| .. SPDX-License-Identifier: CC-BY-SA-2.0-UK |
| |
| ************************ |
| Using the Extensible SDK |
| ************************ |
| |
| This chapter describes the extensible SDK and how to install it. |
| Information covers the pieces of the SDK, how to install it, and |
| presents a look at using the ``devtool`` functionality. The extensible |
| SDK makes it easy to add new applications and libraries to an image, |
| modify the source for an existing component, test changes on the target |
| hardware, and ease integration into the rest of the |
| :term:`OpenEmbedded Build System`. |
| |
| .. note:: |
| |
| For a side-by-side comparison of main features supported for an |
| extensible SDK as compared to a standard SDK, see the |
| :ref:`sdk-manual/intro:introduction` section. |
| |
| In addition to the functionality available through ``devtool``, you can |
| alternatively make use of the toolchain directly, for example from |
| Makefile and Autotools. See the |
| ":ref:`sdk-manual/working-projects:using the sdk toolchain directly`" chapter |
| for more information. |
| |
| Why use the Extensible SDK and What is in It? |
| ============================================= |
| |
| The extensible SDK provides a cross-development toolchain and libraries |
| tailored to the contents of a specific image. You would use the |
| Extensible SDK if you want a toolchain experience supplemented with the |
| powerful set of ``devtool`` commands tailored for the Yocto Project |
| environment. |
| |
| The installed extensible SDK consists of several files and directories. |
| Basically, it contains an SDK environment setup script, some |
| configuration files, an internal build system, and the ``devtool`` |
| functionality. |
| |
| Installing the Extensible SDK |
| ============================= |
| |
| Two ways to install the Extensible SDK |
| -------------------------------------- |
| |
| Extensible SDK can be installed in two different ways, and both have |
| their own pros and cons: |
| |
| 1. *Setting up the Extensible SDK environment directly in a Yocto build*. This |
| avoids having to produce, test, distribute and maintain separate SDK installer |
| archives, which can get very large. There is only one environment for the regular |
| Yocto build and the SDK and less code paths where things can go not according to plan. |
| It's easier to update the SDK: it simply means updating the Yocto layers with |
| git fetch or layer management tooling. The SDK extensibility is better than in the |
| second option: just run ``bitbake`` again to add more things to the sysroot, or add layers |
| if even more things are required. |
| |
| 2. *Setting up the Extensible SDK from a standalone installer*. This has the benefit of |
| having a single, self-contained archive that includes all the needed binary artifacts. |
| So nothing needs to be rebuilt, and there is no need to provide a well-functioning |
| binary artefact cache over the network for developers with underpowered laptops. |
| |
| Setting up the Extensible SDK environment directly in a Yocto build |
| ------------------------------------------------------------------- |
| |
| 1. Set up all the needed layers and a Yocto :term:`Build Directory`, e.g. a regular Yocto |
| build where ``bitbake`` can be executed. |
| |
| 2. Run: |
| $ bitbake meta-ide-support |
| $ bitbake -c populate_sysroot gtk+3 |
| (or any other target or native item that the application developer would need) |
| $ bitbake build-sysroots |
| |
| |
| Setting up the Extensible SDK from a standalone installer |
| --------------------------------------------------------- |
| |
| The first thing you need to do is install the SDK on your :term:`Build |
| Host` by running the ``*.sh`` installation script. |
| |
| You can download a tarball installer, which includes the pre-built |
| toolchain, the ``runqemu`` script, the internal build system, |
| ``devtool``, and support files from the appropriate |
| :yocto_dl:`toolchain </releases/yocto/yocto-&DISTRO;/toolchain/>` directory within the Index of |
| Releases. Toolchains are available for several 32-bit and 64-bit |
| architectures with the ``x86_64`` directories, respectively. The |
| toolchains the Yocto Project provides are based off the |
| ``core-image-sato`` and ``core-image-minimal`` images and contain |
| libraries appropriate for developing against that image. |
| |
| The names of the tarball installer scripts are such that a string |
| representing the host system appears first in the filename and then is |
| immediately followed by a string representing the target architecture. |
| An extensible SDK has the string "-ext" as part of the name. Following |
| is the general form:: |
| |
| poky-glibc-host_system-image_type-arch-toolchain-ext-release_version.sh |
| |
| Where: |
| host_system is a string representing your development system: |
| |
| i686 or x86_64. |
| |
| image_type is the image for which the SDK was built: |
| |
| core-image-sato or core-image-minimal |
| |
| arch is a string representing the tuned target architecture: |
| |
| aarch64, armv5e, core2-64, i586, mips32r2, mips64, ppc7400, or cortexa8hf-neon |
| |
| release_version is a string representing the release number of the Yocto Project: |
| |
| &DISTRO;, &DISTRO;+snapshot |
| |
| For example, the following SDK installer is for a 64-bit |
| development host system and a i586-tuned target architecture based off |
| the SDK for ``core-image-sato`` and using the current &DISTRO; snapshot:: |
| |
| poky-glibc-x86_64-core-image-sato-i586-toolchain-ext-&DISTRO;.sh |
| |
| .. note:: |
| |
| As an alternative to downloading an SDK, you can build the SDK |
| installer. For information on building the installer, see the |
| :ref:`sdk-manual/appendix-obtain:building an sdk installer` |
| section. |
| |
| The SDK and toolchains are self-contained and by default are installed |
| into the ``poky_sdk`` folder in your home directory. You can choose to |
| install the extensible SDK in any location when you run the installer. |
| However, because files need to be written under that directory during |
| the normal course of operation, the location you choose for installation |
| must be writable for whichever users need to use the SDK. |
| |
| The following command shows how to run the installer given a toolchain |
| tarball for a 64-bit x86 development host system and a 64-bit x86 target |
| architecture. The example assumes the SDK installer is located in |
| ``~/Downloads/`` and has execution rights. |
| |
| .. note:: |
| |
| If you do not have write permissions for the directory into which you |
| are installing the SDK, the installer notifies you and exits. For |
| that case, set up the proper permissions in the directory and run the |
| installer again. |
| |
| :: |
| |
| $ ./Downloads/poky-glibc-x86_64-core-image-minimal-core2-64-toolchain-ext-2.5.sh |
| Poky (Yocto Project Reference Distro) Extensible SDK installer version 2.5 |
| ========================================================================== |
| Enter target directory for SDK (default: poky_sdk): |
| You are about to install the SDK to "/home/scottrif/poky_sdk". Proceed [Y/n]? Y |
| Extracting SDK..............done |
| Setting it up... |
| Extracting buildtools... |
| Preparing build system... |
| Parsing recipes: 100% |##################################################################| Time: 0:00:52 |
| Initialising tasks: 100% |###############################################################| Time: 0:00:00 |
| Checking sstate mirror object availability: 100% |#######################################| Time: 0:00:00 |
| Loading cache: 100% |####################################################################| Time: 0:00:00 |
| Initialising tasks: 100% |###############################################################| Time: 0:00:00 |
| done |
| SDK has been successfully set up and is ready to be used. |
| Each time you wish to use the SDK in a new shell session, you need to source the environment setup script e.g. |
| $ . /home/scottrif/poky_sdk/environment-setup-core2-64-poky-linux |
| |
| Running the Extensible SDK Environment Setup Script |
| =================================================== |
| |
| Once you have the SDK installed, you must run the SDK environment setup |
| script before you can actually use the SDK. |
| |
| When using a SDK directly in a Yocto build, you will find the script in |
| ``tmp/deploy/images/qemux86-64/`` in your :term:`Build Directory`. |
| |
| When using a standalone SDK installer, this setup script resides in |
| the directory you chose when you installed the SDK, which is either the |
| default ``poky_sdk`` directory or the directory you chose during |
| installation. |
| |
| Before running the script, be sure it is the one that matches the |
| architecture for which you are developing. Environment setup scripts |
| begin with the string "``environment-setup``" and include as part of |
| their name the tuned target architecture. As an example, the following |
| commands set the working directory to where the SDK was installed and |
| then source the environment setup script. In this example, the setup |
| script is for an IA-based target machine using i586 tuning:: |
| |
| $ cd /home/scottrif/poky_sdk |
| $ source environment-setup-core2-64-poky-linux |
| SDK environment now set up; additionally you may now run devtool to perform development tasks. |
| Run devtool --help for further details. |
| |
| When using the environment script directly in a Yocto build, it can |
| be run similarly: |
| |
| $ source tmp/deploy/images/qemux86-64/environment-setup-core2-64-poky-linux |
| |
| Running the setup script defines many environment variables needed in |
| order to use the SDK (e.g. ``PATH``, |
| :term:`CC`, |
| :term:`LD`, and so forth). If you want to |
| see all the environment variables the script exports, examine the |
| installation file itself. |
| |
| Using ``devtool`` in Your SDK Workflow |
| ====================================== |
| |
| The cornerstone of the extensible SDK is a command-line tool called |
| ``devtool``. This tool provides a number of features that help you |
| build, test and package software within the extensible SDK, and |
| optionally integrate it into an image built by the OpenEmbedded build |
| system. |
| |
| .. note:: |
| |
| The use of |
| devtool |
| is not limited to the extensible SDK. You can use |
| devtool |
| to help you easily develop any project whose build output must be |
| part of an image built using the build system. |
| |
| The ``devtool`` command line is organized similarly to |
| :ref:`overview-manual/development-environment:git` in that it has a number of |
| sub-commands for each function. You can run ``devtool --help`` to see |
| all the commands. |
| |
| .. note:: |
| |
| See the " |
| devtool |
| Quick Reference |
| " in the Yocto Project Reference Manual for a |
| devtool |
| quick reference. |
| |
| Three ``devtool`` subcommands provide entry-points into |
| development: |
| |
| - *devtool add*: Assists in adding new software to be built. |
| |
| - *devtool modify*: Sets up an environment to enable you to modify |
| the source of an existing component. |
| |
| - *devtool upgrade*: Updates an existing recipe so that you can |
| build it for an updated set of source files. |
| |
| As with the build system, "recipes" represent software packages within |
| ``devtool``. When you use ``devtool add``, a recipe is automatically |
| created. When you use ``devtool modify``, the specified existing recipe |
| is used in order to determine where to get the source code and how to |
| patch it. In both cases, an environment is set up so that when you build |
| the recipe a source tree that is under your control is used in order to |
| allow you to make changes to the source as desired. By default, new |
| recipes and the source go into a "workspace" directory under the SDK. |
| |
| The remainder of this section presents the ``devtool add``, |
| ``devtool modify``, and ``devtool upgrade`` workflows. |
| |
| Use ``devtool add`` to Add an Application |
| ----------------------------------------- |
| |
| The ``devtool add`` command generates a new recipe based on existing |
| source code. This command takes advantage of the |
| :ref:`devtool-the-workspace-layer-structure` |
| layer that many ``devtool`` commands use. The command is flexible enough |
| to allow you to extract source code into both the workspace or a |
| separate local Git repository and to use existing code that does not |
| need to be extracted. |
| |
| Depending on your particular scenario, the arguments and options you use |
| with ``devtool add`` form different combinations. The following diagram |
| shows common development flows you would use with the ``devtool add`` |
| command: |
| |
| .. image:: figures/sdk-devtool-add-flow.png |
| :width: 100% |
| |
| 1. *Generating the New Recipe*: The top part of the flow shows three |
| scenarios by which you could use ``devtool add`` to generate a recipe |
| based on existing source code. |
| |
| In a shared development environment, it is typical for other |
| developers to be responsible for various areas of source code. As a |
| developer, you are probably interested in using that source code as |
| part of your development within the Yocto Project. All you need is |
| access to the code, a recipe, and a controlled area in which to do |
| your work. |
| |
| Within the diagram, three possible scenarios feed into the |
| ``devtool add`` workflow: |
| |
| - *Left*: The left scenario in the figure represents a common |
| situation where the source code does not exist locally and needs |
| to be extracted. In this situation, the source code is extracted |
| to the default workspace --- you do not want the files in some |
| specific location outside of the workspace. Thus, everything you |
| need will be located in the workspace:: |
| |
| $ devtool add recipe fetchuri |
| |
| With this command, ``devtool`` extracts the upstream |
| source files into a local Git repository within the ``sources`` |
| folder. The command then creates a recipe named recipe and a |
| corresponding append file in the workspace. If you do not provide |
| recipe, the command makes an attempt to determine the recipe name. |
| |
| - *Middle*: The middle scenario in the figure also represents a |
| situation where the source code does not exist locally. In this |
| case, the code is again upstream and needs to be extracted to some |
| local area --- this time outside of the default workspace. |
| |
| .. note:: |
| |
| If required, |
| devtool |
| always creates a Git repository locally during the extraction. |
| |
| Furthermore, the first positional argument ``srctree`` in this case |
| identifies where the ``devtool add`` command will locate the |
| extracted code outside of the workspace. You need to specify an |
| empty directory:: |
| |
| $ devtool add recipe srctree fetchuri |
| |
| In summary, |
| the source code is pulled from fetchuri and extracted into the |
| location defined by ``srctree`` as a local Git repository. |
| |
| Within workspace, ``devtool`` creates a recipe named recipe along |
| with an associated append file. |
| |
| - *Right*: The right scenario in the figure represents a situation |
| where the ``srctree`` has been previously prepared outside of the |
| ``devtool`` workspace. |
| |
| The following command provides a new recipe name and identifies |
| the existing source tree location:: |
| |
| $ devtool add recipe srctree |
| |
| The command examines the source code and creates a recipe named |
| recipe for the code and places the recipe into the workspace. |
| |
| Because the extracted source code already exists, ``devtool`` does |
| not try to relocate the source code into the workspace --- only the |
| new recipe is placed in the workspace. |
| |
| Aside from a recipe folder, the command also creates an associated |
| append folder and places an initial ``*.bbappend`` file within. |
| |
| 2. *Edit the Recipe*: You can use ``devtool edit-recipe`` to open up the |
| editor as defined by the ``$EDITOR`` environment variable and modify |
| the file:: |
| |
| $ devtool edit-recipe recipe |
| |
| From within the editor, you |
| can make modifications to the recipe that take effect when you build |
| it later. |
| |
| 3. *Build the Recipe or Rebuild the Image*: The next step you take |
| depends on what you are going to do with the new code. |
| |
| If you need to eventually move the build output to the target |
| hardware, use the following ``devtool`` command: |
| :; |
| |
| $ devtool build recipe |
| |
| On the other hand, if you want an image to contain the recipe's |
| packages from the workspace for immediate deployment onto a device |
| (e.g. for testing purposes), you can use the ``devtool build-image`` |
| command:: |
| |
| $ devtool build-image image |
| |
| 4. *Deploy the Build Output*: When you use the ``devtool build`` command |
| to build out your recipe, you probably want to see if the resulting |
| build output works as expected on the target hardware. |
| |
| .. note:: |
| |
| This step assumes you have a previously built image that is |
| already either running in QEMU or is running on actual hardware. |
| Also, it is assumed that for deployment of the image to the |
| target, SSH is installed in the image and, if the image is running |
| on real hardware, you have network access to and from your |
| development machine. |
| |
| You can deploy your build output to that target hardware by using the |
| ``devtool deploy-target`` command: $ devtool deploy-target recipe |
| target The target is a live target machine running as an SSH server. |
| |
| You can, of course, also deploy the image you build to actual |
| hardware by using the ``devtool build-image`` command. However, |
| ``devtool`` does not provide a specific command that allows you to |
| deploy the image to actual hardware. |
| |
| 5. *Finish Your Work With the Recipe*: The ``devtool finish`` command |
| creates any patches corresponding to commits in the local Git |
| repository, moves the new recipe to a more permanent layer, and then |
| resets the recipe so that the recipe is built normally rather than |
| from the workspace. |
| :: |
| |
| $ devtool finish recipe layer |
| |
| .. note:: |
| |
| Any changes you want to turn into patches must be committed to the |
| Git repository in the source tree. |
| |
| As mentioned, the ``devtool finish`` command moves the final recipe |
| to its permanent layer. |
| |
| As a final process of the ``devtool finish`` command, the state of |
| the standard layers and the upstream source is restored so that you |
| can build the recipe from those areas rather than the workspace. |
| |
| .. note:: |
| |
| You can use the |
| devtool reset |
| command to put things back should you decide you do not want to |
| proceed with your work. If you do use this command, realize that |
| the source tree is preserved. |
| |
| Use ``devtool modify`` to Modify the Source of an Existing Component |
| -------------------------------------------------------------------- |
| |
| The ``devtool modify`` command prepares the way to work on existing code |
| that already has a local recipe in place that is used to build the |
| software. The command is flexible enough to allow you to extract code |
| from an upstream source, specify the existing recipe, and keep track of |
| and gather any patch files from other developers that are associated |
| with the code. |
| |
| Depending on your particular scenario, the arguments and options you use |
| with ``devtool modify`` form different combinations. The following |
| diagram shows common development flows for the ``devtool modify`` |
| command: |
| |
| .. image:: figures/sdk-devtool-modify-flow.png |
| :width: 100% |
| |
| 1. *Preparing to Modify the Code*: The top part of the flow shows three |
| scenarios by which you could use ``devtool modify`` to prepare to |
| work on source files. Each scenario assumes the following: |
| |
| - The recipe exists locally in a layer external to the ``devtool`` |
| workspace. |
| |
| - The source files exist either upstream in an un-extracted state or |
| locally in a previously extracted state. |
| |
| The typical situation is where another developer has created a layer |
| for use with the Yocto Project and their recipe already resides in |
| that layer. Furthermore, their source code is readily available |
| either upstream or locally. |
| |
| - *Left*: The left scenario in the figure represents a common |
| situation where the source code does not exist locally and it |
| needs to be extracted from an upstream source. In this situation, |
| the source is extracted into the default ``devtool`` workspace |
| location. The recipe, in this scenario, is in its own layer |
| outside the workspace (i.e. ``meta-``\ layername). |
| |
| The following command identifies the recipe and, by default, |
| extracts the source files:: |
| |
| $ devtool modify recipe |
| |
| Once |
| ``devtool``\ locates the recipe, ``devtool`` uses the recipe's |
| :term:`SRC_URI` statements to |
| locate the source code and any local patch files from other |
| developers. |
| |
| With this scenario, there is no ``srctree`` argument. Consequently, the |
| default behavior of the ``devtool modify`` command is to extract |
| the source files pointed to by the :term:`SRC_URI` statements into a |
| local Git structure. Furthermore, the location for the extracted |
| source is the default area within the ``devtool`` workspace. The |
| result is that the command sets up both the source code and an |
| append file within the workspace while the recipe remains in its |
| original location. |
| |
| Additionally, if you have any non-patch local files (i.e. files |
| referred to with ``file://`` entries in :term:`SRC_URI` statement |
| excluding ``*.patch/`` or ``*.diff``), these files are copied to |
| an ``oe-local-files`` folder under the newly created source tree. |
| Copying the files here gives you a convenient area from which you |
| can modify the files. Any changes or additions you make to those |
| files are incorporated into the build the next time you build the |
| software just as are other changes you might have made to the |
| source. |
| |
| - *Middle*: The middle scenario in the figure represents a situation |
| where the source code also does not exist locally. In this case, |
| the code is again upstream and needs to be extracted to some local |
| area as a Git repository. The recipe, in this scenario, is again |
| local and in its own layer outside the workspace. |
| |
| The following command tells ``devtool`` the recipe with which to |
| work and, in this case, identifies a local area for the extracted |
| source files that exists outside of the default ``devtool`` |
| workspace:: |
| |
| $ devtool modify recipe srctree |
| |
| .. note:: |
| |
| You cannot provide a URL for |
| srctree |
| using the |
| devtool |
| command. |
| |
| As with all extractions, the command uses the recipe's :term:`SRC_URI` |
| statements to locate the source files and any associated patch |
| files. Non-patch files are copied to an ``oe-local-files`` folder |
| under the newly created source tree. |
| |
| Once the files are located, the command by default extracts them |
| into ``srctree``. |
| |
| Within workspace, ``devtool`` creates an append file for the |
| recipe. The recipe remains in its original location but the source |
| files are extracted to the location you provide with ``srctree``. |
| |
| - *Right*: The right scenario in the figure represents a situation |
| where the source tree (``srctree``) already exists locally as a |
| previously extracted Git structure outside of the ``devtool`` |
| workspace. In this example, the recipe also exists elsewhere |
| locally in its own layer. |
| |
| The following command tells ``devtool`` the recipe with which to |
| work, uses the "-n" option to indicate source does not need to be |
| extracted, and uses ``srctree`` to point to the previously extracted |
| source files:: |
| |
| $ devtool modify -n recipe srctree |
| |
| If an ``oe-local-files`` subdirectory happens to exist and it |
| contains non-patch files, the files are used. However, if the |
| subdirectory does not exist and you run the ``devtool finish`` |
| command, any non-patch files that might exist next to the recipe |
| are removed because it appears to ``devtool`` that you have |
| deleted those files. |
| |
| Once the ``devtool modify`` command finishes, it creates only an |
| append file for the recipe in the ``devtool`` workspace. The |
| recipe and the source code remain in their original locations. |
| |
| 2. *Edit the Source*: Once you have used the ``devtool modify`` command, |
| you are free to make changes to the source files. You can use any |
| editor you like to make and save your source code modifications. |
| |
| 3. *Build the Recipe or Rebuild the Image*: The next step you take |
| depends on what you are going to do with the new code. |
| |
| If you need to eventually move the build output to the target |
| hardware, use the following ``devtool`` command:: |
| |
| $ devtool build recipe |
| |
| On the other hand, if you want an image to contain the recipe's |
| packages from the workspace for immediate deployment onto a device |
| (e.g. for testing purposes), you can use the ``devtool build-image`` |
| command: $ devtool build-image image |
| |
| 4. *Deploy the Build Output*: When you use the ``devtool build`` command |
| to build out your recipe, you probably want to see if the resulting |
| build output works as expected on target hardware. |
| |
| .. note:: |
| |
| This step assumes you have a previously built image that is |
| already either running in QEMU or running on actual hardware. |
| Also, it is assumed that for deployment of the image to the |
| target, SSH is installed in the image and if the image is running |
| on real hardware that you have network access to and from your |
| development machine. |
| |
| You can deploy your build output to that target hardware by using the |
| ``devtool deploy-target`` command:: |
| |
| $ devtool deploy-target recipe target |
| |
| The target is a live target machine running as an SSH server. |
| |
| You can, of course, use other methods to deploy the image you built |
| using the ``devtool build-image`` command to actual hardware. |
| ``devtool`` does not provide a specific command to deploy the image |
| to actual hardware. |
| |
| 5. *Finish Your Work With the Recipe*: The ``devtool finish`` command |
| creates any patches corresponding to commits in the local Git |
| repository, updates the recipe to point to them (or creates a |
| ``.bbappend`` file to do so, depending on the specified destination |
| layer), and then resets the recipe so that the recipe is built |
| normally rather than from the workspace. |
| :: |
| |
| $ devtool finish recipe layer |
| |
| .. note:: |
| |
| Any changes you want to turn into patches must be staged and |
| committed within the local Git repository before you use the |
| devtool finish |
| command. |
| |
| Because there is no need to move the recipe, ``devtool finish`` |
| either updates the original recipe in the original layer or the |
| command creates a ``.bbappend`` file in a different layer as provided |
| by layer. Any work you did in the ``oe-local-files`` directory is |
| preserved in the original files next to the recipe during the |
| ``devtool finish`` command. |
| |
| As a final process of the ``devtool finish`` command, the state of |
| the standard layers and the upstream source is restored so that you |
| can build the recipe from those areas rather than from the workspace. |
| |
| .. note:: |
| |
| You can use the |
| devtool reset |
| command to put things back should you decide you do not want to |
| proceed with your work. If you do use this command, realize that |
| the source tree is preserved. |
| |
| Use ``devtool upgrade`` to Create a Version of the Recipe that Supports a Newer Version of the Software |
| ------------------------------------------------------------------------------------------------------- |
| |
| The ``devtool upgrade`` command upgrades an existing recipe to that of a |
| more up-to-date version found upstream. Throughout the life of software, |
| recipes continually undergo version upgrades by their upstream |
| publishers. You can use the ``devtool upgrade`` workflow to make sure |
| your recipes you are using for builds are up-to-date with their upstream |
| counterparts. |
| |
| .. note:: |
| |
| Several methods exist by which you can upgrade recipes - |
| ``devtool upgrade`` |
| happens to be one. You can read about all the methods by which you |
| can upgrade recipes in the |
| :ref:`dev-manual/common-tasks:upgrading recipes` section |
| of the Yocto Project Development Tasks Manual. |
| |
| The ``devtool upgrade`` command is flexible enough to allow you to |
| specify source code revision and versioning schemes, extract code into |
| or out of the ``devtool`` |
| :ref:`devtool-the-workspace-layer-structure`, |
| and work with any source file forms that the |
| :ref:`bitbake:bitbake-user-manual/bitbake-user-manual-fetching:fetchers` support. |
| |
| The following diagram shows the common development flow used with the |
| ``devtool upgrade`` command: |
| |
| .. image:: figures/sdk-devtool-upgrade-flow.png |
| :width: 100% |
| |
| 1. *Initiate the Upgrade*: The top part of the flow shows the typical |
| scenario by which you use the ``devtool upgrade`` command. The |
| following conditions exist: |
| |
| - The recipe exists in a local layer external to the ``devtool`` |
| workspace. |
| |
| - The source files for the new release exist in the same location |
| pointed to by :term:`SRC_URI` |
| in the recipe (e.g. a tarball with the new version number in the |
| name, or as a different revision in the upstream Git repository). |
| |
| A common situation is where third-party software has undergone a |
| revision so that it has been upgraded. The recipe you have access to |
| is likely in your own layer. Thus, you need to upgrade the recipe to |
| use the newer version of the software:: |
| |
| $ devtool upgrade -V version recipe |
| |
| By default, the ``devtool upgrade`` command extracts source |
| code into the ``sources`` directory in the |
| :ref:`devtool-the-workspace-layer-structure`. |
| If you want the code extracted to any other location, you need to |
| provide the ``srctree`` positional argument with the command as follows:: |
| |
| $ devtool upgrade -V version recipe srctree |
| |
| .. note:: |
| |
| In this example, the "-V" option specifies the new version. If you |
| don't use "-V", the command upgrades the recipe to the latest |
| version. |
| |
| If the source files pointed to by the :term:`SRC_URI` statement in the |
| recipe are in a Git repository, you must provide the "-S" option and |
| specify a revision for the software. |
| |
| Once ``devtool`` locates the recipe, it uses the :term:`SRC_URI` variable |
| to locate the source code and any local patch files from other |
| developers. The result is that the command sets up the source code, |
| the new version of the recipe, and an append file all within the |
| workspace. |
| |
| Additionally, if you have any non-patch local files (i.e. files |
| referred to with ``file://`` entries in :term:`SRC_URI` statement |
| excluding ``*.patch/`` or ``*.diff``), these files are copied to an |
| ``oe-local-files`` folder under the newly created source tree. |
| Copying the files here gives you a convenient area from which you can |
| modify the files. Any changes or additions you make to those files |
| are incorporated into the build the next time you build the software |
| just as are other changes you might have made to the source. |
| |
| 2. *Resolve any Conflicts created by the Upgrade*: Conflicts could happen |
| after upgrading the software to a new version. Conflicts occur |
| if your recipe specifies some patch files in :term:`SRC_URI` that |
| conflict with changes made in the new version of the software. For |
| such cases, you need to resolve the conflicts by editing the source |
| and following the normal ``git rebase`` conflict resolution process. |
| |
| Before moving onto the next step, be sure to resolve any such |
| conflicts created through use of a newer or different version of the |
| software. |
| |
| 3. *Build the Recipe or Rebuild the Image*: The next step you take |
| depends on what you are going to do with the new code. |
| |
| If you need to eventually move the build output to the target |
| hardware, use the following ``devtool`` command:: |
| |
| $ devtool build recipe |
| |
| On the other hand, if you want an image to contain the recipe's |
| packages from the workspace for immediate deployment onto a device |
| (e.g. for testing purposes), you can use the ``devtool build-image`` |
| command:: |
| |
| $ devtool build-image image |
| |
| 4. *Deploy the Build Output*: When you use the ``devtool build`` command |
| or ``bitbake`` to build your recipe, you probably want to see if the |
| resulting build output works as expected on target hardware. |
| |
| .. note:: |
| |
| This step assumes you have a previously built image that is |
| already either running in QEMU or running on actual hardware. |
| Also, it is assumed that for deployment of the image to the |
| target, SSH is installed in the image and if the image is running |
| on real hardware that you have network access to and from your |
| development machine. |
| |
| You can deploy your build output to that target hardware by using the |
| ``devtool deploy-target`` command: $ devtool deploy-target recipe |
| target The target is a live target machine running as an SSH server. |
| |
| You can, of course, also deploy the image you build using the |
| ``devtool build-image`` command to actual hardware. However, |
| ``devtool`` does not provide a specific command that allows you to do |
| this. |
| |
| 5. *Finish Your Work With the Recipe*: The ``devtool finish`` command |
| creates any patches corresponding to commits in the local Git |
| repository, moves the new recipe to a more permanent layer, and then |
| resets the recipe so that the recipe is built normally rather than |
| from the workspace. |
| |
| Any work you did in the ``oe-local-files`` directory is preserved in |
| the original files next to the recipe during the ``devtool finish`` |
| command. |
| |
| If you specify a destination layer that is the same as the original |
| source, then the old version of the recipe and associated files are |
| removed prior to adding the new version. |
| :: |
| |
| $ devtool finish recipe layer |
| |
| .. note:: |
| |
| Any changes you want to turn into patches must be committed to the |
| Git repository in the source tree. |
| |
| As a final process of the ``devtool finish`` command, the state of |
| the standard layers and the upstream source is restored so that you |
| can build the recipe from those areas rather than the workspace. |
| |
| .. note:: |
| |
| You can use the |
| devtool reset |
| command to put things back should you decide you do not want to |
| proceed with your work. If you do use this command, realize that |
| the source tree is preserved. |
| |
| A Closer Look at ``devtool add`` |
| ================================ |
| |
| The ``devtool add`` command automatically creates a recipe based on the |
| source tree you provide with the command. Currently, the command has |
| support for the following: |
| |
| - Autotools (``autoconf`` and ``automake``) |
| |
| - CMake |
| |
| - Scons |
| |
| - ``qmake`` |
| |
| - Plain ``Makefile`` |
| |
| - Out-of-tree kernel module |
| |
| - Binary package (i.e. "-b" option) |
| |
| - Node.js module |
| |
| - Python modules that use ``setuptools`` or ``distutils`` |
| |
| Apart from binary packages, the determination of how a source tree |
| should be treated is automatic based on the files present within that |
| source tree. For example, if a ``CMakeLists.txt`` file is found, then |
| the source tree is assumed to be using CMake and is treated accordingly. |
| |
| .. note:: |
| |
| In most cases, you need to edit the automatically generated recipe in |
| order to make it build properly. Typically, you would go through |
| several edit and build cycles until the recipe successfully builds. |
| Once the recipe builds, you could use possible further iterations to |
| test the recipe on the target device. |
| |
| The remainder of this section covers specifics regarding how parts of |
| the recipe are generated. |
| |
| Name and Version |
| ---------------- |
| |
| If you do not specify a name and version on the command line, |
| ``devtool add`` uses various metadata within the source tree in an |
| attempt to determine the name and version of the software being built. |
| Based on what the tool determines, ``devtool`` sets the name of the |
| created recipe file accordingly. |
| |
| If ``devtool`` cannot determine the name and version, the command prints |
| an error. For such cases, you must re-run the command and provide the |
| name and version, just the name, or just the version as part of the |
| command line. |
| |
| Sometimes the name or version determined from the source tree might be |
| incorrect. For such a case, you must reset the recipe:: |
| |
| $ devtool reset -n recipename |
| |
| After running the ``devtool reset`` command, you need to |
| run ``devtool add`` again and provide the name or the version. |
| |
| Dependency Detection and Mapping |
| -------------------------------- |
| |
| The ``devtool add`` command attempts to detect build-time dependencies |
| and map them to other recipes in the system. During this mapping, the |
| command fills in the names of those recipes as part of the |
| :term:`DEPENDS` variable within the |
| recipe. If a dependency cannot be mapped, ``devtool`` places a comment |
| in the recipe indicating such. The inability to map a dependency can |
| result from naming not being recognized or because the dependency simply |
| is not available. For cases where the dependency is not available, you |
| must use the ``devtool add`` command to add an additional recipe that |
| satisfies the dependency. Once you add that recipe, you need to update |
| the :term:`DEPENDS` variable in the original recipe to include the new |
| recipe. |
| |
| If you need to add runtime dependencies, you can do so by adding the |
| following to your recipe:: |
| |
| RDEPENDS:${PN} += "dependency1 dependency2 ..." |
| |
| .. note:: |
| |
| The |
| devtool add |
| command often cannot distinguish between mandatory and optional |
| dependencies. Consequently, some of the detected dependencies might |
| in fact be optional. When in doubt, consult the documentation or the |
| configure script for the software the recipe is building for further |
| details. In some cases, you might find you can substitute the |
| dependency with an option that disables the associated functionality |
| passed to the configure script. |
| |
| License Detection |
| ----------------- |
| |
| The ``devtool add`` command attempts to determine if the software you |
| are adding is able to be distributed under a common, open-source |
| license. If so, the command sets the |
| :term:`LICENSE` value accordingly. |
| You should double-check the value added by the command against the |
| documentation or source files for the software you are building and, if |
| necessary, update that :term:`LICENSE` value. |
| |
| The ``devtool add`` command also sets the |
| :term:`LIC_FILES_CHKSUM` |
| value to point to all files that appear to be license-related. Realize |
| that license statements often appear in comments at the top of source |
| files or within the documentation. In such cases, the command does not |
| recognize those license statements. Consequently, you might need to |
| amend the :term:`LIC_FILES_CHKSUM` variable to point to one or more of those |
| comments if present. Setting :term:`LIC_FILES_CHKSUM` is particularly |
| important for third-party software. The mechanism attempts to ensure |
| correct licensing should you upgrade the recipe to a newer upstream |
| version in future. Any change in licensing is detected and you receive |
| an error prompting you to check the license text again. |
| |
| If the ``devtool add`` command cannot determine licensing information, |
| ``devtool`` sets the :term:`LICENSE` value to "CLOSED" and leaves the |
| :term:`LIC_FILES_CHKSUM` value unset. This behavior allows you to continue |
| with development even though the settings are unlikely to be correct in |
| all cases. You should check the documentation or source files for the |
| software you are building to determine the actual license. |
| |
| Adding Makefile-Only Software |
| ----------------------------- |
| |
| The use of Make by itself is very common in both proprietary and |
| open-source software. Unfortunately, Makefiles are often not written |
| with cross-compilation in mind. Thus, ``devtool add`` often cannot do |
| very much to ensure that these Makefiles build correctly. It is very |
| common, for example, to explicitly call ``gcc`` instead of using the |
| :term:`CC` variable. Usually, in a |
| cross-compilation environment, ``gcc`` is the compiler for the build |
| host and the cross-compiler is named something similar to |
| ``arm-poky-linux-gnueabi-gcc`` and might require arguments (e.g. to |
| point to the associated sysroot for the target machine). |
| |
| When writing a recipe for Makefile-only software, keep the following in |
| mind: |
| |
| - You probably need to patch the Makefile to use variables instead of |
| hardcoding tools within the toolchain such as ``gcc`` and ``g++``. |
| |
| - The environment in which Make runs is set up with various standard |
| variables for compilation (e.g. :term:`CC`, :term:`CXX`, and so forth) in a |
| similar manner to the environment set up by the SDK's environment |
| setup script. One easy way to see these variables is to run the |
| ``devtool build`` command on the recipe and then look in |
| ``oe-logs/run.do_compile``. Towards the top of this file, there is |
| a list of environment variables that are set. You can take |
| advantage of these variables within the Makefile. |
| |
| - If the Makefile sets a default for a variable using "=", that default |
| overrides the value set in the environment, which is usually not |
| desirable. For this case, you can either patch the Makefile so it |
| sets the default using the "?=" operator, or you can alternatively |
| force the value on the ``make`` command line. To force the value on |
| the command line, add the variable setting to |
| :term:`EXTRA_OEMAKE` or |
| :term:`PACKAGECONFIG_CONFARGS` |
| within the recipe. Here is an example using :term:`EXTRA_OEMAKE`:: |
| |
| EXTRA_OEMAKE += "'CC=${CC}' 'CXX=${CXX}'" |
| |
| In the above example, |
| single quotes are used around the variable settings as the values are |
| likely to contain spaces because required default options are passed |
| to the compiler. |
| |
| - Hardcoding paths inside Makefiles is often problematic in a |
| cross-compilation environment. This is particularly true because |
| those hardcoded paths often point to locations on the build host and |
| thus will either be read-only or will introduce contamination into |
| the cross-compilation because they are specific to the build host |
| rather than the target. Patching the Makefile to use prefix variables |
| or other path variables is usually the way to handle this situation. |
| |
| - Sometimes a Makefile runs target-specific commands such as |
| ``ldconfig``. For such cases, you might be able to apply patches that |
| remove these commands from the Makefile. |
| |
| Adding Native Tools |
| ------------------- |
| |
| Often, you need to build additional tools that run on the :term:`Build |
| Host` as opposed to |
| the target. You should indicate this requirement by using one of the |
| following methods when you run ``devtool add``: |
| |
| - Specify the name of the recipe such that it ends with "-native". |
| Specifying the name like this produces a recipe that only builds for |
| the build host. |
| |
| - Specify the "--also-native" option with the ``devtool add`` |
| command. Specifying this option creates a recipe file that still |
| builds for the target but also creates a variant with a "-native" |
| suffix that builds for the build host. |
| |
| .. note:: |
| |
| If you need to add a tool that is shipped as part of a source tree |
| that builds code for the target, you can typically accomplish this by |
| building the native and target parts separately rather than within |
| the same compilation process. Realize though that with the |
| "--also-native" option, you can add the tool using just one |
| recipe file. |
| |
| Adding Node.js Modules |
| ---------------------- |
| |
| You can use the ``devtool add`` command two different ways to add |
| Node.js modules: 1) Through ``npm`` and, 2) from a repository or local |
| source. |
| |
| Use the following form to add Node.js modules through ``npm``:: |
| |
| $ devtool add "npm://registry.npmjs.org;name=forever;version=0.15.1" |
| |
| The name and |
| version parameters are mandatory. Lockdown and shrinkwrap files are |
| generated and pointed to by the recipe in order to freeze the version |
| that is fetched for the dependencies according to the first time. This |
| also saves checksums that are verified on future fetches. Together, |
| these behaviors ensure the reproducibility and integrity of the build. |
| |
| .. note:: |
| |
| - You must use quotes around the URL. The ``devtool add`` does not |
| require the quotes, but the shell considers ";" as a splitter |
| between multiple commands. Thus, without the quotes, |
| ``devtool add`` does not receive the other parts, which results in |
| several "command not found" errors. |
| |
| - In order to support adding Node.js modules, a ``nodejs`` recipe |
| must be part of your SDK. |
| |
| As mentioned earlier, you can also add Node.js modules directly from a |
| repository or local source tree. To add modules this way, use |
| ``devtool add`` in the following form:: |
| |
| $ devtool add https://github.com/diversario/node-ssdp |
| |
| In this example, ``devtool`` |
| fetches the specified Git repository, detects the code as Node.js code, |
| fetches dependencies using ``npm``, and sets |
| :term:`SRC_URI` accordingly. |
| |
| Working With Recipes |
| ==================== |
| |
| When building a recipe using the ``devtool build`` command, the typical |
| build progresses as follows: |
| |
| 1. Fetch the source |
| |
| 2. Unpack the source |
| |
| 3. Configure the source |
| |
| 4. Compile the source |
| |
| 5. Install the build output |
| |
| 6. Package the installed output |
| |
| For recipes in the workspace, fetching and unpacking is disabled as the |
| source tree has already been prepared and is persistent. Each of these |
| build steps is defined as a function (task), usually with a "do\_" prefix |
| (e.g. :ref:`ref-tasks-fetch`, |
| :ref:`ref-tasks-unpack`, and so |
| forth). These functions are typically shell scripts but can instead be |
| written in Python. |
| |
| If you look at the contents of a recipe, you will see that the recipe |
| does not include complete instructions for building the software. |
| Instead, common functionality is encapsulated in classes inherited with |
| the ``inherit`` directive. This technique leaves the recipe to describe |
| just the things that are specific to the software being built. There is |
| a :ref:`base <ref-classes-base>` class that |
| is implicitly inherited by all recipes and provides the functionality |
| that most recipes typically need. |
| |
| The remainder of this section presents information useful when working |
| with recipes. |
| |
| Finding Logs and Work Files |
| --------------------------- |
| |
| After the first run of the ``devtool build`` command, recipes that were |
| previously created using the ``devtool add`` command or whose sources |
| were modified using the ``devtool modify`` command contain symbolic |
| links created within the source tree: |
| |
| - ``oe-logs``: This link points to the directory in which log files and |
| run scripts for each build step are created. |
| |
| - ``oe-workdir``: This link points to the temporary work area for the |
| recipe. The following locations under ``oe-workdir`` are particularly |
| useful: |
| |
| - ``image/``: Contains all of the files installed during the |
| :ref:`ref-tasks-install` stage. |
| Within a recipe, this directory is referred to by the expression |
| ``${``\ :term:`D`\ ``}``. |
| |
| - ``sysroot-destdir/``: Contains a subset of files installed within |
| :ref:`ref-tasks-install` that have been put into the shared sysroot. For |
| more information, see the |
| ":ref:`dev-manual/common-tasks:sharing files between recipes`" section. |
| |
| - ``packages-split/``: Contains subdirectories for each package |
| produced by the recipe. For more information, see the |
| ":ref:`sdk-manual/extensible:packaging`" section. |
| |
| You can use these links to get more information on what is happening at |
| each build step. |
| |
| Setting Configure Arguments |
| --------------------------- |
| |
| If the software your recipe is building uses GNU autoconf, then a fixed |
| set of arguments is passed to it to enable cross-compilation plus any |
| extras specified by |
| :term:`EXTRA_OECONF` or |
| :term:`PACKAGECONFIG_CONFARGS` |
| set within the recipe. If you wish to pass additional options, add them |
| to :term:`EXTRA_OECONF` or :term:`PACKAGECONFIG_CONFARGS`. Other supported build |
| tools have similar variables (e.g. |
| :term:`EXTRA_OECMAKE` for |
| CMake, :term:`EXTRA_OESCONS` |
| for Scons, and so forth). If you need to pass anything on the ``make`` |
| command line, you can use :term:`EXTRA_OEMAKE` or the |
| :term:`PACKAGECONFIG_CONFARGS` |
| variables to do so. |
| |
| You can use the ``devtool configure-help`` command to help you set the |
| arguments listed in the previous paragraph. The command determines the |
| exact options being passed, and shows them to you along with any custom |
| arguments specified through :term:`EXTRA_OECONF` or |
| :term:`PACKAGECONFIG_CONFARGS`. If applicable, the command also shows you |
| the output of the configure script's "--help" option as a |
| reference. |
| |
| Sharing Files Between Recipes |
| ----------------------------- |
| |
| Recipes often need to use files provided by other recipes on the |
| :term:`Build Host`. For example, |
| an application linking to a common library needs access to the library |
| itself and its associated headers. The way this access is accomplished |
| within the extensible SDK is through the sysroot. There is one sysroot per |
| "machine" for which the SDK is being built. In practical terms, this |
| means there is a sysroot for the target machine, and a sysroot for |
| the build host. |
| |
| Recipes should never write files directly into the sysroot. Instead, |
| files should be installed into standard locations during the |
| :ref:`ref-tasks-install` task within |
| the ``${``\ :term:`D`\ ``}`` directory. A |
| subset of these files automatically goes into the sysroot. The reason |
| for this limitation is that almost all files that go into the sysroot |
| are cataloged in manifests in order to ensure they can be removed later |
| when a recipe is modified or removed. Thus, the sysroot is able to |
| remain free from stale files. |
| |
| Packaging |
| --------- |
| |
| Packaging is not always particularly relevant within the extensible SDK. |
| However, if you examine how build output gets into the final image on |
| the target device, it is important to understand packaging because the |
| contents of the image are expressed in terms of packages and not |
| recipes. |
| |
| During the :ref:`ref-tasks-package` |
| task, files installed during the |
| :ref:`ref-tasks-install` task are |
| split into one main package, which is almost always named the same as |
| the recipe, and into several other packages. This separation exists |
| because not all of those installed files are useful in every image. For |
| example, you probably do not need any of the documentation installed in |
| a production image. Consequently, for each recipe the documentation |
| files are separated into a ``-doc`` package. Recipes that package |
| software containing optional modules or plugins might undergo additional |
| package splitting as well. |
| |
| After building a recipe, you can see where files have gone by looking in |
| the ``oe-workdir/packages-split`` directory, which contains a |
| subdirectory for each package. Apart from some advanced cases, the |
| :term:`PACKAGES` and |
| :term:`FILES` variables controls |
| splitting. The :term:`PACKAGES` variable lists all of the packages to be |
| produced, while the :term:`FILES` variable specifies which files to include |
| in each package by using an override to specify the package. For |
| example, ``FILES:${PN}`` specifies the files to go into the main package |
| (i.e. the main package has the same name as the recipe and |
| ``${``\ :term:`PN`\ ``}`` evaluates to the |
| recipe name). The order of the :term:`PACKAGES` value is significant. For |
| each installed file, the first package whose :term:`FILES` value matches the |
| file is the package into which the file goes. Both the :term:`PACKAGES` and |
| :term:`FILES` variables have default values. Consequently, you might find |
| you do not even need to set these variables in your recipe unless the |
| software the recipe is building installs files into non-standard |
| locations. |
| |
| Restoring the Target Device to its Original State |
| ================================================= |
| |
| If you use the ``devtool deploy-target`` command to write a recipe's |
| build output to the target, and you are working on an existing component |
| of the system, then you might find yourself in a situation where you |
| need to restore the original files that existed prior to running the |
| ``devtool deploy-target`` command. Because the ``devtool deploy-target`` |
| command backs up any files it overwrites, you can use the |
| ``devtool undeploy-target`` command to restore those files and remove |
| any other files the recipe deployed. Consider the following example:: |
| |
| $ devtool undeploy-target lighttpd root@192.168.7.2 |
| |
| If you have deployed |
| multiple applications, you can remove them all using the "-a" option |
| thus restoring the target device to its original state:: |
| |
| $ devtool undeploy-target -a root@192.168.7.2 |
| |
| Information about files deployed to |
| the target as well as any backed up files are stored on the target |
| itself. This storage, of course, requires some additional space on the |
| target machine. |
| |
| .. note:: |
| |
| The |
| devtool deploy-target |
| and |
| devtool undeploy-target |
| commands do not currently interact with any package management system |
| on the target device (e.g. RPM or OPKG). Consequently, you should not |
| intermingle |
| devtool deploy-target |
| and package manager operations on the target device. Doing so could |
| result in a conflicting set of files. |
| |
| Installing Additional Items Into the Extensible SDK |
| =================================================== |
| |
| Out of the box the extensible SDK typically only comes with a small |
| number of tools and libraries. A minimal SDK starts mostly empty and is |
| populated on-demand. Sometimes you must explicitly install extra items |
| into the SDK. If you need these extra items, you can first search for |
| the items using the ``devtool search`` command. For example, suppose you |
| need to link to libGL but you are not sure which recipe provides libGL. |
| You can use the following command to find out:: |
| |
| $ devtool search libGL mesa |
| A free implementation of the OpenGL API |
| |
| Once you know the recipe |
| (i.e. ``mesa`` in this example), you can install it. |
| |
| When using the extensible SDK directly in a Yocto build |
| ------------------------------------------------------- |
| |
| In this scenario, the Yocto build tooling, e.g. ``bitbake`` |
| is directly accessible to build additional items, and it |
| can simply be executed directly: |
| |
| $ bitbake mesa |
| $ bitbake build-sysroots |
| |
| When using a standalone installer for the Extensible SDK |
| -------------------------------------------------------- |
| |
| $ devtool sdk-install mesa |
| |
| By default, the ``devtool sdk-install`` command assumes |
| the item is available in pre-built form from your SDK provider. If the |
| item is not available and it is acceptable to build the item from |
| source, you can add the "-s" option as follows:: |
| |
| $ devtool sdk-install -s mesa |
| |
| It is important to remember that building the item from source |
| takes significantly longer than installing the pre-built artifact. Also, |
| if there is no recipe for the item you want to add to the SDK, you must |
| instead add the item using the ``devtool add`` command. |
| |
| Applying Updates to an Installed Extensible SDK |
| =============================================== |
| |
| If you are working with an installed extensible SDK that gets |
| occasionally updated (e.g. a third-party SDK), then you will need to |
| manually "pull down" the updates into the installed SDK. |
| |
| To update your installed SDK, use ``devtool`` as follows:: |
| |
| $ devtool sdk-update |
| |
| The previous command assumes your SDK provider has set the |
| default update URL for you through the :term:`SDK_UPDATE_URL` |
| variable as described in the |
| ":ref:`sdk-manual/appendix-customizing:Providing Updates to the Extensible SDK After Installation`" |
| section. If the SDK provider has not set that default URL, you need to |
| specify it yourself in the command as follows: $ devtool sdk-update |
| path_to_update_directory |
| |
| .. note:: |
| |
| The URL needs to point specifically to a published SDK and not to an |
| SDK installer that you would download and install. |
| |
| Creating a Derivative SDK With Additional Components |
| ==================================================== |
| |
| You might need to produce an SDK that contains your own custom |
| libraries. A good example would be if you were a vendor with customers |
| that use your SDK to build their own platform-specific software and |
| those customers need an SDK that has custom libraries. In such a case, |
| you can produce a derivative SDK based on the currently installed SDK |
| fairly easily by following these steps: |
| |
| 1. If necessary, install an extensible SDK that you want to use as a |
| base for your derivative SDK. |
| |
| 2. Source the environment script for the SDK. |
| |
| 3. Add the extra libraries or other components you want by using the |
| ``devtool add`` command. |
| |
| 4. Run the ``devtool build-sdk`` command. |
| |
| The previous steps take the recipes added to the workspace and construct |
| a new SDK installer that contains those recipes and the resulting binary |
| artifacts. The recipes go into their own separate layer in the |
| constructed derivative SDK, which leaves the workspace clean and ready |
| for users to add their own recipes. |