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livecd-rootfs/live-build/functions
Robert C Jennings 632ab2b982
Address snap base regression after snap-tool removal 
With the removal of snap-tool failures are seen in image builds that do
not have the 'core' snap included by the seed.  This is the case for the
minimized subproject of the ubuntu-cpc project where lxd/core is removed.
In that subproject, any binary hook which adds a snap that is based
on 'core' will not add 'core' and fail 'snap debug validate-seed'.
snap-tool included the following logic in the 'snap-tool info' when
determining snap bases:

    # Have "base" initialized to something meaningful.
    if self.is_core_snap():
        snap_data["snap"]["base"] = ""
    elif snap_data["snap"].get("base") is None:
        snap_data["snap"]["base"] = "core"

The snap store does not return a base if the base is core which makes
this necessary.  This patch looks for the base in 'snap info' output
and if none is found (and the snap is not snapd or core) it assumes the
base is 'core' and installs it.  This restores the behavior lost in the
migration from snap-tool to snap cli.
2020-02-27 16:40:23 -06:00

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# vi: ts=4 expandtab syntax=sh
# default imagesize = 2252*1024**2 = 2.2G (the current size we ship)
imagesize=${IMAGE_SIZE:-2361393152}
fs_label="${FS_LABEL:-rootfs}"
rootfs_dev_mapper=
loop_device=
loop_raw=
backing_img=
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="$1" bs=1 count=0 seek="${imagesize}"
}
create_manifest() {
local chroot_root=${1}
local target_file=${2}
echo "create_manifest chroot_root: ${chroot_root}"
dpkg-query --show --admindir="${chroot_root}/var/lib/dpkg" > ${target_file}
echo "create_manifest call to dpkg-query finished."
./config/snap-seed-parse "${chroot_root}" "${target_file}"
echo "create_manifest call to snap_seed_parse finished."
echo "create_manifest finished"
}
make_ext4_partition() {
device="$1"
label=${fs_label:+-L "${fs_label}"}
mkfs.ext4 -F -b 4096 -i 8192 -m 0 ${label} -E resize=536870912 "$device"
}
mount_image() {
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_p1%p[0-9]*}"
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="$1"
mount --rbind --make-rslave /dev "$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
}
teardown_mountpoint() {
# Reverse the operations from setup_mountpoint
local mountpoint="$1"
# ensure we have exactly one trailing slash, and escape all slashes for awk
mountpoint_match=$(echo "$mountpoint" | sed -e's,/$,,; s,/,\\/,g;')'\/'
# sort -r ensures that deeper mountpoints are unmounted first
for submount in $(awk </proc/self/mounts "\$2 ~ /$mountpoint_match/ \
{ print \$2 }" | LC_ALL=C sort -r); do
umount $submount
done
mv resolv.conf.tmp "$mountpoint/etc/resolv.conf"
}
mount_partition() {
partition="$1"
mountpoint="$2"
mount "$partition" "$mountpoint"
setup_mountpoint "$mountpoint"
}
mount_overlay() {
lower="$1"
upper="$2"
work="$2/../work"
path="$3"
mkdir -p "$work"
mount -t overlay overlay \
-olowerdir="$lower",upperdir="$upper",workdir="$work" \
"$path"
}
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
# ${IMAGE_STR}
echo "All runlevel operations denied by policy" >&2
exit 101
EOF
chmod 0755 $mountpoint/usr/sbin/policy-rc.d
}
umount_partition() {
local mountpoint=${1}
teardown_mountpoint $mountpoint
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
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
# zero fill free space in UEFI partition
cat < /dev/zero > "$mountpoint/boot/efi/bloat_file" 2> /dev/null || true
rm "$mountpoint/boot/efi/bloat_file"
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 $mountpoint
clean_loops
}
modify_vmdk_header() {
# Modify the VMDK headers so that both VirtualBox _and_ VMware can
# read the vmdk and import them.
vmdk_name="${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}"
streamconverter="VMDKstream"
scratch_d=$(mktemp -d)
cp ${src} ${scratch_d}/resize.img
truncate --size=${size}M ${scratch_d}/resize.img
python -m ${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() {
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 right labelled disk
CHROOT_ROOT="$1"
# If boot by partuuid has been requested, don't override.
if [ -f $CHROOT_ROOT/etc/default/grub.d/40-force-partuuid.cfg ] && \
grep -q ^GRUB_FORCE_PARTUUID= $CHROOT_ROOT/etc/default/grub.d/40-force-partuuid.cfg
then
return 0
fi
sed -i -e "s,root=[^ ]*,root=LABEL=${fs_label}," \
"$CHROOT_ROOT/boot/grub/grub.cfg"
}
# When running update-grub in a chroot on a build host, we don't want it to
# probe for disks or probe for other installed OSes. Extract common
# diversion wrappers, so this isn't reinvented differently for each image.
divert_grub() {
CHROOT_ROOT="$1"
chroot "$CHROOT_ROOT" dpkg-divert --local \
--rename /usr/sbin/grub-probe
chroot "$CHROOT_ROOT" touch /usr/sbin/grub-probe
chroot "$CHROOT_ROOT" chmod +x /usr/sbin/grub-probe
chroot "$CHROOT_ROOT" dpkg-divert --local \
--divert /etc/grub.d/30_os-prober.dpkg-divert \
--rename /etc/grub.d/30_os-prober
# Divert systemd-detect-virt; /etc/kernel/postinst.d/zz-update-grub
# no-ops if we are in a container, and the launchpad farm runs builds
# in lxd. We therefore pretend that we're never in a container (by
# exiting 1).
chroot "$CHROOT_ROOT" dpkg-divert --local \
--rename /usr/bin/systemd-detect-virt
echo "exit 1" > "$CHROOT_ROOT"/usr/bin/systemd-detect-virt
chmod +x "$CHROOT_ROOT"/usr/bin/systemd-detect-virt
}
undivert_grub() {
CHROOT_ROOT="$1"
chroot "$CHROOT_ROOT" rm /usr/sbin/grub-probe
chroot "$CHROOT_ROOT" dpkg-divert --remove --local \
--rename /usr/sbin/grub-probe
chroot "$CHROOT_ROOT" dpkg-divert --remove --local \
--divert /etc/grub.d/30_os-prober.dpkg-divert \
--rename /etc/grub.d/30_os-prober
rm "$CHROOT_ROOT"/usr/bin/systemd-detect-virt
chroot "$CHROOT_ROOT" dpkg-divert --remove --local \
--rename /usr/bin/systemd-detect-virt
}
recreate_initramfs() {
# Regenerate the initramfs by running update-initramfs in the
# chroot at $1 and copying the generated initramfs
# around. Beware that this was written for a single use case
# (live-server) and may not work in all cases without
# tweaking...
# config/common must be sourced before calling this function.
CHROOT="$1"
# Start by cargo culting bits of lb_chroot_hacks:
if [ -n "$LB_INITRAMFS_COMPRESSION" ]; then
echo "COMPRESS=$LB_INITRAMFS_COMPRESSION" > "$CHROOT"/etc/initramfs-tools/conf.d/livecd-rootfs.conf
fi
chroot "$CHROOT" sh -c "${UPDATE_INITRAMFS_OPTIONS:-} update-initramfs -k all -t -u"
rm -rf "$CHROOT"/etc/initramfs-tools/conf.d/livecd-rootfs.conf
# Then bits of lb_binary_linux-image:
case "${LB_INITRAMFS}" in
casper)
DESTDIR="binary/casper"
;;
live-boot)
DESTDIR="binary/live"
;;
*)
DESTDIR="binary/boot"
;;
esac
mv "$CHROOT"/boot/initrd.img-* $DESTDIR
}
release_ver() {
# Return the release version number
distro-info --series="$LB_DISTRIBUTION" -r | awk '{ print $1 }'
}
_snap_post_process() {
# Look for the 'core' snap. If it is not present, assume that the image
# contains only snaps with bases >= core18. In that case snapd is
# preseeded. However, when 'core' is being installed and snapd has not
# been installed by a call to 'snap_preseed' (see below) then it is
# removed again.
local CHROOT_ROOT=$1
local SNAP_NAME=$2
local seed_dir="$CHROOT_ROOT/var/lib/snapd/seed"
local snaps_dir="$seed_dir/snaps"
local seed_yaml="$seed_dir/seed.yaml"
local assertions_dir="$seed_dir/assertions"
local snapd_install_stamp="$seed_dir/.snapd-explicit-install-stamp"
case $SNAP_NAME in
core[0-9]*)
# If the 'core' snap is not present, assume we are coreXX-only and
# install the snapd snap.
if [ ! -f ${snaps_dir}/core_[0-9]*.snap ]; then
_snap_preseed $CHROOT_ROOT snapd stable
fi
;;
core)
# If the snapd snap has been seeded, but not marked as explicitly
# installed (see snap_preseed below), then remove it.
if [ -f ${snaps_dir}/snapd_[0-9]*.snap ] && \
[ ! -f "$snapd_install_stamp" ]
then
# Remove snap, assertions and entry in seed.yaml
rm -f ${snaps_dir}/snapd_[0-9]*.snap
rm -f ${assertions_dir}/snapd_[0-9]*.assert
sed -i -e'N;/name: snapd/,+2d' $seed_yaml
fi
;;
*)
# ignore
;;
esac
}
_snap_preseed() {
# Download the snap/assertion and add to the preseed
local CHROOT_ROOT=$1
local SNAP=$2
local SNAP_NAME=${SNAP%/*}
local CHANNEL=${3:?Snap channel must be specified}
local seed_dir="$CHROOT_ROOT/var/lib/snapd/seed"
local snaps_dir="$seed_dir/snaps"
local seed_yaml="$seed_dir/seed.yaml"
local assertions_dir="$seed_dir/assertions"
# Download the snap & assertion
local snap_download_failed=0
# Preseed a snap only once
if [ -f ${snaps_dir}/${SNAP_NAME}_[0-9]*.snap ]; then
return
fi
# Pre-seed snap's base
case $SNAP_NAME in
snapd)
# snapd is self-contained, ignore base
;;
core|core[0-9][0-9])
# core and core## are self-contained, ignore base
;;
*)
# Determine which core snap is needed
local snap_info
snap_info=$(snap info --verbose "${SNAP_NAME}")
if [ $? -ne 0 ]; then
echo "Failed to retrieve base of $SNAP_NAME!"
exit 1
fi
local core_snap=$(echo "$snap_info" | grep '^base:' | awk '{print $2}')
# If snap info does not list a base use 'core'
core_snap=${core_snap:-core}
_snap_preseed $CHROOT_ROOT $core_snap stable
;;
esac
sh -c "
set -x;
cd \"$CHROOT_ROOT/var/lib/snapd/seed\";
SNAPPY_STORE_NO_CDN=1 snap download \
--cohort=\"${COHORT_KEY:-}\" \
--channel=\"$CHANNEL\" \"$SNAP_NAME\"" || snap_download_failed=1
if [ $snap_download_failed = 1 ] ; then
echo "If the channel ($CHANNEL) includes '*/ubuntu-##.##' track per "
echo "Ubuntu policy (ex. stable/ubuntu-18.04) the publisher will need "
echo "to temporarily create the channel/track to allow fallback during"
echo "download (ex. stable/ubuntu-18.04 falls back to stable if the"
echo "prior had been created in the past)."
exit 1
fi
mv -v $seed_dir/*.assert $assertions_dir
mv -v $seed_dir/*.snap $snaps_dir
# Add the snap to the seed.yaml
! [ -e $seed_yaml ] && echo "snaps:" > $seed_yaml
cat <<EOF >> $seed_yaml
-
name: ${SNAP_NAME}
channel: ${CHANNEL}
EOF
case ${SNAP} in */classic) echo " classic: true" >> $seed_yaml;; esac
echo -n " file: " >> $seed_yaml
(cd $snaps_dir; ls -1 ${SNAP_NAME}_*.snap) >> $seed_yaml
# If $core_snap is the empty string then SNAP itself *may be* a core snap,
# and we run some post-processing logic.
if [ -z "$core_snap" ]; then
_snap_post_process $CHROOT_ROOT $SNAP_NAME
fi
}
snap_prepare_assertions() {
# Configure basic snapd assertions
local CHROOT_ROOT=$1
# A colon-separated string of brand:model to be used for the image's model
# assertion
local CUSTOM_BRAND_MODEL=$2
local seed_dir="$CHROOT_ROOT/var/lib/snapd/seed"
local snaps_dir="$seed_dir/snaps"
local assertions_dir="$seed_dir/assertions"
local model_assertion="$assertions_dir/model"
local account_key_assertion="$assertions_dir/account-key"
local account_assertion="$assertions_dir/account"
mkdir -p "$assertions_dir"
mkdir -p "$snaps_dir"
local brand="$(echo $CUSTOM_BRAND_MODEL | cut -d: -f 1)"
local model="$(echo $CUSTOM_BRAND_MODEL | cut -d: -f 2)"
if ! [ -e "$model_assertion" ] ; then
snap known --remote model series=16 \
model=$model brand-id=$brand \
> "$model_assertion"
fi
if ! [ -e "$account_key_assertion" ] ; then
local account_key=$(sed -n -e's/sign-key-sha3-384: //p' \
< "$model_assertion")
snap known --remote account-key \
public-key-sha3-384="$account_key" \
> "$account_key_assertion"
fi
if ! [ -e "$account_assertion" ] ; then
local account=$(sed -n -e's/account-id: //p' < "$account_key_assertion")
snap known --remote account account-id=$account \
> "$account_assertion"
fi
}
snap_prepare() {
# Configure basic snapd assertions and pre-seeds the 'core' snap
local CHROOT_ROOT=$1
# Optional. If set, should be a colon-separated string of brand:model to be
# used for the image's model assertion
local CUSTOM_BRAND_MODEL=${2:-generic:generic-classic}
local seed_dir="$CHROOT_ROOT/var/lib/snapd/seed"
local snaps_dir="$seed_dir/snaps"
snap_prepare_assertions "$CHROOT_ROOT" "$CUSTOM_BRAND_MODEL"
# ubuntu-cpc:minimized has its own special snap handling
if [ "$PROJECT:${SUBPROJECT:-}" != ubuntu-cpc:minimized ]; then
# Download the core snap
_snap_preseed "$CHROOT_ROOT" core stable
fi
}
snap_preseed() {
# Preseed a snap in the image
local CHROOT_ROOT=$1
local SNAP=$2
local SNAP_NAME=${SNAP%/*}
# Per Ubuntu policy, all seeded snaps (with the exception of the core
# snap) must pull from stable/ubuntu-$(release_ver) as their channel.
local CHANNEL=${3:-"stable/ubuntu-$(release_ver)"}
snap_prepare $CHROOT_ROOT
_snap_preseed $CHROOT_ROOT $SNAP $CHANNEL
# Mark this image as having snapd installed explicitly.
case $SNAP_NAME in
snapd)
touch "$CHROOT_ROOT/var/lib/snapd/seed/.snapd-explicit-install-stamp"
;;
esac
# Do basic validation of generated snapd seed.yaml, doing it here
# means we catch all the places(tm) that snaps are added but the
# downside is that each time a snap is added the seed must be valid,
# i.e. snaps with bases need to add bases first etc.
if [ -e chroot/var/lib/snapd/seed/seed.yaml ]; then
snap debug validate-seed "$CHROOT_ROOT/var/lib/snapd/seed/seed.yaml"
fi
}
is_live_layer () {
local pass=$1
for livepass in $LIVE_PASSES; do
[ "$livepass" != "$pass" ] && continue
return 0
done
return 1
}
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