I don’t do a ton of Linux kernel development these days, but I’ve done a fair bit in the past, and picked up a number of useful techniques for doing kernel development in a relatively painless fashion. This blog post is a writeup of the tools and techniques I use when developing for the Linux kernel. Nothing I write here is “the one way” to do it, but this is a workflow I’ve found to work for me, that I hope others may find useful. I’d love to hear if anyone has incremental improvements or alternate strategies.

The instructions as-listed assume you’re developing an x86_64 kernel, from an x86_64 host (kernel and userspace). I will attempt to mention and explain the tweaks necessary for 32-bit kernels and/or hosts where appropriate, out-of-line. Even if you’re running a 32-bit userspace, if you have a 64-bit kernel on the host, it’s perfectly possible to develop on a 64-bit guest, following these instructions.

I’m assuming a Debian or Ubuntu host for development. If you’re not on one of those platforms, the kvm command-lines should still work, but you may need something other than debootstrap to build your images.

Kernel config 🔗︎

For kernel development, unless I have a specific reason to do otherwise, I use an extremely lightweight .config – no modules (everything is built-in), and minimal driver support – in particular, I use virtio drivers for everything, and disable all other driver support. The advantage of no-modules is that it is extremely easy to boot a VM (no fussing around with an initrd), and a minimal config dramatically reduces build times.

I started with an allnoconfig , and manually enabled the features I need. I recommend you just start with my .config file (for kernel 3.12), but I’ll include a detailed list at the end of this post explaining which things I enabled, if you want to construct your own.

(For 32-bit: Just disable CONFIG_64BIT (“64-bit kernel”))

Building a disk image 🔗︎

I use debootstrap to build a minimal Debian userspace, and then transplant that onto a disk image and boot off of that. Here’s an annotated sequence of command lines:

# Build a Wheezy chroot. Install an sshd, since it will be handy # later. mkdir wheezy sudo debootstrap wheezy wheezy --include=openssh-server # Perform some manual cleanup on the resulting chroot: # Make root passwordless for convenience. sudo sed -i '/^root/ { s/:x:/::/ }' wheezy/etc/passwd # Add a getty on the virtio console echo 'V0:23:respawn:/sbin/getty 115200 hvc0' | sudo tee -a wheezy/etc/inittab # Automatically bring up eth0 using DHCP printf '

auto eth0

iface eth0 inet dhcp

' | sudo tee -a wheezy/etc/network/interfaces # Set up my ssh pubkey for root in the VM sudo mkdir wheezy/root/.ssh/ cat ~/.ssh/id_?sa.pub | sudo tee wheezy/root/.ssh/authorized_keys # Build a disk image dd if=/dev/zero of=wheezy.img bs=1M seek=4095 count=1 mkfs.ext4 -F wheezy.img sudo mkdir -p /mnt/wheezy sudo mount -o loop wheezy.img /mnt/wheezy sudo cp -a wheezy/. /mnt/wheezy/. sudo umount /mnt/wheezy # At this point, you can delete the "wheezy" directory. I usually # keep it around in case I've messed up the VM image and want to # recreate it.

(For different architectures: You can pass --arch={i386,amd64} to debootstrap to control the architecture of the bootstrapped chroot)

Booting to userspace 🔗︎

At this point, you can boot to a working userspace by using a simple kvm invocation, giving it your disk image (specifying it should be exposed as a virtio device) and your kernel, and telling the kernel to boot from the virtual disk:

kvm -kernel arch/x86/boot/bzImage \ -drive file=$HOME/vms/wheezy.img,if=virtio \ -append root=/dev/vda

(For 32-bit: Use qemu-system-i386 to emulate a 32-bit VM, instead)

Configuring networking 🔗︎

The easiest way to get working networking in your VM is to use the KVM user-mode networking driver, which makes KVM set up a virtual LAN and NAT your VM to the outside world. To get ssh access, you can tell KVM to set up a port-forward. Just add these arguments to your command-line:

kvm [...] -net nic,model=virtio,macaddr=52:54:00:12:34:56 \ -net user,hostfwd=tcp:127.0.0.1:4444-:22

The MAC address I’ve chosen is the default address historically assigned by KVM. It doesn’t overly matter what you specify, but you want to be consistent, since if the MAC address changes, Debian will renumber the ethernet device (to eth1 , eth2 , etc.), potentially screwing up your networking config.

The hostfwd=tcp:127.0.0.1:4444-:22 fragment forwards port 4444 on localhost on the host to the VM on port 22, so you can ssh to your VM on localhost:4444 .

If you’ve followed the setup above (installing openssh-server , configuring /etc/network/interfaces , and adding your pubkey to the image), ssh should Just Work once the VM boots.

Headless operation 🔗︎

By default, KVM will pop up a graphical console for your VM. This is probably more annoying than useful. To get headless operation, add this to your command-line:

kvm [...] -append 'root=/dev/vda console=hvc0' \ -chardev stdio,id=stdio,mux=on,signal=off \ -device virtio-serial-pci \ -device virtconsole,chardev=stdio \ -mon chardev=stdio \ -display none

Note that the -append here should replace any other -append lines you have; If you’ve added any extra kernel options of your own, you’ll need to merge them all into one -append line.

This will multiplex the KVM console and a virtual console for the VM onto stdout. Type Ctrl-A h to get a help message about switching between them. If everything works right, the kernel console output will appear in your shell, and a getty will run there once you’ve finished booting.

Note that you may need to wait a few seconds before any output shows up, while the kernel boots itself far enough to connect to the virtual console and redirect output.

(For some reason, using a virtconsole like this is not completely reliable for me – every few boots, the console will just fail to come up, somehow. Let me know if you figure it out…)

Sharing a filesystem tree with the VM 🔗︎

scp ing file back and forth with your VM image isn’t too bad, but it’s even easier to directly share a filesystem tree with the VM. To do this, I use a virtio 9P mount. Say I want to share ~/code/linux with the VM. I’d add this to my command-line:

kvm [...] -fsdev local,id=fs1,path=$HOME/code/linux,security_model=none \ -device virtio-9p-pci,fsdev=fs1,mount_tag=host-code

Then, from within the VM, I could run

mkdir -p /mnt/host mount host-code -t 9p /mnt/host

And I’d be sharing the directory back and forth!

A few notes:

security_model=none causes the VM to map permissions between the host and the guest as best it can using the qemu process’s uid, and ignore errors if it can’t (e.g. permission bits will be passed through on files you own, but chowning the file inside the VM will have no effect)

If you’d rather, you can use security_model=passthrough , and run qemu as root, to directly map permissions between the host and guest.

You can add ,readonly on the -fsdev argument to pass the directory through read-only – the VM will be blocked from writing to it.

Building initrds 🔗︎

Booting to a complete userspace inside the VM is great, and super-convenient for exploration and experimentation, but also comparatively slow. One alternative, which is somewhat limited but super lightweight and flexible, is to build test programs into an initrd, and boot directly into that.

To build an initrd from a directory, you can just run:

( cd my-dir && find . | cpio -o -H newc ) | gzip > initrd.gz

In the most lightweight version, you’ll want to build a static binary ( gcc -static should suffice), and store it as /init in your initrd. For example:

$ cat hello.c #include <stdio.h> #include <unistd.h> #include <sys/reboot.h> int main(void) { printf("Hello, world!

"); reboot(0x4321fedc); return 0; } $ mkdir initrd $ gcc -o initrd/init -static hello.c $ ( cd initrd/ && find . | cpio -o -H newc ) | gzip > initrd.gz 1751 blocks $ kvm -kernel arch/x86/boot/bzImage \ -initrd initrd.gz \ -append 'console=hvc0' \ -chardev stdio,id=stdio,mux=on \ -device virtio-serial-pci \ -device virtconsole,chardev=stdio \ -mon chardev=stdio \ -display none input: AT Translated Set 2 keyboard as /devices/platform/i8042/serio0/input/input1 Freeing unused kernel memory: 676K (ffffffff81646000 - ffffffff816ef000) Write protecting the kernel read-only data: 6144k Freeing unused kernel memory: 1156K (ffff8800012df000 - ffff880001400000) Freeing unused kernel memory: 1300K (ffff8800014bb000 - ffff880001600000) Hello, world! ACPI: Preparing to enter system sleep state S5 reboot: Power down

(For 32-bit: You may need to pass gcc -m32 or gcc -m64 if you want to build binaries for a different bittedness than your host)

Kernel debugging with gdb 🔗︎

Add -s to your KVM command line. Once the VM is running, you can attach gdb via:

$ gdb vmlinux (gdb) set architecture i386:x86-64 (gdb) target remote :1234

You can now set breakpoints, inspect memory, single-step, all that goodness, without ever having to think the letters “kgdb”.

You can step seamlessly between userspace and kernelspace, although getting symbols for everything may be tricky (Let me know if you figure out a good way to make gdb manage everything). I’m not aware of a good way to use gdb to inspect physical memory, or the virtual address space of non-running processes. If you need that, it may be worth playing with KVM/qemu’s own built-in console, although I have no expertise with that myself.

(For 32-bit: You may need “set architecture i386” instead, for a 32-bit target. If your host is 32-bit, you may need the gdb-multiarch package to debug a 64-bit target)

Appendix: Kernel config in detail 🔗︎

The .config file I’m using was generated by starting with make allnoconfig and adding in the following options. I’ve attached explanations to some of them.

CONFIG_64BIT

CONFIG_BLK_DEV_INITRD For booting test programs in an initrd.

For booting test programs in an initrd. CONFIG_BLK_DEV

CONGIG_BLK_DEV_RAM Required for initrd

Required for initrd CONFIG_SMP Nearly every computer is SMP these days, so let’s build for testing on SMP.

Nearly every computer is SMP these days, so let’s build for testing on SMP. CONFIG_PCI Virtio all runs over fake PCI devices

Virtio all runs over fake PCI devices CONFIG_ELF

CONFIG_BINFMT_SCRIPT We really need ELF and shebang support.

We really need ELF and shebang support. CONFIG_IA32_EMULATION Optional, but being able to run 32-bit binaries can be useful for testing.

Optional, but being able to run 32-bit binaries can be useful for testing. CONFIG_FILE_LOCKING dpkg and and many other essential userspace tools need file locking.

and and many other essential userspace tools need file locking. CONFIG_NET

CONFIG_UNIX

CONFIG_PACKET dhclient needs CONFIG_PACKET

dhclient needs CONFIG_INET TCP/IP

TCP/IP CONFIG_NETDEVICES

CONFIG_VIRTIO_NET

CONFIG_NET_9P Virtual 9P networking device

Virtual 9P networking device CONFIG_VIRTIO_PCI Support virtio PCI devices

Support virtio PCI devices CONFIG_NET_9P_VIRTIO

CONFIG_9P_FS Support 9P-based filesystem exports.

Support 9P-based filesystem exports. CONFIG_EXT4_FS

CONFIG_EXT4_USE_FOR_EXT23 ext2/3/4 support for the root

ext2/3/4 support for the root CONFIG_TMPFS Needed for udev

Needed for udev CONFIG_INOTIFY_USER Needed for udev

Needed for udev CONFIG_VIRTIO_BLK Needed for the virtio HDD

Needed for the virtio HDD CONFIG_VIRTIO_CONSOLE Needed for the virtio console

Needed for the virtio console CONFIG_DEBUG_KERNEL

CONFIG_DEBUG_INFO

CONFIG_DEBUG_INFO_REDUCED Build with debug symbols; _REDUCED gives significantly better build times, but still keeps key symbols around. Drop it if you’re going to be doing serious kernel debugging.