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livecd-rootfs/live-build/ubuntu-cpc/functions

272 lines
7.9 KiB

# vi: ts=4 expandtab syntax=sh
CLOUD_IMG_STR="# CLOUD_IMG: This file was created/modified by the Cloud Image build process"
IMAGE_SIZE=$((2252*1024**2)) # 2.2G (the current size we ship)
rootfs_dev_mapper=
loop_device=
loop_raw=
backing_img=
apt-get -qqy install dosfstools gdisk
clean_loops() {
local kpartx_ret
local kpartx_stdout
if [ -n "${backing_img}" ]; then
# sync before removing loop to avoid "Device or resource busy" errors
sync
kpartx_ret=""
kpartx_stdout=$(kpartx -v -d "${backing_img}") || kpartx_ret=$?
echo "$kpartx_stdout"
if [ -n "$kpartx_ret" ]; then
if echo "$kpartx_stdout" | grep -q "loop deleted"; then
echo "Suppressing kpartx returning error (#860894)"
else
exit $kpartx_ret
fi
fi
unset backing_img
fi
if [ -z "${rootfs_dev_mapper}" ]; then
return 0
fi
unset loop_device
unset loop_raw
unset rootfs_dev_mapper
}
create_empty_disk_image() {
# Prepare an empty disk image
dd if=/dev/zero of="$1" bs=1 count=0 seek="${IMAGE_SIZE}"
}
make_ext4_partition() {
device="$1"
mkfs.ext4 -F -b 4096 -i 8192 -m 0 -L cloudimg-rootfs -E resize=536870912 "$device"
}
mount_image() {
apt-get install -qqy kpartx
trap clean_loops EXIT
backing_img="$1"
local rootpart="$2"
kpartx_mapping="$(kpartx -s -v -a ${backing_img})"
# Find the loop device
loop_p1="$(echo -e ${kpartx_mapping} | head -n1 | awk '{print$3}')"
loop_device="/dev/loop$(echo ${loop_p1} | cut -b5)"
if [ ! -b ${loop_device} ]; then
echo "unable to find loop device for ${backing_img}"
exit 1
fi
# Find the rootfs location
rootfs_dev_mapper="/dev/mapper/${loop_p1%%[0-9]}${rootpart}"
if [ ! -b "${rootfs_dev_mapper}" ]; then
echo "${rootfs_dev_mapper} is not a block device";
exit 1
fi
# Add some information to the debug logs
echo "Mounted disk image ${backing_img} to ${rootfs_dev_mapper}"
blkid ${rootfs_dev_mapper}
return 0
}
setup_mountpoint() {
local mountpoint="$1"
mount --rbind /dev "$mountpoint/dev"
mount proc-live -t proc "$mountpoint/proc"
mount sysfs-live -t sysfs "$mountpoint/sys"
mount -t tmpfs none "$mountpoint/tmp"
mount -t tmpfs none "$mountpoint/var/lib/apt"
mount -t tmpfs none "$mountpoint/var/cache/apt"
mv "$mountpoint/etc/resolv.conf" resolv.conf.tmp
cp /etc/resolv.conf "$mountpoint/etc/resolv.conf"
chroot "$mountpoint" apt-get update
}
mount_partition() {
partition="$1"
mountpoint="$2"
mount "$partition" "$mountpoint"
setup_mountpoint "$mountpoint"
}
mount_disk_image() {
local disk_image=${1}
local mountpoint=${2}
mount_image ${disk_image} 1
mount_partition "${rootfs_dev_mapper}" $mountpoint
local uefi_dev="/dev/mapper${loop_device///dev/}p15"
if [ -b ${uefi_dev} -a -e $mountpoint/boot/efi ]; then
mount "${uefi_dev}" $mountpoint/boot/efi
fi
# This is needed to allow for certain operations
# such as updating grub and installing software
cat > $mountpoint/usr/sbin/policy-rc.d << EOF
#!/bin/sh
# ${CLOUD_IMG_STR}
echo "All runlevel operations denied by policy" >&2
exit 101
EOF
chmod 0755 $mountpoint/usr/sbin/policy-rc.d
}
umount_settle() {
# Unmount device, and let it settle
umount $1
udevadm settle
sleep 3
}
umount_partition() {
local mountpoint=${1}
mv resolv.conf.tmp "$mountpoint/etc/resolv.conf"
umount -R $mountpoint
udevadm settle
if [ -n "${rootfs_dev_mapper}" -a -b "${rootfs_dev_mapper}" ]; then
# buildd's don't have /etc/mtab symlinked
# /etc/mtab is needed in order zerofree space for ext4 filesystems
[ -e /etc/mtab ] || ln -s /proc/mounts /etc/mtab
# both of these are likely overkill, but it does result in slightly
# smaller ext4 filesystem
apt-get -qqy install zerofree
e2fsck -y -E discard ${rootfs_dev_mapper}
zerofree ${rootfs_dev_mapper}
fi
}
umount_disk_image() {
mountpoint="$1"
local uefi_dev="/dev/mapper${loop_device///dev/}p15"
if [ -e "$mountpoint/boot/efi" -a -b "$uefi_dev" ]; then
umount --detach-loop "$mountpoint/boot/efi"
fi
if [ -e $mountpoint/usr/sbin/policy-rc.d ]; then
rm $mountpoint/usr/sbin/policy-rc.d
fi
umount_partition $mountpoint
clean_loops
}
modify_vmdk_header() {
# Modify the VMDK headers so that both VirtualBox _and_ VMware can
# read the vmdk and import them. The vodoo here is _not_ documented
# anywhere....so this will have to do. This is undocumented vodoo
# that has been learned by the Cloud Image team.
vmdk_name="${1}"
descriptor=$(mktemp)
newdescriptor=$(mktemp)
# Extract the vmdk header for manipulation
dd if="${vmdk_name}" of="${descriptor}" bs=1 skip=512 count=1024
# The sed lines below is where the magic is. Specifically:
# ddb.toolsVersion: sets the open-vm-tools so that VMware shows
# the tooling as current
# ddb.virtualHWVersion: set the version to 7, which covers most
# current versions of VMware
# createType: make sure its set to stream Optimized
# remove the vmdk-stream-converter comment and replace with
# # Disk DescriptorFile. This is needed for Virtualbox
# remove the comments from vmdk-stream-converter which causes
# VirtualBox and others to fail VMDK validation
sed -e 's|# Description file.*|# Disk DescriptorFile|' \
-e '/# Believe this is random*/d' \
-e '/# Indicates no parent/d' \
-e '/# The Disk Data Base/d' \
-e 's|ddb.comment.*|ddb.toolsVersion = "2147483647"|' \
"${descriptor}" > "${newdescriptor}"
# The header is cannot be bigger than 1024
expr $(stat --format=%s ${newdescriptor}) \< 1024 > /dev/null 2>&1 || {
echo "descriptor is too large, VMDK will be invalid!"; exit 1; }
# Overwrite the vmdk header with our new, modified one
dd conv=notrunc,nocreat \
if="${newdescriptor}" of="${vmdk_name}" \
bs=1 seek=512 count=1024
rm ${descriptor} ${newdescriptor}
}
create_vmdk() {
# There is no real good way to create a _compressed_ VMDK using open source
# tooling that works across multiple VMDK-capable platforms. This functions
# uses vmdk-stream-converter and then calls modify_vmdk_header to produce a
# compatible VMDK.
src="$1"
destination="$2"
size="${3:-10240}"
apt-get install -qqy qemu-utils vmdk-stream-converter
streamconverter="/usr/share/pyshared/VMDKstream.py"
scratch_d=$(mktemp -d)
cp ${src} ${scratch_d}/resize.img
truncate --size=${size}M ${scratch_d}/resize.img
python ${streamconverter} ${scratch_d}/resize.img ${destination}
modify_vmdk_header ${destination}
qemu-img info ${destination}
rm -rf ${scratch_d}
}
create_derivative() {
# arg1 is the disk type
# arg2 is the new name
unset derivative_img
case ${1} in
uefi) disk_image="binary/boot/disk-uefi.ext4";
dname="${disk_image//-uefi/-$2-uefi}";;
*) disk_image="binary/boot/disk.ext4";
dname="${disk_image//.ext4/-$2.ext4}";;
esac
if [ ! -e ${disk_image} ]; then
echo "Did not find ${disk_image}!"; exit 1;
fi
cp ${disk_image} ${dname}
export derivative_img=${dname}
}
convert_to_qcow2() {
apt-get install -qqy qemu-utils
src="$1"
destination="$2"
qemu-img convert -c -O qcow2 -o compat=0.10 "$src" "$destination"
qemu-img info "$destination"
}
replace_grub_root_with_label() {
# When update-grub is run, it will detect the disks in the build system.
# Instead, we want grub to use the cloudimg-rootfs labelled disk
CHROOT_ROOT="$1"
sed -i -e "s,root=[^ ]\+,root=LABEL=cloudimg-rootfs," \
"$CHROOT_ROOT/boot/grub/grub.cfg"
}