4 Yocto Project Concepts
This chapter provides explanations for Yocto Project concepts that go beyond the surface of “how-to” information and reference (or look-up) material. Concepts such as components, the OpenEmbedded Build System workflow, cross-development toolchains, shared state cache, and so forth are explained.
4.1 Yocto Project Components
The BitBake task executor together with various types of configuration files form the OpenEmbedded-Core (OE-Core). This section overviews these components by describing their use and how they interact.
BitBake handles the parsing and execution of the data files. The data itself is of various types:
Recipes: Provides details about particular pieces of software.
Class Data: Abstracts common build information (e.g. how to build a Linux kernel).
Configuration Data: Defines machine-specific settings, policy decisions, and so forth. Configuration data acts as the glue to bind everything together.
BitBake knows how to combine multiple data sources together and refers to each data source as a layer. For information on layers, see the “Understanding and Creating Layers” section of the Yocto Project Development Tasks Manual.
Following are some brief details on these core components. For additional information on how these components interact during a build, see the “OpenEmbedded Build System Concepts” section.
4.1.1 BitBake
BitBake is the tool at the heart of the OpenEmbedded Build System and is responsible for parsing the Metadata, generating a list of tasks from it, and then executing those tasks.
This section briefly introduces BitBake. If you want more information on BitBake, see the BitBake User Manual.
To see a list of the options BitBake supports, use either of the following commands:
$ bitbake -h
$ bitbake --help
The most common usage for BitBake is bitbake recipename
, where
recipename
is the name of the recipe you want to build (referred
to as the “target”). The target often equates to the first part of a
recipe’s filename (e.g. “foo” for a recipe named foo_1.3.0-r0.bb
).
So, to process the matchbox-desktop_1.2.3.bb
recipe file, you might
type the following:
$ bitbake matchbox-desktop
Several different
versions of matchbox-desktop
might exist. BitBake chooses the one
selected by the distribution configuration. You can get more details
about how BitBake chooses between different target versions and
providers in the
“Preferences” section
of the BitBake User Manual.
BitBake also tries to execute any dependent tasks first. So for example,
before building matchbox-desktop
, BitBake would build a cross
compiler and glibc
if they had not already been built.
A useful BitBake option to consider is the -k
or --continue
option. This option instructs BitBake to try and continue processing the
job as long as possible even after encountering an error. When an error
occurs, the target that failed and those that depend on it cannot be
remade. However, when you use this option other dependencies can still
be processed.
4.1.2 Recipes
Files that have the .bb
suffix are “recipes” files. In general, a
recipe contains information about a single piece of software. This
information includes the location from which to download the unaltered
source, any source patches to be applied to that source (if needed),
which special configuration options to apply, how to compile the source
files, and how to package the compiled output.
The term “package” is sometimes used to refer to recipes. However, since
the word “package” is used for the packaged output from the OpenEmbedded
build system (i.e. .ipk
or .deb
files), this document avoids
using the term “package” when referring to recipes.
4.1.3 Classes
Class files (.bbclass
) contain information that is useful to share
between recipes files. An example is the
autotools class,
which contains common settings for any application that is built with
the GNU Autotools.
The “Classes” chapter in the Yocto Project
Reference Manual provides details about classes and how to use them.
4.1.4 Configurations
The configuration files (.conf
) define various configuration
variables that govern the OpenEmbedded build process. These files fall
into several areas that define machine configuration options,
distribution configuration options, compiler tuning options, general
common configuration options, and user configuration options in
conf/local.conf
, which is found in the Build Directory.
4.2 Layers
Layers are repositories that contain related metadata (i.e. sets of instructions) that tell the OpenEmbedded build system how to build a target. The Yocto Project Layer Model facilitates collaboration, sharing, customization, and reuse within the Yocto Project development environment. Layers logically separate information for your project. For example, you can use a layer to hold all the configurations for a particular piece of hardware. Isolating hardware-specific configurations allows you to share other metadata by using a different layer where that metadata might be common across several pieces of hardware.
There are many layers working in the Yocto Project development environment. The Yocto Project Compatible Layer Index and OpenEmbedded Layer Index both contain layers from which you can use or leverage.
By convention, layers in the Yocto Project follow a specific form.
Conforming to a known structure allows BitBake to make assumptions
during builds on where to find types of metadata. You can find
procedures and learn about tools (i.e. bitbake-layers
) for creating
layers suitable for the Yocto Project in the
“Understanding and Creating Layers”
section of the Yocto Project Development Tasks Manual.
4.3 OpenEmbedded Build System Concepts
This section takes a more detailed look inside the build process used by the OpenEmbedded Build System, which is the build system specific to the Yocto Project. At the heart of the build system is BitBake, the task executor.
The following diagram represents the high-level workflow of a build. The remainder of this section expands on the fundamental input, output, process, and metadata logical blocks that make up the workflow.
In general, the build’s workflow consists of several functional areas:
User Configuration: metadata you can use to control the build process.
Metadata Layers: Various layers that provide software, machine, and distro metadata.
Source Files: Upstream releases, local projects, and SCMs.
Build System: Processes under the control of BitBake. This block expands on how BitBake fetches source, applies patches, completes compilation, analyzes output for package generation, creates and tests packages, generates images, and generates cross-development tools.
Package Feeds: Directories containing output packages (RPM, DEB or IPK), which are subsequently used in the construction of an image or Software Development Kit (SDK), produced by the build system. These feeds can also be copied and shared using a web server or other means to facilitate extending or updating existing images on devices at runtime if runtime package management is enabled.
Images: Images produced by the workflow.
Application Development SDK: Cross-development tools that are produced along with an image or separately with BitBake.
4.3.1 User Configuration
User configuration helps define the build. Through user configuration, you can tell BitBake the target architecture for which you are building the image, where to store downloaded source, and other build properties.
The following figure shows an expanded representation of the “User Configuration” box of the general workflow figure:
BitBake needs some basic configuration files in order to complete a
build. These files are *.conf
files. The minimally necessary ones
reside as example files in the build/conf
directory of the
Source Directory. For simplicity,
this section refers to the Source Directory as the “Poky Directory.”
When you clone the Poky Git repository
or you download and unpack a Yocto Project release, you can set up the
Source Directory to be named anything you want. For this discussion, the
cloned repository uses the default name poky
.
Note
The Poky repository is primarily an aggregation of existing repositories. It is not a canonical upstream source.
The meta-poky
layer inside Poky contains a conf
directory that
has example configuration files. These example files are used as a basis
for creating actual configuration files when you source
oe-init-build-env, which is the
build environment script.
Sourcing the build environment script creates a
Build Directory if one does not
already exist. BitBake uses the Build Directory for all its work during
builds. The Build Directory has a conf
directory that contains
default versions of your local.conf
and bblayers.conf
configuration files. These default configuration files are created only
if versions do not already exist in the Build Directory at the time you
source the build environment setup script.
Because the Poky repository is fundamentally an aggregation of existing repositories, some users might be familiar with running the oe-init-build-env script in the context of separate OpenEmbedded-Core (OE-Core) and BitBake repositories rather than a single Poky repository. This discussion assumes the script is executed from within a cloned or unpacked version of Poky.
Depending on where the script is sourced, different sub-scripts are
called to set up the Build Directory (Yocto or OpenEmbedded).
Specifically, the script scripts/oe-setup-builddir
inside the poky
directory sets up the Build Directory and seeds the directory (if
necessary) with configuration files appropriate for the Yocto Project
development environment.
Note
The
scripts/oe-setup-builddir
script uses the
$TEMPLATECONF
variable to determine which sample configuration files to locate.
The local.conf
file provides many basic variables that define a
build environment. Here is a list of a few. To see the default
configurations in a local.conf
file created by the build environment
script, see the
local.conf.sample
in the meta-poky
layer:
Target Machine Selection: Controlled by the MACHINE variable.
Download Directory: Controlled by the DL_DIR variable.
Shared State Directory: Controlled by the SSTATE_DIR variable.
Build Output: Controlled by the TMPDIR variable.
Distribution Policy: Controlled by the DISTRO variable.
Packaging Format: Controlled by the PACKAGE_CLASSES variable.
SDK Target Architecture: Controlled by the SDKMACHINE variable.
Extra Image Packages: Controlled by the EXTRA_IMAGE_FEATURES variable.
Note
Configurations set in the conf/local.conf
file can also be set
in the conf/site.conf
and conf/auto.conf
configuration files.
The bblayers.conf
file tells BitBake what layers you want considered
during the build. By default, the layers listed in this file include
layers minimally needed by the build system. However, you must manually
add any custom layers you have created. You can find more information on
working with the bblayers.conf
file in the
“Enabling Your Layer”
section in the Yocto Project Development Tasks Manual.
The files site.conf
and auto.conf
are not created by the
environment initialization script. If you want the site.conf
file,
you need to create it yourself. The auto.conf
file is typically
created by an autobuilder:
site.conf: You can use the
conf/site.conf
configuration file to configure multiple build directories. For example, suppose you had several build environments and they shared some common features. You can set these default build properties here. A good example is perhaps the packaging format to use through the PACKAGE_CLASSES variable.auto.conf: The file is usually created and written to by an autobuilder. The settings put into the file are typically the same as you would find in the
conf/local.conf
or theconf/site.conf
files.
You can edit all configuration files to further define any particular build environment. This process is represented by the “User Configuration Edits” box in the figure.
When you launch your build with the bitbake target
command, BitBake
sorts out the configurations to ultimately define your build
environment. It is important to understand that the
OpenEmbedded Build System reads the
configuration files in a specific order: site.conf
, auto.conf
,
and local.conf
. And, the build system applies the normal assignment
statement rules as described in the
“Syntax and Operators” chapter
of the BitBake User Manual. Because the files are parsed in a specific
order, variable assignments for the same variable could be affected. For
example, if the auto.conf
file and the local.conf
set variable1
to different values, because the build system parses local.conf
after auto.conf
, variable1 is assigned the value from the
local.conf
file.
4.3.2 Metadata, Machine Configuration, and Policy Configuration
The previous section described the user configurations that define BitBake’s global behavior. This section takes a closer look at the layers the build system uses to further control the build. These layers provide Metadata for the software, machine, and policies.
In general, there are three types of layer input. You can see them below the “User Configuration” box in the general workflow figure <overview-manual/concepts:openembedded build system concepts>:
Metadata (.bb + Patches): Software layers containing user-supplied recipe files, patches, and append files. A good example of a software layer might be the meta-qt5 layer from the OpenEmbedded Layer Index. This layer is for version 5.0 of the popular Qt cross-platform application development framework for desktop, embedded and mobile.
Machine BSP Configuration: Board Support Package (BSP) layers (i.e. “BSP Layer” in the following figure) providing machine-specific configurations. This type of information is specific to a particular target architecture. A good example of a BSP layer from the Reference Distribution (Poky) is the meta-yocto-bsp layer.
Policy Configuration: Distribution Layers (i.e. “Distro Layer” in the following figure) providing top-level or general policies for the images or SDKs being built for a particular distribution. For example, in the Poky Reference Distribution the distro layer is the meta-poky layer. Within the distro layer is a
conf/distro
directory that contains distro configuration files (e.g. poky.conf that contain many policy configurations for the Poky distribution.
The following figure shows an expanded representation of these three layers from the general workflow figure:
In general, all layers have a similar structure. They all contain a
licensing file (e.g. COPYING.MIT
) if the layer is to be distributed,
a README
file as good practice and especially if the layer is to be
distributed, a configuration directory, and recipe directories. You can
learn about the general structure for layers used with the Yocto Project
in the
“Creating Your Own Layer”
section in the
Yocto Project Development Tasks Manual. For a general discussion on
layers and the many layers from which you can draw, see the
“Layers” and
“The Yocto Project Layer Model” sections both
earlier in this manual.
If you explored the previous links, you discovered some areas where many layers that work with the Yocto Project exist. The Source Repositories also shows layers categorized under “Yocto Metadata Layers.”
Note
There are layers in the Yocto Project Source Repositories that cannot be found in the OpenEmbedded Layer Index. Such layers are either deprecated or experimental in nature.
BitBake uses the conf/bblayers.conf
file, which is part of the user
configuration, to find what layers it should be using as part of the
build.
4.3.2.1 Distro Layer
The distribution layer provides policy configurations for your
distribution. Best practices dictate that you isolate these types of
configurations into their own layer. Settings you provide in
conf/distro/distro.conf
override similar settings that BitBake finds
in your conf/local.conf
file in the Build Directory.
The following list provides some explanation and references for what you typically find in the distribution layer:
classes: Class files (
.bbclass
) hold common functionality that can be shared among recipes in the distribution. When your recipes inherit a class, they take on the settings and functions for that class. You can read more about class files in the “Classes” chapter of the Yocto Reference Manual.conf: This area holds configuration files for the layer (
conf/layer.conf
), the distribution (conf/distro/distro.conf
), and any distribution-wide include files.recipes-:* Recipes and append files that affect common functionality across the distribution. This area could include recipes and append files to add distribution-specific configuration, initialization scripts, custom image recipes, and so forth. Examples of
recipes-*
directories arerecipes-core
andrecipes-extra
. Hierarchy and contents within arecipes-*
directory can vary. Generally, these directories contain recipe files (*.bb
), recipe append files (*.bbappend
), directories that are distro-specific for configuration files, and so forth.
4.3.2.2 BSP Layer
The BSP Layer provides machine configurations that target specific hardware. Everything in this layer is specific to the machine for which you are building the image or the SDK. A common structure or form is defined for BSP layers. You can learn more about this structure in the Yocto Project Board Support Package Developer’s Guide.
Note
In order for a BSP layer to be considered compliant with the Yocto Project, it must meet some structural requirements.
The BSP Layer’s configuration directory contains configuration files for
the machine (conf/machine/machine.conf
) and, of course, the layer
(conf/layer.conf
).
The remainder of the layer is dedicated to specific recipes by function:
recipes-bsp
, recipes-core
, recipes-graphics
,
recipes-kernel
, and so forth. There can be metadata for multiple
formfactors, graphics support systems, and so forth.
Note
While the figure shows several recipes-* directories, not all these directories appear in all BSP layers.
4.3.2.3 Software Layer
The software layer provides the Metadata for additional software packages used during the build. This layer does not include Metadata that is specific to the distribution or the machine, which are found in their respective layers.
This layer contains any recipes, append files, and patches, that your project needs.
4.3.3 Sources
In order for the OpenEmbedded build system to create an image or any target, it must be able to access source files. The general workflow figure represents source files using the “Upstream Project Releases”, “Local Projects”, and “SCMs (optional)” boxes. The figure represents mirrors, which also play a role in locating source files, with the “Source Materials” box.
The method by which source files are ultimately organized is a function of the project. For example, for released software, projects tend to use tarballs or other archived files that can capture the state of a release guaranteeing that it is statically represented. On the other hand, for a project that is more dynamic or experimental in nature, a project might keep source files in a repository controlled by a Source Control Manager (SCM) such as Git. Pulling source from a repository allows you to control the point in the repository (the revision) from which you want to build software. A combination of the two is also possible.
BitBake uses the SRC_URI variable to point to source files regardless of their location. Each recipe must have a SRC_URI variable that points to the source.
Another area that plays a significant role in where source files come from is pointed to by the DL_DIR variable. This area is a cache that can hold previously downloaded source. You can also instruct the OpenEmbedded build system to create tarballs from Git repositories, which is not the default behavior, and store them in the DL_DIR by using the BB_GENERATE_MIRROR_TARBALLS variable.
Judicious use of a DL_DIR directory can save the build system a trip across the Internet when looking for files. A good method for using a download directory is to have DL_DIR point to an area outside of your Build Directory. Doing so allows you to safely delete the Build Directory if needed without fear of removing any downloaded source file.
The remainder of this section provides a deeper look into the source files and the mirrors. Here is a more detailed look at the source file area of the general workflow figure:
4.3.3.1 Upstream Project Releases
Upstream project releases exist anywhere in the form of an archived file (e.g. tarball or zip file). These files correspond to individual recipes. For example, the figure uses specific releases each for BusyBox, Qt, and Dbus. An archive file can be for any released product that can be built using a recipe.
4.3.3.2 Local Projects
Local projects are custom bits of software the user provides. These bits reside somewhere local to a project — perhaps a directory into which the user checks in items (e.g. a local directory containing a development source tree used by the group).
The canonical method through which to include a local project is to use
the externalsrc
class to include that local project. You use either the local.conf
or a recipe’s append file to override or set the recipe to point to the
local directory on your disk to pull in the whole source tree.
4.3.3.3 Source Control Managers (Optional)
Another place from which the build system can get source files is with Fetchers employing various Source Control Managers (SCMs) such as Git or Subversion. In such cases, a repository is cloned or checked out. The do_fetch task inside BitBake uses the SRC_URI variable and the argument’s prefix to determine the correct fetcher module.
Note
For information on how to have the OpenEmbedded build system generate tarballs for Git repositories and place them in the DL_DIR directory, see the BB_GENERATE_MIRROR_TARBALLS variable in the Yocto Project Reference Manual.
When fetching a repository, BitBake uses the SRCREV variable to determine the specific revision from which to build.
4.3.3.4 Source Mirror(s)
There are two kinds of mirrors: pre-mirrors and regular mirrors. The PREMIRRORS and MIRRORS variables point to these, respectively. BitBake checks pre-mirrors before looking upstream for any source files. Pre-mirrors are appropriate when you have a shared directory that is not a directory defined by the DL_DIR variable. A Pre-mirror typically points to a shared directory that is local to your organization.
Regular mirrors can be any site across the Internet that is used as an alternative location for source code should the primary site not be functioning for some reason or another.
4.3.4 Package Feeds
When the OpenEmbedded build system generates an image or an SDK, it gets the packages from a package feed area located in the Build Directory. The general workflow figure shows this package feeds area in the upper-right corner.
This section looks a little closer into the package feeds area used by the build system. Here is a more detailed look at the area:
Package feeds are an intermediary step in the build process. The OpenEmbedded build system provides classes to generate different package types, and you specify which classes to enable through the PACKAGE_CLASSES variable. Before placing the packages into package feeds, the build process validates them with generated output quality assurance checks through the insane class.
The package feed area resides in the Build Directory. The directory the build system uses to temporarily store packages is determined by a combination of variables and the particular package manager in use. See the “Package Feeds” box in the illustration and note the information to the right of that area. In particular, the following defines where package files are kept:
DEPLOY_DIR: Defined as
tmp/deploy
in the Build Directory.DEPLOY_DIR_*
: Depending on the package manager used, the package type sub-folder. Given RPM, IPK, or DEB packaging and tarball creation, the DEPLOY_DIR_RPM, DEPLOY_DIR_IPK, DEPLOY_DIR_DEB, or DEPLOY_DIR_TAR, variables are used, respectively.PACKAGE_ARCH: Defines architecture-specific sub-folders. For example, packages could be available for the i586 or qemux86 architectures.
BitBake uses the
do_package_write_*
tasks to generate packages and place them into the package holding area
(e.g. do_package_write_ipk
for IPK packages). See the
“do_package_write_deb”,
“do_package_write_ipk”,
“do_package_write_rpm”,
and
“do_package_write_tar”
sections in the Yocto Project Reference Manual for additional
information. As an example, consider a scenario where an IPK packaging
manager is being used and there is package architecture support for both
i586 and qemux86. Packages for the i586 architecture are placed in
build/tmp/deploy/ipk/i586
, while packages for the qemux86
architecture are placed in build/tmp/deploy/ipk/qemux86
.
4.3.5 BitBake Tool
The OpenEmbedded build system uses BitBake to produce images and Software Development Kits (SDKs). You can see from the general workflow figure, the BitBake area consists of several functional areas. This section takes a closer look at each of those areas.
Note
Documentation for the BitBake tool is available separately. See the BitBake User Manual for reference material on BitBake.
4.3.5.1 Source Fetching
The first stages of building a recipe are to fetch and unpack the source code:
The do_fetch and do_unpack tasks fetch the source files and unpack them into the Build Directory.
Note
For every local file (e.g. file://
) that is part of a recipe’s
SRC_URI statement, the OpenEmbedded build system takes a
checksum of the file for the recipe and inserts the checksum into
the signature for the do_fetch task. If any local
file has been modified, the do_fetch task and all
tasks that depend on it are re-executed.
By default, everything is accomplished in the Build Directory, which has a defined structure. For additional general information on the Build Directory, see the “build/” section in the Yocto Project Reference Manual.
Each recipe has an area in the Build Directory where the unpacked source code resides. The S variable points to this area for a recipe’s unpacked source code. The name of that directory for any given recipe is defined from several different variables. The preceding figure and the following list describe the Build Directory’s hierarchy:
TMPDIR: The base directory where the OpenEmbedded build system performs all its work during the build. The default base directory is the
tmp
directory.PACKAGE_ARCH: The architecture of the built package or packages. Depending on the eventual destination of the package or packages (i.e. machine architecture, Build Host, SDK, or specific machine), PACKAGE_ARCH varies. See the variable’s description for details.
TARGET_OS: The operating system of the target device. A typical value would be “linux” (e.g. “qemux86-poky-linux”).
PN: The name of the recipe used to build the package. This variable can have multiple meanings. However, when used in the context of input files, PN represents the name of the recipe.
WORKDIR: The location where the OpenEmbedded build system builds a recipe (i.e. does the work to create the package).
S: Contains the unpacked source files for a given recipe.
Note
In the previous figure, notice that there are two sample hierarchies: one based on package architecture (i.e. PACKAGE_ARCH) and one based on a machine (i.e. MACHINE). The underlying structures are identical. The differentiator being what the OpenEmbedded build system is using as a build target (e.g. general architecture, a build host, an SDK, or a specific machine).
4.3.5.2 Patching
Once source code is fetched and unpacked, BitBake locates patch files and applies them to the source files:
The do_patch task uses a recipe’s SRC_URI statements and the FILESPATH variable to locate applicable patch files.
Default processing for patch files assumes the files have either
*.patch
or *.diff
file types. You can use SRC_URI parameters
to change the way the build system recognizes patch files. See the
do_patch task for more
information.
BitBake finds and applies multiple patches for a single recipe in the order in which it locates the patches. The FILESPATH variable defines the default set of directories that the build system uses to search for patch files. Once found, patches are applied to the recipe’s source files, which are located in the S directory.
For more information on how the source directories are created, see the “Source Fetching” section. For more information on how to create patches and how the build system processes patches, see the “Patching Code” section in the Yocto Project Development Tasks Manual. You can also see the “Use devtool modify to Modify the Source of an Existing Component” section in the Yocto Project Application Development and the Extensible Software Development Kit (SDK) manual and the “Using Traditional Kernel Development to Patch the Kernel” section in the Yocto Project Linux Kernel Development Manual.
4.3.5.3 Configuration, Compilation, and Staging
After source code is patched, BitBake executes tasks that configure and compile the source code. Once compilation occurs, the files are copied to a holding area (staged) in preparation for packaging:
This step in the build process consists of the following tasks:
do_prepare_recipe_sysroot: This task sets up the two sysroots in
${
WORKDIR}
(i.e.recipe-sysroot
andrecipe-sysroot-native
) so that during the packaging phase the sysroots can contain the contents of the do_populate_sysroot tasks of the recipes on which the recipe containing the tasks depends. A sysroot exists for both the target and for the native binaries, which run on the host system.do_configure: This task configures the source by enabling and disabling any build-time and configuration options for the software being built. Configurations can come from the recipe itself as well as from an inherited class. Additionally, the software itself might configure itself depending on the target for which it is being built.
The configurations handled by the do_configure task are specific to configurations for the source code being built by the recipe.
If you are using the autotools class, you can add additional configuration options by using the EXTRA_OECONF or PACKAGECONFIG_CONFARGS variables. For information on how this variable works within that class, see the autotools class here.
do_compile: Once a configuration task has been satisfied, BitBake compiles the source using the do_compile task. Compilation occurs in the directory pointed to by the B variable. Realize that the B directory is, by default, the same as the S directory.
do_install: After compilation completes, BitBake executes the do_install task. This task copies files from the B directory and places them in a holding area pointed to by the D variable. Packaging occurs later using files from this holding directory.
4.3.5.4 Package Splitting
After source code is configured, compiled, and staged, the build system analyzes the results and splits the output into packages:
The do_package and do_packagedata tasks combine to analyze the files found in the D directory and split them into subsets based on available packages and files. Analysis involves the following as well as other items: splitting out debugging symbols, looking at shared library dependencies between packages, and looking at package relationships.
The do_packagedata task creates package metadata based on the analysis such that the build system can generate the final packages. The do_populate_sysroot task stages (copies) a subset of the files installed by the do_install task into the appropriate sysroot. Working, staged, and intermediate results of the analysis and package splitting process use several areas:
PKGD: The destination directory (i.e.
package
) for packages before they are split into individual packages.PKGDESTWORK: A temporary work area (i.e.
pkgdata
) used by the do_package task to save package metadata.PKGDEST: The parent directory (i.e.
packages-split
) for packages after they have been split.PKGDATA_DIR: A shared, global-state directory that holds packaging metadata generated during the packaging process. The packaging process copies metadata from PKGDESTWORK to the PKGDATA_DIR area where it becomes globally available.
STAGING_DIR_HOST: The path for the sysroot for the system on which a component is built to run (i.e.
recipe-sysroot
).STAGING_DIR_NATIVE: The path for the sysroot used when building components for the build host (i.e.
recipe-sysroot-native
).STAGING_DIR_TARGET: The path for the sysroot used when a component that is built to execute on a system and it generates code for yet another machine (e.g. cross-canadian recipes).
The FILES variable defines the files that go into each package in PACKAGES. If you want details on how this is accomplished, you can look at package.bbclass.
Depending on the type of packages being created (RPM, DEB, or IPK), the
do_package_write_*
task creates the actual packages and places them in the Package Feed
area, which is ${TMPDIR}/deploy
. You can see the
“Package Feeds” section for more detail on
that part of the build process.
Note
Support for creating feeds directly from the deploy/*
directories does not exist. Creating such feeds usually requires some
kind of feed maintenance mechanism that would upload the new packages
into an official package feed (e.g. the Ångström distribution). This
functionality is highly distribution-specific and thus is not
provided out of the box.
4.3.5.5 Image Generation
Once packages are split and stored in the Package Feeds area, the build system uses BitBake to generate the root filesystem image:
The image generation process consists of several stages and depends on several tasks and variables. The do_rootfs task creates the root filesystem (file and directory structure) for an image. This task uses several key variables to help create the list of packages to actually install:
IMAGE_INSTALL: Lists out the base set of packages from which to install from the Package Feeds area.
PACKAGE_EXCLUDE: Specifies packages that should not be installed into the image.
IMAGE_FEATURES: Specifies features to include in the image. Most of these features map to additional packages for installation.
PACKAGE_CLASSES: Specifies the package backend (e.g. RPM, DEB, or IPK) to use and consequently helps determine where to locate packages within the Package Feeds area.
IMAGE_LINGUAS: Determines the language(s) for which additional language support packages are installed.
PACKAGE_INSTALL: The final list of packages passed to the package manager for installation into the image.
With IMAGE_ROOTFS pointing to the location of the filesystem under construction and the PACKAGE_INSTALL variable providing the final list of packages to install, the root file system is created.
Package installation is under control of the package manager (e.g. dnf/rpm, opkg, or apt/dpkg) regardless of whether or not package management is enabled for the target. At the end of the process, if package management is not enabled for the target, the package manager’s data files are deleted from the root filesystem. As part of the final stage of package installation, post installation scripts that are part of the packages are run. Any scripts that fail to run on the build host are run on the target when the target system is first booted. If you are using a read-only root filesystem, all the post installation scripts must succeed on the build host during the package installation phase since the root filesystem on the target is read-only.
The final stages of the do_rootfs task handle post processing. Post processing includes creation of a manifest file and optimizations.
The manifest file (.manifest
) resides in the same directory as the
root filesystem image. This file lists out, line-by-line, the installed
packages. The manifest file is useful for the
testimage class,
for example, to determine whether or not to run specific tests. See the
IMAGE_MANIFEST
variable for additional information.
Optimizing processes that are run across the image include mklibs
and any other post-processing commands as defined by the
ROOTFS_POSTPROCESS_COMMAND
variable. The mklibs
process optimizes the size of the libraries.
After the root filesystem is built, processing begins on the image through the do_image task. The build system runs any pre-processing commands as defined by the IMAGE_PREPROCESS_COMMAND variable. This variable specifies a list of functions to call before the build system creates the final image output files.
The build system dynamically creates do_image_* tasks as needed, based on the image types specified in the IMAGE_FSTYPES variable. The process turns everything into an image file or a set of image files and can compress the root filesystem image to reduce the overall size of the image. The formats used for the root filesystem depend on the IMAGE_FSTYPES variable. Compression depends on whether the formats support compression.
As an example, a dynamically created task when creating a particular image type would take the following form:
do_image_type
So, if the type
as specified by the IMAGE_FSTYPES were ext4
, the dynamically
generated task would be as follows:
do_image_ext4
The final task involved in image creation is the do_image_complete task. This task completes the image by applying any image post processing as defined through the IMAGE_POSTPROCESS_COMMAND variable. The variable specifies a list of functions to call once the build system has created the final image output files.
Note
The entire image generation process is run under Pseudo. Running under Pseudo ensures that the files in the root filesystem have correct ownership.
4.3.5.6 SDK Generation
The OpenEmbedded build system uses BitBake to generate the Software Development Kit (SDK) installer scripts for both the standard SDK and the extensible SDK (eSDK):
Note
For more information on the cross-development toolchain generation, see the “Cross-Development Toolchain Generation” section. 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.
Like image generation, the SDK script process consists of several stages and depends on many variables. The do_populate_sdk and do_populate_sdk_ext tasks use these key variables to help create the list of packages to actually install. For information on the variables listed in the figure, see the “Application Development SDK” section.
The do_populate_sdk task helps create the standard SDK and handles two parts: a target part and a host part. The target part is the part built for the target hardware and includes libraries and headers. The host part is the part of the SDK that runs on the SDKMACHINE.
The do_populate_sdk_ext task helps create the extensible SDK and handles host and target parts differently than its counter part does for the standard SDK. For the extensible SDK, the task encapsulates the build system, which includes everything needed (host and target) for the SDK.
Regardless of the type of SDK being constructed, the tasks perform some
cleanup after which a cross-development environment setup script and any
needed configuration files are created. The final output is the
Cross-development toolchain installation script (.sh
file), which
includes the environment setup script.
4.3.5.7 Stamp Files and the Rerunning of Tasks
For each task that completes successfully, BitBake writes a stamp file into the STAMPS_DIR directory. The beginning of the stamp file’s filename is determined by the STAMP variable, and the end of the name consists of the task’s name and current input checksum.
Note
This naming scheme assumes that BB_SIGNATURE_HANDLER is “OEBasicHash”, which is almost always the case in current OpenEmbedded.
To determine if a task needs to be rerun, BitBake checks if a stamp file with a matching input checksum exists for the task. In this case, the task’s output is assumed to exist and still be valid. Otherwise, the task is rerun.
Note
The stamp mechanism is more general than the shared state (sstate) cache mechanism described in the “Setscene Tasks and Shared State” section. BitBake avoids rerunning any task that has a valid stamp file, not just tasks that can be accelerated through the sstate cache.
However, you should realize that stamp files only serve as a marker that some work has been done and that these files do not record task output. The actual task output would usually be somewhere in TMPDIR (e.g. in some recipe’s WORKDIR.) What the sstate cache mechanism adds is a way to cache task output that can then be shared between build machines.
Since STAMPS_DIR is usually a subdirectory of TMPDIR, removing TMPDIR will also remove STAMPS_DIR, which means tasks will properly be rerun to repopulate TMPDIR.
If you want some task to always be considered “out of date”, you can mark it with the nostamp varflag. If some other task depends on such a task, then that task will also always be considered out of date, which might not be what you want.
For details on how to view information about a task’s signature, see the “Viewing Task Variable Dependencies” section in the Yocto Project Development Tasks Manual.
4.3.6 Images
The images produced by the build system are compressed forms of the root filesystem and are ready to boot on a target device. You can see from the general workflow figure that BitBake output, in part, consists of images. This section takes a closer look at this output:
Note
For a list of example images that the Yocto Project provides, see the “Images” chapter in the Yocto Project Reference Manual.
The build process writes images out to the Build Directory
inside the
tmp/deploy/images/machine/
folder as shown in the figure. This
folder contains any files expected to be loaded on the target device.
The DEPLOY_DIR variable
points to the deploy
directory, while the
DEPLOY_DIR_IMAGE
variable points to the appropriate directory containing images for the
current configuration.
kernel-image: A kernel binary file. The KERNEL_IMAGETYPE variable determines the naming scheme for the kernel image file. Depending on this variable, the file could begin with a variety of naming strings. The
deploy/images/
machine directory can contain multiple image files for the machine.root-filesystem-image: Root filesystems for the target device (e.g.
*.ext3
or*.bz2
files). The IMAGE_FSTYPES variable determines the root filesystem image type. Thedeploy/images/
machine directory can contain multiple root filesystems for the machine.kernel-modules: Tarballs that contain all the modules built for the kernel. Kernel module tarballs exist for legacy purposes and can be suppressed by setting the MODULE_TARBALL_DEPLOY variable to “0”. The
deploy/images/
machine directory can contain multiple kernel module tarballs for the machine.bootloaders: If applicable to the target machine, bootloaders supporting the image. The
deploy/images/
machine directory can contain multiple bootloaders for the machine.symlinks: The
deploy/images/
machine folder contains a symbolic link that points to the most recently built file for each machine. These links might be useful for external scripts that need to obtain the latest version of each file.
4.3.7 Application Development SDK
In the general workflow figure, the
output labeled “Application Development SDK” represents an SDK. The SDK
generation process differs depending on whether you build an extensible
SDK (e.g. bitbake -c populate_sdk_ext
imagename) or a standard SDK
(e.g. bitbake -c populate_sdk
imagename). This section takes a
closer look at this output:
The specific form of this output is a set of files that includes a
self-extracting SDK installer (*.sh
), host and target manifest
files, and files used for SDK testing. When the SDK installer file is
run, it installs the SDK. The SDK consists of a cross-development
toolchain, a set of libraries and headers, and an SDK environment setup
script. Running this installer essentially sets up your
cross-development environment. You can think of the cross-toolchain as
the “host” part because it runs on the SDK machine. You can think of the
libraries and headers as the “target” part because they are built for
the target hardware. The environment setup script is added so that you
can initialize the environment before using the tools.
Note
The Yocto Project supports several methods by which you can set up this cross-development environment. These methods include downloading pre-built SDK installers or building and installing your own SDK installer.
For background information on cross-development toolchains in the Yocto Project development environment, see the “Cross-Development Toolchain Generation” section.
For information on setting up a cross-development environment, see the Yocto Project Application Development and the Extensible Software Development Kit (eSDK) manual.
All the output files for an SDK are written to the deploy/sdk
folder
inside the Build Directory as
shown in the previous figure. Depending on the type of SDK, there are
several variables to configure these files. Here are the variables
associated with an extensible SDK:
DEPLOY_DIR: Points to the
deploy
directory.SDK_EXT_TYPE: Controls whether or not shared state artifacts are copied into the extensible SDK. By default, all required shared state artifacts are copied into the SDK.
SDK_INCLUDE_PKGDATA: Specifies whether or not packagedata is included in the extensible SDK for all recipes in the “world” target.
SDK_INCLUDE_TOOLCHAIN: Specifies whether or not the toolchain is included when building the extensible SDK.
ESDK_LOCALCONF_ALLOW: A list of variables allowed through from the build system configuration into the extensible SDK configuration.
ESDK_LOCALCONF_REMOVE: A list of variables not allowed through from the build system configuration into the extensible SDK configuration.
ESDK_CLASS_INHERIT_DISABLE: A list of classes to remove from the INHERIT value globally within the extensible SDK configuration.
This next list, shows the variables associated with a standard SDK:
DEPLOY_DIR: Points to the
deploy
directory.SDKMACHINE: Specifies the architecture of the machine on which the cross-development tools are run to create packages for the target hardware.
SDKIMAGE_FEATURES: Lists the features to include in the “target” part of the SDK.
TOOLCHAIN_HOST_TASK: Lists packages that make up the host part of the SDK (i.e. the part that runs on the SDKMACHINE). When you use
bitbake -c populate_sdk imagename
to create the SDK, a set of default packages apply. This variable allows you to add more packages.TOOLCHAIN_TARGET_TASK: Lists packages that make up the target part of the SDK (i.e. the part built for the target hardware).
SDKPATH: Defines the default SDK installation path offered by the installation script.
SDK_HOST_MANIFEST: Lists all the installed packages that make up the host part of the SDK. This variable also plays a minor role for extensible SDK development as well. However, it is mainly used for the standard SDK.
SDK_TARGET_MANIFEST: Lists all the installed packages that make up the target part of the SDK. This variable also plays a minor role for extensible SDK development as well. However, it is mainly used for the standard SDK.
4.4 Cross-Development Toolchain Generation
The Yocto Project does most of the work for you when it comes to creating The Cross-Development Toolchain. This section provides some technical background on how cross-development toolchains are created and used. For more information on toolchains, you can also see the Yocto Project Application Development and the Extensible Software Development Kit (eSDK) manual.
In the Yocto Project development environment, cross-development toolchains are used to build images and applications that run on the target hardware. With just a few commands, the OpenEmbedded build system creates these necessary toolchains for you.
The following figure shows a high-level build environment regarding toolchain construction and use.
Most of the work occurs on the Build Host. This is the machine used to
build images and generally work within the the Yocto Project
environment. When you run
BitBake to create an image, the
OpenEmbedded build system uses the host gcc
compiler to bootstrap a
cross-compiler named gcc-cross
. The gcc-cross
compiler is what
BitBake uses to compile source files when creating the target image. You
can think of gcc-cross
simply as an automatically generated
cross-compiler that is used internally within BitBake only.
Note
The extensible SDK does not use gcc-cross-canadian
since this SDK ships a copy of the OpenEmbedded build system and the
sysroot within it contains gcc-cross
.
The chain of events that occurs when the standard toolchain is bootstrapped:
binutils-cross -> linux-libc-headers -> gcc-cross -> libgcc-initial -> glibc -> libgcc -> gcc-runtime
gcc
: The compiler, GNU Compiler Collection (GCC).binutils-cross
: The binary utilities needed in order to run thegcc-cross
phase of the bootstrap operation and build the headers for the C library.linux-libc-headers
: Headers needed for the cross-compiler and C library build.libgcc-initial
: An initial version of the gcc support library needed to bootstrapglibc
.libgcc
: The final version of the gcc support library which can only be built once there is a C library to link against.glibc
: The GNU C Library.gcc-cross
: The final stage of the bootstrap process for the cross-compiler. This stage results in the actual cross-compiler that BitBake uses when it builds an image for a targeted device.This tool is a “native” tool (i.e. it is designed to run on the build host).
gcc-runtime
: Runtime libraries resulting from the toolchain bootstrapping process. This tool produces a binary that consists of the runtime libraries need for the targeted device.
You can use the OpenEmbedded build system to build an installer for the
relocatable SDK used to develop applications. When you run the
installer, it installs the toolchain, which contains the development
tools (e.g., gcc-cross-canadian
, binutils-cross-canadian
, and
other nativesdk-*
tools), which are tools native to the SDK (i.e.
native to SDK_ARCH), you
need to cross-compile and test your software. The figure shows the
commands you use to easily build out this toolchain. This
cross-development toolchain is built to execute on the
SDKMACHINE, which might or
might not be the same machine as the Build Host.
Note
If your target architecture is supported by the Yocto Project, you can take advantage of pre-built images that ship with the Yocto Project and already contain cross-development toolchain installers.
Here is the bootstrap process for the relocatable toolchain:
gcc -> binutils-crosssdk -> gcc-crosssdk-initial -> linux-libc-headers -> glibc-initial -> nativesdk-glibc -> gcc-crosssdk -> gcc-cross-canadian
gcc
: The build host’s GNU Compiler Collection (GCC).binutils-crosssdk
: The bare minimum binary utilities needed in order to run thegcc-crosssdk-initial
phase of the bootstrap operation.gcc-crosssdk-initial
: An early stage of the bootstrap process for creating the cross-compiler. This stage builds enough of thegcc-crosssdk
and supporting pieces so that the final stage of the bootstrap process can produce the finished cross-compiler. This tool is a “native” binary that runs on the build host.linux-libc-headers
: Headers needed for the cross-compiler.glibc-initial
: An initial version of the Embedded GLIBC needed to bootstrapnativesdk-glibc
.nativesdk-glibc
: The Embedded GLIBC needed to bootstrap thegcc-crosssdk
.gcc-crosssdk
: The final stage of the bootstrap process for the relocatable cross-compiler. Thegcc-crosssdk
is a transitory compiler and never leaves the build host. Its purpose is to help in the bootstrap process to create the eventualgcc-cross-canadian
compiler, which is relocatable. This tool is also a “native” package (i.e. it is designed to run on the build host).gcc-cross-canadian
: The final relocatable cross-compiler. When run on the SDKMACHINE, this tool produces executable code that runs on the target device. Only one cross-canadian compiler is produced per architecture since they can be targeted at different processor optimizations using configurations passed to the compiler through the compile commands. This circumvents the need for multiple compilers and thus reduces the size of the toolchains.
Note
For information on advantages gained when building a cross-development toolchain installer, see the “Building an SDK Installer” appendix in the Yocto Project Application Development and the Extensible Software Development Kit (eSDK) manual.
4.6 Automatically Added Runtime Dependencies
The OpenEmbedded build system automatically adds common types of runtime
dependencies between packages, which means that you do not need to
explicitly declare the packages using
RDEPENDS. There are three automatic
mechanisms (shlibdeps
, pcdeps
, and depchains
) that
handle shared libraries, package configuration (pkg-config) modules, and
-dev
and -dbg
packages, respectively. For other types of runtime
dependencies, you must manually declare the dependencies.
shlibdeps
: During the do_package task of each recipe, all shared libraries installed by the recipe are located. For each shared library, the package that contains the shared library is registered as providing the shared library. More specifically, the package is registered as providing the soname of the library. The resulting shared-library-to-package mapping is saved globally in PKGDATA_DIR by the do_packagedata task.Simultaneously, all executables and shared libraries installed by the recipe are inspected to see what shared libraries they link against. For each shared library dependency that is found, PKGDATA_DIR is queried to see if some package (likely from a different recipe) contains the shared library. If such a package is found, a runtime dependency is added from the package that depends on the shared library to the package that contains the library.
The automatically added runtime dependency also includes a version restriction. This version restriction specifies that at least the current version of the package that provides the shared library must be used, as if “package (>= version)” had been added to RDEPENDS. This forces an upgrade of the package containing the shared library when installing the package that depends on the library, if needed.
If you want to avoid a package being registered as providing a particular shared library (e.g. because the library is for internal use only), then add the library to PRIVATE_LIBS inside the package’s recipe.
pcdeps
: During the do_package task of each recipe, all pkg-config modules (*.pc
files) installed by the recipe are located. For each module, the package that contains the module is registered as providing the module. The resulting module-to-package mapping is saved globally in PKGDATA_DIR by the do_packagedata task.Simultaneously, all pkg-config modules installed by the recipe are inspected to see what other pkg-config modules they depend on. A module is seen as depending on another module if it contains a “Requires:” line that specifies the other module. For each module dependency, PKGDATA_DIR is queried to see if some package contains the module. If such a package is found, a runtime dependency is added from the package that depends on the module to the package that contains the module.
Note
The pcdeps mechanism most often infers dependencies between -dev packages.
depchains
: If a packagefoo
depends on a packagebar
, thenfoo-dev
andfoo-dbg
are also made to depend onbar-dev
andbar-dbg
, respectively. Taking the-dev
packages as an example, thebar-dev
package might provide headers and shared library symlinks needed byfoo-dev
, which shows the need for a dependency between the packages.The dependencies added by
depchains
are in the form of RRECOMMENDS.Note
By default,
foo-dev
also has an RDEPENDS-style dependency onfoo
, because the default value ofRDEPENDS:${PN}-dev
(set inbitbake.conf
) includes “${PN}”.To ensure that the dependency chain is never broken,
-dev
and-dbg
packages are always generated by default, even if the packages turn out to be empty. See the ALLOW_EMPTY variable for more information.
The do_package task depends on the do_packagedata task of each
recipe in DEPENDS through use
of a [
deptask]
declaration, which guarantees that the required
shared-library/module-to-package mapping information will be available
when needed as long as DEPENDS has been correctly set.
4.7 Fakeroot and Pseudo
Some tasks are easier to implement when allowed to perform certain operations that are normally reserved for the root user (e.g. do_install, do_package_write*, do_rootfs, and do_image_*). For example, the do_install task benefits from being able to set the UID and GID of installed files to arbitrary values.
One approach to allowing tasks to perform root-only operations would be to require BitBake to run as root. However, this method is cumbersome and has security issues. The approach that is actually used is to run tasks that benefit from root privileges in a “fake” root environment. Within this environment, the task and its child processes believe that they are running as the root user, and see an internally consistent view of the filesystem. As long as generating the final output (e.g. a package or an image) does not require root privileges, the fact that some earlier steps ran in a fake root environment does not cause problems.
The capability to run tasks in a fake root environment is known as “fakeroot”, which is derived from the BitBake keyword/variable flag that requests a fake root environment for a task.
In the OpenEmbedded Build System, the program that implements
fakeroot is known as Pseudo. Pseudo
overrides system calls by using the environment variable LD_PRELOAD
,
which results in the illusion of running as root. To keep track of
“fake” file ownership and permissions resulting from operations that
require root permissions, Pseudo uses an SQLite 3 database. This
database is stored in
${
WORKDIR}/pseudo/files.db
for individual recipes. Storing the database in a file as opposed to in
memory gives persistence between tasks and builds, which is not
accomplished using fakeroot.
Note
If you add your own task that manipulates the same files or
directories as a fakeroot task, then that task also needs to run
under fakeroot. Otherwise, the task cannot run root-only operations,
and cannot see the fake file ownership and permissions set by the
other task. You need to also add a dependency on
virtual/fakeroot-native:do_populate_sysroot
, giving the following:
fakeroot do_mytask () {
...
}
do_mytask[depends] += "virtual/fakeroot-native:do_populate_sysroot"
For more information, see the FAKEROOT* variables in the BitBake User Manual. You can also reference the “Why Not Fakeroot?” article for background information on Fakeroot and Pseudo.