Difference between revisions of "Ubuntu Disk Image for ARM Full System"
(Update the page to account for changes in Ubuntu since 11.04) |
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This page describes how to build a serial-console filesystem of Ubuntu Linux for ARM ISA simulation after the bare image file is created. An example Ubuntu Natty ARM image is available on the [[Download]] page. | This page describes how to build a serial-console filesystem of Ubuntu Linux for ARM ISA simulation after the bare image file is created. An example Ubuntu Natty ARM image is available on the [[Download]] page. | ||
− | |||
== Using Rootstock and Qemu to build the filesystem == | == Using Rootstock and Qemu to build the filesystem == | ||
− | + | One way to create a disk image is to use the rootstock tool provided in older versions of Ubuntu to build an ARM filesystem. To create a base 2GB filesystem that can be booted to the serial console, run the following command: | |
<nowiki>%>rootstock --fqdn gem5sim --login gem5 --password 5meg --imagesize 2G --seed build-essential</nowiki> | <nowiki>%>rootstock --fqdn gem5sim --login gem5 --password 5meg --imagesize 2G --seed build-essential</nowiki> | ||
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== Using Ubuntu CoreFS and Qemu to build an Ubuntu file system for 12.04LTS+ == | == Using Ubuntu CoreFS and Qemu to build an Ubuntu file system for 12.04LTS+ == | ||
− | [http://cdimage.ubuntu.com/ubuntu-core/releases/12.04/release/ Ubuntu Core] offers pre-compiled base file systems in a tarball | + | [http://cdimage.ubuntu.com/ubuntu-core/releases/12.04/release/ Ubuntu Core] offers pre-compiled base file systems in a tarball to use instead of rootstock. Since v12.04 of Ubuntu, cannonical now offers hardfloat (hf) ABI compiled binaries to make better use of VFP and NEON along with the usual softfloat binaries (armel). Make sure to install the qemu-arm-static package to be able to install packages to your file-system after you have unpacked the tarball to a blank disk image. After unpacking the tarball to the blank image copy the qemu-arm-static binary from /usr/bin from your host system to the usr/bin directory of your disk image. This allows ARM emulation for installing packages directly to the disk image, and even for compiling source packages using an ARM version of GCC. Perform the following operations to get a functional Ubuntu file system that can run hardfloat and softfloat binaries. |
<nowiki> | <nowiki> | ||
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apt-get install gcc-multilib | apt-get install gcc-multilib | ||
apt-get install g++-multilib | apt-get install g++-multilib | ||
− | apt-get install <what ever packages you want> | + | apt-get install <what ever other packages you want> |
</nowiki> | </nowiki> | ||
− | If you transfer the file system created | + | If you transfer the file system created here to another computer make sure resolv.conf in /etc of the created filesystem is updated to match the resolv.conf of the host system, otherwise apt-get will fail to function properly. |
== Setting up Upstart to be Gem5 friendly == | == Setting up Upstart to be Gem5 friendly == | ||
− | Instead of the old SysV and init.d, Ubuntu uses Upstart for mounting filesystems and loading the various daemons upon boot. To speed up the process | + | Instead of the old SysV and init.d, Ubuntu uses Upstart for mounting filesystems and loading the various daemons upon boot. To speed up the process in simulation the following upstart scripts should be removed from the /etc/init folder in the new filesystem as they are not needed: |
* console.conf | * console.conf |
Revision as of 09:57, 27 June 2012
This page describes how to build a serial-console filesystem of Ubuntu Linux for ARM ISA simulation after the bare image file is created. An example Ubuntu Natty ARM image is available on the Download page.
Using Rootstock and Qemu to build the filesystem
One way to create a disk image is to use the rootstock tool provided in older versions of Ubuntu to build an ARM filesystem. To create a base 2GB filesystem that can be booted to the serial console, run the following command:
%>rootstock --fqdn gem5sim --login gem5 --password 5meg --imagesize 2G --seed build-essential
Other packages can be added to the --seed option list to be installed by rootstock. Rootstock will create a tar file containing the file system. Unpack this tar file into the blank disk image. Packages can also be installed at a later date by mounting the filesystem to a loop device, mounting its proc filesystem and chroot'ing into the filesystem. Qemu will be used to emulate the binaries within the ARM filesystem to install additional packages using apt-get. For the below to work you need to have installed the rootstock packages so the various qemu emulators are available. For example
Attention: Rootstock has been deprecated by Ubuntu for making ARM disk images from x86 machines. They now offer core file system image tarballs for download.
Using Ubuntu CoreFS and Qemu to build an Ubuntu file system for 12.04LTS+
Ubuntu Core offers pre-compiled base file systems in a tarball to use instead of rootstock. Since v12.04 of Ubuntu, cannonical now offers hardfloat (hf) ABI compiled binaries to make better use of VFP and NEON along with the usual softfloat binaries (armel). Make sure to install the qemu-arm-static package to be able to install packages to your file-system after you have unpacked the tarball to a blank disk image. After unpacking the tarball to the blank image copy the qemu-arm-static binary from /usr/bin from your host system to the usr/bin directory of your disk image. This allows ARM emulation for installing packages directly to the disk image, and even for compiling source packages using an ARM version of GCC. Perform the following operations to get a functional Ubuntu file system that can run hardfloat and softfloat binaries.
// if you have not mounted the disk image, do so now, make sure to unpack the core // fs to this disk image before continuing mount -oloop,offset=32256 /tmp/Ubuntu-arm.img /mnt cd /mnt mount -o bind /proc /mnt/proc mount -o bind /dev /mnt/dev mount -o bind /sys /mnt/sys cp /etc/resolv.conf /mnt/etc/ chroot . // enable the universe repo in etc/apt/sources.list apt-get update apt-get install ubuntu-minimal apt-get install build-essential apt-get install vim apt-get install gcc-multilib apt-get install g++-multilib apt-get install <what ever other packages you want>
If you transfer the file system created here to another computer make sure resolv.conf in /etc of the created filesystem is updated to match the resolv.conf of the host system, otherwise apt-get will fail to function properly.
Setting up Upstart to be Gem5 friendly
Instead of the old SysV and init.d, Ubuntu uses Upstart for mounting filesystems and loading the various daemons upon boot. To speed up the process in simulation the following upstart scripts should be removed from the /etc/init folder in the new filesystem as they are not needed:
- console.conf
- console-setup.conf
- container-detect.conf
- cron.conf
- dmesg.conf
- hwclock.conf
- hwclock-save.conf
- mounted-debugfs.conf
- mounted-tmp.conf
- mountall-net.conf
- network-interface-container.conf
- network-interface-security.conf
- plymouth.conf
- plymouth-log.conf
- plymouth-splash.conf
- plymouth-stop.conf
- plymouth-upstart-bridge.conf
- rsyslog.conf
- setvtrgb.conf
- tty[x].conf (only need tty1.conf)
- udev-fallback-graphics.conf
- ureadahead.conf
- ureadahead-other.conf
The following changes should be made to the mountall.conf script:
- Remove the fsck checks at the beginning of the script declaration
- Remove the fsck checks in the post-script declaration
- Remove the exec mountall --daemon declaration so total control of what filesystems are mounted and when is retained
To the script field on the mountall.conf file, add at least the following:
# Mount appropriate file systems from fstab and remount root. mount /proc mount /tmp mount /sys mount -o remount,rw /dev/sda1 / swapon /swapfile # if present # Make sure to emit all events that mountall would have initctl emit virtual-filesystems initctl emit local-filesystems initctl emit remote-filesystems initctl emit all-swaps initctl emit filesystem initctl emit mounting initctl emit mounted
Additionally, one of the tty.conf scripts should be modified like below to get a login prompt within m5term or load an .rcS job script with multi-user and job-control enabled:
script if [ ! -c /dev/ttyAMA0 ] then mknod /dev/ttyAMA0 c 204 64 fi if [ ! -c /dev/ttySA0 ] then if [ ! -L /dev/ttySA0 ] then ln -s /dev/ttyAMA0 /dev/ttySA0 fi fi /sbin/m5 readfile > /tmp/script chmod 755 /tmp/script if [ -s /tmp/script ] then exec su root -c '/tmp/script' # gives script full privileges as root user in multi-user mode exit 0 else exec /sbin/getty -L ttySA0 38400 vt100 # login prompt fi end script
By default a modules.dep file will not be created by rootstock, this file is needed to prevent certain upstart scripts from failing. To create this file, add the following to the beginning of the script declaration in init/modules-init-tools.conf, or simply add your own custom modules.dep file in the appropriate directory for your kernel.
if [ ! -e /lib/modules/`uname -r`/modules.dep ] then mkdir /lib/modules/`uname -r` echo "#No modules for this run of Gem5" > /lib/modules/`uname -r`/modules.dep fi
To allow passwordless login to the filesystem, edit the /etc/shadow file to have the gem5 and root entries look like the following.
root::15201:0:99999:7::: gem5::15201:0:99999:7:::
Ensure that the tty that will be used as the login tty is contained within the /etc/securetty file. In most cases this will probably be ttyAMA0. Go through the mounted-proc.conf, mounted-dev.conf, mounted.tmp.conf and mounted-varrun.conf and verify all use the clause
start on mounted
so the scripts start running.
The rc-sysinit.conf file should have most of the script body commented out except for these lines:
[ -n "${FROM_SINGLE_USER_MODE}" ] || /etc/init.d/rcS telinit "${DEFAULT_RUNLEVEL}"
Finally the /etc/hosts file must contain the following to get proper behavior for programs that use sockets to do RPC:
127.0.0.1 localhost ::1 localhost ip6-localhost ip6-loopback fe00::0 ip6-localnet ff00::0 ip6-mcastprefix ff02::1 ip6-allnodes ff02::2 ip6-allrouters ff02::3 ip6-allhosts