| .. SPDX-License-Identifier: CC-BY-SA-2.0-UK |
| |
| ********************** |
| 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 :term:`OpenEmbedded Build System` |
| workflow, |
| cross-development toolchains, shared state cache, and so forth are |
| explained. |
| |
| Yocto Project Components |
| ======================== |
| |
| The :term:`BitBake` task executor |
| together with various types of configuration files form the |
| :term:`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 |
| ":ref:`dev-manual/common-tasks: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 |
| ":ref:`overview-manual/concepts:openembedded build system concepts`" |
| section. |
| |
| BitBake |
| ------- |
| |
| BitBake is the tool at the heart of the :term:`OpenEmbedded Build System` |
| and is responsible |
| for parsing the :term:`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 :doc:`BitBake User Manual <bitbake:index>`. |
| |
| 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 |
| ":ref:`bitbake:bitbake-user-manual/bitbake-user-manual-execution: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. |
| |
| 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. |
| |
| Classes |
| ------- |
| |
| Class files (``.bbclass``) contain information that is useful to share |
| between recipes files. An example is the |
| :ref:`autotools <ref-classes-autotools>` class, |
| which contains common settings for any application that is built with |
| the `GNU Autotools <https://en.wikipedia.org/wiki/GNU_Autotools>`__. |
| The ":ref:`ref-manual/classes:Classes`" chapter in the Yocto Project |
| Reference Manual provides details about classes and how to use them. |
| |
| 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 :term:`Build Directory`. |
| |
| |
| Layers |
| ====== |
| |
| Layers are repositories that contain related metadata (i.e. sets of |
| instructions) that tell the OpenEmbedded build system how to build a |
| target. :ref:`overview-manual/yp-intro: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_home:`Yocto Project Compatible Layer Index </software-overview/layers/>` |
| and :oe_layerindex:`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 |
| ":ref:`dev-manual/common-tasks:understanding and creating layers`" |
| section of the Yocto Project Development Tasks Manual. |
| |
| OpenEmbedded Build System Concepts |
| ================================== |
| |
| This section takes a more detailed look inside the build process used by |
| the :term:`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. |
| |
| .. image:: figures/YP-flow-diagram.png |
| :width: 100% |
| |
| 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 |
| :term:`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. |
| |
| 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 :ref:`general workflow |
| figure <overview-manual/concepts:openembedded build system concepts>`: |
| |
| .. image:: figures/user-configuration.png |
| :width: 100% |
| |
| 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 |
| :term:`Source Directory`. For simplicity, |
| this section refers to the Source Directory as the "Poky Directory." |
| |
| When you clone the :term:`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 |
| :ref:`structure-core-script`, which is the |
| build environment script. |
| |
| Sourcing the build environment script creates a |
| :term:`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 |
| :ref:`structure-core-script` script in the context of separate |
| :term:`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 |
| :yocto_git:`local.conf.sample </poky/tree/meta-poky/conf/templates/default/local.conf.sample>` |
| in the ``meta-poky`` layer: |
| |
| - *Target Machine Selection:* Controlled by the |
| :term:`MACHINE` variable. |
| |
| - *Download Directory:* Controlled by the |
| :term:`DL_DIR` variable. |
| |
| - *Shared State Directory:* Controlled by the |
| :term:`SSTATE_DIR` variable. |
| |
| - *Build Output:* Controlled by the |
| :term:`TMPDIR` variable. |
| |
| - *Distribution Policy:* Controlled by the |
| :term:`DISTRO` variable. |
| |
| - *Packaging Format:* Controlled by the |
| :term:`PACKAGE_CLASSES` |
| variable. |
| |
| - *SDK Target Architecture:* Controlled by the |
| :term:`SDKMACHINE` variable. |
| |
| - *Extra Image Packages:* Controlled by the |
| :term:`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 |
| ":ref:`dev-manual/common-tasks: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 |
| :term:`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 the ``conf/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 |
| :term:`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 |
| ":doc:`bitbake:bitbake-user-manual/bitbake-user-manual-metadata`" 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. |
| |
| 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 :oe_layer:`meta-qt5 layer </meta-qt5>` |
| from the :oe_layerindex:`OpenEmbedded Layer Index <>`. This layer is for |
| version 5.0 of the popular `Qt <https://wiki.qt.io/About_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 |
| :ref:`overview-manual/yp-intro:reference distribution (poky)` is the |
| :yocto_git:`meta-yocto-bsp </poky/tree/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 |
| :yocto_git:`meta-poky </poky/tree/meta-poky>` |
| layer. Within the distro layer is a ``conf/distro`` directory that |
| contains distro configuration files (e.g. |
| :yocto_git:`poky.conf </poky/tree/meta-poky/conf/distro/poky.conf>` |
| that contain many policy configurations for the Poky distribution. |
| |
| The following figure shows an expanded representation of these three |
| layers from the :ref:`general workflow figure |
| <overview-manual/concepts:openembedded build system concepts>`: |
| |
| .. image:: figures/layer-input.png |
| :align: center |
| :width: 70% |
| |
| 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 |
| ":ref:`dev-manual/common-tasks: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 |
| ":ref:`overview-manual/concepts:layers`" and |
| ":ref:`overview-manual/yp-intro: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 :yocto_git:`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. |
| |
| 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 |
| ":ref:`ref-manual/classes: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 are ``recipes-core`` and |
| ``recipes-extra``. Hierarchy and contents within a ``recipes-*`` |
| 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. |
| |
| 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 |
| :doc:`/bsp-guide/index`. |
| |
| .. 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. |
| |
| 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. |
| |
| Sources |
| ------- |
| |
| In order for the OpenEmbedded build system to create an image or any |
| target, it must be able to access source files. The :ref:`general workflow |
| figure <overview-manual/concepts:openembedded build system concepts>` |
| 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 :term:`SRC_URI` |
| variable to point to source files regardless of their location. Each |
| recipe must have a :term:`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 |
| :term:`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 |
| :term:`DL_DIR` by using the |
| :term:`BB_GENERATE_MIRROR_TARBALLS` |
| variable. |
| |
| Judicious use of a :term:`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 :term:`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 :ref:`general workflow figure <overview-manual/concepts:openembedded build system concepts>`: |
| |
| .. image:: figures/source-input.png |
| :align: center |
| :width: 70% |
| |
| 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. |
| |
| 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 :ref:`externalsrc <ref-classes-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. |
| |
| Source Control Managers (Optional) |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| Another place from which the build system can get source files is with |
| :ref:`bitbake:bitbake-user-manual/bitbake-user-manual-fetching:fetchers` employing various Source |
| Control Managers (SCMs) such as Git or Subversion. In such cases, a |
| repository is cloned or checked out. The |
| :ref:`ref-tasks-fetch` task inside |
| BitBake uses the :term:`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 :term:`BB_GENERATE_MIRROR_TARBALLS` |
| variable in the Yocto Project Reference Manual. |
| |
| When fetching a repository, BitBake uses the |
| :term:`SRCREV` variable to determine |
| the specific revision from which to build. |
| |
| Source Mirror(s) |
| ~~~~~~~~~~~~~~~~ |
| |
| There are two kinds of mirrors: pre-mirrors and regular mirrors. The |
| :term:`PREMIRRORS` and |
| :term:`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 |
| :term:`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. |
| |
| 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 |
| :term:`Build Directory`. The :ref:`general workflow figure |
| <overview-manual/concepts:openembedded build system concepts>` |
| 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: |
| |
| .. image:: figures/package-feeds.png |
| :width: 100% |
| |
| 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 |
| :term:`PACKAGE_CLASSES` |
| variable. Before placing the packages into package feeds, the build |
| process validates them with generated output quality assurance checks |
| through the :ref:`insane <ref-classes-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: |
| |
| - :term:`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 |
| :term:`DEPLOY_DIR_RPM`, |
| :term:`DEPLOY_DIR_IPK`, |
| :term:`DEPLOY_DIR_DEB`, or |
| :term:`DEPLOY_DIR_TAR`, |
| variables are used, respectively. |
| |
| - :term:`PACKAGE_ARCH`: Defines |
| architecture-specific sub-folders. For example, packages could be |
| available for the i586 or qemux86 architectures. |
| |
| BitBake uses the |
| :ref:`do_package_write_* <ref-tasks-package_write_deb>` |
| tasks to generate packages and place them into the package holding area |
| (e.g. ``do_package_write_ipk`` for IPK packages). See the |
| ":ref:`ref-tasks-package_write_deb`", |
| ":ref:`ref-tasks-package_write_ipk`", |
| ":ref:`ref-tasks-package_write_rpm`", |
| and |
| ":ref:`ref-tasks-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``. |
| |
| BitBake Tool |
| ------------ |
| |
| The OpenEmbedded build system uses |
| :term:`BitBake` to produce images and |
| Software Development Kits (SDKs). You can see from the :ref:`general workflow |
| figure <overview-manual/concepts:openembedded build system concepts>`, |
| 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. |
| |
| Source Fetching |
| ~~~~~~~~~~~~~~~ |
| |
| The first stages of building a recipe are to fetch and unpack the source |
| code: |
| |
| .. image:: figures/source-fetching.png |
| :width: 100% |
| |
| The :ref:`ref-tasks-fetch` and |
| :ref:`ref-tasks-unpack` tasks fetch |
| the source files and unpack them into the |
| :term:`Build Directory`. |
| |
| .. note:: |
| |
| For every local file (e.g. ``file://``) that is part of a recipe's |
| :term:`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 :ref:`ref-tasks-fetch` task. If any local |
| file has been modified, the :ref:`ref-tasks-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 ":ref:`structure-core-build`" section in |
| the Yocto Project Reference Manual. |
| |
| Each recipe has an area in the Build Directory where the unpacked source |
| code resides. The :term:`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: |
| |
| - :term:`TMPDIR`: The base directory |
| where the OpenEmbedded build system performs all its work during the |
| build. The default base directory is the ``tmp`` directory. |
| |
| - :term:`PACKAGE_ARCH`: The |
| architecture of the built package or packages. Depending on the |
| eventual destination of the package or packages (i.e. machine |
| architecture, :term:`Build Host`, SDK, or |
| specific machine), :term:`PACKAGE_ARCH` varies. See the variable's |
| description for details. |
| |
| - :term:`TARGET_OS`: The operating |
| system of the target device. A typical value would be "linux" (e.g. |
| "qemux86-poky-linux"). |
| |
| - :term:`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, :term:`PN` represents |
| the name of the recipe. |
| |
| - :term:`WORKDIR`: The location |
| where the OpenEmbedded build system builds a recipe (i.e. does the |
| work to create the package). |
| |
| - :term:`PV`: The version of the |
| recipe used to build the package. |
| |
| - :term:`PR`: The revision of the |
| recipe used to build the package. |
| |
| - :term:`S`: Contains the unpacked source |
| files for a given recipe. |
| |
| - :term:`BPN`: The name of the recipe |
| used to build the package. The :term:`BPN` variable is a version of |
| the :term:`PN` variable but with common prefixes and suffixes removed. |
| |
| - :term:`PV`: The version of the |
| recipe used to build the package. |
| |
| .. note:: |
| |
| In the previous figure, notice that there are two sample hierarchies: |
| one based on package architecture (i.e. :term:`PACKAGE_ARCH`) |
| and one based on a machine (i.e. :term:`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). |
| |
| Patching |
| ~~~~~~~~ |
| |
| Once source code is fetched and unpacked, BitBake locates patch files |
| and applies them to the source files: |
| |
| .. image:: figures/patching.png |
| :width: 100% |
| |
| The :ref:`ref-tasks-patch` task uses a |
| recipe's :term:`SRC_URI` statements |
| and the :term:`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 :term:`SRC_URI` parameters |
| to change the way the build system recognizes patch files. See the |
| :ref:`ref-tasks-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 :term:`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 |
| :term:`S` directory. |
| |
| For more information on how the source directories are created, see the |
| ":ref:`overview-manual/concepts:source fetching`" section. For |
| more information on how to create patches and how the build system |
| processes patches, see the |
| ":ref:`dev-manual/common-tasks:patching code`" |
| section in the |
| Yocto Project Development Tasks Manual. You can also see the |
| ":ref:`sdk-manual/extensible: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 |
| ":ref:`kernel-dev/common:using traditional kernel development to patch the kernel`" |
| section in the Yocto Project Linux Kernel Development Manual. |
| |
| 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: |
| |
| .. image:: figures/configuration-compile-autoreconf.png |
| :width: 100% |
| |
| This step in the build process consists of the following tasks: |
| |
| - :ref:`ref-tasks-prepare_recipe_sysroot`: |
| This task sets up the two sysroots in |
| ``${``\ :term:`WORKDIR`\ ``}`` |
| (i.e. ``recipe-sysroot`` and ``recipe-sysroot-native``) so that |
| during the packaging phase the sysroots can contain the contents of |
| the |
| :ref:`ref-tasks-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 |
| :ref:`ref-tasks-configure` task |
| are specific to configurations for the source code being built by the |
| recipe. |
| |
| If you are using the |
| :ref:`autotools <ref-classes-autotools>` class, |
| you can add additional configuration options by using the |
| :term:`EXTRA_OECONF` or |
| :term:`PACKAGECONFIG_CONFARGS` |
| variables. For information on how this variable works within that |
| class, see the |
| :ref:`autotools <ref-classes-autotools>` class |
| :yocto_git:`here </poky/tree/meta/classes-recipe/autotools.bbclass>`. |
| |
| - *do_compile*: Once a configuration task has been satisfied, |
| BitBake compiles the source using the |
| :ref:`ref-tasks-compile` task. |
| Compilation occurs in the directory pointed to by the |
| :term:`B` variable. Realize that the |
| :term:`B` directory is, by default, the same as the |
| :term:`S` directory. |
| |
| - *do_install*: After compilation completes, BitBake executes the |
| :ref:`ref-tasks-install` task. |
| This task copies files from the :term:`B` directory and places them in a |
| holding area pointed to by the :term:`D` |
| variable. Packaging occurs later using files from this holding |
| directory. |
| |
| Package Splitting |
| ~~~~~~~~~~~~~~~~~ |
| |
| After source code is configured, compiled, and staged, the build system |
| analyzes the results and splits the output into packages: |
| |
| .. image:: figures/analysis-for-package-splitting.png |
| :width: 100% |
| |
| The :ref:`ref-tasks-package` and |
| :ref:`ref-tasks-packagedata` |
| tasks combine to analyze the files found in the |
| :term:`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 :ref:`ref-tasks-packagedata` task creates package metadata based on the |
| analysis such that the build system can generate the final packages. The |
| :ref:`ref-tasks-populate_sysroot` |
| task stages (copies) a subset of the files installed by the |
| :ref:`ref-tasks-install` task into |
| the appropriate sysroot. Working, staged, and intermediate results of |
| the analysis and package splitting process use several areas: |
| |
| - :term:`PKGD`: The destination |
| directory (i.e. ``package``) for packages before they are split into |
| individual packages. |
| |
| - :term:`PKGDESTWORK`: A |
| temporary work area (i.e. ``pkgdata``) used by the :ref:`ref-tasks-package` |
| task to save package metadata. |
| |
| - :term:`PKGDEST`: The parent |
| directory (i.e. ``packages-split``) for packages after they have been |
| split. |
| |
| - :term:`PKGDATA_DIR`: A shared, |
| global-state directory that holds packaging metadata generated during |
| the packaging process. The packaging process copies metadata from |
| :term:`PKGDESTWORK` to the :term:`PKGDATA_DIR` area where it becomes globally |
| available. |
| |
| - :term:`STAGING_DIR_HOST`: |
| The path for the sysroot for the system on which a component is built |
| to run (i.e. ``recipe-sysroot``). |
| |
| - :term:`STAGING_DIR_NATIVE`: |
| The path for the sysroot used when building components for the build |
| host (i.e. ``recipe-sysroot-native``). |
| |
| - :term:`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 :term:`FILES` variable defines the |
| files that go into each package in |
| :term:`PACKAGES`. If you want |
| details on how this is accomplished, you can look at |
| :yocto_git:`package.bbclass </poky/tree/meta/classes-global/package.bbclass>`. |
| |
| Depending on the type of packages being created (RPM, DEB, or IPK), the |
| :ref:`do_package_write_* <ref-tasks-package_write_deb>` |
| task creates the actual packages and places them in the Package Feed |
| area, which is ``${TMPDIR}/deploy``. You can see the |
| ":ref:`overview-manual/concepts: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. |
| |
| Image Generation |
| ~~~~~~~~~~~~~~~~ |
| |
| Once packages are split and stored in the Package Feeds area, the build |
| system uses BitBake to generate the root filesystem image: |
| |
| .. image:: figures/image-generation.png |
| :width: 100% |
| |
| The image generation process consists of several stages and depends on |
| several tasks and variables. The |
| :ref:`ref-tasks-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: |
| |
| - :term:`IMAGE_INSTALL`: Lists |
| out the base set of packages from which to install from the Package |
| Feeds area. |
| |
| - :term:`PACKAGE_EXCLUDE`: |
| Specifies packages that should not be installed into the image. |
| |
| - :term:`IMAGE_FEATURES`: |
| Specifies features to include in the image. Most of these features |
| map to additional packages for installation. |
| |
| - :term:`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. |
| |
| - :term:`IMAGE_LINGUAS`: |
| Determines the language(s) for which additional language support |
| packages are installed. |
| |
| - :term:`PACKAGE_INSTALL`: |
| The final list of packages passed to the package manager for |
| installation into the image. |
| |
| With :term:`IMAGE_ROOTFS` |
| pointing to the location of the filesystem under construction and the |
| :term:`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 |
| :ref:`read-only root filesystem <dev-manual/common-tasks:creating 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 :ref:`ref-tasks-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 |
| :ref:`testimage <ref-classes-testimage>` class, |
| for example, to determine whether or not to run specific tests. See the |
| :term:`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 |
| :term:`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 :ref:`ref-tasks-image` |
| task. The build system runs any pre-processing commands as defined by |
| the |
| :term:`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 :ref:`do_image_* <ref-tasks-image>` tasks as needed, |
| based on the image types specified in the |
| :term:`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 |
| :term:`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 :term:`IMAGE_FSTYPES` were ``ext4``, the dynamically |
| generated task would be as follows:: |
| |
| do_image_ext4 |
| |
| The final task involved in image creation is the |
| :ref:`do_image_complete <ref-tasks-image-complete>` |
| task. This task completes the image by applying any image post |
| processing as defined through the |
| :term:`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. |
| |
| 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): |
| |
| .. image:: figures/sdk-generation.png |
| :width: 100% |
| |
| .. note:: |
| |
| For more information on the cross-development toolchain generation, |
| see the ":ref:`overview-manual/concepts:cross-development toolchain generation`" |
| section. For information on advantages gained when building a |
| cross-development toolchain using the :ref:`ref-tasks-populate_sdk` task, see the |
| ":ref:`sdk-manual/appendix-obtain: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 |
| :ref:`ref-tasks-populate_sdk` |
| and |
| :ref:`ref-tasks-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 ":ref:`overview-manual/concepts:application development sdk`" |
| section. |
| |
| The :ref:`ref-tasks-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 |
| :term:`SDKMACHINE`. |
| |
| The :ref:`ref-tasks-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. |
| |
| Stamp Files and the Rerunning of Tasks |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| For each task that completes successfully, BitBake writes a stamp file |
| into the :term:`STAMPS_DIR` |
| directory. The beginning of the stamp file's filename is determined by |
| the :term:`STAMP` variable, and the end |
| of the name consists of the task's name and current :ref:`input |
| checksum <overview-manual/concepts:checksums (signatures)>`. |
| |
| .. 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 |
| ":ref:`overview-manual/concepts: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 |
| :term:`TMPDIR` (e.g. in some |
| recipe's :term:`WORKDIR`.) What |
| the sstate cache mechanism adds is a way to cache task output that |
| can then be shared between build machines. |
| |
| Since :term:`STAMPS_DIR` is usually a subdirectory of :term:`TMPDIR`, removing |
| :term:`TMPDIR` will also remove :term:`STAMPS_DIR`, which means tasks will |
| properly be rerun to repopulate :term:`TMPDIR`. |
| |
| If you want some task to always be considered "out of date", you can |
| mark it with the :ref:`nostamp <bitbake:bitbake-user-manual/bitbake-user-manual-metadata:variable flags>` |
| 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 |
| ":ref:`dev-manual/common-tasks:viewing task variable dependencies`" |
| section in the Yocto Project Development Tasks Manual. |
| |
| Setscene Tasks and Shared State |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| The description of tasks so far assumes that BitBake needs to build |
| everything and no available prebuilt objects exist. BitBake does support |
| skipping tasks if prebuilt objects are available. These objects are |
| usually made available in the form of a shared state (sstate) cache. |
| |
| .. note:: |
| |
| For information on variables affecting sstate, see the |
| :term:`SSTATE_DIR` |
| and |
| :term:`SSTATE_MIRRORS` |
| variables. |
| |
| The idea of a setscene task (i.e ``do_taskname_setscene``) is a |
| version of the task where instead of building something, BitBake can |
| skip to the end result and simply place a set of files into specific |
| locations as needed. In some cases, it makes sense to have a setscene |
| task variant (e.g. generating package files in the |
| :ref:`do_package_write_* <ref-tasks-package_write_deb>` |
| task). In other cases, it does not make sense (e.g. a |
| :ref:`ref-tasks-patch` task or a |
| :ref:`ref-tasks-unpack` task) since |
| the work involved would be equal to or greater than the underlying task. |
| |
| In the build system, the common tasks that have setscene variants are |
| :ref:`ref-tasks-package`, |
| :ref:`do_package_write_* <ref-tasks-package_write_deb>`, |
| :ref:`ref-tasks-deploy`, |
| :ref:`ref-tasks-packagedata`, and |
| :ref:`ref-tasks-populate_sysroot`. |
| Notice that these tasks represent most of the tasks whose output is an |
| end result. |
| |
| The build system has knowledge of the relationship between these tasks |
| and other preceding tasks. For example, if BitBake runs |
| ``do_populate_sysroot_setscene`` for something, it does not make sense |
| to run any of the :ref:`ref-tasks-fetch`, :ref:`ref-tasks-unpack`, :ref:`ref-tasks-patch`, |
| :ref:`ref-tasks-configure`, :ref:`ref-tasks-compile`, and :ref:`ref-tasks-install` tasks. However, if |
| :ref:`ref-tasks-package` needs to be run, BitBake needs to run those other tasks. |
| |
| It becomes more complicated if everything can come from an sstate cache |
| because some objects are simply not required at all. For example, you do |
| not need a compiler or native tools, such as quilt, if there isn't anything |
| to compile or patch. If the :ref:`do_package_write_* <ref-tasks-package_write_deb>` packages are available |
| from sstate, BitBake does not need the :ref:`ref-tasks-package` task data. |
| |
| To handle all these complexities, BitBake runs in two phases. The first |
| is the "setscene" stage. During this stage, BitBake first checks the |
| sstate cache for any targets it is planning to build. BitBake does a |
| fast check to see if the object exists rather than doing a complete download. |
| If nothing exists, the second phase, which is the setscene stage, |
| completes and the main build proceeds. |
| |
| If objects are found in the sstate cache, the build system works |
| backwards from the end targets specified by the user. For example, if an |
| image is being built, the build system first looks for the packages |
| needed for that image and the tools needed to construct an image. If |
| those are available, the compiler is not needed. Thus, the compiler is |
| not even downloaded. If something was found to be unavailable, or the |
| download or setscene task fails, the build system then tries to install |
| dependencies, such as the compiler, from the cache. |
| |
| The availability of objects in the sstate cache is handled by the |
| function specified by the :term:`BB_HASHCHECK_FUNCTION` |
| variable and returns a list of available objects. The function specified |
| by the :term:`BB_SETSCENE_DEPVALID` |
| variable is the function that determines whether a given dependency |
| needs to be followed, and whether for any given relationship the |
| function needs to be passed. The function returns a True or False value. |
| |
| 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 :ref:`general workflow figure |
| <overview-manual/concepts:openembedded build system concepts>` that BitBake |
| output, in part, consists of images. This section takes a closer look at |
| this output: |
| |
| .. image:: figures/images.png |
| :align: center |
| :width: 75% |
| |
| .. note:: |
| |
| For a list of example images that the Yocto Project provides, see the |
| ":doc:`/ref-manual/images`" chapter in the Yocto Project Reference |
| Manual. |
| |
| The build process writes images out to the :term:`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 :term:`DEPLOY_DIR` variable |
| points to the ``deploy`` directory, while the |
| :term:`DEPLOY_DIR_IMAGE` |
| variable points to the appropriate directory containing images for the |
| current configuration. |
| |
| - kernel-image: A kernel binary file. The |
| :term:`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 |
| :term:`IMAGE_FSTYPES` |
| variable determines the root filesystem image type. The |
| ``deploy/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 |
| :term:`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. |
| |
| Application Development SDK |
| --------------------------- |
| |
| In the :ref:`general workflow figure |
| <overview-manual/concepts:openembedded build system concepts>`, 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: |
| |
| .. image:: figures/sdk.png |
| :width: 100% |
| |
| 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 |
| ":ref:`overview-manual/concepts:cross-development toolchain generation`" |
| section. |
| |
| - For information on setting up a cross-development environment, see |
| the :doc:`/sdk-manual/index` manual. |
| |
| All the output files for an SDK are written to the ``deploy/sdk`` folder |
| inside the :term:`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: |
| |
| - :term:`DEPLOY_DIR`: Points to |
| the ``deploy`` directory. |
| |
| - :term:`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. |
| |
| - :term:`SDK_INCLUDE_PKGDATA`: |
| Specifies whether or not packagedata is included in the extensible |
| SDK for all recipes in the "world" target. |
| |
| - :term:`SDK_INCLUDE_TOOLCHAIN`: |
| Specifies whether or not the toolchain is included when building the |
| extensible SDK. |
| |
| - :term:`ESDK_LOCALCONF_ALLOW`: |
| A list of variables allowed through from the build system |
| configuration into the extensible SDK configuration. |
| |
| - :term:`ESDK_LOCALCONF_REMOVE`: |
| A list of variables not allowed through from the build system |
| configuration into the extensible SDK configuration. |
| |
| - :term:`ESDK_CLASS_INHERIT_DISABLE`: |
| A list of classes to remove from the |
| :term:`INHERIT` value globally |
| within the extensible SDK configuration. |
| |
| This next list, shows the variables associated with a standard SDK: |
| |
| - :term:`DEPLOY_DIR`: Points to |
| the ``deploy`` directory. |
| |
| - :term:`SDKMACHINE`: Specifies |
| the architecture of the machine on which the cross-development tools |
| are run to create packages for the target hardware. |
| |
| - :term:`SDKIMAGE_FEATURES`: |
| Lists the features to include in the "target" part of the SDK. |
| |
| - :term:`TOOLCHAIN_HOST_TASK`: |
| Lists packages that make up the host part of the SDK (i.e. the part |
| that runs on the :term:`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. |
| |
| - :term:`TOOLCHAIN_TARGET_TASK`: |
| Lists packages that make up the target part of the SDK (i.e. the part |
| built for the target hardware). |
| |
| - :term:`SDKPATH`: Defines the |
| default SDK installation path offered by the installation script. |
| |
| - :term:`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. |
| |
| - :term:`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. |
| |
| Cross-Development Toolchain Generation |
| ====================================== |
| |
| The Yocto Project does most of the work for you when it comes to |
| creating :ref:`sdk-manual/intro: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 :doc:`/sdk-manual/index` 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. |
| |
| .. image:: figures/cross-development-toolchains.png |
| :width: 100% |
| |
| Most of the work occurs on the Build Host. This is the machine used to |
| build images and generally work within the Yocto Project |
| environment. When you run |
| :term:`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 the ``gcc-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 bootstrap ``glibc``. |
| |
| - ``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 :term:`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 |
| :term:`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 the ``gcc-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 the |
| ``gcc-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 |
| bootstrap ``nativesdk-glibc``. |
| |
| - ``nativesdk-glibc``: The Embedded GLIBC needed to bootstrap the |
| ``gcc-crosssdk``. |
| |
| - ``gcc-crosssdk``: The final stage of the bootstrap process for the |
| relocatable cross-compiler. The ``gcc-crosssdk`` is a transitory |
| compiler and never leaves the build host. Its purpose is to help in |
| the bootstrap process to create the eventual ``gcc-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 :term:`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 |
| ":ref:`sdk-manual/appendix-obtain:building an sdk installer`" appendix |
| in the Yocto Project Application Development and the |
| Extensible Software Development Kit (eSDK) manual. |
| |
| Shared State Cache |
| ================== |
| |
| By design, the OpenEmbedded build system builds everything from scratch |
| unless :term:`BitBake` can determine |
| that parts do not need to be rebuilt. Fundamentally, building from |
| scratch is attractive as it means all parts are built fresh and there is |
| no possibility of stale data that can cause problems. When |
| developers hit problems, they typically default back to building from |
| scratch so they have a known state from the start. |
| |
| Building an image from scratch is both an advantage and a disadvantage |
| to the process. As mentioned in the previous paragraph, building from |
| scratch ensures that everything is current and starts from a known |
| state. However, building from scratch also takes much longer as it |
| generally means rebuilding things that do not necessarily need to be |
| rebuilt. |
| |
| The Yocto Project implements shared state code that supports incremental |
| builds. The implementation of the shared state code answers the |
| following questions that were fundamental roadblocks within the |
| OpenEmbedded incremental build support system: |
| |
| - What pieces of the system have changed and what pieces have not |
| changed? |
| |
| - How are changed pieces of software removed and replaced? |
| |
| - How are pre-built components that do not need to be rebuilt from |
| scratch used when they are available? |
| |
| For the first question, the build system detects changes in the "inputs" |
| to a given task by creating a checksum (or signature) of the task's |
| inputs. If the checksum changes, the system assumes the inputs have |
| changed and the task needs to be rerun. For the second question, the |
| shared state (sstate) code tracks which tasks add which output to the |
| build process. This means the output from a given task can be removed, |
| upgraded or otherwise manipulated. The third question is partly |
| addressed by the solution for the second question assuming the build |
| system can fetch the sstate objects from remote locations and install |
| them if they are deemed to be valid. |
| |
| .. note:: |
| |
| - The build system does not maintain |
| :term:`PR` information as part of |
| the shared state packages. Consequently, there are considerations that |
| affect maintaining shared state feeds. For information on how the |
| build system works with packages and can track incrementing :term:`PR` |
| information, see the ":ref:`dev-manual/common-tasks:automatically incrementing a package version number`" |
| section in the Yocto Project Development Tasks Manual. |
| |
| - The code in the build system that supports incremental builds is |
| complex. For techniques that help you work around issues |
| related to shared state code, see the |
| ":ref:`dev-manual/common-tasks:viewing metadata used to create the input signature of a shared state task`" |
| and |
| ":ref:`dev-manual/common-tasks:invalidating shared state to force a task to run`" |
| sections both in the Yocto Project Development Tasks Manual. |
| |
| The rest of this section goes into detail about the overall incremental |
| build architecture, the checksums (signatures), and shared state. |
| |
| Overall Architecture |
| -------------------- |
| |
| When determining what parts of the system need to be built, BitBake |
| works on a per-task basis rather than a per-recipe basis. You might |
| wonder why using a per-task basis is preferred over a per-recipe basis. |
| To help explain, consider having the IPK packaging backend enabled and |
| then switching to DEB. In this case, the |
| :ref:`ref-tasks-install` and |
| :ref:`ref-tasks-package` task outputs |
| are still valid. However, with a per-recipe approach, the build would |
| not include the ``.deb`` files. Consequently, you would have to |
| invalidate the whole build and rerun it. Rerunning everything is not the |
| best solution. Also, in this case, the core must be "taught" much about |
| specific tasks. This methodology does not scale well and does not allow |
| users to easily add new tasks in layers or as external recipes without |
| touching the packaged-staging core. |
| |
| Checksums (Signatures) |
| ---------------------- |
| |
| The shared state code uses a checksum, which is a unique signature of a |
| task's inputs, to determine if a task needs to be run again. Because it |
| is a change in a task's inputs that triggers a rerun, the process needs |
| to detect all the inputs to a given task. For shell tasks, this turns |
| out to be fairly easy because the build process generates a "run" shell |
| script for each task and it is possible to create a checksum that gives |
| you a good idea of when the task's data changes. |
| |
| To complicate the problem, there are things that should not be included |
| in the checksum. First, there is the actual specific build path of a |
| given task --- the :term:`WORKDIR`. It |
| does not matter if the work directory changes because it should not |
| affect the output for target packages. Also, the build process has the |
| objective of making native or cross packages relocatable. |
| |
| .. note:: |
| |
| Both native and cross packages run on the |
| build host. However, cross packages generate output for the target |
| architecture. |
| |
| The checksum therefore needs to exclude :term:`WORKDIR`. The simplistic |
| approach for excluding the work directory is to set :term:`WORKDIR` to some |
| fixed value and create the checksum for the "run" script. |
| |
| Another problem results from the "run" scripts containing functions that |
| might or might not get called. The incremental build solution contains |
| code that figures out dependencies between shell functions. This code is |
| used to prune the "run" scripts down to the minimum set, thereby |
| alleviating this problem and making the "run" scripts much more readable |
| as a bonus. |
| |
| So far, there are solutions for shell scripts. What about Python tasks? The |
| same approach applies even though these tasks are more difficult. The |
| process needs to figure out what variables a Python function accesses |
| and what functions it calls. Again, the incremental build solution |
| contains code that first figures out the variable and function |
| dependencies, and then creates a checksum for the data used as the input |
| to the task. |
| |
| Like the :term:`WORKDIR` case, there can be situations where dependencies should be |
| ignored. For these situations, you can instruct the build process to |
| ignore a dependency by using a line like the following:: |
| |
| PACKAGE_ARCHS[vardepsexclude] = "MACHINE" |
| |
| This example ensures that the :term:`PACKAGE_ARCHS` variable |
| does not depend on the value of :term:`MACHINE`, even if it does |
| reference it. |
| |
| Equally, there are cases where you need to add dependencies BitBake is |
| not able to find. You can accomplish this by using a line like the |
| following:: |
| |
| PACKAGE_ARCHS[vardeps] = "MACHINE" |
| |
| This example explicitly |
| adds the :term:`MACHINE` variable as a dependency for :term:`PACKAGE_ARCHS`. |
| |
| As an example, consider a case with in-line Python where BitBake is not |
| able to figure out dependencies. When running in debug mode (i.e. using |
| ``-DDD``), BitBake produces output when it discovers something for which |
| it cannot figure out dependencies. The Yocto Project team has currently |
| not managed to cover those dependencies in detail and is aware of the |
| need to fix this situation. |
| |
| Thus far, this section has limited discussion to the direct inputs into |
| a task. Information based on direct inputs is referred to as the |
| "basehash" in the code. However, the question of a task's indirect |
| inputs still exits --- items already built and present in the |
| :term:`Build Directory`. The checksum (or |
| signature) for a particular task needs to add the hashes of all the |
| tasks on which the particular task depends. Choosing which dependencies |
| to add is a policy decision. However, the effect is to generate a |
| checksum that combines the basehash and the hashes of the task's |
| dependencies. |
| |
| At the code level, there are multiple ways by which both the basehash |
| and the dependent task hashes can be influenced. Within the BitBake |
| configuration file, you can give BitBake some extra information to help |
| it construct the basehash. The following statement effectively results |
| in a list of global variable dependency excludes (i.e. variables never |
| included in any checksum):: |
| |
| BB_BASEHASH_IGNORE_VARS ?= "TMPDIR FILE PATH PWD BB_TASKHASH BBPATH DL_DIR \\ |
| SSTATE_DIR THISDIR FILESEXTRAPATHS FILE_DIRNAME HOME LOGNAME SHELL TERM \\ |
| USER FILESPATH STAGING_DIR_HOST STAGING_DIR_TARGET COREBASE PRSERV_HOST \\ |
| PRSERV_DUMPDIR PRSERV_DUMPFILE PRSERV_LOCKDOWN PARALLEL_MAKE \\ |
| CCACHE_DIR EXTERNAL_TOOLCHAIN CCACHE CCACHE_DISABLE LICENSE_PATH SDKPKGSUFFIX" |
| |
| The previous example does not include :term:`WORKDIR` since that variable is |
| actually constructed as a path within :term:`TMPDIR`, which is included above. |
| |
| The rules for deciding which hashes of dependent tasks to include |
| through dependency chains are more complex and are generally |
| accomplished with a Python function. The code in |
| ``meta/lib/oe/sstatesig.py`` shows two examples of this and also |
| illustrates how you can insert your own policy into the system if so |
| desired. This file defines the two basic signature generators |
| :term:`OpenEmbedded-Core (OE-Core)` uses: "OEBasic" and |
| "OEBasicHash". By default, a dummy "noop" signature handler is enabled |
| in BitBake. This means that behavior is unchanged from previous |
| versions. OE-Core uses the "OEBasicHash" signature handler by default |
| through this setting in the ``bitbake.conf`` file:: |
| |
| BB_SIGNATURE_HANDLER ?= "OEBasicHash" |
| |
| The "OEBasicHash" :term:`BB_SIGNATURE_HANDLER` is the same |
| as the "OEBasic" version but adds the task hash to the :ref:`stamp |
| files <overview-manual/concepts:stamp files and the rerunning of tasks>`. This |
| results in any metadata change that changes the task hash, automatically causing |
| the task to be run again. This removes the need to bump |
| :term:`PR` values, and changes to metadata |
| automatically ripple across the build. |
| |
| It is also worth noting that the end result of these signature |
| generators is to make some dependency and hash information available to |
| the build. This information includes: |
| |
| - ``BB_BASEHASH:task-``\ taskname: The base hashes for each task in the |
| recipe. |
| |
| - ``BB_BASEHASH_``\ filename\ ``:``\ taskname: The base hashes for each |
| dependent task. |
| |
| - :term:`BB_TASKHASH`: The hash of the currently running task. |
| |
| Shared State |
| ------------ |
| |
| Checksums and dependencies, as discussed in the previous section, solve |
| half the problem of supporting a shared state. The other half of the |
| problem is being able to use checksum information during the build and |
| being able to reuse or rebuild specific components. |
| |
| The :ref:`sstate <ref-classes-sstate>` class is a |
| relatively generic implementation of how to "capture" a snapshot of a |
| given task. The idea is that the build process does not care about the |
| source of a task's output. Output could be freshly built or it could be |
| downloaded and unpacked from somewhere. In other words, the build |
| process does not need to worry about its origin. |
| |
| Two types of output exist. One type is just about creating a directory |
| in :term:`WORKDIR`. A good example is |
| the output of either |
| :ref:`ref-tasks-install` or |
| :ref:`ref-tasks-package`. The other |
| type of output occurs when a set of data is merged into a shared |
| directory tree such as the sysroot. |
| |
| The Yocto Project team has tried to keep the details of the |
| implementation hidden in the :ref:`sstate <ref-classes-sstate>` class. From a user's perspective, |
| adding shared state wrapping to a task is as simple as this |
| :ref:`ref-tasks-deploy` example taken |
| from the :ref:`deploy <ref-classes-deploy>` class:: |
| |
| DEPLOYDIR = "${WORKDIR}/deploy-${PN}" |
| SSTATETASKS += "do_deploy" |
| do_deploy[sstate-inputdirs] = "${DEPLOYDIR}" |
| do_deploy[sstate-outputdirs] = "${DEPLOY_DIR_IMAGE}" |
| |
| python do_deploy_setscene () { |
| sstate_setscene(d) |
| } |
| addtask do_deploy_setscene |
| do_deploy[dirs] = "${DEPLOYDIR} ${B}" |
| do_deploy[stamp-extra-info] = "${MACHINE_ARCH}" |
| |
| The following list explains the previous example: |
| |
| - Adding ``do_deploy`` to ``SSTATETASKS`` adds some required |
| sstate-related processing, which is implemented in the |
| :ref:`sstate <ref-classes-sstate>` class, to |
| before and after the |
| :ref:`ref-tasks-deploy` task. |
| |
| - The ``do_deploy[sstate-inputdirs] = "${DEPLOYDIR}"`` declares that |
| :ref:`ref-tasks-deploy` places its output in ``${DEPLOYDIR}`` when run normally |
| (i.e. when not using the sstate cache). This output becomes the input |
| to the shared state cache. |
| |
| - The ``do_deploy[sstate-outputdirs] = "${DEPLOY_DIR_IMAGE}"`` line |
| causes the contents of the shared state cache to be copied to |
| ``${DEPLOY_DIR_IMAGE}``. |
| |
| .. note:: |
| |
| If :ref:`ref-tasks-deploy` is not already in the shared state cache or if its input |
| checksum (signature) has changed from when the output was cached, the task |
| runs to populate the shared state cache, after which the contents of the |
| shared state cache is copied to ${:term:`DEPLOY_DIR_IMAGE`}. If |
| :ref:`ref-tasks-deploy` is in the shared state cache and its signature indicates |
| that the cached output is still valid (i.e. if no relevant task inputs |
| have changed), then the contents of the shared state cache copies |
| directly to ${:term:`DEPLOY_DIR_IMAGE`} by the ``do_deploy_setscene`` task |
| instead, skipping the :ref:`ref-tasks-deploy` task. |
| |
| - The following task definition is glue logic needed to make the |
| previous settings effective:: |
| |
| python do_deploy_setscene () { |
| sstate_setscene(d) |
| } |
| addtask do_deploy_setscene |
| |
| ``sstate_setscene()`` takes the flags above as input and accelerates the :ref:`ref-tasks-deploy` task |
| through the shared state cache if possible. If the task was |
| accelerated, ``sstate_setscene()`` returns True. Otherwise, it |
| returns False, and the normal :ref:`ref-tasks-deploy` task runs. For more |
| information, see the ":ref:`bitbake:bitbake-user-manual/bitbake-user-manual-execution:setscene`" |
| section in the BitBake User Manual. |
| |
| - The ``do_deploy[dirs] = "${DEPLOYDIR} ${B}"`` line creates |
| ``${DEPLOYDIR}`` and ``${B}`` before the :ref:`ref-tasks-deploy` task runs, and |
| also sets the current working directory of :ref:`ref-tasks-deploy` to ``${B}``. |
| For more information, see the ":ref:`bitbake:bitbake-user-manual/bitbake-user-manual-metadata:variable flags`" |
| section in the BitBake |
| User Manual. |
| |
| .. note:: |
| |
| In cases where ``sstate-inputdirs`` and ``sstate-outputdirs`` would be |
| the same, you can use ``sstate-plaindirs``. For example, to preserve the |
| ${:term:`PKGD`} and ${:term:`PKGDEST`} output from the :ref:`ref-tasks-package` |
| task, use the following:: |
| |
| do_package[sstate-plaindirs] = "${PKGD} ${PKGDEST}" |
| |
| |
| - The ``do_deploy[stamp-extra-info] = "${MACHINE_ARCH}"`` line appends |
| extra metadata to the :ref:`stamp |
| file <overview-manual/concepts:stamp files and the rerunning of tasks>`. In |
| this case, the metadata makes the task specific to a machine's architecture. |
| See |
| ":ref:`bitbake:bitbake-user-manual/bitbake-user-manual-execution:the task list`" |
| section in the BitBake User Manual for more information on the |
| ``stamp-extra-info`` flag. |
| |
| - ``sstate-inputdirs`` and ``sstate-outputdirs`` can also be used with |
| multiple directories. For example, the following declares |
| :term:`PKGDESTWORK` and ``SHLIBWORK`` as shared state input directories, |
| which populates the shared state cache, and :term:`PKGDATA_DIR` and |
| ``SHLIBSDIR`` as the corresponding shared state output directories:: |
| |
| do_package[sstate-inputdirs] = "${PKGDESTWORK} ${SHLIBSWORKDIR}" |
| do_package[sstate-outputdirs] = "${PKGDATA_DIR} ${SHLIBSDIR}" |
| |
| - These methods also include the ability to take a lockfile when |
| manipulating shared state directory structures, for cases where file |
| additions or removals are sensitive:: |
| |
| do_package[sstate-lockfile] = "${PACKAGELOCK}" |
| |
| Behind the scenes, the shared state code works by looking in |
| :term:`SSTATE_DIR` and |
| :term:`SSTATE_MIRRORS` for |
| shared state files. Here is an example:: |
| |
| SSTATE_MIRRORS ?= "\ |
| file://.* https://someserver.tld/share/sstate/PATH;downloadfilename=PATH \ |
| file://.* file:///some/local/dir/sstate/PATH" |
| |
| .. note:: |
| |
| The shared state directory (:term:`SSTATE_DIR`) is organized into two-character |
| subdirectories, where the subdirectory names are based on the first two |
| characters of the hash. |
| If the shared state directory structure for a mirror has the same structure |
| as :term:`SSTATE_DIR`, you must specify "PATH" as part of the URI to enable the build |
| system to map to the appropriate subdirectory. |
| |
| The shared state package validity can be detected just by looking at the |
| filename since the filename contains the task checksum (or signature) as |
| described earlier in this section. If a valid shared state package is |
| found, the build process downloads it and uses it to accelerate the |
| task. |
| |
| The build processes use the ``*_setscene`` tasks for the task |
| acceleration phase. BitBake goes through this phase before the main |
| execution code and tries to accelerate any tasks for which it can find |
| shared state packages. If a shared state package for a task is |
| available, the shared state package is used. This means the task and any |
| tasks on which it is dependent are not executed. |
| |
| As a real world example, the aim is when building an IPK-based image, |
| only the |
| :ref:`ref-tasks-package_write_ipk` |
| tasks would have their shared state packages fetched and extracted. |
| Since the sysroot is not used, it would never get extracted. This is |
| another reason why a task-based approach is preferred over a |
| recipe-based approach, which would have to install the output from every |
| task. |
| |
| Hash Equivalence |
| ---------------- |
| |
| The above section explained how BitBake skips the execution of tasks |
| whose output can already be found in the Shared State cache. |
| |
| During a build, it may often be the case that the output / result of a task might |
| be unchanged despite changes in the task's input values. An example might be |
| whitespace changes in some input C code. In project terms, this is what we define |
| as "equivalence". |
| |
| To keep track of such equivalence, BitBake has to manage three hashes |
| for each task: |
| |
| - The *task hash* explained earlier: computed from the recipe metadata, |
| the task code and the task hash values from its dependencies. |
| When changes are made, these task hashes are therefore modified, |
| causing the task to re-execute. The task hashes of tasks depending on this |
| task are therefore modified too, causing the whole dependency |
| chain to re-execute. |
| |
| - The *output hash*, a new hash computed from the output of Shared State tasks, |
| tasks that save their resulting output to a Shared State tarball. |
| The mapping between the task hash and its output hash is reported |
| to a new *Hash Equivalence* server. This mapping is stored in a database |
| by the server for future reference. |
| |
| - The *unihash*, a new hash, initially set to the task hash for the task. |
| This is used to track the *unicity* of task output, and we will explain |
| how its value is maintained. |
| |
| When Hash Equivalence is enabled, BitBake computes the task hash |
| for each task by using the unihash of its dependencies, instead |
| of their task hash. |
| |
| Now, imagine that a Shared State task is modified because of a change in |
| its code or metadata, or because of a change in its dependencies. |
| Since this modifies its task hash, this task will need re-executing. |
| Its output hash will therefore be computed again. |
| |
| Then, the new mapping between the new task hash and its output hash |
| will be reported to the Hash Equivalence server. The server will |
| let BitBake know whether this output hash is the same as a previously |
| reported output hash, for a different task hash. |
| |
| If the output hash is already known, BitBake will update the task's |
| unihash to match the original task hash that generated that output. |
| Thanks to this, the depending tasks will keep a previously recorded |
| task hash, and BitBake will be able to retrieve their output from |
| the Shared State cache, instead of re-executing them. Similarly, the |
| output of further downstream tasks can also be retrieved from Shared |
| Shate. |
| |
| If the output hash is unknown, a new entry will be created on the Hash |
| Equivalence server, matching the task hash to that output. |
| The depending tasks, still having a new task hash because of the |
| change, will need to re-execute as expected. The change propagates |
| to the depending tasks. |
| |
| To summarize, when Hash Equivalence is enabled, a change in one of the |
| tasks in BitBake's run queue doesn't have to propagate to all the |
| downstream tasks that depend on the output of this task, causing a |
| full rebuild of such tasks, and so on with the next depending tasks. |
| Instead, when the output of this task remains identical to previously |
| recorded output, BitBake can safely retrieve all the downstream |
| task output from the Shared State cache. |
| |
| .. note:: |
| |
| Having :doc:`/test-manual/reproducible-builds` is a key ingredient for |
| the stability of the task's output hash. Therefore, the effectiveness |
| of Hash Equivalence strongly depends on it. |
| |
| This applies to multiple scenarios: |
| |
| - A "trivial" change to a recipe that doesn't impact its generated output, |
| such as whitespace changes, modifications to unused code paths or |
| in the ordering of variables. |
| |
| - Shared library updates, for example to fix a security vulnerability. |
| For sure, the programs using such a library should be rebuilt, but |
| their new binaries should remain identical. The corresponding tasks should |
| have a different output hash because of the change in the hash of their |
| library dependency, but thanks to their output being identical, Hash |
| Equivalence will stop the propagation down the dependency chain. |
| |
| - Native tool updates. Though the depending tasks should be rebuilt, |
| it's likely that they will generate the same output and be marked |
| as equivalent. |
| |
| This mechanism is enabled by default in Poky, and is controlled by three |
| variables: |
| |
| - :term:`bitbake:BB_HASHSERVE`, specifying a local or remote Hash |
| Equivalence server to use. |
| |
| - :term:`BB_HASHSERVE_UPSTREAM`, when ``BB_HASHSERVE = "auto"``, |
| allowing to connect the local server to an upstream one. |
| |
| - :term:`bitbake:BB_SIGNATURE_HANDLER`, which must be set to ``OEEquivHash``. |
| |
| Therefore, the default configuration in Poky corresponds to the |
| below settings:: |
| |
| BB_HASHSERVE = "auto" |
| BB_SIGNATURE_HANDLER = "OEEquivHash" |
| |
| Rather than starting a local server, another possibility is to rely |
| on a Hash Equivalence server on a network, by setting:: |
| |
| BB_HASHSERVE = "<HOSTNAME>:<PORT>" |
| |
| .. note:: |
| |
| The shared Hash Equivalence server needs to be maintained together with the |
| Shared State cache. Otherwise, the server could report Shared State hashes |
| that only exist on specific clients. |
| |
| We therefore recommend that one Hash Equivalence server be set up to |
| correspond with a given Shared State cache, and to start this server |
| in *read-only mode*, so that it doesn't store equivalences for |
| Shared State caches that are local to clients. |
| |
| See the :term:`BB_HASHSERVE` reference for details about starting |
| a Hash Equivalence server. |
| |
| See the `video <https://www.youtube.com/watch?v=zXEdqGS62Wc>`__ |
| of Joshua Watt's `Hash Equivalence and Reproducible Builds |
| <https://elinux.org/images/3/37/Hash_Equivalence_and_Reproducible_Builds.pdf>`__ |
| presentation at ELC 2020 for a very synthetic introduction to the |
| Hash Equivalence implementation in the Yocto Project. |
| |
| 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 |
| :term:`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 |
| :ref:`ref-tasks-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 <https://en.wikipedia.org/wiki/Soname>`__ of the library. The |
| resulting shared-library-to-package mapping is saved globally in |
| :term:`PKGDATA_DIR` by the |
| :ref:`ref-tasks-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, :term:`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 :term:`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 |
| :term:`PRIVATE_LIBS` inside |
| the package's recipe. |
| |
| - ``pcdeps``: During the :ref:`ref-tasks-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 :term:`PKGDATA_DIR` by the |
| :ref:`ref-tasks-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, :term:`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 package ``foo`` depends on a package ``bar``, |
| then ``foo-dev`` and ``foo-dbg`` are also made to depend on |
| ``bar-dev`` and ``bar-dbg``, respectively. Taking the ``-dev`` |
| packages as an example, the ``bar-dev`` package might provide headers |
| and shared library symlinks needed by ``foo-dev``, which shows the |
| need for a dependency between the packages. |
| |
| The dependencies added by ``depchains`` are in the form of |
| :term:`RRECOMMENDS`. |
| |
| .. note:: |
| |
| By default, ``foo-dev`` also has an :term:`RDEPENDS`-style dependency on |
| ``foo``, because the default value of ``RDEPENDS:${PN}-dev`` (set in |
| ``bitbake.conf``) includes "${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 |
| :term:`ALLOW_EMPTY` variable |
| for more information. |
| |
| The :ref:`ref-tasks-package` task depends on the :ref:`ref-tasks-packagedata` task of each |
| recipe in :term:`DEPENDS` through use |
| of a ``[``\ :ref:`deptask <bitbake:bitbake-user-manual/bitbake-user-manual-metadata:variable flags>`\ ``]`` |
| declaration, which guarantees that the required |
| shared-library/module-to-package mapping information will be available |
| when needed as long as :term:`DEPENDS` has been correctly set. |
| |
| 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. |
| :ref:`ref-tasks-install`, |
| :ref:`do_package_write* <ref-tasks-package_write_deb>`, |
| :ref:`ref-tasks-rootfs`, and |
| :ref:`do_image_* <ref-tasks-image>`). For example, |
| the :ref:`ref-tasks-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 :term:`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 <http://man.he.net/man1/fakeroot>`__", which is derived from |
| the BitBake keyword/variable flag that requests a fake root environment |
| for a task. |
| |
| In the :term:`OpenEmbedded Build System`, the program that implements |
| fakeroot is known as :yocto_home:`Pseudo </software-item/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 |
| ``${``\ :term:`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 |
| :term:`FAKEROOT* <bitbake:FAKEROOT>` variables in the |
| BitBake User Manual. You can also reference the "`Why Not |
| Fakeroot? <https://github.com/wrpseudo/pseudo/wiki/WhyNotFakeroot>`__" |
| article for background information on Fakeroot and Pseudo. |