This article will serve as a primer to people who are new to the world of Linux hacking, and are attempting to compile the Linux kernel from source. The various steps from downloading the kernel source to booting from the new kernel image are explained. Also given are tips on cleaning up the source code, doing verbose compilation etc.
1. Downloading the kernel source code
In order to compile a new kernel we have to download the source code of the Linux kernel. We can download the source from www.kernel.org. Here we can find all versions of the Linux kernel source code. Let's take an example. Suppose we want to compile the 2.6.9 version of the linux kernel. We have to download the 2.6.9 source code from:
http://www.kernel.org/pub/linux/kernel/v2.6/linux-2.6.16.tar.bz2
It's better to download the bzipped version, as that will be more compressed than its gzipped counterpart; hence will take less time to download. A wget from the command line will look like:
wget http://www.kernel.org/pub/linux/kernel/v2.6/linux-2.6.16.tar.bz2
Once we download the required kernel version source, we need to bunzip and untar it. We can do the following:
tar xvjf linux-2.6.16.tar.bz2
The 'x' option is to denote the untarring (e'x'traction), 'v' for verbose, 'j' for specifying that we need to bunzip the file before untarring and 'f' for stating the name of the input file.
The file will untar into the directory linux-2.6.16. Once it's untarred 'cd' to linux-2.6.16.
2. Configuring the kernel
We have to configure the kernel before we start compiling it. During the configuration phase, we will select the components which we want to be part of the kernel. For example: suppose we are using the ext3 filesystem. Then we need to select the ext3 filesystem support while configuring the kernel. Typically we have to run a
make menuconfig
This will bring up the ncurses interface for configuring the kernel. There are other options such as 'make xconfig' and 'make config'. The former will bring up the configuration menu in graphical mode and the latter in text mode.
Once we select the different components we want for our kernel, we can exit the configuration interface. We should select the option to save the configuration from the configuration menu, before exiting.
After we have configured the kernel as mentioned above, we can find a file named '.config' in the top level directory of the source. This file is the configuration file. It contains various options and their states (whether they are selected or not). For example, if we choose to have the PCI support in our kernel we can find an entry of the form:
CONFIG_PCI=y
in the .config file. Similarly, options which are selected as not required will appear as not set. Suppose we have not selected the XFS filesystem support in our kernel we will find the following in the .config
# CONFIG_XFS_FS is not set
A great feature of 2.6 kernels is that if we are running make menuconfig (or xconfig or config) for the first time, then the configuration menu we are presented with is based on our current kernel configuration. In my case, I have a Fedora Core 1 system. The kernel which I run is '2.4.22-1.2115.nptl'. Hence when I run a 'make menuconfig' for the first time on the source then the configuration menu presented will contain the options as given in '/boot/config-2.4.22-1.2115.nptl'.
3. Building Dependencies
This step is required in kernels prior to 2.6 series (here I am only referring to the stable series kernels). For example if we are using a 2.4 kernel then we have to build the dependencies explicitly. We have to run the following:
make dep
This will build the dependencies. But for a 2.6 kernel we can skip this step. The dependencies are automatically created when making the final image with a 2.6 kernel.
4. Creating the final image
We can build various types of kernel binary images. We can build a plain kernel image, or a compressed version of it; the usual choice is compressed, or the 'bzImage'. We can create the bzImage by running
make bzImage
In 2.6 kernels this step will also resolve the dependencies and proceed to create a bzImage image.
After the compilation is over we can find the kernel image at the path arch/i386/boot/bzImage in case of an image for a 386 based processor (Pentium, AMD etc.).
5. Compiling and Installing the modules
In the configuring section if we have selected some components to be built as kernel modules then we need to compile those modules. To compile the modules we should run the command:
make modules
This command will compile the components (which are selected for module compilation) to modules. In a 2.4 kernel the result will be .o files of the corresponding components. But in a 2.6 kernel the output file will be a .ko module. For example if we have given the option for the Network driver of Realtek cards to be built as modules then after giving a 'make modules' we can find in 'driver/net/' a file named 8139too.o in the case of a 2.4 kernel and 8139too.ko in the case of a 2.6 kernel.
After we have compiled the modules, it's time now to install the modules. To install the modules run:
make modules_install
as root. This will install the modules and other necessary files into the /lib/modules/2.6.9 directory.
6. Booting from the new kernel
Once we are done with the installation of modules, we can go for an automatic installation procedure for the kernel binary. We just have to run
make install
This will update the kernel image on to the /boot area, update the configuration file of the bootloader (lilo.conf or grub.conf) and then do the necessary actions to make the new kernel bootable.
After this we need to reboot the machine. When the machine boots next time the boot menu will present us with the option to boot from the new kernel we built. We choose that option and voila!! boot into a kernel we built all by ourselves!
7. Manual installation of the kernel
In case 'make install' does not work, or if we cannot perform an automatic installation due to some other reason, we can go for a manual installation of the kernel. For example, if we are using the grub boot loader then we have to copy the bzImage into the boot partition and then change the '/etc/grub.conf' to reflect the presence of the new image. If we are having lilo boot loader then we have to copy the bzImage to the boot location and then modify the lilo.conf and then run the 'lilo' command to make sure that next time we boot we will have our new image as a choice to boot from. The following are the steps we should perform as root user if we are using lilo boot loader:
cp -a arch/i386/boot/bzImage /boot/bzImage-2.6.9
After this we add the following entry to /etc/lilo.conf
image=/boot/bzImage-2.6.9 label=2.6.9-kernel root=your_root_disk
We should run lilo after this
lilo -v
We will reboot the machine after this. When we are prompted at the lilo prompt enter '2.6.9-kernel' as the boot option and we will be booting to the new custom built kernel.
8. Verbose compilation
We find that the compilation of the kernel is very quiet. Much less information on what is getting compiled is shown on the screen while the compilation proceeds.
#make bzImage CHK include/linux/version.h UPD include/linux/version.h SPLIT include/linux/autoconf.h -> include/config/* CC scripts/mod/empty.o HOSTCC scripts/mod/mk_elfconfig MKELF scripts/mod/elfconfig.h HOSTCC scripts/mod/file2alias.o HOSTCC scripts/mod/modpost.o HOSTCC scripts/mod/sumversion.o .... ....
If we need to know what commands are used for compilation, then we need to give the verbose compilation option while compiling. That is:
make bzImage V=1
This will output the commands which are executed while compiling. Here is a snippet from the compilation output:
<..snip..>make -f scripts/Makefile.build obj=init gcc -Wp,-MD,init/.main.o.d -nostdinc -iwithprefix include -D__KERNEL__ -Iinclude -Wall -Wstrict-prototypes -Wno-trigraphs -fno-strict-aliasing -fno-common -pipe -msoft-float -mpreferred-stack-boundary=2 -march=i686 -Iinclude/asm-i386/mach-default -O2 -fomit-frame-pointer -DKBUILD_BASENAME=main -DKBUILD_MODNAME=main -c -o init/main.o init/main.c CHK include/linux/compile.h UPD include/linux/compile.h gcc -Wp,-MD,init/.version.o.d -nostdinc -iwithprefix include -D__KERNEL__ -Iinclude -Wall -Wstrict-prototypes -Wno-trigraphs -fno-strict-aliasing -fno-common -pipe -msoft-float -mpreferred-stack-boundary=2 -march=i686 -Iinclude/asm-i386/mach-default -O2 -fomit-frame-pointer -DKBUILD_BASENAME=version -DKBUILD_MODNAME=version -c -o init/version.o init/version.c<..snip..>
9. Cleaning the kernel source
After we have initiated compilation once on the source if we want to clean the object files and other temporary files then we have to run the following:
make clean
This will remove most generated files but will keep the configuration file.
If we need an absolute cleaning, i.e. if we want to return the source to the state in which it was before we started the compilation, then do a
make mrproper
This command will delete all generated files, the configuration file as well as various backup files. This will in effect unwind all the changes we made to the source. The source after this step will be as good as it was just after the download and untar.
10. Conclusion
We have seen how to obtain the linux kernel source, how to configure it, how to build the kernel image and modules, how to boot from the newly compiled kernel and how to do a verbose compilation. Also we have seen how to clean up the temporary files and configuration files which were created during the compilation. The next step for a budding kernel hacker would be to modify the kernel source and try experimenting with it.