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Adaptation Guide/Step by step
(→Make a bootloader package (if needed for the image)) |
(→Pre-requisites) |
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* a kernel capable of bringing the device to a framebuffer console | * a kernel capable of bringing the device to a framebuffer console | ||
* X drivers (optional) | * X drivers (optional) | ||
− | * for this simplified guide you will need an account on the [[:Category:cobs|Community OBS]] | + | * for this simplified guide you will need an account on the [[:Category:cobs|Community OBS]] |
= Make a kernel package = | = Make a kernel package = |
Revision as of 09:05, 7 October 2012
The objective of this phase is to provide a minimal booting image for a device. Initially bring the device up with a kernel to a framebuffer/console (ideally with console or networking) and then to X.
Contents |
Pre-requisites
- device suitable with one of the Mer architectures. See: OBS_architecture_naming
- Platform_SDK installed and preferribly updated.
- a bootloader for your device
- a kernel capable of bringing the device to a framebuffer console
- X drivers (optional)
- for this simplified guide you will need an account on the Community OBS
Make a kernel package
First setup the osc. See Osc_Setup guide.
After the osc is setup properly, create a home project for the adaptation in the selected OBS. Check the OBS_architecture_naming for the repository naming. Example of creating a project:
cat >> my_new_project.conf << EOF <project name="home:user:subproject"> <repository name="latest_i586"> <path repository="Core_i586" project="Mer:fake:Core:i586"/> <arch>i586</arch> </repository> </project> EOF osc meta prj home:user:subproject -F my_new_project.conf
After project is done we create a package for the kernel package to just created project
osc meta pkg home:user:subproject kernel-adaptation-sample
Then check out the package
osc co home:user:subproject kernel-adaptation-sample cd home:user:subproject/kernel-adaptation-sample
Next thing is to get the adaptation template
git clone https://github.com/lbt/mer-kernel-adaptation.git cp mer-kernel-adaptation/* .
After this we have the very basic structure and files for the kernel packaging.
Note: we're using the name '-sample' here - you shouldn't change this just yet unless you know what you're doing.
Git method (preferred):
- Start with a clone of an upstream kernel
- You should have or create a branch with your patches applied onto a mainline tag location. Eg a branch based at v2.6.32.25 with local patches.
Now to create a tarball, a set of patches and produce a Patches: section for the yaml file.
In the root directory of your kernel git tree create a tarball and patchset using the git2tarball.sh script from the kernel-adaptation package. eg:
/path/to/Mer:Sample:HA/kernel-adaptation-sample/git2tarball.sh /path/to/Mer:Sample:HA/kernel-adaptation-sample 2.6.38.4
The 'version' must correspond to a 'v' kernel tag (eg in this case v2.6.38.4). Then every commit from that tag to HEAD is exported as a patch to the package directory and a Patches: section is printed.
In the Mer:Sample:HA/kernel-adaptation-sample directory, modify the yaml file to include suitable values for Version:, Release: etc. Also include the Patches: section generated by the script. The yaml and spec files contain comments explaining how values are used.
Tarball method:
In your package directory, modify the yaml file to include suitable values for Version:, Release: etc. Also include a Patches: section if you have any patches (see the spectacle page for links to more details).
Copy the kernel tarball to the directory with the other files and ensure that the first source filename format matches to the tarball. One can use macros like %{name} and %{version} that will match to the Name and Version fields. Note that this VERSION string must mach the yaml and the Makefile in the tarball. Also the tarball should unpack the source to a directory such as linux-XYZ/*
Additional patches must be handled manually but can be placed in the yaml file Patches: section.
Both methods; build and/or hack on code:
To update the .spec file you must run:
specify kernel-adaptation-sample.yaml
You can now do a local build by running:
osc build <arch> kernel-adaptation-sample.spec
This will send your .spec file (only) to the server to determine what packages need downloading. It will then create a minimal chroot environment and unpack your src locally. Finally it will run rpmbuild to make an rpm of your kernel.
The <arch> value should match to the architectures determined earlier when creating the project.
The build environment is accessed using:
osc chroot <arch> kernel-adaptation-sample.spec
This will tell you where the chroot is located (hint, edit your ~/.oscrc to modify this and note that the build user is 'abuild' and the build happens in /home/abuild/rpmbuild/BUILD/ inside the chroot) - so you can edit files there using your desktop editor. You can then do :
cd rpmbuild/BUILD/kernel/ export ARCH=x86 (or whatever you need - note that this is the *KERNEL* arch specification and is differen to the Mer/OBS arch) make menuconfig/bzImage/modules/...
It is frequently necessary to revisit this step to change the kernel. The steps are:
- build an image (coming next)
- image boots but fails to run properly (missing device driver etc)
- enter kernel chroot
- change the config
- build the kernel
- copy the kernel to the image built in step 1 to avoid rebuilds
- go to step 2
When the kernel is satisfactory you MUST COPY THE CONFIG OUT OF THE CHROOT to the kernel-adaptation-sample.config file in the packging directory or as it will be lost because the chroot is modified (sources wiped) every time you do an 'osc build'. See the section about osc chroots for more information.
Having copied the config (and any patches) out of the chroot and put them in the package you can build a clean kernel package.
At this point in a full development deployment you would normally send your changes up to a private OBS/BOSS instance to be built and QA'ed. We'll move on to making an image locally to test the device.
Make a bootloader package (if needed for the image)
For devices that need a bootloader in the same image as the OS, a bootloader package is needed.
The Mer:Sample:HA has an example EFI grub bootloader. It simply contains a tar of the required configuration files and the bootloader binary. The Makefile copies these into the /boot partition created by mic (see the next step)
The bootloader should pass a kernel command line (or this can be set in the CONFIG_CMDLINE kernel configuration) that sets systemd.unit=start.getty
Make graphics adaptation package (optional)
For Mer there are certain binaries that are expected to be present when accelerated graphics are expected. For this there is a template packaging available at https://github.com/saukko/mer-graphics-adaptation that can be used as and base for graphics adaptation packaging.
Make an image
This section provides a bare minimum of information to get going; see the mic2 section for more details.
The kickstart file for your device needs to prepare a rootfs and setup any needed bootloader. FIXME: Replace this with kickstarter oriented approach
First install the configs for creating the .ks files.
sudo zypper install mer-kickstarter-configs
Then create the example kickstarts. Ref: default Mer kickstart
mer-kickstarter -c /usr/share/kickstarter-configs/mer-reference-images/00reference.yaml -o reference-kickstarts/
Next thing is to take one of the reference kickstarts and add your own adaptation to it. This can be done by adding following lines repo that contains the path to the repository where packages are. All the packages for the adaptation are put under the %packages section, e.g., kernel-adaptation-<my_adaptation>, bootloader-xyz etc.
After you have modified the .ks for your needs, we can build the image. See Category:Mic for more detailed information.
mic cr raw reference-kickstarts/mer-core-i586-xorg-basic-qmlviewer.ks --outdir=images
For devices which need the kernel in a distinct file. mic has an option called --save-kernel which creates a rootfs/kernel pair.
[1]: http://wiki.merproject.org/Image_Creation
Flashing your device
If your device uses SD or mmc or another block device then you can just create an image and write it.
If you use NAND flash / mtd then you'll need to make a rootfs and use a suitable tool to make a filesystem image.
Hack image
Once the image boots you should try to login as root using the password "mer"
If you are missing a login prompt do the following inside the target rootfs from the / level.
ln -s ../serial-getty@.service ./lib/systemd/system/getty.target.wants/serial-getty@tty<xx>.service.
Set <xx> to suit your device eg S0, mxc0 etc
Boot device and debugging
Hints, tips and tricks:
- The kernel command line: systemd.unit=$SOME.target can be used to specify a specific systemd target. rescue.target should be useful.
- Consider using kernel option "rootwait" if your rootfs device may be slow to appear (eg on a usb stick)
- The evbug module is useful for debugging touch and other keylike events
Prepare X / Wayland and Qt
To install X on a device you'll need to package/install:
- A Rendering Manager (DRM) kernel module for your device
- An Xorg driver for your device
- GL libraries for your device
- Any devel files
The Intel EMGD drivers have been packaged as a sample adaptation. Note:
- The drm module must be built against or compatible with your kernel
- The xorg driver must have an ABI version match to the Mer X server
- The GL libraries should provide ???
When debugging X with this minimal Mer build note that:
- the X log is in /var/log/Xorg.0.log
- when X starts, the program specified in /usr/share/xsessions/default.desktop runs (usually qmlviewer)
- That application logs errors to /home/mer/.xsession-errors
eglinfo and egltest from the mer-gfx-tests package may be useful
Higher level features
something for video, sound, networking and similar
Extending the image
To extend your image properly you should use the kickstarter approach which allows you to generate kickstart files that inherit from the Mer base image definition (and from other definitions within your organisation).
A quicker but less maintainable approach is to just edit the kickstart file and add more repos and packages.
To make ad-hoc changes on a device use 'zypper ar' and add the url of a suitable .repo file.
Finally you can simply use 'scp' or 'curl -O' to pull in rpm files and then usr 'rpm -i' to install them.
Note: Although this method uses the public OBS you do not need to publish your source code or .config file and you won't need to use the C.OBS in a proper product development environment.