Funtoo Linux Kernels
This Swction will give you an overview of kernels used in funtoo.
Funtoo Linux provides a number of new kernels for your use. This is the official page for all Funtoo Linux kernel information.
Some points of interest:
- Most Funtoo Linux kernels support the handy binary USE flag, described below.
- Funtoo Linux offers quality kernels from other Linux Distributions, like ubuntu-server and debian-sources.
- A detailed Kernel Features and Stability table can be found below.
- Advanced users may want to take a look at Additional Kernel Resources.
- There is a quick'n dirty howto to compile your own kernel with initramfs the funtoo way.
Overview of Kernels
This kernel is from the SystemRescueCD project, and is based on Fedora 14/15, plus some other patches related to booting from a live CD. It is a quality kernel, and is generally pretty stable. It is not suitable for production servers but is a good choice for Funtoo Linux desktops. The Funtoo Linux Installation Guide recommends this kernel for general users.
This will install the "vanilla" (unmodified) Linux kernel sources. Current recommended version is 3.x. Funtoo Linux fully supports Linux 3.x. The advantages of this kernel include recent improvements to Linux Containers, a very modern networking stack with lots of bug fixes, and high reliability for desktops and servers. The downside is that this kernel must be manually configured by the user and does not have built-in genkernel support via the binary USE flag at this time.
This is a RHEL6-based kernel with OpenVZ support. This kernel is now the preferred kernel for production OpenVZ deployments. It requires gcc-4.4.5 to build. We use this version of gcc since this is the version of gcc used by Red Hat to build this kernel.
This kernel is based on the latest Red Hat Enterprise Linux 5.6 kernel, and contains additional OpenVZ (virtual containers) patches from the OpenVZ project. It is a very stable and reliable kernel, and is recommended for use in production environments. The only major downside to this kernel is that it is based on Linux 2.6.18 -- some parts of the kernel are out-of-date, and it is not compatible with modern versions of udev. However, it is pretty trivial to downgrade udev to an earlier version on Funtoo Linux and this kernel has a track-record of being rock-solid. When stability is paramount, you put up with the udev downgrade, use this kernel, and can enjoy hundreds of days of uptime. For more information on how to use this kernel with Funtoo Linux, see the RHEL5 Kernel HOWTO.
This is the kernel from Ubuntu Server. Version 22.214.171.124.62 is the same version used in Ubuntu Server 10.04 LTS, and version 126.96.36.199.50 is the one used in Ubuntu Server 10.10 (currently masked). In our testing of 188.8.131.52.62, it has been very reliable and offers very good performance. One exception, which is common among 2.6.32-based kernels, is that it's recommended that you emerge broadcom-netxtreme2 if you have any Broadcom-based NICs, as the in-kernel drivers have compatibility issues with certain models. This kernel is a very good option if you want a relatively modern server kernel and do not need OpenVZ support. We use gcc-4.4.5 to build this kernel.
This is the Debian kernel. These ebuilds now support the binary USE flag. Daniel has added a special config-extract command which can be used to list all available official Debian kernel configurations, and generate them from the Debian files included with the kernel. This kernel has optional OpenVZ support, but it is much better to use openvz-rhel6-stable if you want a production-quality OpenVZ installation. For more information about how to use debian-sources and config-extract, see Using debian-sources with Genkernel below.
This is the Debian long-term stable kernel. These ebuilds now support the binary USE flag. Daniel has added a special config-extract command which can be used to list all available official Debian kernel configurations, and generate them from the Debian files included with the kernel.
Many of the kernel ebuilds in Funtoo Linux support the very useful binary USE flag. By enabling this USE flag and emerging the kernel, the ebuild will automatically build a binary kernel image, initramfs and kernel modules and install them to /boot. The binary kernel image and initramfs can be used to boot your Funtoo Linux system without requiring any additional configuration. This is a great way to get a Funtoo Linux system up and running quickly. Here's how to do it:
# echo "sys-kernel/openvz-rhel5-stable binary" >> /etc/portage/package.use # emerge openvz-rhel5-stable # nano -w /etc/boot.conf # boot-update
More information can be found in the Funtoo Linux Installation Guide.
Funtoo Linux Genkernel
Funtoo Linux contains a forked/enhanced version of genkernel with the following new capabilities:
- genkernel can use a build directory that is separate from the kernel source directory. This is enabled using the new --build-dst option.
- --build-src is a new option that is equivalent to the --kerneldir option.
- --fullname can be used to specify the entire name of the kernel and initramfs images -- everything after kernel- and initramfs-.
- --firmware-src - a new option that works identically to --firmware-dir.
- --firmware-dst - a new capability - you can now define where genkernel installs firmware.
- Genkernel uses Funtoo Linux lvm2 rather than building its own.
- Some compile fixes.
Kernel Features and Stability
This page provides an overview of kernel features and stability information:
|Kernel Name||Version||USE flags||Stability||Extra Features||Req'd udev||Notes|
|vanilla-sources||3.1.5||N/A||Excellent - recommended for desktops and servers.||N/A||Any||Recommended for modern networking stack, hardware and Linux Containers support. This kernel must be manually configured by the user.|
|sysrescue-std-sources||184.108.40.206||binary||Good - recommended for desktops||N/A||Any||Nvidia card users: binary use flag installs nouveau drivers. Not compatible with nvidia-drivers.|
|openvz-rhel6-stable||2.6.32.042.044.11||binary||Excellent - recommended for production servers||N/A||Any||This kernel is built with gcc-4.4.5. emerge broadcom-netxtreme2 for reliable BCM5709+ support (integrated NIC)|
|openvz-rhel5-stable||2.6.18.028.095.1||binary||Excellent - recommended for production servers||OpenVZ||=sys-fs/udev-146*||Broadcom bnx2 driver module bundled with kernel appears to be OK. This kernel is built with gcc-4.1.2. Enabling the binary USE flag will cause gcc-4.1.2 to be emerged and used for building the kernel.|
|ubuntu-server||220.127.116.11.62||binary||Excellent - recommended for production servers (still in extended testing)||N/A||Any||This kernel is built with gcc-4.4.5. emerge broadcom-netxtreme2 for reliable BCM5709+ support (integrated NIC)|
|ubuntu-server||18.104.22.168.50||binary||not yet tested||N/A||Any||This kernel is built with gcc-4.4.5. emerge broadcom-netxtreme2 for reliable BCM5709+ support (integrated NIC)|
|debian-sources||22.214.171.124||openvz||Good - still being evaluated by Funtoo||OpenVZ (optional)||Any||See #Using debian-sources with Genkernel, below.|
Using Debian-Sources with Genkernel
This section describes how to build a binary kernel with debian-sources and genkernel, and it also explains how to use Funtoo Linux's config-extract tool to list and create official Debian kernel configurations.
First step: emerging the required packages
The first step is to emerge:
- The Debian sources
- Genkernel itself
This is achieved with:
# emerge sys-kernel/debian-sources sys-kernel/genkernel
Once the Debian kernel sources are deployed, you should find a directory named linux-debian-version (e.g. linux-debian-126.96.36.199) under /usr/src. Update your the linux symlink to point on this directory:
# cd /usr/src # rm linux # ln -s linux-debian-188.8.131.52 linux
Alternatively, emerge the debian-sources with USE="symlink"
Second step: Grabbing a configuration file
If is now time to download the kernel configuration file. For this tutorial we will use a configuration file for AMD64 (several others architectures like MIPS or SPARC64 are available.) To view a complete list of available kernel configurations, type ./config-extract -l in the Debian kernel source directory:
ninja1 linux-debian-184.108.40.206 # ./config-extract -l ====== standard featureset ====== alpha: alpha-generic, alpha-legacy, alpha-smp amd64 armel: iop32x, ixp4xx, kirkwood, orion5x, versatile hppa: parisc, parisc-smp, parisc64, parisc64-smp i386: 486, 686, 686-bigmem, amd64 ia64: itanium, mckinley m68k: amiga, atari, bvme6000, mac, mvme147, mvme16x mips: 4kc-malta, 5kc-malta, r4k-ip22, r5k-ip32, sb1-bcm91250a, sb1a-bcm91480b mipsel: 4kc-malta, 5kc-malta, r5k-cobalt, sb1-bcm91250a, sb1a-bcm91480b powerpc: powerpc, powerpc-smp, powerpc64 s390: s390x, s390x-tape sh4: sh7751r, sh7785lcr sparc: sparc64, sparc64-smp sparc64: sparc64, sparc64-smp ====== vserver featureset ====== amd64 i386: 686, 686-bigmem ia64: itanium, mckinley powerpc: powerpc, powerpc64 s390 sparc sparc64 ====== xen featureset ====== amd64 i386 ====== openvz featureset ====== amd64 i386
Type config-extract -h for extended usage information:
ninja1 linux-debian-220.127.116.11 # ./config-extract -h This work is free software. Copyright 2011 Funtoo Technologies. You can redistribute and/or modify it under the terms of the GNU General Public License version 3 as published by the Free Software Foundation. Alternatively you may (at your option) use any other license that has been publicly approved for use with this program by Funtoo Technologies (or its successors, if any.) usage: config-extract [options] arch [featureset] [subarch] -h --help print this usage and exit -l --list list all available kernel configurations -o --outfile specify kernel config outfile -- defaults to .config in current directory [featureset] defaults to "none" if not specified [subarch] defaults to the only one available; otherwise required This program was written by Daniel Robbins for Funtoo Linux, for the purpose of easily and conveniently extracting Debian kernel configurations. To see a nice list of all available kernel configurations, use the --list option. Debian's kernel configs are specified internally in arch_featureset_flavor format, such as: "amd64_openvz_amd64". The featureset typically describes an optional kernel configuration such as "xen" or "openvz", while the flavor in Debian terminology typically refers to the sub-architecture of the CPU. When using this command, you must specify an arch. A featureset of "none" is assumed unless you specify one, and by default this program will pick the only available subarch if there is only one to choose from. If not, you will need to pick one (and the program will remind you to do this.) The kernel configuration will be written to ".config" in the current directory, or the location you specified using the -o/--outfile option.
Let's use config-extract to create a kernel configuration for an amd64 system:
# cd linux # ./config-extract amd64 Wrote amd64_none_amd64 kernel configuration to /usr/src/linux-debian-18.104.22.168/.config.
config-extract also allows you to extract special Debian featuresets, such as settings for Xen and OpenVZ kernels:
# ./config-extract amd64 openvz Wrote amd64_openvz_amd64 kernel configuration to /usr/src/linux-debian-22.214.171.124/.config.
After using config-extract, run make oldconfig and accept all default options by hitting Enter at all prompts.
Third step: Building and installing the kernel
This is simply achieved by:
# genkernel --kernel-config=config-2.6.32-5-amd64 all
- --kernel-config: use the given configfile. If you only give a filename here, it is searched for in your current working dir. You can also use a relative or an absolute path leading to your configfile here (for example: "--kernel-config=/usr/src/linux/configfile").
- all: rebuild the kernel image and the initramfs ramdisk image (aside of kernel modules, the ramdisk image contains tools such as BusyBox and some generic startup scripts, depending on options you use on the command line several additional tools like lvm or raid volume management can be incorporated as well).
Unless explicitly stated via --no-clean or --no-mrproper, Genkernel will do a make mrproper in the kernel source tree, thus cleaning a previous build and removing the previous kernel configuration file in it.
If you use Genkernel to rebuild a Linux kernel on SPARC64, remember to either:
- Set sparc64-unknown-linux-gnu- in General setup --> Cross-compiler tool prefix
- Put --kernel-cross-compile=sparc64-unknown-linux-gnu- on the Genkernel command line
One the kernel has been compiled and the ram disk has been generated, the kernel image plus its companion files (initramfs image and System.map) are placed in the /boot directory, You can use your favourite tool to update your bootloader configuration files.