Line 348: | Line 348: | ||
=== Configuring the kernel === | === Configuring the kernel === | ||
{{admon/note| | {{admon/note| Potential options to the instructions below|Consider using the make targets "mrproper" and "menuconfig" as specified in the top-level README file. The "menuconfig" target is an alternative to "oldconfig" and pops up a GUI that allows you to set virtually all build options. Accepting the defaults is generally fine, although you can use the "General Setup->Local version" option to append a label to your build instead of tweaking "EXTRAVERSION" in the .config file.}} | ||
Chances are that the kernel you are running is older than the one you are about to configure. This means there will be new options. | Chances are that the kernel you are running is older than the one you are about to configure. This means there will be new options. |
Revision as of 21:50, 2 February 2016
This document provides instructions for advanced users who want to rebuild the kernel from some source. Note, however, that when building or running any such kernel, one should NOT expect support from the Fedora kernel team; you're pretty much on your own here if something doesn't work as you'd hoped or expected. But hey, you're an advanced user, so you can handle it, right? Anyway, advanced users build custom kernels for a variety of reasons:
- To apply patches for testing that they either generated or obtained from another source
- To reconfigure the existing kernel
- To learn more about the kernel and kernel development
Dependencies for building kernels
Not all of these will apply to all methods but this provides a good dependency list of items to install
# sudo dnf install fedpkg fedora-packager rpmdevtools ncurses-devel pesign pesign-rh-test-certs
Give the following command from the top directory of the kernel source tree once you have checked it out
# sudo dnf builddep kernel.spec
if you plan to run 'make xconfig'
# sudo dnf install qt3-devel libXi-devel gcc-c++
Also make sure you add the user doing the build to /etc/pesign/users and run the authorize user script:
# sudo /usr/libexec/pesign/pesign-authorize-users
It should be noted that pesign pesign-rh-test-certs gets pulled in automatically for some, but not for everyone, it depends on how you installed pesign. It is best to make sure that you have it installed.
Building a Kernel from the Fedora source tree
Make sure you have installed all dependencies
$ fedpkg clone kernel
you will likely need to checkout the source anonymously unless you have an Fedora developer account
$ fedpkg clone -a kernel
As of the time of this wiki writing (April 2015), the kernel was managed using git. Each fedora release is a separate branch. rawhide tracks master. To get the tree for a particular release, you can use git checkout from the top of your newly created source tree.
e.g. for fedora 22,
$ git checkout origin/f22
You can now make whatever changes / customizations you need before generating the rpms and installing them. When finished, generate the appropriate rpms with
$ fedpkg local
The rpms will be generated in a subdirectory $ARCH which can then be installed:
$ dnf install --nogpgcheck ./x86_64/kernel-$version.rpm
Building a non-debugging kernel
Branched kernels are built with debugging enabled by default in the early stages of the release to assist developers. To make a kernel with debugging information disabled, you can follow the above instructions to check out and do:
$ make release
$ fedpkg local
Enabling config options
If there are configuration options that need to be adjusted for your build, you can add changes in the config-local file. This will override anything set in the rest of the defconfigs.
Updating
$ cd kernel
kernel $ git status
- your tree will be dirty in the configs and kernel.spec
kernel $ git stash
- puts aside your changes so your tree will be clean
kernel $ git pull origin
- update to the latest tree from fedpkg git
Now you can run whatever other commands you want (e.g. make release)
Building a Kernel from the source RPM
Make sure you have installed all dependencies
Get the Source
- Prepare an RPM package-building environment in your (non-root) home directory by running the following command:
rpmdev-setuptree
This command creates a new directory~/rpmbuild
, with several empty subdirectories includingSPECS
,SOURCES
,BUILD
and others. It also creates an initial~/.rpmmacros
customization file for you. - Download the
kernel-<version>.src.rpm
file. It is not necessary to enable the Fedora source repositories -- thednf download
command will do that for you automatically:dnf download --source kernel
- Install build dependencies for the kernel source with the
dnf builddep
command (root is required to install these packages):su -c 'dnf builddep kernel-<version>.src.rpm'
- Install
kernel-<version>.src.rpm
with the following command:rpm -Uvh kernel-<version>.src.rpm
This command writes the RPM contents into${HOME}/rpmbuild/SOURCES
and${HOME}/rpmbuild/SPECS
, where${HOME}
is your home directory. It is safe to ignore any messages similar to the following:
warning: user kojibuilder does not exist - using root warning: group kojibuilder does not exist - using root
Prepare the Kernel Source Tree
This step expands all of the source code files for the kernel. This is required to view the code, edit the code, or to generate a patch. (Again, all of this should be done as a regular user, not as root.)
1. Prepare the kernel source tree using the following commands:
cd ~/rpmbuild/SPECS rpmbuild -bp --target=$(uname -m) kernel.spec
The unloaded and patched kernel source tree is now located in the ~/rpmbuild/BUILD/kernel-<version>/linux-<version>.<arch>
directory.
Copy the Source Tree and Generate a Patch
This step is for applying a patch to the kernel source. If a patch is not needed, proceed to "Configure Kernel Options".
Copy the source tree to preserve the original tree while making changes to the
export arch=x86_64 # replace x86_64 with your arch export ver=3.7 # replace 3.1 with your kernel version export subver=4-204 export fedver=fc16 # replace fc16 with your fedora version cp -r ~/rpmbuild/BUILD/kernel-$ver.$subver.$fedver ~/rpmbuild/BUILD/kernel-$ver.$fedver.orig cp -al ~/rpmbuild/BUILD/kernel-$ver.$subver.$fedver.orig ~/rpmbuild/BUILD/kernel-$ver.$fedver.new
Using vim on FC14, it treated the hard link as a hard link and thus the above technique failed. It was necessary to repeat the original copy used for the .orig directory for the .new directory. Note that this uses twice the space.
Make changes directly to the code in the .new
source tree, or copy in a modified file. This file might come from a developer who has requested a test, from the upstream kernel sources, or from a different distribution.
After the .new
source tree is modified, generate a patch. To generate the patch, run diff
against the entire .new
and .orig
source trees with the following command:
cd ~/rpmbuild/BUILD diff -uNrp kernel-$ver.$subver.$fedver.orig kernel-$ver.$subver.$fedver.new > ../SOURCES/linux-$ver.$subver.$fedver-mynewpatch.patch
Replace 'linux-$ver.$subver.$fedver-mynewpatch.patch' with the desired name for the new patch.
Lastly edit the patch file to remove the leading directory, this is required because the kernel spec file applies patches with '-p1' only.
For example the following:
--- kernel-3.8.fc18.orig/linux-3.8.11-200.bz708406.fc18.x86_64/kernel/kexec.c 2013-02-18 18:58:34.000000000 -0500 +++ kernel-3.8.fc18.new/linux-3.8.11-200.bz708406.fc18.x86_64/kernel/kexec.c 1969-12-31 19:00:00.000000000 -0500
Should be changed to:
--- linux-3.8.11-200.bz708406.fc18.x86_64/kernel/kexec.c 2013-02-18 18:58:34.000000000 -0500 +++ linux-3.8.11-200.bz708406.fc18.x86_64/kernel/kexec.c 1969-12-31 19:00:00.000000000 -0500
Configure Kernel Options
This step is for modifying the options the kernel is configured with. This step is optional. If no configuration changes are needed, proceed to "Prepare Build Files".
- Change to the kernel source tree directory:
cd ~/rpmbuild/BUILD/kernel-$ver.$fedver/linux-$ver.$subver.$fedver.$arch/
If you only want to make minor changes to the default fedora kernel, skip to step 4., and use one of the two configuration tools to edit those minor changes into the default config file. - Select the desired configuration file from
~/rpmbuild/BUILD/kernel-$ver.$fedver/linux-$ver.$subver.$fedver.$arch/configs
. Copy the desired config file to~/rpmbuild/BUILD/kernel-$ver.$fedver/linux-$ver.$subver.$fedver.$arch/.config
:cp configs/<desired-config-file> .config
- Run the following command:
make oldconfig
- Then run the following command, selecting and saving the desired kernel options from the text-based UI:
make menuconfig
- For a graphical UI, instead run:
make xconfig
- For a graphical UI, instead run:
- Add a new line to the top of the config file that contains the hardware platform the kernel is built for (the output of
uname -i
). The line is preceded by a#
sign. For example, an x86_64 machine would have the following line added to the top of the config file:# x86_64
- Copy the config file to
~/rpmbuild/SOURCES/
:cp .config ~/rpmbuild/SOURCES/config-`uname -m`-generic
Prepare Build Files
This step makes the necessary changes to the kernel.spec
file. This step is required for building a custom kernel.
1. Change to the ~/rpmbuild/SPECS
directory:
cd ~/rpmbuild/SPECS
2. Open the kernel.spec
file for editing.
3. Give the kernel a unique name. This is important to ensure the custom kernel is not confused with any released kernel. Add a unique string to the kernel name by changing the 'buildid' line. Optionally, change ".local" to your initials, a bug number, the date or any other unique string.
Change this line:
#% define buildid .local
To this (note the extra space is removed in addition to the pound sign):
%define buildid .<custom_text>
4. If you generated a patch, add the patch to the kernel.spec
file, preferably at the end of all the existing patches and clearly commented.
# cputime accounting is broken, revert to 2.6.22 version Patch2220: linux-2.6-cputime-fix-accounting.patch Patch9999: linux-2.6-samfw-test.patch
The patch then needs to be applied in the patch application section of the spec file. Again, at the end of the existing patch applications and clearly commented.
ApplyPatch linux-2.6-cputime-fix-accounting.patch ApplyPatch linux-2.6-samfw-test.patch
Build the New Kernel
This step actually generates the kernel RPM files. This step is required for building a custom kernel.
Use the rpmbuild
utility to build the new kernel:
- Ensure /usr/sbin is in your path (to pull in /usr/sbin/modinfo):
export PATH=/usr/sbin:$PATH
- To build all kernel flavors:
rpmbuild -bb --target=`uname -m` kernel.spec
- To disable specific kernel flavors from the build (for a faster build):
rpmbuild -bb --without <option> --target=`uname -m` kernel.spec
Valid values for "option" above include xen
, smp
, up
, pae
, kdump
, debug
and debuginfo
. Specifying --without debug
strips out some debugging code from the kernels, where specifying --without debuginfo
disables the building of the kernel-debuginfo
packages.
- To specify that only a specific kernel should be built:
rpmbuild -bb --with <option> --target=`uname -m` kernel.spec
Valid values for "option" above include xenonly
, smponly
, and baseonly
.
- For example, to build just the kernel and kernel-devel packages, the command would be:
rpmbuild -bb --with baseonly --without debuginfo --target=`uname -m` kernel.spec
The build process takes a long time to complete. A lot of messages will be printed to the screen. These messages can be ignored, unless the build ends with an error. If the build completes successfully, the new kernel packages will be located in the ~/rpmbuild/RPMS
directory.
Following Generic Textbooks
Many of the tutorials, examples, and textbooks about Linux kernel development assume the kernel sources are installed under the /usr/src/linux/
directory. If you make a symbolic link, as shown below, you should be able to use those learning materials with the Fedora packages. Install the appropriate kernel sources, as shown earlier, and then run the following command:
su -c 'ln -s /usr/src/kernels/<version>.<release>-<arch> /usr/src/linux'
Enter the root
password when prompted.
Install the New Kernel
This step actually installs the new kernel into the running system.
To install the new kernel, use the rpm -ivh
command, not the -U
or --upgrade
options:
su -c "rpm -ivh $HOME/rpmbuild/RPMS/<arch>/kernel-<version>.<arch>.rpm"
This command will install your kernel in /boot, create a new initramfs to bootstrap your kernel, and automatically add your new kernel to your grub bootloader "menu.lst". At this point, you can reboot to give control to your new kernel.
Building Only Kernel Modules (Out Of Tree Modules)
This section is for users who are only interested in working on a kernel module, and who do not wish to build an entire custom kernel. It is not necessary to download and rebuild the entire kernel in order to build a module. To build a module for the currently running kernel, only the matching kernel-devel
package is required. Run the following command to install the kernel-devel
package using dnf
.
su -c 'dnf install kernel-devel'
You can build against any kernel version, as long as you have kernel
and kernel-devel
packages installed for that version. The rest of this section assumes we're building for the running kernel; if not, replace
with the desired version number.
uname -r
As a simple example, to build the foo.ko
module from foo.c
, create the following Makefile
in the directory containing the foo.c
file:
obj-m := foo.o KDIR := /lib/modules/$(shell uname -r)/build PWD := $(shell pwd) default: [TAB]$(MAKE) -C $(KDIR) M=$(PWD) modules
[TAB] Denotes a tab character which must come first for makefile lines containing commands.
Then, issue the make
command to build the foo.ko
module.
The above is a helpful local Makefile wrapper invoking kbuild; in general you can simply do things like
# make -C /lib/modules/`uname -r`/build M=`pwd` modules # make -C /lib/modules/`uname -r`/build M=`pwd` clean # make -C /lib/modules/`uname -r`/build M=`pwd` modules_install
etc to build those targets.
Building Vanilla upstream kernel
Sometimes a Fedora developer may ask you to try building and installing an upstream kernel (possibly with a patch added) for testing. If there are multiple iterations, it may be quicker for you to do this than for the developer to turn around several RPMs.
Existing Fedora Vanilla packages
There is an effort underway for packaging vanilla kernels. See if this meets your needs first
Getting the sources
Clone a kernel tree from kernel.org
$ git clone git://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git
This will clone the entire upstream tree. This may take a while depending on your connection speed. (While the tree is syncing, why not take the time to update some steps on this wiki that are inevitably out of date?)
$ cd linux
Double check what baseline is being used and check out a new one if necessary:
$ git checkout v3.19
Applying patches
The patch method
If you were asked to apply any patches by the developer, this is the stage at which we would do so. These would typically be applied using a command something like..
$ cat ~/testpatch.diff | patch -p1
If you have to try multiple different patches individually, you can unapply the previous one after testing by adding -R on the end of the above command.
The git method
Most developers these days generate patches using git and you can use git to help apply patches. You can do:
$ git am -3 <patch file>
This will create a git commit of a single patch in your tree.
Configuring the kernel
Chances are that the kernel you are running is older than the one you are about to configure. This means there will be new options. There are several possibilities here.
- If the developer has pointed you at a specific config file to use, save it in the linux directory with the filename .config
- You can take your existing .config file by using the command
cp /boot/config-
uname -r
* .config
When you run the next step, you'll be asked (potentially lots of) questions about all the new options. Just hitting return 'should' always pick the safe decision for each option. However, it's worth taking care and reading each option, as this isn't always the case, and they may introduce new features your distro isn't capable of running, which may result in a non-booting system.
- FIXME how to grab a rawhide config
With the config in place, you are now ready to move on to the next step.
Building the kernel
$EDITOR Makefile
Change the EXTRAVERSION line to add something on the end. For example, if it reads "EXTRAVERSION = -rc5" change it to "EXTRAVERSION = -rc5-dave" (what you choose is only relevant for the final part of this procedure)
$ make oldconfig
$ make bzImage
$ make modules
(become root)
# make modules_install
# make install
You have now built and installed a kernel. It will show up in the grub menu next time you reboot.
Rebuilding
If you have been asked to try several different things, the procedure once you have already built the tree once is mostly the same. A make clean
is recommended between builds. This will leave the .config in place, so you can skip that step above and proceed straight to the make bzImage
part of the steps above. Because we installed ccache in the first step, subsequent builds may go a lot faster as the compiler hits files that haven't changed since the last time it built them.
Cleaning up
Once you have tested the kernel, and you've booted back to one of your kernels installed from an RPM, you can clean up the files that the above procedure installed by becoming root, and calling these commands. (Be sure to get the kernel version correct!) Remember above, we changed EXTRAVERSION to add a 'tag' to the kernel ? All the files it installed will have this as part of the filename. So you should be able to use wildcards to delete them safely using commands similar to those below. (Just replace 'dave' with whatever tag you chose)
rm -f /boot/config-2.6.*dave* /boot/initrd-2.6.*dave* /boot/vmlinuz-*dave* /boot/System.map-*dave* rm -rf /lib/modules/2.6*dave*
Finally, you will need to remove the kernel as an option to your bootloader. This will change from architecture to architecture. For x86, (as root), edit /boot/grub2/grub.cfg or /boot/efi/EFI/fedora/grub.cfg if you have EFI enabled and delete the four lines relating to your kernel (They should be easy to spot, they'll be the ones with your tag). They'll look something like this..
title Fedora Core (2.6.22-rc3-dave) root (hd0,0) kernel /vmlinuz-2.6.22-rc3-dave ro root=/dev/md0 initrd /initrd-2.6.22-rc3-dave.img