Difference between revisions of "HowTo Build Your Own Custom Kernel"
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=== Compiling the Kernel and Modules ===
=== Compiling the Kernel and Modules ===
Now, the kernel:
, if you configured any code to load as modules, build the modules:
Revision as of 23:51, 13 August 2009
- 1 Two Ways to Compile a Kernel
- 2 Cross-compiling a Custom Kernel
- 3 Compiling a Native Kernel
Two Ways to Compile a Kernel
There are two ways to build a custom kernel for the LinkStation/Kurobox. If you have access to an i686 host running some flavor of Linux, you can cross-compile a kernel for ARM9 on an i686 host. Alternatively, if your NAS has enough RAM, you could compile the kernel on the NAS itself, using the system's native gcc. Both ways of these approaches to building a custom kernel are described in the instructions that follow.
Cross-compiling a Custom Kernel
Download All the Required Tarballs
To use the cross toolchain to compile a kernel for ARM9, you'll need access to an i686 host running some flavor of Linux. First, download the cross toolchain (arm-2005q3-2-arm-none-linux-gnueabi-i686-pc-linux-gnu.tar.bz2), mkimage, and the source archive (linux-2.6.12_lsp.1.7.8.tgz):
$ cd /some_directory $ wget -H -c http://downloads.nas-central.org/LSPro_ARM9/DevelopmentTools/CrossToolchains/CodeSourcery/arm-2005q3-2-arm-none-linux-gnueabi-i686-pc-linux-gnu.tar.bz2 $ wget -H -c http://downloads.nas-central.org/LSPro_ARM9/DevelopmentTools/CrossToolchains/mkimage $ wget -H -c http://downloads.nas-central.org/LSPro_ARM9/GPL/gpl_ls-gl/linux-2.6.12_lsp.1.7.8.tgz
If the files were not at the locations indicated above, fear not! Just look in every directory on the server (like I did).
Prepare the Environment
Then, install (i.e., untar) the toolchain and mkimage:
$ cd /some_path $ tar -xjf /some_directory/arm-2005q3-2-arm-none-linux-gnueabi-i686-pc-linux-gnu.tar.bz2 $ cd bin $ export PATH=`pwd`:$PATH $ cp -p /some_directory/mkimage . $ chmod a+rx mkimage
Strictly speaking mkimage should not go into /some_path/bin. But, hey...
Now untar the source of the kernel in some directory:
$ cd /some_directory $ tar -xzf linux-2.6.12_lsp.1.7.8.tgz $ cd linux-2.6.12_lsp.1.7.8
Ready, Get Set, Build!
In some_directory you can find the configs Buffalo used to build the kernels shipped with their various firmwares:
$ ls buffalo/
and choose one to use as a template for yours.
$ cp buffalo/buffalo_lsgl_arm_110.config .config
Then you can modify the configuration as you want:
$ make menuconfig
and start up the build!
$ make uImage
If you selected some features to be built as modules, they need to be prepared too.
$ make modules
The kernel and modules will be ready at arch/arm/boot/uImage.
Compiling a Native Kernel
Software and Source Code Requirements
If the distribution you have installed on your NAS has gcc, and enough RAM to compile a kernel, you should be able to build a custom kernel directly on the box itself. To do this, you will need gcc, a utility called mkimage, and the Buffalo kernel sources for your device. Those using GenLink will already have sys-devel/gcc on their system. mkimage is part of the dev-embedded/u-boot-tools package:
emerge --getbinpkg --usepkg dev-embedded/u-boot-tools
If you're running a different distribution, you should use the commands appropriate to your distribution to install gcc and u-boot-tools.
In case you're wondering, mkimage is a utility used to create kernel and/or initrd images for use with u-boot. u-boot is the standard bootloader used on the LS. The mkimage utility is run by the Makefile during the kernel build process, and is needed to package the kernel so it can later be loaded by u-boot.
The Buffalo kernel sources for your NAS should be available on the Buffalo Source Code Download page. Just look for the model device that you have, follow the link for the firmware version you want, look for a package name starting with "linux-", and download it.
Of course, that's only an example. Download the source package that matches your device.
Unpack and Fix Sources
Once you have the kernel sources, you should unpack them somewhere convenient. For the sake of example, we'll use /usr/src/linux.
cd /usr/src tar -xvjf /wherever/i/downloaded/linux-2.6.22_lsp.3.0.5.tar.bz2 ln -s linux-2.6.22_lsp.3.0.5 linux
(That ln -s is optional, of course, and just for convenience.)
Now that you've unpacked the source, a small change needs to be made to the main Makefile. Since the Makefile was written for cross-compilation, you need to comment out some lines and uncomment others:
#ARCH ?= $(SUBARCH) CROSS_COMPILE ?= ARCH ?= arm #CROSS_COMPILE=arm-none-linux-gnueabi-
There's also a small bug in arch/arm/mach-feroceon/Board/boardEnv/mv88F5182BoardEnv.c that you'll want to fix:
//#if 0 #ifdef CONFIG_BUFFALO_LINKSTATION_LSGL
(Why did they put #if0 in there? Who knows? Just comment it out.)
Configuring the Kernel
Next, you'll want to pre-configure the kernel with the default .config for your NAS. Assuming you have an LS-GL or LS-CL, which are based on the mv88f5182 chip:
cd /usr/src/linux make mv88f5182_defconfig
That will copy the default Buffalo config file (arch/arm/configs/mv88f5182_defconfig) to .config.
Now, you have to configure the kernel.
For some reason, the default .config has CONFIG_BLK_DEV_INITRD and CONFIG_BLK_DEV_RAM disabled, and CONFIG_SYSFS_DEPRECATED and CONFIG_LEGACY_PTYS enabled. So, poke around for those options and change them. When you're done, somewhere in your .config file, you should have each of these lines:
CONFIG_BLK_DEV_INITRD=y CONFIG_BLK_DEV_RAM=y # CONFIG_SYSFS_DEPRECATED is not set # CONFIG_LEGACY_PTYS is not set
You may also want to set a "local version" for your kernel:
Compiling the Kernel and Modules
Now, compile the kernel:
And, if you configured any code to load as modules, build the modules:
The kernel and modules should now be ready at arch/arm/boot/uImage (but hold on a minute, I haven't really gotten this far, yet).