| .. SPDX-License-Identifier: CC-BY-SA-2.0-UK |
| |
| Building |
| ******** |
| |
| This section describes various build procedures, such as the steps |
| needed for a simple build, building a target for multiple configurations, |
| generating an image for more than one machine, and so forth. |
| |
| Building a Simple Image |
| ======================= |
| |
| In the development environment, you need to build an image whenever you |
| change hardware support, add or change system libraries, or add or |
| change services that have dependencies. There are several methods that allow |
| you to build an image within the Yocto Project. This section presents |
| the basic steps you need to build a simple image using BitBake from a |
| build host running Linux. |
| |
| .. note:: |
| |
| - For information on how to build an image using |
| :term:`Toaster`, see the |
| :doc:`/toaster-manual/index`. |
| |
| - For information on how to use ``devtool`` to build images, see the |
| ":ref:`sdk-manual/extensible:using \`\`devtool\`\` in your sdk workflow`" |
| section in the Yocto Project Application Development and the |
| Extensible Software Development Kit (eSDK) manual. |
| |
| - For a quick example on how to build an image using the |
| OpenEmbedded build system, see the |
| :doc:`/brief-yoctoprojectqs/index` document. |
| |
| - You can also use the `Yocto Project BitBake |
| <https://marketplace.visualstudio.com/items?itemName=yocto-project.yocto-bitbake>`__ |
| extension for Visual Studio Code to build images. |
| |
| The build process creates an entire Linux distribution from source and |
| places it in your :term:`Build Directory` under ``tmp/deploy/images``. For |
| detailed information on the build process using BitBake, see the |
| ":ref:`overview-manual/concepts:images`" section in the Yocto Project Overview |
| and Concepts Manual. |
| |
| The following figure and list overviews the build process: |
| |
| .. image:: figures/bitbake-build-flow.png |
| :width: 100% |
| |
| #. *Set up Your Host Development System to Support Development Using the |
| Yocto Project*: See the ":doc:`start`" section for options on how to get a |
| build host ready to use the Yocto Project. |
| |
| #. *Initialize the Build Environment:* Initialize the build environment |
| by sourcing the build environment script (i.e. |
| :ref:`structure-core-script`):: |
| |
| $ source oe-init-build-env [build_dir] |
| |
| When you use the initialization script, the OpenEmbedded build system |
| uses ``build`` as the default :term:`Build Directory` in your current work |
| directory. You can use a `build_dir` argument with the script to |
| specify a different :term:`Build Directory`. |
| |
| .. note:: |
| |
| A common practice is to use a different :term:`Build Directory` for |
| different targets; for example, ``~/build/x86`` for a ``qemux86`` |
| target, and ``~/build/arm`` for a ``qemuarm`` target. In any |
| event, it's typically cleaner to locate the :term:`Build Directory` |
| somewhere outside of your source directory. |
| |
| #. *Make Sure Your* ``local.conf`` *File is Correct*: Ensure the |
| ``conf/local.conf`` configuration file, which is found in the |
| :term:`Build Directory`, is set up how you want it. This file defines many |
| aspects of the build environment including the target machine architecture |
| through the :term:`MACHINE` variable, the packaging format used during |
| the build (:term:`PACKAGE_CLASSES`), and a centralized tarball download |
| directory through the :term:`DL_DIR` variable. |
| |
| #. *Build the Image:* Build the image using the ``bitbake`` command:: |
| |
| $ bitbake target |
| |
| .. note:: |
| |
| For information on BitBake, see the :doc:`bitbake:index`. |
| |
| The target is the name of the recipe you want to build. Common |
| targets are the images in ``meta/recipes-core/images``, |
| ``meta/recipes-sato/images``, and so forth all found in the |
| :term:`Source Directory`. Alternatively, the target |
| can be the name of a recipe for a specific piece of software such as |
| BusyBox. For more details about the images the OpenEmbedded build |
| system supports, see the |
| ":ref:`ref-manual/images:Images`" chapter in the Yocto |
| Project Reference Manual. |
| |
| As an example, the following command builds the |
| ``core-image-minimal`` image:: |
| |
| $ bitbake core-image-minimal |
| |
| Once an |
| image has been built, it often needs to be installed. The images and |
| kernels built by the OpenEmbedded build system are placed in the |
| :term:`Build Directory` in ``tmp/deploy/images``. For information on how to |
| run pre-built images such as ``qemux86`` and ``qemuarm``, see the |
| :doc:`/sdk-manual/index` manual. For |
| information about how to install these images, see the documentation |
| for your particular board or machine. |
| |
| Building Images for Multiple Targets Using Multiple Configurations |
| ================================================================== |
| |
| You can use a single ``bitbake`` command to build multiple images or |
| packages for different targets where each image or package requires a |
| different configuration (multiple configuration builds). The builds, in |
| this scenario, are sometimes referred to as "multiconfigs", and this |
| section uses that term throughout. |
| |
| This section describes how to set up for multiple configuration builds |
| and how to account for cross-build dependencies between the |
| multiconfigs. |
| |
| Setting Up and Running a Multiple Configuration Build |
| ----------------------------------------------------- |
| |
| To accomplish a multiple configuration build, you must define each |
| target's configuration separately using a parallel configuration file in |
| the :term:`Build Directory` or configuration directory within a layer, and you |
| must follow a required file hierarchy. Additionally, you must enable the |
| multiple configuration builds in your ``local.conf`` file. |
| |
| Follow these steps to set up and execute multiple configuration builds: |
| |
| - *Create Separate Configuration Files*: You need to create a single |
| configuration file for each build target (each multiconfig). |
| The configuration definitions are implementation dependent but often |
| each configuration file will define the machine and the |
| temporary directory BitBake uses for the build. Whether the same |
| temporary directory (:term:`TMPDIR`) can be shared will depend on what is |
| similar and what is different between the configurations. Multiple MACHINE |
| targets can share the same (:term:`TMPDIR`) as long as the rest of the |
| configuration is the same, multiple :term:`DISTRO` settings would need separate |
| (:term:`TMPDIR`) directories. |
| |
| For example, consider a scenario with two different multiconfigs for the same |
| :term:`MACHINE`: "qemux86" built |
| for two distributions such as "poky" and "poky-lsb". In this case, |
| you would need to use the different :term:`TMPDIR`. |
| |
| Here is an example showing the minimal statements needed in a |
| configuration file for a "qemux86" target whose temporary build |
| directory is ``tmpmultix86``:: |
| |
| MACHINE = "qemux86" |
| TMPDIR = "${TOPDIR}/tmpmultix86" |
| |
| The location for these multiconfig configuration files is specific. |
| They must reside in the current :term:`Build Directory` in a sub-directory of |
| ``conf`` named ``multiconfig`` or within a layer's ``conf`` directory |
| under a directory named ``multiconfig``. Here is an example that defines |
| two configuration files for the "x86" and "arm" multiconfigs: |
| |
| .. image:: figures/multiconfig_files.png |
| :align: center |
| :width: 50% |
| |
| The usual :term:`BBPATH` search path is used to locate multiconfig files in |
| a similar way to other conf files. |
| |
| - *Add the BitBake Multi-configuration Variable to the Local |
| Configuration File*: Use the |
| :term:`BBMULTICONFIG` |
| variable in your ``conf/local.conf`` configuration file to specify |
| each multiconfig. Continuing with the example from the previous |
| figure, the :term:`BBMULTICONFIG` variable needs to enable two |
| multiconfigs: "x86" and "arm" by specifying each configuration file:: |
| |
| BBMULTICONFIG = "x86 arm" |
| |
| .. note:: |
| |
| A "default" configuration already exists by definition. This |
| configuration is named: "" (i.e. empty string) and is defined by |
| the variables coming from your ``local.conf`` |
| file. Consequently, the previous example actually adds two |
| additional configurations to your build: "arm" and "x86" along |
| with "". |
| |
| - *Launch BitBake*: Use the following BitBake command form to launch |
| the multiple configuration build:: |
| |
| $ bitbake [mc:multiconfigname:]target [[[mc:multiconfigname:]target] ... ] |
| |
| For the example in this section, the following command applies:: |
| |
| $ bitbake mc:x86:core-image-minimal mc:arm:core-image-sato mc::core-image-base |
| |
| The previous BitBake command builds a ``core-image-minimal`` image |
| that is configured through the ``x86.conf`` configuration file, a |
| ``core-image-sato`` image that is configured through the ``arm.conf`` |
| configuration file and a ``core-image-base`` that is configured |
| through your ``local.conf`` configuration file. |
| |
| .. note:: |
| |
| Support for multiple configuration builds in the Yocto Project &DISTRO; |
| (&DISTRO_NAME;) Release does not include Shared State (sstate) |
| optimizations. Consequently, if a build uses the same object twice |
| in, for example, two different :term:`TMPDIR` |
| directories, the build either loads from an existing sstate cache for |
| that build at the start or builds the object fresh. |
| |
| Enabling Multiple Configuration Build Dependencies |
| -------------------------------------------------- |
| |
| Sometimes dependencies can exist between targets (multiconfigs) in a |
| multiple configuration build. For example, suppose that in order to |
| build a ``core-image-sato`` image for an "x86" multiconfig, the root |
| filesystem of an "arm" multiconfig must exist. This dependency is |
| essentially that the |
| :ref:`ref-tasks-image` task in the |
| ``core-image-sato`` recipe depends on the completion of the |
| :ref:`ref-tasks-rootfs` task of the |
| ``core-image-minimal`` recipe. |
| |
| To enable dependencies in a multiple configuration build, you must |
| declare the dependencies in the recipe using the following statement |
| form:: |
| |
| task_or_package[mcdepends] = "mc:from_multiconfig:to_multiconfig:recipe_name:task_on_which_to_depend" |
| |
| To better show how to use this statement, consider the example scenario |
| from the first paragraph of this section. The following statement needs |
| to be added to the recipe that builds the ``core-image-sato`` image:: |
| |
| do_image[mcdepends] = "mc:x86:arm:core-image-minimal:do_rootfs" |
| |
| In this example, the `from_multiconfig` is "x86". The `to_multiconfig` is "arm". The |
| task on which the :ref:`ref-tasks-image` task in the recipe depends is the |
| :ref:`ref-tasks-rootfs` task from the ``core-image-minimal`` recipe associated |
| with the "arm" multiconfig. |
| |
| Once you set up this dependency, you can build the "x86" multiconfig |
| using a BitBake command as follows:: |
| |
| $ bitbake mc:x86:core-image-sato |
| |
| This command executes all the tasks needed to create the |
| ``core-image-sato`` image for the "x86" multiconfig. Because of the |
| dependency, BitBake also executes through the :ref:`ref-tasks-rootfs` task for the |
| "arm" multiconfig build. |
| |
| Having a recipe depend on the root filesystem of another build might not |
| seem that useful. Consider this change to the statement in the |
| ``core-image-sato`` recipe:: |
| |
| do_image[mcdepends] = "mc:x86:arm:core-image-minimal:do_image" |
| |
| In this case, BitBake must |
| create the ``core-image-minimal`` image for the "arm" build since the |
| "x86" build depends on it. |
| |
| Because "x86" and "arm" are enabled for multiple configuration builds |
| and have separate configuration files, BitBake places the artifacts for |
| each build in the respective temporary build directories (i.e. |
| :term:`TMPDIR`). |
| |
| Building an Initial RAM Filesystem (Initramfs) Image |
| ==================================================== |
| |
| An initial RAM filesystem (:term:`Initramfs`) image provides a temporary root |
| filesystem used for early system initialization, typically providing tools and |
| loading modules needed to locate and mount the final root filesystem. |
| |
| Follow these steps to create an :term:`Initramfs` image: |
| |
| #. *Create the Initramfs Image Recipe:* You can reference the |
| ``core-image-minimal-initramfs.bb`` recipe found in the |
| ``meta/recipes-core`` directory of the :term:`Source Directory` |
| as an example from which to work. |
| |
| #. *Decide if You Need to Bundle the Initramfs Image Into the Kernel |
| Image:* If you want the :term:`Initramfs` image that is built to be bundled |
| in with the kernel image, set the :term:`INITRAMFS_IMAGE_BUNDLE` |
| variable to ``"1"`` in your ``local.conf`` configuration file and set the |
| :term:`INITRAMFS_IMAGE` variable in the recipe that builds the kernel image. |
| |
| Setting the :term:`INITRAMFS_IMAGE_BUNDLE` flag causes the :term:`Initramfs` |
| image to be unpacked into the ``${B}/usr/`` directory. The unpacked |
| :term:`Initramfs` image is then passed to the kernel's ``Makefile`` using the |
| :term:`CONFIG_INITRAMFS_SOURCE` variable, allowing the :term:`Initramfs` |
| image to be built into the kernel normally. |
| |
| #. *Optionally Add Items to the Initramfs Image Through the Initramfs |
| Image Recipe:* If you add items to the :term:`Initramfs` image by way of its |
| recipe, you should use :term:`PACKAGE_INSTALL` rather than |
| :term:`IMAGE_INSTALL`. :term:`PACKAGE_INSTALL` gives more direct control of |
| what is added to the image as compared to the defaults you might not |
| necessarily want that are set by the :ref:`ref-classes-image` |
| or :ref:`ref-classes-core-image` classes. |
| |
| #. *Build the Kernel Image and the Initramfs Image:* Build your kernel |
| image using BitBake. Because the :term:`Initramfs` image recipe is a |
| dependency of the kernel image, the :term:`Initramfs` image is built as well |
| and bundled with the kernel image if you used the |
| :term:`INITRAMFS_IMAGE_BUNDLE` variable described earlier. |
| |
| Bundling an Initramfs Image From a Separate Multiconfig |
| ------------------------------------------------------- |
| |
| There may be a case where we want to build an :term:`Initramfs` image which does not |
| inherit the same distro policy as our main image, for example, we may want |
| our main image to use ``TCLIBC="glibc"``, but to use ``TCLIBC="musl"`` in our :term:`Initramfs` |
| image to keep a smaller footprint. However, by performing the steps mentioned |
| above the :term:`Initramfs` image will inherit ``TCLIBC="glibc"`` without allowing us |
| to override it. |
| |
| To achieve this, you need to perform some additional steps: |
| |
| #. *Create a multiconfig for your Initramfs image:* You can perform the steps |
| on ":ref:`dev-manual/building:building images for multiple targets using multiple configurations`" to create a separate multiconfig. |
| For the sake of simplicity let's assume such multiconfig is called: ``initramfscfg.conf`` and |
| contains the variables:: |
| |
| TMPDIR="${TOPDIR}/tmp-initramfscfg" |
| TCLIBC="musl" |
| |
| #. *Set additional Initramfs variables on your main configuration:* |
| Additionally, on your main configuration (``local.conf``) you need to set the |
| variables:: |
| |
| INITRAMFS_MULTICONFIG = "initramfscfg" |
| INITRAMFS_DEPLOY_DIR_IMAGE = "${TOPDIR}/tmp-initramfscfg/deploy/images/${MACHINE}" |
| |
| The variables :term:`INITRAMFS_MULTICONFIG` and :term:`INITRAMFS_DEPLOY_DIR_IMAGE` |
| are used to create a multiconfig dependency from the kernel to the :term:`INITRAMFS_IMAGE` |
| to be built coming from the ``initramfscfg`` multiconfig, and to let the |
| buildsystem know where the :term:`INITRAMFS_IMAGE` will be located. |
| |
| Building a system with such configuration will build the kernel using the |
| main configuration but the :ref:`ref-tasks-bundle_initramfs` task will grab the |
| selected :term:`INITRAMFS_IMAGE` from :term:`INITRAMFS_DEPLOY_DIR_IMAGE` |
| instead, resulting in a musl based :term:`Initramfs` image bundled in the kernel |
| but a glibc based main image. |
| |
| The same is applicable to avoid inheriting :term:`DISTRO_FEATURES` on :term:`INITRAMFS_IMAGE` |
| or to build a different :term:`DISTRO` for it such as ``poky-tiny``. |
| |
| |
| Building a Tiny System |
| ====================== |
| |
| Very small distributions have some significant advantages such as |
| requiring less on-die or in-package memory (cheaper), better performance |
| through efficient cache usage, lower power requirements due to less |
| memory, faster boot times, and reduced development overhead. Some |
| real-world examples where a very small distribution gives you distinct |
| advantages are digital cameras, medical devices, and small headless |
| systems. |
| |
| This section presents information that shows you how you can trim your |
| distribution to even smaller sizes than the ``poky-tiny`` distribution, |
| which is around 5 Mbytes, that can be built out-of-the-box using the |
| Yocto Project. |
| |
| Tiny System Overview |
| -------------------- |
| |
| The following list presents the overall steps you need to consider and |
| perform to create distributions with smaller root filesystems, achieve |
| faster boot times, maintain your critical functionality, and avoid |
| initial RAM disks: |
| |
| - :ref:`Determine your goals and guiding principles |
| <dev-manual/building:goals and guiding principles>` |
| |
| - :ref:`dev-manual/building:understand what contributes to your image size` |
| |
| - :ref:`Reduce the size of the root filesystem |
| <dev-manual/building:trim the root filesystem>` |
| |
| - :ref:`Reduce the size of the kernel <dev-manual/building:trim the kernel>` |
| |
| - :ref:`dev-manual/building:remove package management requirements` |
| |
| - :ref:`dev-manual/building:look for other ways to minimize size` |
| |
| - :ref:`dev-manual/building:iterate on the process` |
| |
| Goals and Guiding Principles |
| ---------------------------- |
| |
| Before you can reach your destination, you need to know where you are |
| going. Here is an example list that you can use as a guide when creating |
| very small distributions: |
| |
| - Determine how much space you need (e.g. a kernel that is 1 Mbyte or |
| less and a root filesystem that is 3 Mbytes or less). |
| |
| - Find the areas that are currently taking 90% of the space and |
| concentrate on reducing those areas. |
| |
| - Do not create any difficult "hacks" to achieve your goals. |
| |
| - Leverage the device-specific options. |
| |
| - Work in a separate layer so that you keep changes isolated. For |
| information on how to create layers, see the |
| ":ref:`dev-manual/layers:understanding and creating layers`" section. |
| |
| Understand What Contributes to Your Image Size |
| ---------------------------------------------- |
| |
| It is easiest to have something to start with when creating your own |
| distribution. You can use the Yocto Project out-of-the-box to create the |
| ``poky-tiny`` distribution. Ultimately, you will want to make changes in |
| your own distribution that are likely modeled after ``poky-tiny``. |
| |
| .. note:: |
| |
| To use ``poky-tiny`` in your build, set the :term:`DISTRO` variable in your |
| ``local.conf`` file to "poky-tiny" as described in the |
| ":ref:`dev-manual/custom-distribution:creating your own distribution`" |
| section. |
| |
| Understanding some memory concepts will help you reduce the system size. |
| Memory consists of static, dynamic, and temporary memory. Static memory |
| is the TEXT (code), DATA (initialized data in the code), and BSS |
| (uninitialized data) sections. Dynamic memory represents memory that is |
| allocated at runtime: stacks, hash tables, and so forth. Temporary |
| memory is recovered after the boot process. This memory consists of |
| memory used for decompressing the kernel and for the ``__init__`` |
| functions. |
| |
| To help you see where you currently are with kernel and root filesystem |
| sizes, you can use two tools found in the :term:`Source Directory` |
| in the |
| ``scripts/tiny/`` directory: |
| |
| - ``ksize.py``: Reports component sizes for the kernel build objects. |
| |
| - ``dirsize.py``: Reports component sizes for the root filesystem. |
| |
| This next tool and command help you organize configuration fragments and |
| view file dependencies in a human-readable form: |
| |
| - ``merge_config.sh``: Helps you manage configuration files and |
| fragments within the kernel. With this tool, you can merge individual |
| configuration fragments together. The tool allows you to make |
| overrides and warns you of any missing configuration options. The |
| tool is ideal for allowing you to iterate on configurations, create |
| minimal configurations, and create configuration files for different |
| machines without having to duplicate your process. |
| |
| The ``merge_config.sh`` script is part of the Linux Yocto kernel Git |
| repositories (i.e. ``linux-yocto-3.14``, ``linux-yocto-3.10``, |
| ``linux-yocto-3.8``, and so forth) in the ``scripts/kconfig`` |
| directory. |
| |
| For more information on configuration fragments, see the |
| ":ref:`kernel-dev/common:creating configuration fragments`" |
| section in the Yocto Project Linux Kernel Development Manual. |
| |
| - ``bitbake -u taskexp -g bitbake_target``: Using the BitBake command |
| with these options brings up a Dependency Explorer from which you can |
| view file dependencies. Understanding these dependencies allows you |
| to make informed decisions when cutting out various pieces of the |
| kernel and root filesystem. |
| |
| Trim the Root Filesystem |
| ------------------------ |
| |
| The root filesystem is made up of packages for booting, libraries, and |
| applications. To change things, you can configure how the packaging |
| happens, which changes the way you build them. You can also modify the |
| filesystem itself or select a different filesystem. |
| |
| First, find out what is hogging your root filesystem by running the |
| ``dirsize.py`` script from your root directory:: |
| |
| $ cd root-directory-of-image |
| $ dirsize.py 100000 > dirsize-100k.log |
| $ cat dirsize-100k.log |
| |
| You can apply a filter to the script to ignore files |
| under a certain size. The previous example filters out any files below |
| 100 Kbytes. The sizes reported by the tool are uncompressed, and thus |
| will be smaller by a relatively constant factor in a compressed root |
| filesystem. When you examine your log file, you can focus on areas of |
| the root filesystem that take up large amounts of memory. |
| |
| You need to be sure that what you eliminate does not cripple the |
| functionality you need. One way to see how packages relate to each other |
| is by using the Dependency Explorer UI with the BitBake command:: |
| |
| $ cd image-directory |
| $ bitbake -u taskexp -g image |
| |
| Use the interface to |
| select potential packages you wish to eliminate and see their dependency |
| relationships. |
| |
| When deciding how to reduce the size, get rid of packages that result in |
| minimal impact on the feature set. For example, you might not need a VGA |
| display. Or, you might be able to get by with ``devtmpfs`` and ``mdev`` |
| instead of ``udev``. |
| |
| Use your ``local.conf`` file to make changes. For example, to eliminate |
| ``udev`` and ``glib``, set the following in the local configuration |
| file:: |
| |
| VIRTUAL-RUNTIME_dev_manager = "" |
| |
| Finally, you should consider exactly the type of root filesystem you |
| need to meet your needs while also reducing its size. For example, |
| consider ``cramfs``, ``squashfs``, ``ubifs``, ``ext2``, or an |
| :term:`Initramfs` using ``initramfs``. Be aware that ``ext3`` requires a 1 |
| Mbyte journal. If you are okay with running read-only, you do not need |
| this journal. |
| |
| .. note:: |
| |
| After each round of elimination, you need to rebuild your system and |
| then use the tools to see the effects of your reductions. |
| |
| Trim the Kernel |
| --------------- |
| |
| The kernel is built by including policies for hardware-independent |
| aspects. What subsystems do you enable? For what architecture are you |
| building? Which drivers do you build by default? |
| |
| .. note:: |
| |
| You can modify the kernel source if you want to help with boot time. |
| |
| Run the ``ksize.py`` script from the top-level Linux build directory to |
| get an idea of what is making up the kernel:: |
| |
| $ cd top-level-linux-build-directory |
| $ ksize.py > ksize.log |
| $ cat ksize.log |
| |
| When you examine the log, you will see how much space is taken up with |
| the built-in ``.o`` files for drivers, networking, core kernel files, |
| filesystem, sound, and so forth. The sizes reported by the tool are |
| uncompressed, and thus will be smaller by a relatively constant factor |
| in a compressed kernel image. Look to reduce the areas that are large |
| and taking up around the "90% rule." |
| |
| To examine, or drill down, into any particular area, use the ``-d`` |
| option with the script:: |
| |
| $ ksize.py -d > ksize.log |
| |
| Using this option |
| breaks out the individual file information for each area of the kernel |
| (e.g. drivers, networking, and so forth). |
| |
| Use your log file to see what you can eliminate from the kernel based on |
| features you can let go. For example, if you are not going to need |
| sound, you do not need any drivers that support sound. |
| |
| After figuring out what to eliminate, you need to reconfigure the kernel |
| to reflect those changes during the next build. You could run |
| ``menuconfig`` and make all your changes at once. However, that makes it |
| difficult to see the effects of your individual eliminations and also |
| makes it difficult to replicate the changes for perhaps another target |
| device. A better method is to start with no configurations using |
| ``allnoconfig``, create configuration fragments for individual changes, |
| and then manage the fragments into a single configuration file using |
| ``merge_config.sh``. The tool makes it easy for you to iterate using the |
| configuration change and build cycle. |
| |
| Each time you make configuration changes, you need to rebuild the kernel |
| and check to see what impact your changes had on the overall size. |
| |
| Remove Package Management Requirements |
| -------------------------------------- |
| |
| Packaging requirements add size to the image. One way to reduce the size |
| of the image is to remove all the packaging requirements from the image. |
| This reduction includes both removing the package manager and its unique |
| dependencies as well as removing the package management data itself. |
| |
| To eliminate all the packaging requirements for an image, be sure that |
| "package-management" is not part of your |
| :term:`IMAGE_FEATURES` |
| statement for the image. When you remove this feature, you are removing |
| the package manager as well as its dependencies from the root |
| filesystem. |
| |
| Look for Other Ways to Minimize Size |
| ------------------------------------ |
| |
| Depending on your particular circumstances, other areas that you can |
| trim likely exist. The key to finding these areas is through tools and |
| methods described here combined with experimentation and iteration. Here |
| are a couple of areas to experiment with: |
| |
| - ``glibc``: In general, follow this process: |
| |
| #. Remove ``glibc`` features from |
| :term:`DISTRO_FEATURES` |
| that you think you do not need. |
| |
| #. Build your distribution. |
| |
| #. If the build fails due to missing symbols in a package, determine |
| if you can reconfigure the package to not need those features. For |
| example, change the configuration to not support wide character |
| support as is done for ``ncurses``. Or, if support for those |
| characters is needed, determine what ``glibc`` features provide |
| the support and restore the configuration. |
| |
| 4. Rebuild and repeat the process. |
| |
| - ``busybox``: For BusyBox, use a process similar as described for |
| ``glibc``. A difference is you will need to boot the resulting system |
| to see if you are able to do everything you expect from the running |
| system. You need to be sure to integrate configuration fragments into |
| Busybox because BusyBox handles its own core features and then allows |
| you to add configuration fragments on top. |
| |
| Iterate on the Process |
| ---------------------- |
| |
| If you have not reached your goals on system size, you need to iterate |
| on the process. The process is the same. Use the tools and see just what |
| is taking up 90% of the root filesystem and the kernel. Decide what you |
| can eliminate without limiting your device beyond what you need. |
| |
| Depending on your system, a good place to look might be Busybox, which |
| provides a stripped down version of Unix tools in a single, executable |
| file. You might be able to drop virtual terminal services or perhaps |
| ipv6. |
| |
| Building Images for More than One Machine |
| ========================================= |
| |
| A common scenario developers face is creating images for several |
| different machines that use the same software environment. In this |
| situation, it is tempting to set the tunings and optimization flags for |
| each build specifically for the targeted hardware (i.e. "maxing out" the |
| tunings). Doing so can considerably add to build times and package feed |
| maintenance collectively for the machines. For example, selecting tunes |
| that are extremely specific to a CPU core used in a system might enable |
| some micro optimizations in GCC for that particular system but would |
| otherwise not gain you much of a performance difference across the other |
| systems as compared to using a more general tuning across all the builds |
| (e.g. setting :term:`DEFAULTTUNE` |
| specifically for each machine's build). Rather than "max out" each |
| build's tunings, you can take steps that cause the OpenEmbedded build |
| system to reuse software across the various machines where it makes |
| sense. |
| |
| If build speed and package feed maintenance are considerations, you |
| should consider the points in this section that can help you optimize |
| your tunings to best consider build times and package feed maintenance. |
| |
| - *Share the :term:`Build Directory`:* If at all possible, share the |
| :term:`TMPDIR` across builds. The Yocto Project supports switching between |
| different :term:`MACHINE` values in the same :term:`TMPDIR`. This practice |
| is well supported and regularly used by developers when building for |
| multiple machines. When you use the same :term:`TMPDIR` for multiple |
| machine builds, the OpenEmbedded build system can reuse the existing native |
| and often cross-recipes for multiple machines. Thus, build time decreases. |
| |
| .. note:: |
| |
| If :term:`DISTRO` settings change or fundamental configuration settings |
| such as the filesystem layout, you need to work with a clean :term:`TMPDIR`. |
| Sharing :term:`TMPDIR` under these circumstances might work but since it is |
| not guaranteed, you should use a clean :term:`TMPDIR`. |
| |
| - *Enable the Appropriate Package Architecture:* By default, the |
| OpenEmbedded build system enables three levels of package |
| architectures: "all", "tune" or "package", and "machine". Any given |
| recipe usually selects one of these package architectures (types) for |
| its output. Depending for what a given recipe creates packages, |
| making sure you enable the appropriate package architecture can |
| directly impact the build time. |
| |
| A recipe that just generates scripts can enable "all" architecture |
| because there are no binaries to build. To specifically enable "all" |
| architecture, be sure your recipe inherits the |
| :ref:`ref-classes-allarch` class. |
| This class is useful for "all" architectures because it configures |
| many variables so packages can be used across multiple architectures. |
| |
| If your recipe needs to generate packages that are machine-specific |
| or when one of the build or runtime dependencies is already |
| machine-architecture dependent, which makes your recipe also |
| machine-architecture dependent, make sure your recipe enables the |
| "machine" package architecture through the |
| :term:`MACHINE_ARCH` |
| variable:: |
| |
| PACKAGE_ARCH = "${MACHINE_ARCH}" |
| |
| When you do not |
| specifically enable a package architecture through the |
| :term:`PACKAGE_ARCH`, The |
| OpenEmbedded build system defaults to the |
| :term:`TUNE_PKGARCH` setting:: |
| |
| PACKAGE_ARCH = "${TUNE_PKGARCH}" |
| |
| - *Choose a Generic Tuning File if Possible:* Some tunes are more |
| generic and can run on multiple targets (e.g. an ``armv5`` set of |
| packages could run on ``armv6`` and ``armv7`` processors in most |
| cases). Similarly, ``i486`` binaries could work on ``i586`` and |
| higher processors. You should realize, however, that advances on |
| newer processor versions would not be used. |
| |
| If you select the same tune for several different machines, the |
| OpenEmbedded build system reuses software previously built, thus |
| speeding up the overall build time. Realize that even though a new |
| sysroot for each machine is generated, the software is not recompiled |
| and only one package feed exists. |
| |
| - *Manage Granular Level Packaging:* Sometimes there are cases where |
| injecting another level of package architecture beyond the three |
| higher levels noted earlier can be useful. For example, consider how |
| NXP (formerly Freescale) allows for the easy reuse of binary packages |
| in their layer |
| :yocto_git:`meta-freescale </meta-freescale/>`. |
| In this example, the |
| :yocto_git:`fsl-dynamic-packagearch </meta-freescale/tree/classes/fsl-dynamic-packagearch.bbclass>` |
| class shares GPU packages for i.MX53 boards because all boards share |
| the AMD GPU. The i.MX6-based boards can do the same because all |
| boards share the Vivante GPU. This class inspects the BitBake |
| datastore to identify if the package provides or depends on one of |
| the sub-architecture values. If so, the class sets the |
| :term:`PACKAGE_ARCH` value |
| based on the ``MACHINE_SUBARCH`` value. If the package does not |
| provide or depend on one of the sub-architecture values but it |
| matches a value in the machine-specific filter, it sets |
| :term:`MACHINE_ARCH`. This |
| behavior reduces the number of packages built and saves build time by |
| reusing binaries. |
| |
| - *Use Tools to Debug Issues:* Sometimes you can run into situations |
| where software is being rebuilt when you think it should not be. For |
| example, the OpenEmbedded build system might not be using shared |
| state between machines when you think it should be. These types of |
| situations are usually due to references to machine-specific |
| variables such as :term:`MACHINE`, |
| :term:`SERIAL_CONSOLES`, |
| :term:`XSERVER`, |
| :term:`MACHINE_FEATURES`, |
| and so forth in code that is supposed to only be tune-specific or |
| when the recipe depends |
| (:term:`DEPENDS`, |
| :term:`RDEPENDS`, |
| :term:`RRECOMMENDS`, |
| :term:`RSUGGESTS`, and so forth) |
| on some other recipe that already has |
| :term:`PACKAGE_ARCH` defined |
| as "${MACHINE_ARCH}". |
| |
| .. note:: |
| |
| Patches to fix any issues identified are most welcome as these |
| issues occasionally do occur. |
| |
| For such cases, you can use some tools to help you sort out the |
| situation: |
| |
| - ``state-diff-machines.sh``*:* You can find this tool in the |
| ``scripts`` directory of the Source Repositories. See the comments |
| in the script for information on how to use the tool. |
| |
| - *BitBake's "-S printdiff" Option:* Using this option causes |
| BitBake to try to establish the closest signature match it can |
| (e.g. in the shared state cache) and then run ``bitbake-diffsigs`` |
| over the matches to determine the stamps and delta where these two |
| stamp trees diverge. |
| |
| Building Software from an External Source |
| ========================================= |
| |
| By default, the OpenEmbedded build system uses the :term:`Build Directory` |
| when building source code. The build process involves fetching the source |
| files, unpacking them, and then patching them if necessary before the build |
| takes place. |
| |
| There are situations where you might want to build software from source |
| files that are external to and thus outside of the OpenEmbedded build |
| system. For example, suppose you have a project that includes a new BSP |
| with a heavily customized kernel. And, you want to minimize exposing the |
| build system to the development team so that they can focus on their |
| project and maintain everyone's workflow as much as possible. In this |
| case, you want a kernel source directory on the development machine |
| where the development occurs. You want the recipe's |
| :term:`SRC_URI` variable to point to |
| the external directory and use it as is, not copy it. |
| |
| To build from software that comes from an external source, all you need to do |
| is inherit the :ref:`ref-classes-externalsrc` class and then set |
| the :term:`EXTERNALSRC` variable to point to your external source code. Here |
| are the statements to put in your ``local.conf`` file:: |
| |
| INHERIT += "externalsrc" |
| EXTERNALSRC:pn-myrecipe = "path-to-your-source-tree" |
| |
| This next example shows how to accomplish the same thing by setting |
| :term:`EXTERNALSRC` in the recipe itself or in the recipe's append file:: |
| |
| EXTERNALSRC = "path" |
| EXTERNALSRC_BUILD = "path" |
| |
| .. note:: |
| |
| In order for these settings to take effect, you must globally or |
| locally inherit the :ref:`ref-classes-externalsrc` class. |
| |
| By default, :ref:`ref-classes-externalsrc` builds the source code in a |
| directory separate from the external source directory as specified by |
| :term:`EXTERNALSRC`. If you need |
| to have the source built in the same directory in which it resides, or |
| some other nominated directory, you can set |
| :term:`EXTERNALSRC_BUILD` |
| to point to that directory:: |
| |
| EXTERNALSRC_BUILD:pn-myrecipe = "path-to-your-source-tree" |
| |
| Replicating a Build Offline |
| =========================== |
| |
| It can be useful to take a "snapshot" of upstream sources used in a |
| build and then use that "snapshot" later to replicate the build offline. |
| To do so, you need to first prepare and populate your downloads |
| directory your "snapshot" of files. Once your downloads directory is |
| ready, you can use it at any time and from any machine to replicate your |
| build. |
| |
| Follow these steps to populate your Downloads directory: |
| |
| #. *Create a Clean Downloads Directory:* Start with an empty downloads |
| directory (:term:`DL_DIR`). You |
| start with an empty downloads directory by either removing the files |
| in the existing directory or by setting :term:`DL_DIR` to point to either |
| an empty location or one that does not yet exist. |
| |
| #. *Generate Tarballs of the Source Git Repositories:* Edit your |
| ``local.conf`` configuration file as follows:: |
| |
| DL_DIR = "/home/your-download-dir/" |
| BB_GENERATE_MIRROR_TARBALLS = "1" |
| |
| During |
| the fetch process in the next step, BitBake gathers the source files |
| and creates tarballs in the directory pointed to by :term:`DL_DIR`. See |
| the |
| :term:`BB_GENERATE_MIRROR_TARBALLS` |
| variable for more information. |
| |
| #. *Populate Your Downloads Directory Without Building:* Use BitBake to |
| fetch your sources but inhibit the build:: |
| |
| $ bitbake target --runonly=fetch |
| |
| The downloads directory (i.e. ``${DL_DIR}``) now has |
| a "snapshot" of the source files in the form of tarballs, which can |
| be used for the build. |
| |
| #. *Optionally Remove Any Git or other SCM Subdirectories From the |
| Downloads Directory:* If you want, you can clean up your downloads |
| directory by removing any Git or other Source Control Management |
| (SCM) subdirectories such as ``${DL_DIR}/git2/*``. The tarballs |
| already contain these subdirectories. |
| |
| Once your downloads directory has everything it needs regarding source |
| files, you can create your "own-mirror" and build your target. |
| Understand that you can use the files to build the target offline from |
| any machine and at any time. |
| |
| Follow these steps to build your target using the files in the downloads |
| directory: |
| |
| #. *Using Local Files Only:* Inside your ``local.conf`` file, add the |
| :term:`SOURCE_MIRROR_URL` variable, inherit the |
| :ref:`ref-classes-own-mirrors` class, and use the |
| :term:`BB_NO_NETWORK` variable to your ``local.conf``:: |
| |
| SOURCE_MIRROR_URL ?= "file:///home/your-download-dir/" |
| INHERIT += "own-mirrors" |
| BB_NO_NETWORK = "1" |
| |
| The :term:`SOURCE_MIRROR_URL` and :ref:`ref-classes-own-mirrors` |
| class set up the system to use the downloads directory as your "own |
| mirror". Using the :term:`BB_NO_NETWORK` variable makes sure that |
| BitBake's fetching process in step 3 stays local, which means files |
| from your "own-mirror" are used. |
| |
| #. *Start With a Clean Build:* You can start with a clean build by |
| removing the ``${``\ :term:`TMPDIR`\ ``}`` directory or using a new |
| :term:`Build Directory`. |
| |
| #. *Build Your Target:* Use BitBake to build your target:: |
| |
| $ bitbake target |
| |
| The build completes using the known local "snapshot" of source |
| files from your mirror. The resulting tarballs for your "snapshot" of |
| source files are in the downloads directory. |
| |
| .. note:: |
| |
| The offline build does not work if recipes attempt to find the |
| latest version of software by setting |
| :term:`SRCREV` to |
| ``${``\ :term:`AUTOREV`\ ``}``:: |
| |
| SRCREV = "${AUTOREV}" |
| |
| When a recipe sets :term:`SRCREV` to |
| ``${``\ :term:`AUTOREV`\ ``}``, the build system accesses the network in an |
| attempt to determine the latest version of software from the SCM. |
| Typically, recipes that use :term:`AUTOREV` are custom or modified |
| recipes. Recipes that reside in public repositories usually do not |
| use :term:`AUTOREV`. |
| |
| If you do have recipes that use :term:`AUTOREV`, you can take steps to |
| still use the recipes in an offline build. Do the following: |
| |
| #. Use a configuration generated by enabling :ref:`build |
| history <dev-manual/build-quality:maintaining build output quality>`. |
| |
| #. Use the ``buildhistory-collect-srcrevs`` command to collect the |
| stored :term:`SRCREV` values from the build's history. For more |
| information on collecting these values, see the |
| ":ref:`dev-manual/build-quality:build history package information`" |
| section. |
| |
| #. Once you have the correct source revisions, you can modify |
| those recipes to set :term:`SRCREV` to specific versions of the |
| software. |
| |