By Thomas Leonard - 2014-04-16
Author: Thomas Leonard, addendums from Anil Madhavapeddy
These notes detail the process of setting up a Xen system on a Cubieboard2 (or Cubietruck). They are based on the Xen ARM with Virtualization Extensions/Allwinner documentation, but try to collect everything into one place. I'm trying to document the exact steps I took (with the wrong turns removed); some changes will be needed for other systems.
TL;DR: There is now a script available that generates an image with Xen, Ubuntu dom0, and the OCaml tools installed. Just run the
make instructions at mirage/xen-arm-builder and copy the resulting image onto an SDcard and boot up your Cubieboard2 or Cubietruck (password
mirage which you should change as the first thing you do). The script is kept more up-to-date than the instructions on this page.
The remainder of this guide covers:
(Updated 2020-10-26. The following information is of historical interest, since MirageOS 3.9.0 our Xen backend has been revised, and only supports PVH mode and x86_64 as architecture.)
This step can be skipped, but it's useful to check that everything works.
Download Cubieez, a Debian 7.1 image that works on the Cubieboard2. Write to microSD card with:
dd if=cubieez_1.0.0_A20.img of=/dev/mmcblk0
You will need to hook up the serial console on the Cubieboard, being careful not to connect up one of the pins. One good cable that is known is work can be bought here. Follow the instructions at the Sunxi/TTL page to connect up 3 of the cables to the right pins.
Connect the USB serial cable and run "screen" to monitor it:
screen -h 10000 /dev/ttyUSB0 115200
Note: I tried using "minicom" first, but for some reason keyboard input didn't work with that.
Insert microSD card in board and connect power. You should see boot messages in screen:
U-Boot SPL 2013.04-07297-gc8f265c (Jun 17 2013 - 17:26:22) Board: Cubieboard2 DRAM: 1024MB CPU: 960000000Hz, AXI/AHB/APB: 3/2/2 SUNXI SD/MMC: 0
You can connect a keyboard/mouse/screen and use it. The login is cubie/cubieboard.
If the device boots instead into Android then it is probably booting from NAND (it tries the microSD first, then the NAND).
To build the various binaries (U-Boot, Linux, Xen), we need an ARM cross-compiler toolchain.
The A20 has hardware FPU, so use the hf version of the cross-compiler for best performance.
On Arch Linux, run:
yaourt -S arm-linux-gnueabihf-gcc
On Debian testing, run (as root):
apt-get install gcc-arm-none-eabi
On a modern Ubuntu, run:
sudo apt-get install gcc-arm-linux-gnueabihf
This installs files such as, say, on Ubuntu:
Take note of the common prefix. Define a variable to hold it:
Xen needs to be started in non-secure HYP mode. Use this U-Boot Git repository:
git clone https://github.com/jwrdegoede/u-boot-sunxi.git cd u-boot-sunxi git checkout -b sunxi-next origin/sunxi-next
WARNING This branch no longer exists.
Note: only the "sunxi-next" branch has the required hypervisor support; DO NOT use the "sunxi" branch.
Configure and build U-Boot using the ARM toolchain:
make CROSS_COMPILE=$CROSS_COMPILE Cubieboard2_config make CROSS_COMPILE=$CROSS_COMPILE -j 4
The above is configured to:
mmcblk0p2as Linux's root FS
boot/Makefile to compile it using
all: boot.scr %.scr: %.cmd ../tools/mkimage -C none -A arm -T script -d "$<" "$@"
boot and run
make to build
Remark: You may have noticed that the above
.cmd files allocate a
rather large amount of memory to
dom0 (look at the
parameter). This is needed to compile large libraries like
However, if you use
xl will automatically reduce the amount of memory assigned to dom0
to free memory for new domains. An OCaml daemon
squeezed, currently in
development (and based on
xenopsd), will dynamically
move memory between dom0 and VMs to satisfy their needs.
Get my Linux Git tree, master branch. This fork has a few extra patches we need.
cd ../.. git clone https://github.com/talex5/linux.git cd linux
make ARCH=arm multi_v7_defconfig make ARCH=arm menuconfig
Here are the settings I used (check it works with just these settings and whether they're all actually necessary):
CONFIG_CROSS_COMPILE="/usr/bin/arm-linux-gnueabihf-" CONFIG_XEN_DOM0=y CONFIG_XEN=y CONFIG_IPV6=y CONFIG_NETFILTER=y CONFIG_NETFILTER_ADVANCED=y CONFIG_BRIDGE_NETFILTER=y CONFIG_STP=y CONFIG_BRIDGE=y CONFIG_SYS_HYPERVISOR=y CONFIG_XEN_BLKDEV_FRONTEND=y CONFIG_XEN_BLKDEV_BACKEND=y CONFIG_AHCI_SUNXI=y CONFIG_XEN_NETDEV_FRONTEND=y CONFIG_XEN_NETDEV_BACKEND=y CONFIG_INPUT_AXP20X_PEK=y CONFIG_INPUT_XEN_KBDDEV_FRONTEND=y CONFIG_HVC_DRIVER=y CONFIG_HVC_IRQ=y CONFIG_HVC_XEN=y CONFIG_HVC_XEN_FRONTEND=y CONFIG_MFD_AXP20X=y CONFIG_REGULATOR_AXP20X=y CONFIG_FB_SYS_FOPS=y CONFIG_FB_DEFERRED_IO=y CONFIG_XEN_FBDEV_FRONTEND=y CONFIG_MMC_SUNXI=y CONFIG_VIRT_DRIVERS=y CONFIG_XEN_BALLOON=y CONFIG_XEN_SCRUB_PAGES=y CONFIG_XEN_DEV_EVTCHN=y CONFIG_XEN_BACKEND=y CONFIG_XENFS=y CONFIG_XEN_COMPAT_XENFS=y CONFIG_XEN_SYS_HYPERVISOR=y CONFIG_XEN_XENBUS_FRONTEND=y CONFIG_XEN_GNTDEV=y CONFIG_XEN_GRANT_DEV_ALLOC=y CONFIG_SWIOTLB_XEN=y CONFIG_XEN_PRIVCMD=y ONFIG_PHY_SUN4I_USB CONFIG_HAS_IOPORT=y # LVM CONFIG_MD=y CONFIG_BLK_DEV_DM_BUILTIN=y CONFIG_BLK_DEV_DM=y CONFIG_DM_BUFIO=y CONFIG_DM_SNAPSHOT=y
A simpler alternative to
make ARCH=arm menuconfig is to copy
CONFIG_CROSS_COMPILE must have the value of
make ARCH=arm zImage dtbs modules -j 4
Currently, some minor patches are needed to the official Xen 4.4 release, so use this Git version:
cd .. git clone -b stable-4.4 https://github.com/talex5/xen.git cd xen
Config.mk and turn debug on:
debug ?= y.
This enables some features that are useful when debugging guests, such as allowing guests to write debug messages to the Xen console.
Note: If you already built Xen without debug,
make clean is NOT sufficient! Use
git clean -xfd for a clean build.
make dist-xen XEN_TARGET_ARCH=arm32 CROSS_COMPILE=$CROSS_COMPILE CONFIG_EARLY_PRINTK=sun7i -j4
Source: Bootable SD card
Clear the device (maybe not really necessary):
dd if=/dev/zero of=/dev/mmcblk0 bs=1M count=1
Create a partition table. I used gparted (Device -> Create Partition Table -> msdos).
Create the partitions (a 16 MB FAT boot partition, a 4 GB dom0 root, and the rest for the guests as an LVM volume):
sfdisk -R /dev/mmcblk0 cat <<EOT | sudo sfdisk --in-order -uM /dev/mmcblk0 1,16,c ,4096,L ,,8e EOT mkfs.vfat /dev/mmcblk0p1 mkfs.ext4 /dev/mmcblk0p2
Write the U-Boot SPL and main program:
dd if=u-boot-sunxi-with-spl.bin of=/dev/mmcblk0 bs=1024 seek=8
Mount the fat partition and copy in
boot.scr, the Linux kernel, the
FDT and Xen (you must create
/mnt/mmc1 if it does not exist):
mount /dev/mmcblk0p1 /mnt/mmc1 cp u-boot-sunxi/boot/boot.scr /mnt/mmc1/ cp linux/arch/arm/boot/zImage /mnt/mmc1/vmlinuz cp linux/arch/arm/boot/dts/sun7i-a20-cubieboard2.dtb /mnt/mmc1/ cp xen/xen/xen /mnt/mmc1/ umount /mnt/mmc1
For the Cubietruck, replace the third line with:
cp linux/arch/arm/boot/dts/sun7i-a20-cubietruck.dtb /mnt/mmc1/
(You must run these commands as root or prefix them with
The wiki's links to the prebuilt root images are broken, but a bit of searching turns up some alternatives.
mount /dev/mmcblk0p2 /mnt/mmc2 cd /mnt/mmc2 sudo tar xf /your/path/to/linaro-trusty-developer-20140522-661.tar.gz sudo mv binary/* . sudo rmdir binary
Go back to the directory where you compiled your Linux kernel and do:
make ARCH=arm INSTALL_MOD_PATH='/mnt/mmc2' modules_install
/mnt/mmc2/etc/fstab should contain:
/dev/mmcblk0p2 / ext4 rw,relatime,data=ordered 0 1
/mnt/mmc2/etc/network/interfaces (this sets up a bridge, which will be useful for guest networking):
auto lo iface lo inet loopback auto eth0 iface eth0 inet manual up ip link set eth0 up auto br0 iface br0 inet dhcp bridge_ports eth0
At this point, it's possible to boot and get the U-Boot prompt and run Xen and Dom0:
U-Boot SPL 2014.04-rc2-01269-gf8616c0 (Apr 07 2014 - 18:53:46) Board: Cubieboard2 DRAM: 1024 MiB CPU: 960000000Hz, AXI/AHB/APB: 3/2/2 spl: not an uImage at 1600 U-Boot 2014.04-rc2-01269-gf8616c0 (Apr 07 2014 - 18:53:46) Allwinner Technology CPU: Allwinner A20 (SUN7I) Board: Cubieboard2 I2C: ready DRAM: 1 GiB MMC: SUNXI SD/MMC: 0 *** Warning - bad CRC, using default environment In: serial Out: serial Err: serial Net: dwmac.1c50000 Warning: failed to set MAC address Hit any key to stop autoboot: 0
The first bit "U-Boot SPL" is the SPL running, setting up the RAM and loading the main U-Boot. The "spl: not an uImage at 1600" warning is harmless. It looks at offset 1600 first, and then tries 80 next and succeeds.
The "bad CRC" warning is just because we didn't specify an environment file.
After booting, you should get a root prompt. Install openssh:
mount -o remount,rw / mount -t proc proc /proc export PATH=/bin:/usr/bin:/sbin:/usr/sbin export HOME=/root ifup eth0 ip addr show dev eth0 apt-get install openssh-server
Add your ssh key:
cd mkdir .ssh vi .ssh/authorized_keys
apt-get install avahi-daemon libnss-mdns
You must also install these packages and
avahi-utils on your
You probably want to give your Cubieboard a nice name. Edit
/etc/hostname and replace the existing name with the one of your
cubie2 for the following.
(You should also change
For the changes to take effect, you can either reboot or run
hostname cubie2 followed by
You should now be able to connect with e.g., from your computer
To see the list of Avahi services on your network, do
avahi-browse -alr. If you do not see your Cubieboard, check that its network is
ip addr show
at the Cubieboard root prompt, should output some information
including a line starting with
br0: <BROADCAST,MULTICAST,UP,LOWER_UP>. If it doesn't try
brctl addbr br0
If you get
add bridge failed: Package not installed, you forgot to
include Ethernet bridging in your kernel (it is included with the
.config file above so this should not happen).
Kill the network and shut down:
ifdown eth0 mount -o remount,ro / halt -f
boot.cmd and put the new
boot.scr into mmcblk0p1. Then boot again.
You should now be able to ssh in directly.
Ssh to your Cubieboard and install the Xen tools:
apt-get install xen-utils-4.4
Once Xen 4.4 is installed, you can list your domains:
# xl list Name ID Mem VCPUs State Time(s) Domain-0 0 512 2 r----- 19.7
Install the LVM tools in dom0 and set up the volume group:
apt-get install lvm2 pvcreate /dev/mmcblk0p3 vgcreate vg0 /dev/mmcblk0p3
Create a new LVM partition for the guest's root FS and format it:
lvcreate -L 4G vg0 --name linux-guest-1 /sbin/mkfs.ext4 /dev/vg0/linux-guest-1
Note: we're going to make a fairly big VM, as we'll be using it as a build machine soon.
Mount it and install an OS (e.g. Ubuntu 14.04 here):
mount /dev/vg0/linux-guest-1 /mnt debootstrap --arch armhf trusty /mnt chroot /mnt passwd
auto eth0 iface eth0 inet dhcp
/etc/fstab should contain:
/dev/xvda / ext4 rw,relatime,data=ordered 0 1
Add any extra software you want:
apt-get install openssh-server mkdir -m 0700 /root/.ssh vi /root/.ssh/authorized_keys
Note: openssh will fail to start as port 22 is taken, but it still installs.
exit umount /mnt
Copy the Linux kernel image into /root (the dom0 one is fine). Create
kernel = "/root/zImage" memory = 512 name = "Ubuntu-14.04" vcpus = 2 serial="pty" disk = [ 'phy:/dev/vg0/linux-guest-1,xvda,w' ] vif = ['bridge=br0'] extra = 'console=hvc0 xencons=tty root=/dev/xvda'
You should now be able to boot the Linux guest:
xl create domU_test -c
I created a VM on my laptop and installed FreeBSD from FreeBSD-10.0-RELEASE-amd64-bootonly.iso. I then used that to cross-compile the Xen/ARM version. Your build VM will need to have at least 4 GB of disk space.
git clone git://xenbits.xen.org/people/julieng/freebsd.git -b xen-arm-v2
Note: I tested with the
xen-arm branch, but the
xen-arm-v2 branch has some useful fixes.
Note: Installing Git using FreeBSD using ports on a clean system is very slow, uses a lot of disk space, requires many confirmations and, in my case, failed. So I suggest cloning the repository with your main system and then transferring the files directly to the FreeBSD build VM instead.
In the build FreeBSD (note: the build takes several hours; you might want to assign multiple CPUS to your VM and use
cd freebsd truncate -s 512M xenvm.img mdconfig -f xenvm.img -u0 newfs /dev/md0 mount /dev/md0 /mnt make TARGET_ARCH=armv6 kernel-toolchain make TARGET_ARCH=armv6 KERNCONF=XENHVM buildkernel make TARGET_ARCH=armv6 buildworld make TARGET_ARCH=armv6 DESTDIR=/mnt installworld distribution echo "/dev/xbd0 / ufs rw 1 1" > /mnt/etc/fstab echo 'xc0 "/usr/libexec/getty Pc" xterm on secure' >> /mnt/etc/ttys umount /mnt mdconfig -d -u0
Then you can copy
xenvm.img and the kernel (
/usr/obj/arm.armv6/root/freebsd/sys/XENHVM/kernel) to dom0 on the Cubieboard2.
You might want to rename the kernel (e.g. to
Create a new partition for it and copy the filesystem in:
lvcreate --name freebsd -L 512M vg0 dd if=xenvm.img of=/dev/vg0/freebsd
Here's a suitable
freebsd.cfg config file:
kernel="freebsd-kernel" memory=64 name="freebsd" vcpus=1 autoballon="off" disk=[ 'phy:/dev/vg0/freebsd,xvda,w' ]
If you try to start the domain with Debian's version of
xl, you'll get
Unable to find arch FDT info for xen-3.0-unknown.
To fix this, you need to rebuild the Xen toolstack with these two patches (I applied them to the
Build it using the ARM build guest:
cd xen/tools ./configure --prefix=/opt/xen-freebsd make make install
/opt/xen-freebsd to dom0 and you can then start the FreeBSD domain with:
export LD_LIBRARY_PATH=/opt/xen-freebsd/lib/ /opt/xen-freebsd/sbin/xl create -c freebsd.cfg
You should get a root prompt:
# uname -a FreeBSD 11.0-CURRENT FreeBSD 11.0-CURRENT #2: Tue Apr 15 20:37:04 BST 2014 root@freebsd:/usr/obj/arm.armv6/root/freebsd/sys/XENHVM arm
Mini-OS is a small demonstration OS for Xen. I had to make some changes to the (experimental) ARM version to make it work on the Cubieboard2. You'll need to install a few things to build it:
apt-get install build-essential libfdt-dev git
Clone the repository and build:
git clone -b devel https://github.com/talex5/xen.git cd xen/extras/mini-os make
Transfer the resulting
mini-os.img to your dom0 and add a configuration file for it:
kernel = "/root/mini-os.img" memory = 128 name = "Mini-OS" vcpus = 1 serial="pty" disk = [ 'phy:/dev/vg0/mini-os,xvda,w' ] vif = ['bridge=br0']
Create a disk for it:
lvcreate -L 8M vg0 --name mini-os
You should now be able to start it:
xl create mini-os.cfg
On success, it will write lots of text to the Xen console (note: this requires a debug build of Xen):
(d6) dtb_pointer : 87fff000 (d6) MM: Init (d6) _text: 80008000(VA) (d6) _etext: 80018f1c(VA) (d6) _erodata: 8001b000(VA) (d6) _edata: 8002820c(VA) (d6) stack start: 8001c000(VA) (d6) _end: 8002dee0(VA) (d6) start_pfn: 80415 (d6) max_pfn: 8282d (d6) MM: Initialise page allocator for 80415000(80415000) - 0(8282d000) (d6) MM: done (d6) Initialising timer interface ...
You can now try running a MirageOS unikernel.