the EXTRA_OECONF or PACKAGECONFIG_CONFARGS variables.do_compile — runs
make
with arguments that specify the compiler and linker. You can pass additional arguments through the EXTRA_OEMAKE variable.do_install — runs
make install
and passes in${
D}
asDESTDIR
.
5.4 base
The base class is special in that every .bb
file implicitly
inherits the class. This class contains definitions for standard basic
tasks such as fetching, unpacking, configuring (empty by default),
compiling (runs any Makefile
present), installing (empty by default)
and packaging (empty by default). These tasks are often overridden or
extended by other classes such as the autotools* class or the
package class.
The class also contains some commonly used functions such as
oe_runmake
, which runs make
with the arguments specified in
EXTRA_OEMAKE variable as well as the
arguments passed directly to oe_runmake
.
5.5 bash-completion
Sets up packaging and dependencies appropriate for recipes that build software that includes bash-completion data.
5.6 bin_package
The bin_package class is a helper class for recipes, that disables the do_configure and do_compile tasks and copies the content of the S directory into the D directory. This is useful for installing binary packages (e.g. RPM packages) by passing the package in the SRC_URI variable and inheriting this class.
For RPMs and other packages that do not contain a subdirectory, you should set
the SRC_URI option subdir
to BP so that the contents are
extracted to the directory expected by the default value of S. For
example:
SRC_URI = "https://example.com/downloads/somepackage.rpm;subdir=${BP}"
This class can also be used for tarballs. For example:
SRC_URI = "file://somepackage.tar.xz;subdir=${BP}"
The bin_package class will copy the extracted content of the tarball from S to D.
This class assumes that the content of the package as installed in S
mirrors the expected layout once installed on the target, which is generally the
case for binary packages. For example, an RPM package for a library would
usually contain the usr/lib
directory, and should be extracted to
${S}/usr/lib/<library>.so.<version>
to be installed in D correctly.
Note
The extraction of the package passed in SRC_URI is not handled by the bin_package class, but rather by the appropriate fetcher depending on the file extension.
5.7 binconfig
The binconfig class helps to correct paths in shell scripts.
Before pkg-config
had become widespread, libraries shipped shell
scripts to give information about the libraries and include paths needed
to build software (usually named LIBNAME-config
). This class assists
any recipe using such scripts.
During staging, the OpenEmbedded build system installs such scripts into
the sysroots/
directory. Inheriting this class results in all paths
in these scripts being changed to point into the sysroots/
directory
so that all builds that use the script use the correct directories for
the cross compiling layout. See the
BINCONFIG_GLOB variable for more
information.
5.8 binconfig-disabled
An alternative version of the binconfig
class, which disables binary configuration scripts by making them return
an error in favor of using pkg-config
to query the information. The
scripts to be disabled should be specified using the BINCONFIG
variable within the recipe inheriting the class.
5.9 buildhistory
The buildhistory class records a history of build output metadata, which can be used to detect possible regressions as well as used for analysis of the build output. For more information on using Build History, see the “Maintaining Build Output Quality” section in the Yocto Project Development Tasks Manual.
5.10 buildstats
The buildstats class records performance statistics about each task executed during the build (e.g. elapsed time, CPU usage, and I/O usage).
When you use this class, the output goes into the
BUILDSTATS_BASE directory, which defaults
to ${TMPDIR}/buildstats/
. You can analyze the elapsed time using
scripts/pybootchartgui/pybootchartgui.py
, which produces a cascading
chart of the entire build process and can be useful for highlighting
bottlenecks.
Collecting build statistics is enabled by default through the
USER_CLASSES variable from your
local.conf
file. Consequently, you do not have to do anything to
enable the class. However, if you want to disable the class, simply
remove “buildstats” from the USER_CLASSES list.
5.11 buildstats-summary
When inherited globally, prints statistics at the end of the build on sstate re-use. In order to function, this class requires the buildstats class be enabled.
5.12 cargo
The cargo class allows to compile Rust language programs using Cargo. Cargo is Rust’s package manager, allowing to fetch package dependencies and build your program.
Using this class makes it very easy to build Rust programs. All you need
is to use the SRC_URI variable to point to a source repository
which can be built by Cargo, typically one that was created by the
cargo new
command, containing a Cargo.toml
file, a Cargo.lock
file and a src
subdirectory.
If you want to build and package tests of the program, inherit the ptest-cargo class instead of cargo.
You will find an example (that show also how to handle possible git source dependencies) in the zvariant_3.12.0.bb recipe. Another example, with only crate dependencies, is the uutils-coreutils recipe, which was generated by the cargo-bitbake tool.
This class inherits the cargo_common class.
5.13 cargo_c
The cargo_c class can be inherited by a recipe to generate
a Rust library that can be called by C/C++ code. The recipe which inherits this
class has to only replace inherit cargo
by inherit cargo_c
.
See the rust-c-lib-example_git.bb example recipe.
5.14 cargo_common
The cargo_common class is an internal class that is not intended to be used directly.
An exception is the “rust” recipe, to build the Rust compiler and runtime library, which is built by Cargo but cannot use the cargo class. This is why this class was introduced.
5.15 cargo-update-recipe-crates
The cargo-update-recipe-crates class allows
recipe developers to update the list of Cargo crates in SRC_URI
by reading the Cargo.lock
file in the source tree.
To do so, create a recipe for your program, for example using devtool, make it inherit the cargo and cargo-update-recipe-crates and run:
bitbake -c update_crates recipe
This creates a recipe-crates.inc
file that you can include in your
recipe:
require ${BPN}-crates.inc
That’s also something you can achieve by using the cargo-bitbake tool.
5.16 ccache
The ccache class enables the C/C++ Compiler Cache for the build. This class is used to give a minor performance boost during the build.
See https://ccache.samba.org/ for information on the C/C++ Compiler
Cache, and the ccache.bbclass
file for details about how to enable this mechanism in your configuration
file, how to disable it for specific recipes, and how to share ccache
files between builds.
However, using the class can lead to unexpected side-effects. Thus, using this class is not recommended.
5.17 chrpath
The chrpath class is a wrapper around the “chrpath” utility, which
is used during the build process for nativesdk, cross, and
cross-canadian recipes to change RPATH
records within binaries
in order to make them relocatable.
5.18 cmake
The cmake class allows recipes to build software using the
CMake build system. You can use the
EXTRA_OECMAKE variable to specify additional configuration options to
pass to the cmake
command line.
By default, the cmake class uses
Ninja instead of GNU make for building, which
offers better build performance. If a recipe is broken with Ninja, then the
recipe can set the OECMAKE_GENERATOR variable to Unix Makefiles
to
use GNU make instead.
If you need to install custom CMake toolchain files supplied by the application
being built, you should install them (during do_install) to the
preferred CMake Module directory: ${D}${datadir}/cmake/modules/
.
5.19 cmake-qemu
The cmake-qemu class might be used instead of the
cmake class. In addition to the features provided by the
cmake class, the cmake-qemu class passes
the CMAKE_CROSSCOMPILING_EMULATOR
setting to cmake
. This allows to use
QEMU user-mode emulation for the execution of cross-compiled binaries on the
host machine. For more information about CMAKE_CROSSCOMPILING_EMULATOR
please refer to the related section of the CMake documentation.
Not all platforms are supported by QEMU. This class only works for machines with
qemu-usermode
in the Machine Features. Using QEMU user-mode therefore
involves a certain risk, which is also the reason why this feature is not part of
the main cmake class by default.
One use case is the execution of cross-compiled unit tests with CTest on the build
machine. If CMAKE_CROSSCOMPILING_EMULATOR
is configured:
cmake --build --target test
works transparently with QEMU user-mode.
If the CMake project is developed with this use case in mind this works very nicely.
This also applies to an IDE configured to use cmake-native
for cross-compiling.
5.20 cml1
The cml1 class provides basic support for the Linux kernel style build configuration system. “cml” stands for “Configuration Menu Language”, which originates from the Linux kernel but is also used in other projects such as U-Boot and BusyBox. It could have been called “kconfig” too.
5.21 compress_doc
Enables compression for manual and info pages. This class is intended to be inherited globally. The default compression mechanism is gz (gzip) but you can select an alternative mechanism by setting the DOC_COMPRESS variable.
5.22 copyleft_compliance
The copyleft_compliance class preserves source code for the purposes of license compliance. This class is an alternative to the archiver class and is still used by some users even though it has been deprecated in favor of the archiver class.
5.23 copyleft_filter
A class used by the archiver and
copyleft_compliance classes
for filtering licenses. The copyleft_filter
class is an internal
class and is not intended to be used directly.
5.24 core-image
The core-image class provides common definitions for the
core-image-*
image recipes, such as support for additional
IMAGE_FEATURES.
5.25 cpan*
The cpan* classes support Perl modules.
Recipes for Perl modules are simple. These recipes usually only need to point to the source’s archive and then inherit the proper class file. Building is split into two methods depending on which method the module authors used.
Modules that use old
Makefile.PL
-based build system requirecpan.bbclass
in their recipes.Modules that use
Build.PL
-based build system require usingcpan_build.bbclass
in their recipes.
Both build methods inherit the cpan-base class for basic Perl support.
5.26 create-spdx
The create-spdx class provides support for automatically creating SPDX SBOM documents based upon image and SDK contents.
This class is meant to be inherited globally from a configuration file:
INHERIT += "create-spdx"
The toplevel SPDX output file is generated in JSON format as a
IMAGE-MACHINE.spdx.json
file in tmp/deploy/images/MACHINE/
inside the
Build Directory. There are other related files in the same directory,
as well as in tmp/deploy/spdx
.
The exact behaviour of this class, and the amount of output can be controlled by the SPDX_PRETTY, SPDX_ARCHIVE_PACKAGED, SPDX_ARCHIVE_SOURCES and SPDX_INCLUDE_SOURCES variables.
See the description of these variables and the “Creating a Software Bill of Materials” section in the Yocto Project Development Manual for more details.
5.27 cross
The cross class provides support for the recipes that build the cross-compilation tools.
5.28 cross-canadian
The cross-canadian class provides support for the recipes that build the Canadian Cross-compilation tools for SDKs. See the “Cross-Development Toolchain Generation” section in the Yocto Project Overview and Concepts Manual for more discussion on these cross-compilation tools.
5.29 crosssdk
The crosssdk class provides support for the recipes that build the cross-compilation tools used for building SDKs. See the “Cross-Development Toolchain Generation” section in the Yocto Project Overview and Concepts Manual for more discussion on these cross-compilation tools.
5.30 cve-check
The cve-check class looks for known CVEs (Common Vulnerabilities and Exposures) while building with BitBake. This class is meant to be inherited globally from a configuration file:
INHERIT += "cve-check"
To filter out obsolete CVE database entries which are known not to impact software from Poky and OE-Core, add following line to the build configuration file:
include cve-extra-exclusions.inc
You can also look for vulnerabilities in specific packages by passing
-c cve_check
to BitBake.
After building the software with Bitbake, CVE check output reports are available in tmp/deploy/cve
and image specific summaries in tmp/deploy/images/*.cve
or tmp/deploy/images/*.json
files.
When building, the CVE checker will emit build time warnings for any detected
issues which are in the state Unpatched
, meaning that CVE issue seems to affect the software component
and version being compiled and no patches to address the issue are applied. Other states
for detected CVE issues are: Patched
meaning that a patch to address the issue is already
applied, and Ignored
meaning that the issue can be ignored.
The Patched
state of a CVE issue is detected from patch files with the format
CVE-ID.patch
, e.g. CVE-2019-20633.patch
, in the SRC_URI and using
CVE metadata of format CVE: CVE-ID
in the commit message of the patch file.
Note
Commit message metadata (CVE: CVE-ID
in a patch header) will not be scanned
in any patches that are remote, i.e. that are anything other than local files
referenced via file://
in SRC_URI. However, a CVE-ID
in a remote patch
file name itself will be registered.
If the recipe adds CVE-ID
as flag of the CVE_STATUS variable with status
mapped to Ignored
, then the CVE state is reported as Ignored
:
CVE_STATUS[CVE-2020-15523] = "not-applicable-platform: Issue only applies on Windows"
If CVE check reports that a recipe contains false positives or false negatives, these may be fixed in recipes by adjusting the CVE product name using CVE_PRODUCT and CVE_VERSION variables. CVE_PRODUCT defaults to the plain recipe name BPN which can be adjusted to one or more CVE database vendor and product pairs using the syntax:
CVE_PRODUCT = "flex_project:flex"
where flex_project
is the CVE database vendor name and flex
is the product name. Similarly
if the default recipe version PV does not match the version numbers of the software component
in upstream releases or the CVE database, then the CVE_VERSION variable can be used to set the
CVE database compatible version number, for example:
CVE_VERSION = "2.39"
Any bugs or missing or incomplete information in the CVE database entries should be fixed in the CVE database via the NVD feedback form.
Users should note that security is a process, not a product, and thus also CVE checking, analyzing results, patching and updating the software should be done as a regular process. The data and assumptions required for CVE checker to reliably detect issues are frequently broken in various ways. These can only be detected by reviewing the details of the issues and iterating over the generated reports, and following what happens in other Linux distributions and in the greater open source community.
You will find some more details in the “Checking for Vulnerabilities” section in the Development Tasks Manual.
5.31 debian
The debian class renames output packages so that they follow the
Debian naming policy (i.e. glibc
becomes libc6
and
glibc-devel
becomes libc6-dev
.) Renaming includes the library
name and version as part of the package name.
If a recipe creates packages for multiple libraries (shared object files
of .so
type), use the LEAD_SONAME
variable in the recipe to specify the library on which to apply the
naming scheme.
5.32 deploy
The deploy class handles deploying files to the
DEPLOY_DIR_IMAGE directory. The main
function of this class is to allow the deploy step to be accelerated by
shared state. Recipes that inherit this class should define their own
do_deploy function to copy the files to be
deployed to DEPLOYDIR, and use addtask
to
add the task at the appropriate place, which is usually after
do_compile or
do_install. The class then takes care of
staging the files from DEPLOYDIR to DEPLOY_DIR_IMAGE.
5.33 devicetree
The devicetree class allows to build a recipe that compiles device tree source files that are not in the kernel tree.
The compilation of out-of-tree device tree sources is the same as the kernel
in-tree device tree compilation process. This includes the ability to include
sources from the kernel such as SoC dtsi
files as well as C header files,
such as gpio.h
.
The do_compile task will compile two kinds of files:
Regular device tree sources with a
.dts
extension.Device tree overlays, detected from the presence of the
/plugin/;
string in the file contents.
This class deploys the generated device tree binaries into
${
DEPLOY_DIR_IMAGE}/devicetree/
. This is similar to
what the kernel-devicetree class does, with the added
devicetree
subdirectory to avoid name clashes. Additionally, the device
trees are populated into the sysroot for access via the sysroot from within
other recipes.
By default, all device tree sources located in DT_FILES_PATH directory
are compiled. To select only particular sources, set DT_FILES to
a space-separated list of files (relative to DT_FILES_PATH). For
convenience, both .dts
and .dtb
extensions can be used.
An extra padding is appended to non-overlay device trees binaries. This can typically be used as extra space for adding extra properties at boot time. The padding size can be modified by setting DT_PADDING_SIZE to the desired size, in bytes.
See devicetree.bbclass sources for further variables controlling this class.
Here is an excerpt of an example recipes-kernel/linux/devicetree-acme.bb
recipe inheriting this class:
inherit devicetree
COMPATIBLE_MACHINE = "^mymachine$"
SRC_URI:mymachine = "file://mymachine.dts"
5.34 devshell
The devshell class adds the do_devshell task. Distribution policy dictates whether to include this class. See the “Using a Development Shell” section in the Yocto Project Development Tasks Manual for more information about using devshell.
5.35 devupstream
The devupstream class uses BBCLASSEXTEND to add a variant of the recipe that fetches from an alternative URI (e.g. Git) instead of a tarball. Here is an example:
BBCLASSEXTEND = "devupstream:target"
SRC_URI:class-devupstream = "git://git.example.com/example;branch=main"
SRCREV:class-devupstream = "abcd1234"
Adding the above statements to your recipe creates a variant that has
DEFAULT_PREFERENCE set to “-1”.
Consequently, you need to select the variant of the recipe to use it.
Any development-specific adjustments can be done by using the
class-devupstream
override. Here is an example:
DEPENDS:append:class-devupstream = " gperf-native"
do_configure:prepend:class-devupstream() {
touch ${S}/README
}
The class currently only supports creating a development variant of the target recipe, not native or nativesdk variants.
The BBCLASSEXTEND syntax (i.e. devupstream:target
) provides
support for native and nativesdk variants. Consequently, this
functionality can be added in a future release.
Support for other version control systems such as Subversion is limited
due to BitBake’s automatic fetch dependencies (e.g.
subversion-native
).
5.36 externalsrc
The externalsrc class supports building software from source code that is external to the OpenEmbedded build system. Building software from an external source tree means that the build system’s normal fetch, unpack, and patch process is not used.
By default, the OpenEmbedded build system uses the S and B variables to locate unpacked recipe source code and to build it, respectively. When your recipe inherits the externalsrc class, you use the EXTERNALSRC and EXTERNALSRC_BUILD variables to ultimately define S and B.
By default, this class expects the source code to support recipe builds that use the B variable to point to the directory in which the OpenEmbedded build system places the generated objects built from the recipes. By default, the B directory is set to the following, which is separate from the source directory (S):
${WORKDIR}/${BPN}-{PV}/
See these variables for more information: WORKDIR, BPN, and PV,
For more information on the externalsrc class, see the comments in
meta/classes/externalsrc.bbclass
in the Source Directory.
For information on how to use the externalsrc class, see the
“Building Software from an External Source”
section in the Yocto Project Development Tasks Manual.
5.37 extrausers
The extrausers class allows additional user and group configuration to be applied at the image level. Inheriting this class either globally or from an image recipe allows additional user and group operations to be performed using the EXTRA_USERS_PARAMS variable.
Note
The user and group operations added using the extrausers class are not tied to a specific recipe outside of the recipe for the image. Thus, the operations can be performed across the image as a whole. Use the useradd* class to add user and group configuration to a specific recipe.
Here is an example that uses this class in an image recipe:
inherit extrausers
EXTRA_USERS_PARAMS = "\
useradd -p '' tester; \
groupadd developers; \
userdel nobody; \
groupdel -g video; \
groupmod -g 1020 developers; \
usermod -s /bin/sh tester; \
"
Here is an example that adds two users named “tester-jim” and “tester-sue” and assigns passwords. First on host, create the (escaped) password hash:
printf "%q" $(mkpasswd -m sha256crypt tester01)
The resulting hash is set to a variable and used in useradd
command parameters:
inherit extrausers
PASSWD = "\$X\$ABC123\$A-Long-Hash"
EXTRA_USERS_PARAMS = "\
useradd -p '${PASSWD}' tester-jim; \
useradd -p '${PASSWD}' tester-sue; \
"
Finally, here is an example that sets the root password:
inherit extrausers
EXTRA_USERS_PARAMS = "\
usermod -p '${PASSWD}' root; \
"
Note
From a security perspective, hardcoding a default password is not generally a good idea or even legal in some jurisdictions. It is recommended that you do not do this if you are building a production image.
5.38 features_check
The features_check class allows individual recipes to check for required and conflicting DISTRO_FEATURES, MACHINE_FEATURES or COMBINED_FEATURES.
This class provides support for the following variables:
REQUIRED_MACHINE_FEATURES
CONFLICT_MACHINE_FEATURES
ANY_OF_MACHINE_FEATURES
REQUIRED_COMBINED_FEATURES
CONFLICT_COMBINED_FEATURES
ANY_OF_COMBINED_FEATURES
If any conditions specified in the recipe using the above variables are not met, the recipe will be skipped, and if the build system attempts to build the recipe then an error will be triggered.
5.39 fontcache
The fontcache class generates the proper post-install and
post-remove (postinst and postrm) scriptlets for font packages. These
scriptlets call fc-cache
(part of Fontconfig
) to add the fonts
to the font information cache. Since the cache files are
architecture-specific, fc-cache
runs using QEMU if the postinst
scriptlets need to be run on the build host during image creation.
If the fonts being installed are in packages other than the main package, set FONT_PACKAGES to specify the packages containing the fonts.
5.40 fs-uuid
The fs-uuid class extracts UUID from
${
ROOTFS}
, which must have been built
by the time that this function gets called. The fs-uuid class only
works on ext
file systems and depends on tune2fs
.
5.41 gconf
The gconf class provides common functionality for recipes that need
to install GConf schemas. The schemas will be put into a separate
package (${
PN}-gconf
) that is created
automatically when this class is inherited. This package uses the
appropriate post-install and post-remove (postinst/postrm) scriptlets to
register and unregister the schemas in the target image.
5.42 gettext
The gettext class provides support for building
software that uses the GNU gettext
internationalization and localization
system. All recipes building software that use gettext
should inherit this
class.
5.43 github-releases
For recipes that fetch release tarballs from github, the github-releases
class sets up a standard way for checking available upstream versions
(to support devtool upgrade
and the Automated Upgrade Helper (AUH)).
To use it, add “github-releases” to the inherit line in the recipe,
and if the default value of GITHUB_BASE_URI is not suitable,
then set your own value in the recipe. You should then use ${GITHUB_BASE_URI}
in the value you set for SRC_URI within the recipe.
5.44 gnomebase
The gnomebase class is the base class for recipes that build software from the GNOME stack. This class sets SRC_URI to download the source from the GNOME mirrors as well as extending FILES with the typical GNOME installation paths.
5.45 go
The go class supports building Go programs. The behavior of this class is controlled by the mandatory GO_IMPORT variable, and by the optional GO_INSTALL and GO_INSTALL_FILTEROUT ones.
To build a Go program with the Yocto Project, you can use the go-helloworld_0.1.bb recipe as an example.
5.46 go-mod
The go-mod class allows to use Go modules, and inherits the go class.
See the associated GO_WORKDIR variable.
5.47 go-vendor
The go-vendor class implements support for offline builds, also known as Go vendoring. In such a scenario, the module dependencias are downloaded during the do_fetch task rather than when modules are imported, thus being coherent with Yocto’s concept of fetching every source beforehand.
The dependencies are unpacked into the modules’ vendor
directory, where a
manifest file is generated.
5.48 gobject-introspection
Provides support for recipes building software that supports GObject introspection. This functionality is only enabled if the “gobject-introspection-data” feature is in DISTRO_FEATURES as well as “qemu-usermode” being in MACHINE_FEATURES.
Note
This functionality is backfilled by default and, if not applicable, should be disabled through DISTRO_FEATURES_BACKFILL_CONSIDERED or MACHINE_FEATURES_BACKFILL_CONSIDERED, respectively.
5.49 grub-efi
The grub-efi class provides grub-efi
-specific functions for
building bootable images.
This class supports several variables:
INITRD: Indicates list of filesystem images to concatenate and use as an initial RAM disk (initrd) (optional).
ROOTFS: Indicates a filesystem image to include as the root filesystem (optional).
GRUB_GFXSERIAL: Set this to “1” to have graphics and serial in the boot menu.
LABELS: A list of targets for the automatic configuration.
APPEND: An override list of append strings for each
LABEL
.GRUB_OPTS: Additional options to add to the configuration (optional). Options are delimited using semi-colon characters (
;
).GRUB_TIMEOUT: Timeout before executing the default
LABEL
(optional).
5.50 gsettings
The gsettings class provides common functionality for recipes that need to install GSettings (glib) schemas. The schemas are assumed to be part of the main package. Appropriate post-install and post-remove (postinst/postrm) scriptlets are added to register and unregister the schemas in the target image.
5.51 gtk-doc
The gtk-doc class is a helper class to pull in the appropriate
gtk-doc
dependencies and disable gtk-doc
.
5.52 gtk-icon-cache
The gtk-icon-cache class generates the proper post-install and
post-remove (postinst/postrm) scriptlets for packages that use GTK+ and
install icons. These scriptlets call gtk-update-icon-cache
to add
the fonts to GTK+’s icon cache. Since the cache files are
architecture-specific, gtk-update-icon-cache
is run using QEMU if
the postinst scriptlets need to be run on the build host during image
creation.
5.53 gtk-immodules-cache
The gtk-immodules-cache class generates the proper post-install and
post-remove (postinst/postrm) scriptlets for packages that install GTK+
input method modules for virtual keyboards. These scriptlets call
gtk-update-icon-cache
to add the input method modules to the cache.
Since the cache files are architecture-specific,
gtk-update-icon-cache
is run using QEMU if the postinst scriptlets
need to be run on the build host during image creation.
If the input method modules being installed are in packages other than the main package, set GTKIMMODULES_PACKAGES to specify the packages containing the modules.
5.54 gzipnative
The gzipnative class enables the use of different native versions of
gzip
and pigz
rather than the versions of these tools from the
build host.
5.55 icecc
The icecc class supports Icecream, which facilitates taking compile jobs and distributing them among remote machines.
The class stages directories with symlinks from gcc
and g++
to
icecc
, for both native and cross compilers. Depending on each
configure or compile, the OpenEmbedded build system adds the directories
at the head of the PATH
list and then sets the ICECC_CXX
and
ICECC_CC
variables, which are the paths to the g++
and gcc
compilers, respectively.
For the cross compiler, the class creates a tar.gz
file that
contains the Yocto Project toolchain and sets ICECC_VERSION
, which
is the version of the cross-compiler used in the cross-development
toolchain, accordingly.
The class handles all three different compile stages (i.e native,
cross-kernel and target) and creates the necessary environment
tar.gz
file to be used by the remote machines. The class also
supports SDK generation.
If ICECC_PATH is not set in your
local.conf
file, then the class tries to locate the icecc
binary
using which
. If ICECC_ENV_EXEC is set
in your local.conf
file, the variable should point to the
icecc-create-env
script provided by the user. If you do not point to
a user-provided script, the build system uses the default script
provided by the recipe icecc-create-env_0.1.bb.
Note
This script is a modified version and not the one that comes with
icecream
.
If you do not want the Icecream distributed compile support to apply to
specific recipes or classes, you can ask them to be ignored by Icecream
by listing the recipes and classes using the
ICECC_RECIPE_DISABLE and
ICECC_CLASS_DISABLE variables,
respectively, in your local.conf
file. Doing so causes the
OpenEmbedded build system to handle these compilations locally.
Additionally, you can list recipes using the
ICECC_RECIPE_ENABLE variable in
your local.conf
file to force icecc
to be enabled for recipes
using an empty PARALLEL_MAKE variable.
Inheriting the icecc class changes all sstate signatures. Consequently, if a development team has a dedicated build system that populates SSTATE_MIRRORS and they want to reuse sstate from SSTATE_MIRRORS, then all developers and the build system need to either inherit the icecc class or nobody should.
At the distribution level, you can inherit the icecc class to be sure that all builders start with the same sstate signatures. After inheriting the class, you can then disable the feature by setting the ICECC_DISABLED variable to “1” as follows:
INHERIT_DISTRO:append = " icecc"
ICECC_DISABLED ??= "1"
This practice
makes sure everyone is using the same signatures but also requires
individuals that do want to use Icecream to enable the feature
individually as follows in your local.conf
file:
ICECC_DISABLED = ""
5.56 image
The image class helps support creating images in different formats.
First, the root filesystem is created from packages using one of the
rootfs*.bbclass
files (depending on the package format used) and
then one or more image files are created.
The IMAGE_FSTYPES variable controls the types of images to generate.
The IMAGE_INSTALL variable controls the list of packages to install into the image.
For information on customizing images, see the “Customizing Images” section in the Yocto Project Development Tasks Manual. For information on how images are created, see the “Images” section in the Yocto Project Overview and Concepts Manual.
5.57 image-buildinfo
The image-buildinfo class writes a plain text file containing
build information to the target filesystem at ${sysconfdir}/buildinfo
by default (as specified by IMAGE_BUILDINFO_FILE).
This can be useful for manually determining the origin of any given
image. It writes out two sections:
Build Configuration: a list of variables and their values (specified by IMAGE_BUILDINFO_VARS, which defaults to DISTRO and DISTRO_VERSION)
Layer Revisions: the revisions of all of the layers used in the build.
Additionally, when building an SDK it will write the same contents
to /buildinfo
by default (as specified by
SDK_BUILDINFO_FILE).
5.58 image_types
The image_types class defines all of the standard image output types that you can enable through the IMAGE_FSTYPES variable. You can use this class as a reference on how to add support for custom image output types.
By default, the image class automatically
enables the image_types class. The image class uses the
IMGCLASSES
variable as follows:
IMGCLASSES = "rootfs_${IMAGE_PKGTYPE} image_types ${IMAGE_CLASSES}"
# Only Linux SDKs support populate_sdk_ext, fall back to populate_sdk_base
# in the non-Linux SDK_OS case, such as mingw32
inherit populate_sdk_base
IMGCLASSES += "${@['', 'populate_sdk_ext']['linux' in d.getVar("SDK_OS")]}"
IMGCLASSES += "${@bb.utils.contains_any('IMAGE_FSTYPES', 'live iso hddimg', 'image-live', '', d)}"
IMGCLASSES += "${@bb.utils.contains('IMAGE_FSTYPES', 'container', 'image-container', '', d)}"
IMGCLASSES += "image_types_wic"
IMGCLASSES += "rootfs-postcommands"
IMGCLASSES += "image-postinst-intercepts"
IMGCLASSES += "overlayfs-etc"
inherit_defer ${IMGCLASSES}
The image_types class also handles conversion and compression of images.
Note
To build a VMware VMDK image, you need to add “wic.vmdk” to IMAGE_FSTYPES. This would also be similar for Virtual Box Virtual Disk Image (“vdi”) and QEMU Copy On Write Version 2 (“qcow2”) images.
5.59 image-live
This class controls building “live” (i.e. HDDIMG and ISO) images. Live images contain syslinux for legacy booting, as well as the bootloader specified by EFI_PROVIDER if MACHINE_FEATURES contains “efi”.
Normally, you do not use this class directly. Instead, you add “live” to IMAGE_FSTYPES.
5.60 insane
The insane class adds a step to the package generation process so that output quality assurance checks are generated by the OpenEmbedded build system. A range of checks are performed that check the build’s output for common problems that show up during runtime. Distribution policy usually dictates whether to include this class.
You can configure the sanity checks so that specific test failures either raise a warning or an error message. Typically, failures for new tests generate a warning. Subsequent failures for the same test would then generate an error message once the metadata is in a known and good condition. See the “QA Error and Warning Messages” Chapter for a list of all the warning and error messages you might encounter using a default configuration.
Use the WARN_QA and
ERROR_QA variables to control the behavior of
these checks at the global level (i.e. in your custom distro
configuration). However, to skip one or more checks in recipes, you
should use INSANE_SKIP. For example, to skip
the check for symbolic link .so
files in the main package of a
recipe, add the following to the recipe. You need to realize that the
package name override, in this example ${PN}
, must be used:
INSANE_SKIP:${PN} += "dev-so"
Please keep in mind that the QA checks are meant to detect real or potential problems in the packaged output. So exercise caution when disabling these checks.
The tests you can list with the WARN_QA and ERROR_QA variables are:
already-stripped:
Checks that produced binaries have not already been stripped prior to the build system extracting debug symbols. It is common for upstream software projects to default to stripping debug symbols for output binaries. In order for debugging to work on the target using-dbg
packages, this stripping must be disabled.arch:
Checks the Executable and Linkable Format (ELF) type, bit size, and endianness of any binaries to ensure they match the target architecture. This test fails if any binaries do not match the type since there would be an incompatibility. The test could indicate that the wrong compiler or compiler options have been used. Sometimes software, like bootloaders, might need to bypass this check.buildpaths:
Checks for paths to locations on the build host inside the output files. Not only can these leak information about the build environment, they also hinder binary reproducibility.build-deps:
Determines if a build-time dependency that is specified through DEPENDS, explicit RDEPENDS, or task-level dependencies exists to match any runtime dependency. This determination is particularly useful to discover where runtime dependencies are detected and added during packaging. If no explicit dependency has been specified within the metadata, at the packaging stage it is too late to ensure that the dependency is built, and thus you can end up with an error when the package is installed into the image during the do_rootfs task because the auto-detected dependency was not satisfied. An example of this would be where the update-rc.d class automatically adds a dependency on theinitscripts-functions
package to packages that install an initscript that refers to/etc/init.d/functions
. The recipe should really have an explicit RDEPENDS for the package in question oninitscripts-functions
so that the OpenEmbedded build system is able to ensure that theinitscripts
recipe is actually built and thus theinitscripts-functions
package is made available.configure-gettext:
Checks that if a recipe is building something that uses automake and the automake files contain anAM_GNU_GETTEXT
directive, that the recipe also inherits the gettext class to ensure that gettext is available during the build.compile-host-path:
Checks the do_compile log for indications that paths to locations on the build host were used. Using such paths might result in host contamination of the build output.cve_status_not_in_db:
Checks for each component if CVEs that are ignored via CVE_STATUS, that those are (still) reported for this component in the NIST database. If not, a warning is printed. This check is disabled by default.debug-deps:
Checks that all packages except-dbg
packages do not depend on-dbg
packages, which would cause a packaging bug.debug-files:
Checks for.debug
directories in anything but the-dbg
package. The debug files should all be in the-dbg
package. Thus, anything packaged elsewhere is incorrect packaging.dep-cmp:
Checks for invalid version comparison statements in runtime dependency relationships between packages (i.e. in RDEPENDS, RRECOMMENDS, RSUGGESTS, RPROVIDES, RREPLACES, and RCONFLICTS variable values). Any invalid comparisons might trigger failures or undesirable behavior when passed to the package manager.desktop:
Runs thedesktop-file-validate
program against any.desktop
files to validate their contents against the specification for.desktop
files.dev-deps:
Checks that all packages except-dev
or-staticdev
packages do not depend on-dev
packages, which would be a packaging bug.dev-so:
Checks that the.so
symbolic links are in the-dev
package and not in any of the other packages. In general, these symlinks are only useful for development purposes. Thus, the-dev
package is the correct location for them. In very rare cases, such as dynamically loaded modules, these symlinks are needed instead in the main package.empty-dirs:
Checks that packages are not installing files to directories that are normally expected to be empty (such as/tmp
) The list of directories that are checked is specified by the QA_EMPTY_DIRS variable.file-rdeps:
Checks that file-level dependencies identified by the OpenEmbedded build system at packaging time are satisfied. For example, a shell script might start with the line#!/bin/bash
. This line would translate to a file dependency on/bin/bash
. Of the three package managers that the OpenEmbedded build system supports, only RPM directly handles file-level dependencies, resolving them automatically to packages providing the files. However, the lack of that functionality in the other two package managers does not mean the dependencies do not still need resolving. This QA check attempts to ensure that explicitly declared RDEPENDS exist to handle any file-level dependency detected in packaged files.files-invalid:
Checks for FILES variable values that contain “//”, which is invalid.host-user-contaminated:
Checks that no package produced by the recipe contains any files outside of/home
with a user or group ID that matches the user running BitBake. A match usually indicates that the files are being installed with an incorrect UID/GID, since target IDs are independent from host IDs. For additional information, see the section describing the do_install task.incompatible-license:
Report when packages are excluded from being created due to being marked with a license that is in INCOMPATIBLE_LICENSE.install-host-path:
Checks the do_install log for indications that paths to locations on the build host were used. Using such paths might result in host contamination of the build output.installed-vs-shipped:
Reports when files have been installed within do_install but have not been included in any package by way of the FILES variable. Files that do not appear in any package cannot be present in an image later on in the build process. Ideally, all installed files should be packaged or not installed at all. These files can be deleted at the end of do_install if the files are not needed in any package.invalid-chars:
Checks that the recipe metadata variables DESCRIPTION, SUMMARY, LICENSE, and SECTION do not contain non-UTF-8 characters. Some package managers do not support such characters.invalid-packageconfig:
Checks that no undefined features are being added to PACKAGECONFIG. For example, any name “foo” for which the following form does not exist:PACKAGECONFIG[foo] = "..."
la:
Checks.la
files for any TMPDIR paths. Any.la
file containing these paths is incorrect sincelibtool
adds the correct sysroot prefix when using the files automatically itself.ldflags:
Ensures that the binaries were linked with the LDFLAGS options provided by the build system. If this test fails, check that the LDFLAGS variable is being passed to the linker command.libdir:
Checks for libraries being installed into incorrect (possibly hardcoded) installation paths. For example, this test will catch recipes that install/lib/bar.so
when${base_libdir}
is “lib32”. Another example is when recipes install/usr/lib64/foo.so
when${libdir}
is “/usr/lib”.libexec:
Checks if a package contains files in/usr/libexec
. This check is not performed if thelibexecdir
variable has been set explicitly to/usr/libexec
.mime:
Check that if a package contains mime type files (.xml
files in${datadir}/mime/packages
) that the recipe also inherits the mime class in order to ensure that these get properly installed.mime-xdg:
Checks that if a package contains a .desktop file with a ‘MimeType’ key present, that the recipe inherits the mime-xdg class that is required in order for that to be activated.missing-update-alternatives:
Check that if a recipe sets the ALTERNATIVE variable that the recipe also inherits update-alternatives such that the alternative will be correctly set up.packages-list:
Checks for the same package being listed multiple times through the PACKAGES variable value. Installing the package in this manner can cause errors during packaging.patch-fuzz:
Checks for fuzz in patch files that may allow them to apply incorrectly if the underlying code changes.patch-status:
Checks that theUpstream-Status
is specified and valid in the headers of patches for recipes.pep517-backend:
checks that a recipe inheriting setuptools3 has a PEP517-compliant backend.perllocalpod:
Checks forperllocal.pod
being erroneously installed and packaged by a recipe.perm-config:
Reports lines infs-perms.txt
that have an invalid format.perm-line:
Reports lines infs-perms.txt
that have an invalid format.perm-link:
Reports lines infs-perms.txt
that specify ‘link’ where the specified target already exists.perms:
Currently, this check is unused but reserved.pkgconfig:
Checks.pc
files for any TMPDIR/WORKDIR paths. Any.pc
file containing these paths is incorrect sincepkg-config
itself adds the correct sysroot prefix when the files are accessed.pkgname:
Checks that all packages in PACKAGES have names that do not contain invalid characters (i.e. characters other than 0-9, a-z, ., +, and -).pkgv-undefined:
Checks to see if the PKGV variable is undefined during do_package.pkgvarcheck:
Checks through the variables RDEPENDS, RRECOMMENDS, RSUGGESTS, RCONFLICTS, RPROVIDES, RREPLACES, FILES, ALLOW_EMPTY,pkg_preinst
,pkg_postinst
,pkg_prerm
andpkg_postrm
, and reports if there are variable sets that are not package-specific. Using these variables without a package suffix is bad practice, and might unnecessarily complicate dependencies of other packages within the same recipe or have other unintended consequences.pn-overrides:
Checks that a recipe does not have a name (PN) value that appears in OVERRIDES. If a recipe is named such that its PN value matches something already in OVERRIDES (e.g. PN happens to be the same as MACHINE or DISTRO), it can have unexpected consequences. For example, assignments such asFILES:${PN} = "xyz"
effectively turn intoFILES = "xyz"
.rpaths:
Checks for rpaths in the binaries that contain build system paths such as TMPDIR. If this test fails, bad-rpath
options are being passed to the linker commands and your binaries have potential security issues.shebang-size:
Check that the shebang line (#!
in the first line) in a packaged script is not longer than 128 characters, which can cause an error at runtime depending on the operating system.split-strip:
Reports that splitting or stripping debug symbols from binaries has failed.staticdev:
Checks for static library files (*.a
) in non-staticdev
packages.src-uri-bad:
Checks that the SRC_URI value set by a recipe does not contain a reference to${PN}
(instead of the correct${BPN}
) nor refers to unstable Github archive tarballs.symlink-to-sysroot:
Checks for symlinks in packages that point into TMPDIR on the host. Such symlinks will work on the host, but are clearly invalid when running on the target.textrel:
Checks for ELF binaries that contain relocations in their.text
sections, which can result in a performance impact at runtime. See the explanation for theELF binary
message in “QA Error and Warning Messages” for more information regarding runtime performance issues.unhandled-features-check:
check that if one of the variables that the features_check class supports (e.g. REQUIRED_DISTRO_FEATURES) is set by a recipe, then the recipe also inherits features_check in order for the requirement to actually work.unimplemented-ptest:
Checks that ptests are implemented for upstream tests.unlisted-pkg-lics:
Checks that all declared licenses applying for a package are also declared on the recipe level (i.e. any license inLICENSE:*
should appear in LICENSE).useless-rpaths:
Checks for dynamic library load paths (rpaths) in the binaries that by default on a standard system are searched by the linker (e.g./lib
and/usr/lib
). While these paths will not cause any breakage, they do waste space and are unnecessary.usrmerge:
Ifusrmerge
is in DISTRO_FEATURES, this check will ensure that no package installs files to root (/bin
,/sbin
,/lib
,/lib64
) directories.var-undefined:
Reports when variables fundamental to packaging (i.e. WORKDIR, DEPLOY_DIR, D, PN, and PKGD) are undefined during do_package.version-going-backwards:
If the buildhistory class is enabled, reports when a package being written out has a lower version than the previously written package under the same name. If you are placing output packages into a feed and upgrading packages on a target system using that feed, the version of a package going backwards can result in the target system not correctly upgrading to the “new” version of the package.Note
This is only relevant when you are using runtime package management on your target system.
virtual-slash:
Checks to see ifvirtual/
is being used in RDEPENDS or RPROVIDES, which is not good practice —virtual/
is a convention intended for use in the build context (i.e. PROVIDES and DEPENDS) rather than the runtime context.xorg-driver-abi:
Checks that all packages containing Xorg drivers have ABI dependencies. Thexserver-xorg
recipe provides driver ABI names. All drivers should depend on the ABI versions that they have been built against. Driver recipes that includexorg-driver-input.inc
orxorg-driver-video.inc
will automatically get these versions. Consequently, you should only need to explicitly add dependencies to binary driver recipes.
5.61 kernel
The kernel class handles building Linux kernels. The class contains code to build all kernel trees. All needed headers are staged into the STAGING_KERNEL_DIR directory to allow out-of-tree module builds using the module class.
If a file named defconfig
is listed in SRC_URI, then by default
do_configure copies it as .config
in the build directory,
so it is automatically used as the kernel configuration for the build. This
copy is not performed in case .config
already exists there: this allows
recipes to produce a configuration by other means in
do_configure:prepend
.
Each built kernel module is packaged separately and inter-module
dependencies are created by parsing the modinfo
output. If all modules
are required, then installing the kernel-modules
package installs all
packages with modules and various other kernel packages such as
kernel-vmlinux
.
The kernel class contains logic that allows you to embed an initial RAM filesystem (Initramfs) image when you build the kernel image. For information on how to build an Initramfs, see the “Building an Initial RAM Filesystem (Initramfs) Image” section in the Yocto Project Development Tasks Manual.
Various other classes are used by the kernel and module classes internally including the kernel-arch, module-base, and linux-kernel-base classes.
5.62 kernel-arch
The kernel-arch class sets the ARCH
environment variable for
Linux kernel compilation (including modules).
5.63 kernel-devicetree
The kernel-devicetree class, which is inherited by the kernel class, supports device tree generation.
Its behavior is mainly controlled by the following variables:
KERNEL_DEVICETREE_BUNDLE: whether to bundle the kernel and device tree
KERNEL_DTBDEST: directory where to install DTB files
KERNEL_DTBVENDORED: whether to keep vendor subdirectories
KERNEL_DTC_FLAGS: flags for
dtc
, the Device Tree CompilerKERNEL_PACKAGE_NAME: base name of the kernel packages
5.64 kernel-fitimage
The kernel-fitimage class provides support to pack a kernel image, device trees, a U-boot script, an Initramfs bundle and a RAM disk into a single FIT image. In theory, a FIT image can support any number of kernels, U-boot scripts, Initramfs bundles, RAM disks and device-trees. However, kernel-fitimage currently only supports limited usecases: just one kernel image, an optional U-boot script, an optional Initramfs bundle, an optional RAM disk, and any number of device trees.
To create a FIT image, it is required that KERNEL_CLASSES is set to include “kernel-fitimage” and one of KERNEL_IMAGETYPE, KERNEL_ALT_IMAGETYPE or KERNEL_IMAGETYPES to include “fitImage”.
The options for the device tree compiler passed to mkimage -D
when creating the FIT image are specified using the
UBOOT_MKIMAGE_DTCOPTS variable.
Only a single kernel can be added to the FIT image created by kernel-fitimage and the kernel image in FIT is mandatory. The address where the kernel image is to be loaded by U-Boot is specified by UBOOT_LOADADDRESS and the entrypoint by UBOOT_ENTRYPOINT. Setting FIT_ADDRESS_CELLS to “2” is necessary if such addresses are 64 bit ones.
Multiple device trees can be added to the FIT image created by kernel-fitimage and the device tree is optional. The address where the device tree is to be loaded by U-Boot is specified by UBOOT_DTBO_LOADADDRESS for device tree overlays and by UBOOT_DTB_LOADADDRESS for device tree binaries.
Only a single RAM disk can be added to the FIT image created by kernel-fitimage and the RAM disk in FIT is optional. The address where the RAM disk image is to be loaded by U-Boot is specified by UBOOT_RD_LOADADDRESS and the entrypoint by UBOOT_RD_ENTRYPOINT. The ramdisk is added to the FIT image when INITRAMFS_IMAGE is specified and requires that INITRAMFS_IMAGE_BUNDLE is not set to 1.
Only a single Initramfs bundle can be added to the FIT image created by kernel-fitimage and the Initramfs bundle in FIT is optional. In case of Initramfs, the kernel is configured to be bundled with the root filesystem in the same binary (example: zImage-initramfs-MACHINE.bin). When the kernel is copied to RAM and executed, it unpacks the Initramfs root filesystem. The Initramfs bundle can be enabled when INITRAMFS_IMAGE is specified and requires that INITRAMFS_IMAGE_BUNDLE is set to 1. The address where the Initramfs bundle is to be loaded by U-boot is specified by UBOOT_LOADADDRESS and the entrypoint by UBOOT_ENTRYPOINT.
Only a single U-boot boot script can be added to the FIT image created by kernel-fitimage and the boot script is optional. The boot script is specified in the ITS file as a text file containing U-boot commands. When using a boot script the user should configure the U-boot do_install task to copy the script to sysroot. So the script can be included in the FIT image by the kernel-fitimage class. At run-time, U-boot CONFIG_BOOTCOMMAND define can be configured to load the boot script from the FIT image and execute it.
The FIT image generated by the kernel-fitimage class is signed when the variables UBOOT_SIGN_ENABLE, UBOOT_MKIMAGE_DTCOPTS, UBOOT_SIGN_KEYDIR and UBOOT_SIGN_KEYNAME are set appropriately. The default values used for FIT_HASH_ALG and FIT_SIGN_ALG in kernel-fitimage are “sha256” and “rsa2048” respectively. The keys for signing the FIT image can be generated using the kernel-fitimage class when both FIT_GENERATE_KEYS and UBOOT_SIGN_ENABLE are set to “1”.
5.65 kernel-grub
The kernel-grub class updates the boot area and the boot menu with the kernel as the priority boot mechanism while installing a RPM to update the kernel on a deployed target.
5.66 kernel-module-split
The kernel-module-split class provides common functionality for splitting Linux kernel modules into separate packages.
5.67 kernel-uboot
The kernel-uboot class provides support for building from vmlinux-style kernel sources.
5.68 kernel-uimage
The kernel-uimage class provides support to pack uImage.
5.69 kernel-yocto
The kernel-yocto class provides common functionality for building from linux-yocto style kernel source repositories.
5.70 kernelsrc
The kernelsrc class sets the Linux kernel source and version.
5.71 lib_package
The lib_package class supports recipes that build libraries and
produce executable binaries, where those binaries should not be
installed by default along with the library. Instead, the binaries are
added to a separate ${
PN}-bin
package to
make their installation optional.
5.72 libc*
The libc* classes support recipes that build packages with libc
:
The libc-common class provides common support for building with
libc
.The libc-package class supports packaging up
glibc
andeglibc
.
5.73 license
The license class provides license manifest creation and license exclusion. This class is enabled by default using the default value for the INHERIT_DISTRO variable.
5.74 linux-kernel-base
The linux-kernel-base class provides common functionality for recipes that build out of the Linux kernel source tree. These builds goes beyond the kernel itself. For example, the Perf recipe also inherits this class.
5.75 linuxloader
Provides the function linuxloader()
, which gives the value of the
dynamic loader/linker provided on the platform. This value is used by a
number of other classes.
5.76 logging
The logging class provides the standard shell functions used to log
messages for various BitBake severity levels (i.e. bbplain
,
bbnote
, bbwarn
, bberror
, bbfatal
, and bbdebug
).
This class is enabled by default since it is inherited by the base class.
5.77 meson
The meson class allows to create recipes that build software
using the Meson build system. You can use the
MESON_BUILDTYPE, MESON_TARGET and EXTRA_OEMESON
variables to specify additional configuration options to be passed using the
meson
command line.
5.78 metadata_scm
The metadata_scm class provides functionality for querying the branch and revision of a Source Code Manager (SCM) repository.
The base class uses this class to print the revisions of each layer before starting every build. The metadata_scm class is enabled by default because it is inherited by the base class.
5.79 migrate_localcount
The migrate_localcount class verifies a recipe’s localcount data and increments it appropriately.
5.80 mime
The mime class generates the proper post-install and post-remove
(postinst/postrm) scriptlets for packages that install MIME type files.
These scriptlets call update-mime-database
to add the MIME types to
the shared database.
5.81 mime-xdg
The mime-xdg class generates the proper
post-install and post-remove (postinst/postrm) scriptlets for packages
that install .desktop
files containing MimeType
entries.
These scriptlets call update-desktop-database
to add the MIME types
to the database of MIME types handled by desktop files.
Thanks to this class, when users open a file through a file browser on recently created images, they don’t have to choose the application to open the file from the pool of all known applications, even the ones that cannot open the selected file.
If you have recipes installing their .desktop
files as absolute
symbolic links, the detection of such files cannot be done by the current
implementation of this class. In this case, you have to add the corresponding
package names to the MIME_XDG_PACKAGES variable.
5.82 mirrors
The mirrors class sets up some standard MIRRORS entries for source code mirrors. These mirrors provide a fall-back path in case the upstream source specified in SRC_URI within recipes is unavailable.
This class is enabled by default since it is inherited by the base class.
5.83 module
The module class provides support for building out-of-tree Linux kernel modules. The class inherits the module-base and kernel-module-split classes, and implements the do_compile and do_install tasks. The class provides everything needed to build and package a kernel module.
For general information on out-of-tree Linux kernel modules, see the “Incorporating Out-of-Tree Modules” section in the Yocto Project Linux Kernel Development Manual.
5.84 module-base
The module-base class provides the base functionality for building Linux kernel modules. Typically, a recipe that builds software that includes one or more kernel modules and has its own means of building the module inherits this class as opposed to inheriting the module class.
5.85 multilib*
The multilib* classes provide support for building libraries with different target optimizations or target architectures and installing them side-by-side in the same image.
For more information on using the Multilib feature, see the “Combining Multiple Versions of Library Files into One Image” section in the Yocto Project Development Tasks Manual.
5.86 native
The native class provides common functionality for recipes that build tools to run on the Build Host (i.e. tools that use the compiler or other tools from the build host).
You can create a recipe that builds tools that run natively on the host a couple different ways:
Create a
myrecipe-native.bb
recipe that inherits the native class. If you use this method, you must order the inherit statement in the recipe after all other inherit statements so that the native class is inherited last.Note
When creating a recipe this way, the recipe name must follow this naming convention:
myrecipe-native.bb
Not using this naming convention can lead to subtle problems caused by existing code that depends on that naming convention.
Create or modify a target recipe that contains the following:
BBCLASSEXTEND = "native"
Inside the recipe, use
:class-native
and:class-target
overrides to specify any functionality specific to the respective native or target case.
Although applied differently, the native class is used with both methods. The advantage of the second method is that you do not need to have two separate recipes (assuming you need both) for native and target. All common parts of the recipe are automatically shared.
5.87 nativesdk
The nativesdk class provides common functionality for recipes that wish to build tools to run as part of an SDK (i.e. tools that run on SDKMACHINE).
You can create a recipe that builds tools that run on the SDK machine a couple different ways:
Create a
nativesdk-myrecipe.bb
recipe that inherits the nativesdk class. If you use this method, you must order the inherit statement in the recipe after all other inherit statements so that the nativesdk class is inherited last.Create a nativesdk variant of any recipe by adding the following:
BBCLASSEXTEND = "nativesdk"
Inside the recipe, use
:class-nativesdk
and:class-target
overrides to specify any functionality specific to the respective SDK machine or target case.
Note
When creating a recipe, you must follow this naming convention:
nativesdk-myrecipe.bb
Not doing so can lead to subtle problems because there is code that depends on the naming convention.
Although applied differently, the nativesdk class is used with both methods. The advantage of the second method is that you do not need to have two separate recipes (assuming you need both) for the SDK machine and the target. All common parts of the recipe are automatically shared.
5.88 nopackages
Disables packaging tasks for those recipes and classes where packaging is not needed.
5.89 nospdx
The nospdx allows a recipe to opt out of SPDX generation provided by create-spdx.
5.90 npm
Provides support for building Node.js software fetched using the node package manager (NPM).
Note
Currently, recipes inheriting this class must use the npm://
fetcher to have dependencies fetched and packaged automatically.
For information on how to create NPM packages, see the “Creating Node Package Manager (NPM) Packages” section in the Yocto Project Development Tasks Manual.
5.91 oelint
The oelint class is an obsolete lint checking tool available in
meta/classes
in the Source Directory.
There are some classes that could be generally useful in OE-Core but are never actually used within OE-Core itself. The oelint class is one such example. However, being aware of this class can reduce the proliferation of different versions of similar classes across multiple layers.
5.92 overlayfs
It’s often desired in Embedded System design to have a read-only root filesystem.
But a lot of different applications might want to have read-write access to
some parts of a filesystem. It can be especially useful when your update mechanism
overwrites the whole root filesystem, but you may want your application data to be preserved
between updates. The overlayfs class provides a way
to achieve that by means of overlayfs
and at the same time keeping the base
root filesystem read-only.
To use this class, set a mount point for a partition overlayfs
is going to use as upper
layer in your machine configuration. The underlying file system can be anything that
is supported by overlayfs
. This has to be done in your machine configuration:
OVERLAYFS_MOUNT_POINT[data] = "/data"
Note
QA checks fail to catch file existence if you redefine this variable in your recipe!
Only the existence of the systemd mount unit file is checked, not its contents.
To get more details on
overlayfs
, its internals and supported operations, please refer to the official documentation of the Linux kernel.
The class assumes you have a data.mount
systemd unit defined elsewhere in your BSP
(e.g. in systemd-machine-units
recipe) and it’s installed into the image.
Then you can specify writable directories on a recipe basis (e.g. in my-application.bb):
OVERLAYFS_WRITABLE_PATHS[data] = "/usr/share/my-custom-application"
To support several mount points you can use a different variable flag. Assuming we
want to have a writable location on the file system, but do not need that the data
survives a reboot, then we could have a mnt-overlay.mount
unit for a tmpfs
file system.
In your machine configuration:
OVERLAYFS_MOUNT_POINT[mnt-overlay] = "/mnt/overlay"
and then in your recipe:
OVERLAYFS_WRITABLE_PATHS[mnt-overlay] = "/usr/share/another-application"
On a practical note, your application recipe might require multiple
overlays to be mounted before running to avoid writing to the underlying
file system (which can be forbidden in case of read-only file system)
To achieve that overlayfs provides a systemd
helper service for mounting overlays. This helper service is named
${PN}-overlays.service
and can be depended on in your application recipe
(named application
in the following example) systemd
unit by adding
to the unit the following:
[Unit]
After=application-overlays.service
Requires=application-overlays.service
Note
The class does not support the /etc
directory itself, because systemd
depends on it.
In order to get /etc
in overlayfs, see overlayfs-etc.
5.93 overlayfs-etc
In order to have the /etc
directory in overlayfs a special handling at early
boot stage is required. The idea is to supply a custom init script that mounts
/etc
before launching the actual init program, because the latter already
requires /etc
to be mounted.
Example usage in image recipe:
IMAGE_FEATURES += "overlayfs-etc"
Note
This class must not be inherited directly. Use IMAGE_FEATURES or EXTRA_IMAGE_FEATURES
Your machine configuration should define at least the device, mount point, and file system type
you are going to use for overlayfs
:
OVERLAYFS_ETC_MOUNT_POINT = "/data"
OVERLAYFS_ETC_DEVICE = "/dev/mmcblk0p2"
OVERLAYFS_ETC_FSTYPE ?= "ext4"
To control more mount options you should consider setting mount options
(defaults
is used by default):
OVERLAYFS_ETC_MOUNT_OPTIONS = "wsync"
The class provides two options for /sbin/init
generation:
The default option is to rename the original
/sbin/init
to/sbin/init.orig
and place the generated init under original name, i.e./sbin/init
. It has an advantage that you won’t need to change any kernel parameters in order to make it work, but it poses a restriction that package-management can’t be used, because updating the init manager would remove the generated script.If you wish to keep original init as is, you can set:
OVERLAYFS_ETC_USE_ORIG_INIT_NAME = "0"
Then the generated init will be named
/sbin/preinit
and you would need to extend your kernel parameters manually in your bootloader configuration.
5.94 own-mirrors
The own-mirrors class makes it easier to set up your own PREMIRRORS from which to first fetch source before attempting to fetch it from the upstream specified in SRC_URI within each recipe.
To use this class, inherit it globally and specify SOURCE_MIRROR_URL. Here is an example:
INHERIT += "own-mirrors"
SOURCE_MIRROR_URL = "http://example.com/my-source-mirror"
You can specify only a single URL in SOURCE_MIRROR_URL.
5.95 package
The package class supports generating packages from a build’s
output. The core generic functionality is in package.bbclass
. The
code specific to particular package types resides in these
package-specific classes: package_deb,
package_rpm, package_ipk.
You can control the list of resulting package formats by using the
PACKAGE_CLASSES variable defined in your conf/local.conf
configuration file, which is located in the Build Directory.
When defining the variable, you can specify one or more package types.
Since images are generated from packages, a packaging class is needed
to enable image generation. The first class listed in this variable is
used for image generation.
If you take the optional step to set up a repository (package feed) on the development host that can be used by DNF, you can install packages from the feed while you are running the image on the target (i.e. runtime installation of packages). For more information, see the “Using Runtime Package Management” section in the Yocto Project Development Tasks Manual.
The package-specific class you choose can affect build-time performance and has space ramifications. In general, building a package with IPK takes about thirty percent less time as compared to using RPM to build the same or similar package. This comparison takes into account a complete build of the package with all dependencies previously built. The reason for this discrepancy is because the RPM package manager creates and processes more Metadata than the IPK package manager. Consequently, you might consider setting PACKAGE_CLASSES to “package_ipk” if you are building smaller systems.
Before making your package manager decision, however, you should consider some further things about using RPM:
RPM starts to provide more abilities than IPK due to the fact that it processes more Metadata. For example, this information includes individual file types, file checksum generation and evaluation on install, sparse file support, conflict detection and resolution for Multilib systems, ACID style upgrade, and repackaging abilities for rollbacks.
For smaller systems, the extra space used for the Berkeley Database and the amount of metadata when using RPM can affect your ability to perform on-device upgrades.
You can find additional information on the effects of the package class at these two Yocto Project mailing list links:
5.96 package_deb
The package_deb class provides support for creating packages that
use the Debian (i.e. .deb
) file format. The class ensures the
packages are written out in a .deb
file format to the
${
DEPLOY_DIR_DEB}
directory.
This class inherits the package class and
is enabled through the PACKAGE_CLASSES
variable in the local.conf
file.
5.97 package_ipk
The package_ipk class provides support for creating packages that
use the IPK (i.e. .ipk
) file format. The class ensures the packages
are written out in a .ipk
file format to the
${
DEPLOY_DIR_IPK}
directory.
This class inherits the package class and
is enabled through the PACKAGE_CLASSES
variable in the local.conf
file.
5.98 package_rpm
The package_rpm class provides support for creating packages that
use the RPM (i.e. .rpm
) file format. The class ensures the packages
are written out in a .rpm
file format to the
${
DEPLOY_DIR_RPM}
directory.
This class inherits the package class and
is enabled through the PACKAGE_CLASSES
variable in the local.conf
file.
5.99 packagedata
The packagedata class provides common functionality for reading
pkgdata
files found in PKGDATA_DIR. These
files contain information about each output package produced by the
OpenEmbedded build system.
This class is enabled by default because it is inherited by the package class.
5.100 packagegroup
The packagegroup class sets default values appropriate for package group recipes (e.g. PACKAGES, PACKAGE_ARCH, ALLOW_EMPTY, and so forth). It is highly recommended that all package group recipes inherit this class.
For information on how to use this class, see the “Customizing Images Using Custom Package Groups” section in the Yocto Project Development Tasks Manual.
Previously, this class was called the task
class.
5.101 patch
The patch class provides all functionality for applying patches during the do_patch task.
This class is enabled by default because it is inherited by the base class.
5.102 perlnative
When inherited by a recipe, the perlnative class supports using the native version of Perl built by the build system rather than using the version provided by the build host.
5.103 pypi
The pypi class sets variables appropriately for recipes that build Python modules from PyPI, the Python Package Index. By default it determines the PyPI package name based upon BPN (stripping the “python-” or “python3-” prefix off if present), however in some cases you may need to set it manually in the recipe by setting PYPI_PACKAGE.
Variables set by the pypi class include SRC_URI, SECTION, HOMEPAGE, UPSTREAM_CHECK_URI, UPSTREAM_CHECK_REGEX and CVE_PRODUCT.
5.104 python_flit_core
The python_flit_core class enables building Python modules which declare
the PEP-517 compliant
flit_core.buildapi
build-backend
in the [build-system]
section of pyproject.toml
(See PEP-518).
Python modules built with flit_core.buildapi
are pure Python (no
C
or Rust
extensions).
Internally this uses the python_pep517 class.
5.105 python_maturin
The python_maturin class provides support for python-maturin, a replacement for setuptools_rust and another “backend” for building Python Wheels.
5.106 python_mesonpy
The python_mesonpy class enables building Python modules which use the meson-python build system.
Internally this uses the python_pep517 class.
5.107 python_pep517
The python_pep517 class builds and installs a Python wheel
binary
archive (see PEP-517).
Recipes wouldn’t inherit this directly, instead typically another class will inherit this and add the relevant native dependencies.
Examples of classes which do this are python_flit_core, python_setuptools_build_meta, and python_poetry_core.
5.108 python_poetry_core
The python_poetry_core class enables building Python modules which use the Poetry Core build system.
Internally this uses the python_pep517 class.
5.109 python_pyo3
The python_pyo3 class helps make sure that Python extensions written in Rust and built with PyO3, properly set up the environment for cross compilation.
This class is internal to the python-setuptools3_rust class and is not meant to be used directly in recipes.
5.110 python-setuptools3_rust
The python-setuptools3_rust class enables building Python extensions implemented in Rust with PyO3, which allows to compile and distribute Python extensions written in Rust as easily as if they were written in C.
This class inherits the setuptools3 and python_pyo3 classes.
5.111 pixbufcache
The pixbufcache class generates the proper post-install and
post-remove (postinst/postrm) scriptlets for packages that install
pixbuf loaders, which are used with gdk-pixbuf
. These scriptlets
call update_pixbuf_cache
to add the pixbuf loaders to the cache.
Since the cache files are architecture-specific, update_pixbuf_cache
is run using QEMU if the postinst scriptlets need to be run on the build
host during image creation.
If the pixbuf loaders being installed are in packages other than the recipe’s main package, set PIXBUF_PACKAGES to specify the packages containing the loaders.
5.112 pkgconfig
The pkgconfig class provides a standard way to get header and
library information by using pkg-config
. This class aims to smooth
integration of pkg-config
into libraries that use it.
During staging, BitBake installs pkg-config
data into the
sysroots/
directory. By making use of sysroot functionality within
pkg-config
, the pkgconfig class no longer has to manipulate the
files.
5.113 populate_sdk
The populate_sdk class provides support for SDK-only recipes. For information on advantages gained when building a cross-development toolchain using the do_populate_sdk task, see the “Building an SDK Installer” section in the Yocto Project Application Development and the Extensible Software Development Kit (eSDK) manual.
5.114 populate_sdk_*
The populate_sdk_* classes support SDK creation and consist of the following classes:
populate_sdk_base: The base class supporting SDK creation under all package managers (i.e. DEB, RPM, and opkg).
populate_sdk_deb: Supports creation of the SDK given the Debian package manager.
populate_sdk_rpm: Supports creation of the SDK given the RPM package manager.
populate_sdk_ipk: Supports creation of the SDK given the opkg (IPK format) package manager.
populate_sdk_ext: Supports extensible SDK creation under all package managers.
The populate_sdk_base class inherits the appropriate
populate_sdk_*
(i.e. deb
, rpm
, and ipk
) based on
IMAGE_PKGTYPE.
The base class ensures all source and destination directories are
established and then populates the SDK. After populating the SDK, the
populate_sdk_base class constructs two sysroots:
${
SDK_ARCH}-nativesdk
, which
contains the cross-compiler and associated tooling, and the target,
which contains a target root filesystem that is configured for the SDK
usage. These two images reside in SDK_OUTPUT,
which consists of the following:
${SDK_OUTPUT}/${SDK_ARCH}-nativesdk-pkgs
${SDK_OUTPUT}/${SDKTARGETSYSROOT}/target-pkgs
Finally, the base populate SDK class creates the toolchain environment setup script, the tarball of the SDK, and the installer.
The respective populate_sdk_deb, populate_sdk_rpm, and populate_sdk_ipk classes each support the specific type of SDK. These classes are inherited by and used with the populate_sdk_base class.
For more information on the cross-development toolchain generation, see the “Cross-Development Toolchain Generation” section in the Yocto Project Overview and Concepts Manual. For information on advantages gained when building a cross-development toolchain using the do_populate_sdk task, see the “Building an SDK Installer” section in the Yocto Project Application Development and the Extensible Software Development Kit (eSDK) manual.
5.115 prexport
The prexport class provides functionality for exporting PR values.
Note
This class is not intended to be used directly. Rather, it is enabled
when using “bitbake-prserv-tool export
”.
5.116 primport
The primport class provides functionality for importing PR values.
Note
This class is not intended to be used directly. Rather, it is enabled
when using “bitbake-prserv-tool import
”.
5.117 prserv
The prserv class provides functionality for using a PR service in order to automatically manage the incrementing of the PR variable for each recipe.
This class is enabled by default because it is inherited by the package class. However, the OpenEmbedded build system will not enable the functionality of this class unless PRSERV_HOST has been set.
5.118 ptest
The ptest class provides functionality for packaging and installing runtime tests for recipes that build software that provides these tests.
This class is intended to be inherited by individual recipes. However, the class’ functionality is largely disabled unless “ptest” appears in DISTRO_FEATURES. See the “Testing Packages With ptest” section in the Yocto Project Development Tasks Manual for more information on ptest.
5.119 ptest-cargo
The ptest-cargo class is a class which extends the
cargo class and adds compile_ptest_cargo
and
install_ptest_cargo
steps to respectively build and install
test suites defined in the Cargo.toml
file, into a dedicated
-ptest
package.
5.120 ptest-gnome
Enables package tests (ptests) specifically for GNOME packages, which
have tests intended to be executed with gnome-desktop-testing
.
For information on setting up and running ptests, see the “Testing Packages With ptest” section in the Yocto Project Development Tasks Manual.
5.121 python3-dir
The python3-dir class provides the base version, location, and site package location for Python 3.
5.122 python3native
The python3native class supports using the native version of Python 3 built by the build system rather than support of the version provided by the build host.
5.123 python3targetconfig
The python3targetconfig class supports using the native version of Python
3 built by the build system rather than support of the version provided
by the build host, except that the configuration for the target machine
is accessible (such as correct installation directories). This also adds a
dependency on target python3
, so should only be used where appropriate
in order to avoid unnecessarily lengthening builds.
5.124 qemu
The qemu class provides functionality for recipes that either need QEMU or test for the existence of QEMU. Typically, this class is used to run programs for a target system on the build host using QEMU’s application emulation mode.
5.125 recipe_sanity
The recipe_sanity class checks for the presence of any host system recipe prerequisites that might affect the build (e.g. variables that are set or software that is present).
5.126 relocatable
The relocatable class enables relocation of binaries when they are installed into the sysroot.
This class makes use of the chrpath class and is used by both the cross and native classes.
5.127 remove-libtool
The remove-libtool class adds a post function to the
do_install task to remove all .la
files
installed by libtool
. Removing these files results in them being
absent from both the sysroot and target packages.
If a recipe needs the .la
files to be installed, then the recipe can
override the removal by setting REMOVE_LIBTOOL_LA
to “0” as follows:
REMOVE_LIBTOOL_LA = "0"
Note
The remove-libtool class is not enabled by default.
5.128 report-error
The report-error class supports enabling the error reporting tool”, which allows you to submit build error information to a central database.
The class collects debug information for recipe, recipe version, task,
machine, distro, build system, target system, host distro, branch,
commit, and log. From the information, report files using a JSON format
are created and stored in
${
LOG_DIR}/error-report
.
5.129 retain
The retain class can be used to create a tarball of the work directory for a recipe when one of its tasks fails, or any other nominated directories. It is useful in cases where the environment in which builds are run is ephemeral or otherwise inaccessible for examination during debugging.
To enable, add the following to your configuration:
INHERIT += "retain"
The class can be disabled for specific recipes using the RETAIN_ENABLED variable.
5.130 rm_work
The rm_work class supports deletion of temporary workspace, which can ease your hard drive demands during builds.
The OpenEmbedded build system can use a substantial amount of disk space
during the build process. A portion of this space is the work files
under the ${TMPDIR}/work
directory for each recipe. Once the build
system generates the packages for a recipe, the work files for that
recipe are no longer needed. However, by default, the build system
preserves these files for inspection and possible debugging purposes. If
you would rather have these files deleted to save disk space as the build
progresses, you can enable rm_work by adding the following to
your local.conf
file, which is found in the Build Directory:
INHERIT += "rm_work"
If you are modifying and building source code out of the work directory for a
recipe, enabling rm_work will potentially result in your
changes to the source being lost. To exclude some recipes from having their work
directories deleted by rm_work, you can add the names of the
recipe or recipes you are working on to the RM_WORK_EXCLUDE variable,
which can also be set in your local.conf
file. Here is an example:
RM_WORK_EXCLUDE += "busybox glibc"
5.131 rootfs*
The rootfs* classes support creating the root filesystem for an image and consist of the following classes:
The rootfs-postcommands class, which defines filesystem post-processing functions for image recipes.
The rootfs_deb class, which supports creation of root filesystems for images built using
.deb
packages.The rootfs_rpm class, which supports creation of root filesystems for images built using
.rpm
packages.The rootfs_ipk class, which supports creation of root filesystems for images built using
.ipk
packages.The rootfsdebugfiles class, which installs additional files found on the build host directly into the root filesystem.
The root filesystem is created from packages using one of the rootfs* files as determined by the PACKAGE_CLASSES variable.
For information on how root filesystem images are created, see the “Image Generation” section in the Yocto Project Overview and Concepts Manual.
5.132 rust
The rust class is an internal class which is just used in the “rust” recipe, to build the Rust compiler and runtime library. Except for this recipe, it is not intended to be used directly.
5.133 rust-common
The rust-common class is an internal class to the cargo_common and rust classes and is not intended to be used directly.
5.134 sanity
The sanity class checks to see if prerequisite software is present
on the host system so that users can be notified of potential problems
that might affect their build. The class also performs basic user
configuration checks from the local.conf
configuration file to
prevent common mistakes that cause build failures. Distribution policy
usually determines whether to include this class.
5.135 scons
The scons class supports recipes that need to build software that uses the SCons build system. You can use the EXTRA_OESCONS variable to specify additional configuration options you want to pass SCons command line.
5.136 sdl
The sdl class supports recipes that need to build software that uses the Simple DirectMedia Layer (SDL) library.
5.137 python_setuptools_build_meta
The python_setuptools_build_meta class enables building
Python modules which declare the
PEP-517 compliant
setuptools.build_meta
build-backend
in the [build-system]
section of pyproject.toml
(See PEP-518).
Python modules built with setuptools.build_meta
can be pure Python or
include C
or Rust
extensions).
Internally this uses the python_pep517 class.
5.138 setuptools3
The setuptools3 class supports Python version 3.x extensions
that use build systems based on setuptools
(e.g. only have a setup.py
and have not migrated to the official pyproject.toml
format). If your recipe
uses these build systems, the recipe needs to inherit the
setuptools3 class.
Note
The setuptools3 class do_compile task now calls
setup.py bdist_wheel
to build thewheel
binary archive format (See PEP-427).A consequence of this is that legacy software still using deprecated
distutils
from the Python standard library cannot be packaged aswheels
. A common solution is the replacefrom distutils.core import setup
withfrom setuptools import setup
.Note
The setuptools3 class do_install task now installs the
wheel
binary archive. In current versions ofsetuptools
the legacysetup.py install
method is deprecated. If thesetup.py
cannot be used with wheels, for example it creates files outside of the Python module or standard entry points, then setuptools3_legacy should be used.
5.139 setuptools3_legacy
The setuptools3_legacy class supports
Python version 3.x extensions that use build systems based on setuptools
(e.g. only have a setup.py
and have not migrated to the official
pyproject.toml
format). Unlike setuptools3,
this uses the traditional setup.py
build
and install
commands and
not wheels. This use of setuptools
like this is
deprecated
but still relatively common.
5.140 setuptools3-base
The setuptools3-base class provides a reusable base for
other classes that support building Python version 3.x extensions. If you need
functionality that is not provided by the setuptools3 class,
you may want to inherit setuptools3-base
. Some recipes do not need the tasks
in the setuptools3 class and inherit this class instead.
5.141 sign_rpm
The sign_rpm class supports generating signed RPM packages.
5.142 siteinfo
The siteinfo class provides information about the targets that might be needed by other classes or recipes.
As an example, consider Autotools, which can require tests that must
execute on the target hardware. Since this is not possible in general
when cross compiling, site information is used to provide cached test
results so these tests can be skipped over but still make the correct
values available. The meta/site directory
contains test results
sorted into different categories such as architecture, endianness, and
the libc
used. Site information provides a list of files containing
data relevant to the current build in the CONFIG_SITE variable that
Autotools automatically picks up.
The class also provides variables like SITEINFO_ENDIANNESS and SITEINFO_BITS that can be used elsewhere in the metadata.
5.143 sstate
The sstate class provides support for Shared State (sstate). By default, the class is enabled through the INHERIT_DISTRO variable’s default value.
For more information on sstate, see the “Shared State Cache” section in the Yocto Project Overview and Concepts Manual.
5.144 staging
The staging class installs files into individual recipe work directories for sysroots. The class contains the following key tasks:
The do_populate_sysroot task, which is responsible for handing the files that end up in the recipe sysroots.
The do_prepare_recipe_sysroot task (a “partner” task to the
populate_sysroot
task), which installs the files into the individual recipe work directories (i.e. WORKDIR).
The code in the staging class is complex and basically works in two stages:
Stage One: The first stage addresses recipes that have files they want to share with other recipes that have dependencies on the originating recipe. Normally these dependencies are installed through the do_install task into
${
D}
. The do_populate_sysroot task copies a subset of these files into${SYSROOT_DESTDIR}
. This subset of files is controlled by the SYSROOT_DIRS, SYSROOT_DIRS_NATIVE, and SYSROOT_DIRS_IGNORE variables.Note
Additionally, a recipe can customize the files further by declaring a processing function in the SYSROOT_PREPROCESS_FUNCS variable.
A shared state (sstate) object is built from these files and the files are placed into a subdirectory of build/tmp/sysroots-components/. The files are scanned for hardcoded paths to the original installation location. If the location is found in text files, the hardcoded locations are replaced by tokens and a list of the files needing such replacements is created. These adjustments are referred to as “FIXMEs”. The list of files that are scanned for paths is controlled by the SSTATE_SCAN_FILES variable.
Stage Two: The second stage addresses recipes that want to use something from another recipe and declare a dependency on that recipe through the DEPENDS variable. The recipe will have a do_prepare_recipe_sysroot task and when this task executes, it creates the
recipe-sysroot
andrecipe-sysroot-native
in the recipe work directory (i.e. WORKDIR). The OpenEmbedded build system creates hard links to copies of the relevant files fromsysroots-components
into the recipe work directory.Note
If hard links are not possible, the build system uses actual copies.
The build system then addresses any “FIXMEs” to paths as defined from the list created in the first stage.
Finally, any files in
${bindir}
within the sysroot that have the prefix “postinst-
” are executed.Note
Although such sysroot post installation scripts are not recommended for general use, the files do allow some issues such as user creation and module indexes to be addressed.
Because recipes can have other dependencies outside of DEPENDS (e.g.
do_unpack[depends] += "tar-native:do_populate_sysroot"
), the sysroot creation functionextend_recipe_sysroot
is also added as a pre-function for those tasks whose dependencies are not through DEPENDS but operate similarly.When installing dependencies into the sysroot, the code traverses the dependency graph and processes dependencies in exactly the same way as the dependencies would or would not be when installed from sstate. This processing means, for example, a native tool would have its native dependencies added but a target library would not have its dependencies traversed or installed. The same sstate dependency code is used so that builds should be identical regardless of whether sstate was used or not. For a closer look, see the
setscene_depvalid()
function in the sstate class.The build system is careful to maintain manifests of the files it installs so that any given dependency can be installed as needed. The sstate hash of the installed item is also stored so that if it changes, the build system can reinstall it.
5.145 syslinux
The syslinux class provides syslinux-specific functions for building bootable images.
The class supports the following variables:
INITRD: Indicates list of filesystem images to concatenate and use as an initial RAM disk (initrd). This variable is optional.
ROOTFS: Indicates a filesystem image to include as the root filesystem. This variable is optional.
AUTO_SYSLINUXMENU: Enables creating an automatic menu when set to “1”.
LABELS: Lists targets for automatic configuration.
APPEND: Lists append string overrides for each label.
SYSLINUX_OPTS: Lists additional options to add to the syslinux file. Semicolon characters separate multiple options.
SYSLINUX_SPLASH: Lists a background for the VGA boot menu when you are using the boot menu.
SYSLINUX_DEFAULT_CONSOLE: Set to “console=ttyX” to change kernel boot default console.
SYSLINUX_SERIAL: Sets an alternate serial port. Or, turns off serial when the variable is set with an empty string.
SYSLINUX_SERIAL_TTY: Sets an alternate “console=tty…” kernel boot argument.
5.146 systemd
The systemd class provides support for recipes that install systemd unit files.
The functionality for this class is disabled unless you have “systemd” in DISTRO_FEATURES.
Under this class, the recipe or Makefile (i.e. whatever the recipe is
calling during the do_install task)
installs unit files into
${
D}${systemd_unitdir}/system
. If the unit
files being installed go into packages other than the main package, you
need to set SYSTEMD_PACKAGES in your
recipe to identify the packages in which the files will be installed.
You should set SYSTEMD_SERVICE to the
name of the service file. You should also use a package name override to
indicate the package to which the value applies. If the value applies to
the recipe’s main package, use ${
PN}
. Here
is an example from the connman recipe:
SYSTEMD_SERVICE:${PN} = "connman.service"
Services are set up to start on boot automatically unless you have set SYSTEMD_AUTO_ENABLE to “disable”.
For more information on systemd, see the “Selecting an Initialization Manager” section in the Yocto Project Development Tasks Manual.
5.147 systemd-boot
The systemd-boot class provides functions specific to the systemd-boot bootloader for building bootable images. This is an internal class and is not intended to be used directly.
Note
The systemd-boot class is a result from merging the gummiboot
class
used in previous Yocto Project releases with the systemd
project.
Set the EFI_PROVIDER variable to “systemd-boot” to use this class. Doing so creates a standalone EFI bootloader that is not dependent on systemd.
For information on more variables used and supported in this class, see the SYSTEMD_BOOT_CFG, SYSTEMD_BOOT_ENTRIES, and SYSTEMD_BOOT_TIMEOUT variables.
You can also see the Systemd-boot documentation for more information.
5.148 terminal
The terminal class provides support for starting a terminal session. The OE_TERMINAL variable controls which terminal emulator is used for the session.
Other classes use the terminal class anywhere a separate terminal session needs to be started. For example, the patch class assuming PATCHRESOLVE is set to “user”, the cml1 class, and the devshell class all use the terminal class.
5.149 testimage
The testimage class supports running automated tests against images using QEMU and on actual hardware. The classes handle loading the tests and starting the image. To use the classes, you need to perform steps to set up the environment.
To enable this class, add the following to your configuration:
IMAGE_CLASSES += "testimage"
The tests are commands that run on the target system over ssh
. Each
test is written in Python and makes use of the unittest
module.
The testimage class runs tests on an image when called using the following:
$ bitbake -c testimage image
Alternatively, if you wish to have tests automatically run for each image after it is built, you can set TESTIMAGE_AUTO:
TESTIMAGE_AUTO = "1"
For information on how to enable, run, and create new tests, see the “Performing Automated Runtime Testing” section in the Yocto Project Development Tasks Manual.
5.150 testsdk
This class supports running automated tests against software development kits (SDKs). The testsdk class runs tests on an SDK when called using the following:
$ bitbake -c testsdk image
Note
Best practices include using IMAGE_CLASSES rather than INHERIT to inherit the testsdk class for automated SDK testing.
5.151 texinfo
This class should be inherited by recipes whose upstream packages invoke
the texinfo
utilities at build-time. Native and cross recipes are
made to use the dummy scripts provided by texinfo-dummy-native
, for
improved performance. Target architecture recipes use the genuine
Texinfo utilities. By default, they use the Texinfo utilities on the
host system.
Note
If you want to use the Texinfo recipe shipped with the build system, you can remove “texinfo-native” from ASSUME_PROVIDED and makeinfo from SANITY_REQUIRED_UTILITIES.
5.152 toaster
The toaster class collects information about packages and images and sends them as events that the BitBake user interface can receive. The class is enabled when the Toaster user interface is running.
This class is not intended to be used directly.
5.153 toolchain-scripts
The toolchain-scripts class provides the scripts used for setting up the environment for installed SDKs.
5.154 typecheck
The typecheck class provides support for validating the values of variables set at the configuration level against their defined types. The OpenEmbedded build system allows you to define the type of a variable using the “type” varflag. Here is an example:
IMAGE_FEATURES[type] = "list"
5.155 uboot-config
The uboot-config class provides support for U-Boot configuration for a machine. Specify the machine in your recipe as follows:
UBOOT_CONFIG ??= <default>
UBOOT_CONFIG[foo] = "config,images,binary"
You can also specify the machine using this method:
UBOOT_MACHINE = "config"
See the UBOOT_CONFIG and UBOOT_MACHINE variables for additional information.
5.156 uboot-sign
The uboot-sign class provides support for U-Boot verified boot. It is intended to be inherited from U-Boot recipes.
The variables used by this class are:
SPL_MKIMAGE_DTCOPTS: DTC options for U-Boot
mkimage
when building the FIT image.SPL_SIGN_ENABLE: enable signing the FIT image.
SPL_SIGN_KEYDIR: directory containing the signing keys.
SPL_SIGN_KEYNAME: base filename of the signing keys.
UBOOT_FIT_ADDRESS_CELLS:
#address-cells
value for the FIT image.UBOOT_FIT_DESC: description string encoded into the FIT image.
UBOOT_FIT_GENERATE_KEYS: generate the keys if they don’t exist yet.
UBOOT_FIT_HASH_ALG: hash algorithm for the FIT image.
UBOOT_FIT_KEY_GENRSA_ARGS:
openssl genrsa
arguments.UBOOT_FIT_KEY_REQ_ARGS:
openssl req
arguments.UBOOT_FIT_SIGN_ALG: signature algorithm for the FIT image.
UBOOT_FIT_SIGN_NUMBITS: size of the private key for FIT image signing.
UBOOT_FIT_KEY_SIGN_PKCS: algorithm for the public key certificate for FIT image signing.
UBOOT_FITIMAGE_ENABLE: enable the generation of a U-Boot FIT image.
UBOOT_MKIMAGE_DTCOPTS: DTC options for U-Boot
mkimage
when rebuilding the FIT image containing the kernel.
See U-Boot’s documentation for details about verified boot and the signature process.
See also the description of kernel-fitimage class, which this class imitates.
5.157 uninative
Attempts to isolate the build system from the host distribution’s C
library in order to make re-use of native shared state artifacts across
different host distributions practical. With this class enabled, a
tarball containing a pre-built C library is downloaded at the start of
the build. In the Poky reference distribution this is enabled by default
through meta/conf/distro/include/yocto-uninative.inc
. Other
distributions that do not derive from poky can also
“require conf/distro/include/yocto-uninative.inc
” to use this.
Alternatively if you prefer, you can build the uninative-tarball recipe
yourself, publish the resulting tarball (e.g. via HTTP) and set
UNINATIVE_URL
and UNINATIVE_CHECKSUM
appropriately. For an
example, see the meta/conf/distro/include/yocto-uninative.inc
.
The uninative class is also used unconditionally by the extensible
SDK. When building the extensible SDK, uninative-tarball
is built
and the resulting tarball is included within the SDK.
5.158 update-alternatives
The update-alternatives class helps the alternatives system when
multiple sources provide the same command. This situation occurs when
several programs that have the same or similar function are installed
with the same name. For example, the ar
command is available from
the busybox
, binutils
and elfutils
packages. The
update-alternatives class handles renaming the binaries so that
multiple packages can be installed without conflicts. The ar
command
still works regardless of which packages are installed or subsequently
removed. The class renames the conflicting binary in each package and
symlinks the highest priority binary during installation or removal of
packages.
To use this class, you need to define a number of variables:
These variables list alternative commands needed by a package, provide pathnames for links, default links for targets, and so forth. For details on how to use this class, see the comments in the update-alternatives.bbclass file.
Note
You can use the update-alternatives
command directly in your recipes.
However, this class simplifies things in most cases.
5.159 update-rc.d
The update-rc.d class uses update-rc.d
to safely install an
initialization script on behalf of the package. The OpenEmbedded build
system takes care of details such as making sure the script is stopped
before a package is removed and started when the package is installed.
Three variables control this class: INITSCRIPT_PACKAGES, INITSCRIPT_NAME and INITSCRIPT_PARAMS. See the variable links for details.
5.160 useradd*
The useradd* classes support the addition of users or groups for usage by the package on the target. For example, if you have packages that contain system services that should be run under their own user or group, you can use these classes to enable creation of the user or group. The meta-skeleton/recipes-skeleton/useradd/useradd-example.bb recipe in the Source Directory provides a simple example that shows how to add three users and groups to two packages.
The useradd_base class provides basic functionality for user or groups settings.
The useradd* classes support the USERADD_PACKAGES, USERADD_PARAM, GROUPADD_PARAM, and GROUPMEMS_PARAM variables.
The useradd-staticids class supports the addition of users or groups
that have static user identification (uid
) and group identification
(gid
) values.
The default behavior of the OpenEmbedded build system for assigning
uid
and gid
values when packages add users and groups during
package install time is to add them dynamically. This works fine for
programs that do not care what the values of the resulting users and
groups become. In these cases, the order of the installation determines
the final uid
and gid
values. However, if non-deterministic
uid
and gid
values are a problem, you can override the default,
dynamic application of these values by setting static values. When you
set static values, the OpenEmbedded build system looks in
BBPATH for files/passwd
and files/group
files for the values.
To use static uid
and gid
values, you need to set some variables. See
the USERADDEXTENSION, USERADD_UID_TABLES,
USERADD_GID_TABLES, and USERADD_ERROR_DYNAMIC variables.
You can also see the useradd* class for additional
information.
Note
You do not use the useradd-staticids class directly. You either enable
or disable the class by setting the USERADDEXTENSION variable. If you
enable or disable the class in a configured system, TMPDIR might
contain incorrect uid
and gid
values. Deleting the TMPDIR
directory will correct this condition.
5.161 utility-tasks
The utility-tasks class provides support for various “utility” type tasks that are applicable to all recipes, such as do_clean and do_listtasks.
This class is enabled by default because it is inherited by the base class.
5.162 utils
The utils class provides some useful Python functions that are
typically used in inline Python expressions (e.g. ${@...}
). One
example use is for bb.utils.contains()
.
This class is enabled by default because it is inherited by the base class.
5.163 vala
The vala class supports recipes that need to build software written using the Vala programming language.
5.164 vex
The vex class is used to generate metadata needed by external tools to check for vulnerabilities, for example CVEs. It can be used as a replacement for cve-check.
In order to use this class, inherit the class in the local.conf
file and it
will add the generate_vex
task for every recipe:
INHERIT += "vex"
If an image is built it will generate a report in DEPLOY_DIR_IMAGE for all the packages used, it will also generate a file for all recipes used in the build.
Variables use the CVE_CHECK
prefix to keep compatibility with the
cve-check class.
Example usage:
bitbake -c generate_vex openssl
5.165 waf
The waf class supports recipes that need to build software that uses the Waf build system. You can use the EXTRA_OECONF or PACKAGECONFIG_CONFARGS variables to specify additional configuration options to be passed on the Waf command line.