#!/bin/bash -p
# Copyright (c) 2012 The Chromium Authors. All rights reserved.
# Use of this source code is governed by a BSD-style license that can be
# found in the LICENSE file.
# usage: keystone_install.sh update_dmg_mount_point
#
# Called by the Keystone system to update the installed application with a new
# version from a disk image.
#
# Environment variables:
# GOOGLE_CHROME_UPDATER_DEBUG
# When set to a non-empty value, additional information about this script's
# actions will be logged to stderr. The same debugging information will
# also be enabled when "Library/Google/Google Chrome Updater Debug" in the
# root directory or in ${HOME} exists.
#
# Exit codes:
# 0 Happiness
# 1 Unknown failure
# 2 Basic sanity check source failure (e.g. no app on disk image)
# 3 Basic sanity check destination failure (e.g. ticket points to nothing)
# 4 Update driven by user ticket when a system ticket is also present
# 5 Could not prepare existing installed version to receive update
# 6 Patch sanity check failure
# 7 rsync failed (could not copy new versioned directory to Versions)
# 8 rsync failed (could not update outer .app bundle)
# 9 Could not get the version, update URL, or channel after update
# 10 Updated application does not have the version number from the update
# 11 ksadmin failure
# 12 dirpatcher failed for versioned directory
# 13 dirpatcher failed for outer .app bundle
# 14 The update is incompatible with the system
#
# The following exit codes can be used to convey special meaning to Keystone.
# KeystoneRegistration will present these codes to Chrome as "success."
# 66 (unused) success, request reboot
# 77 (unused) try installation again later
set -eu
# http://b/2290916: Keystone runs the installation with a restrictive PATH
# that only includes the directory containing ksadmin, /bin, and /usr/bin. It
# does not include /sbin or /usr/sbin. This script uses lsof, which is in
# /usr/sbin, and it's conceivable that it might want to use other tools in an
# sbin directory. Adjust the path accordingly.
export PATH="${PATH}:/sbin:/usr/sbin"
# Environment sanitization. Clear environment variables that might impact the
# interpreter's operation. The |bash -p| invocation on the #! line takes the
# bite out of BASH_ENV, ENV, and SHELLOPTS (among other features), but
# clearing them here ensures that they won't impact any shell scripts used as
# utility programs. SHELLOPTS is read-only and can't be unset, only
# unexported.
unset BASH_ENV CDPATH ENV GLOBIGNORE IFS POSIXLY_CORRECT
export -n SHELLOPTS
set -o pipefail
shopt -s nullglob
ME="$(basename "${0}")"
readonly ME
readonly KS_CHANNEL_KEY="KSChannelID"
# Workaround for http://code.google.com/p/chromium/issues/detail?id=83180#c3
# In bash 4.0, "declare VAR" no longer initializes VAR if not already set.
: ${GOOGLE_CHROME_UPDATER_DEBUG:=}
err() {
local error="${1}"
local id=
if [[ -n "${GOOGLE_CHROME_UPDATER_DEBUG}" ]]; then
id=": ${$} $(date "+%Y-%m-%d %H:%M:%S %z")"
fi
echo "${ME}${id}: ${error}" >& 2
}
note() {
local message="${1}"
if [[ -n "${GOOGLE_CHROME_UPDATER_DEBUG}" ]]; then
err "${message}"
fi
}
g_temp_dir=
cleanup() {
local status=${?}
trap - EXIT
trap '' HUP INT QUIT TERM
if [[ ${status} -ge 128 ]]; then
err "Caught signal $((${status} - 128))"
fi
if [[ -n "${g_temp_dir}" ]]; then
rm -rf "${g_temp_dir}"
fi
exit ${status}
}
ensure_temp_dir() {
if [[ -z "${g_temp_dir}" ]]; then
# Choose a template that won't be a dot directory. Make it safe by
# removing leading hyphens, too.
local template="${ME}"
if [[ "${template}" =~ ^[-.]+(.*)$ ]]; then
template="${BASH_REMATCH[1]}"
fi
if [[ -z "${template}" ]]; then
template="keystone_install"
fi
g_temp_dir="$(mktemp -d -t "${template}")"
note "g_temp_dir = ${g_temp_dir}"
fi
}
# Returns 0 (true) if |symlink| exists, is a symbolic link, and appears
# writable on the basis of its POSIX permissions. This is used to determine
# writability like test's -w primary, but -w resolves symbolic links and this
# function does not.
is_writable_symlink() {
local symlink="${1}"
local link_mode
link_mode="$(stat -f %Sp "${symlink}" 2> /dev/null || true)"
if [[ -z "${link_mode}" ]] || [[ "${link_mode:0:1}" != "l" ]]; then
return 1
fi
local link_user link_group
link_user="$(stat -f %u "${symlink}" 2> /dev/null || true)"
link_group="$(stat -f %g "${symlink}" 2> /dev/null || true)"
if [[ -z "${link_user}" ]] || [[ -z "${link_group}" ]]; then
return 1
fi
# If the users match, check the owner-write bit.
if [[ ${EUID} -eq "${link_user}" ]]; then
if [[ "${link_mode:2:1}" = "w" ]]; then
return 0
fi
return 1
fi
# If the file's group matches any of the groups that this process is a
# member of, check the group-write bit.
local group_match=
local group
for group in "${GROUPS[@]}"; do
if [[ "${group}" -eq "${link_group}" ]]; then
group_match="y"
break
fi
done
if [[ -n "${group_match}" ]]; then
if [[ "${link_mode:5:1}" = "w" ]]; then
return 0
fi
return 1
fi
# Check the other-write bit.
if [[ "${link_mode:8:1}" = "w" ]]; then
return 0
fi
return 1
}
# If |symlink| exists and is a symbolic link, but is not writable according to
# is_writable_symlink, this function attempts to replace it with a new
# writable symbolic link. If |symlink| does not exist, is not a symbolic
# link, or is already writable, this function does nothing. This function
# always returns 0 (true).
ensure_writable_symlink() {
local symlink="${1}"
if [[ -L "${symlink}" ]] && ! is_writable_symlink "${symlink}"; then
# If ${symlink} refers to a directory, doing this naively might result in
# the new link being placed in that directory, instead of replacing the
# existing link. ln -fhs is supposed to handle this case, but it does so
# by unlinking (removing) the existing symbolic link before creating a new
# one. That leaves a small window during which the symbolic link is not
# present on disk at all.
#
# To avoid that possibility, a new symbolic link is created in a temporary
# location and then swapped into place with mv. An extra temporary
# directory is used to convince mv to replace the symbolic link: again, if
# the existing link refers to a directory, "mv newlink oldlink" will
# actually leave oldlink alone and place newlink into the directory.
# "mv newlink dirname(oldlink)" works as expected, but in order to replace
# oldlink, newlink must have the same basename, hence the temporary
# directory.
local target
target="$(readlink "${symlink}" 2> /dev/null || true)"
if [[ -z "${target}" ]]; then
return 0
fi
# Error handling strategy: if anything fails, such as the mktemp, ln,
# chmod, or mv, ignore the failure and return 0 (success), leaving the
# existing state with the non-writable symbolic link intact. Failures
# in this function will be difficult to understand and diagnose, and a
# non-writable symbolic link is not necessarily fatal. If something else
# requires a writable symbolic link, allowing it to fail when a symbolic
# link is not writable is easier to understand than bailing out of the
# script on failure here.
local symlink_dir temp_link_dir temp_link
symlink_dir="$(dirname "${symlink}")"
temp_link_dir="$(mktemp -d "${symlink_dir}/.symlink_temp.XXXXXX" || true)"
if [[ -z "${temp_link_dir}" ]]; then
return 0
fi
temp_link="${temp_link_dir}/$(basename "${symlink}")"
(ln -fhs "${target}" "${temp_link}" && \
chmod -h 755 "${temp_link}" && \
mv -f "${temp_link}" "${symlink_dir}/") || true
rm -rf "${temp_link_dir}"
fi
return 0
}
# ensure_writable_symlinks_recursive calls ensure_writable_symlink for every
# symbolic link in |directory|, recursively.
#
# In some very weird and rare cases, it is possible to wind up with a user
# installation that contains symbolic links that the user does not have write
# permission over. More on how that might happen later.
#
# If a weird and rare case like this is observed, rsync will exit with an
# error when attempting to update the times on these symbolic links. rsync
# may not be intelligent enough to try creating a new symbolic link in these
# cases, but this script can be.
#
# The problem occurs when an administrative user first drag-installs the
# application to /Applications, resulting in the program's user being set to
# the user's own ID. If, subsequently, a .pkg package is installed over that,
# the existing directory ownership will be preserved, but file ownership will
# be changed to whatever is specified by the package, typically root. This
# applies to symbolic links as well. On a subsequent update, rsync will be
# able to copy the new files into place, because the user still has permission
# to write to the directories. If the symbolic link targets are not changing,
# though, rsync will not replace them, and they will remain owned by root.
# The user will not have permission to update the time on the symbolic links,
# resulting in an rsync error.
ensure_writable_symlinks_recursive() {
local directory="${1}"
# This fix-up is not necessary when running as root, because root will
# always be able to write everything needed.
if [[ ${EUID} -eq 0 ]]; then
return 0
fi
# This step isn't critical.
local set_e=
if [[ "${-}" =~ e ]]; then
set_e="y"
set +e
fi
# Use find -print0 with read -d $'\0' to handle even the weirdest paths.
local symlink
while IFS= read -r -d $'\0' symlink; do
ensure_writable_symlink "${symlink}"
done < <(find "${directory}" -type l -print0)
# Go back to how things were.
if [[ -n "${set_e}" ]]; then
set -e
fi
}
# is_version_ge accepts two version numbers, left and right, and performs a
# piecewise comparison determining the result of left >= right, returning true
# (0) if left >= right, and false (1) if left < right. If left or right are
# missing components relative to the other, the missing components are assumed
# to be 0, such that 10.6 == 10.6.0.
is_version_ge() {
local left="${1}"
local right="${2}"
local -a left_array right_array
IFS=. left_array=(${left})
IFS=. right_array=(${right})
local left_count=${#left_array[@]}
local right_count=${#right_array[@]}
local count=${left_count}
if [[ ${right_count} -lt ${count} ]]; then
count=${right_count}
fi
# Compare the components piecewise, as long as there are corresponding
# components on each side. If left_element and right_element are unequal,
# a comparison can be made.
local index=0
while [[ ${index} -lt ${count} ]]; do
local left_element="${left_array[${index}]}"
local right_element="${right_array[${index}]}"
if [[ ${left_element} -gt ${right_element} ]]; then
return 0
elif [[ ${left_element} -lt ${right_element} ]]; then
return 1
fi
((++index))
done
# If there are more components on the left than on the right, continue
# comparing, assuming 0 for each of the missing components on the right.
while [[ ${index} -lt ${left_count} ]]; do
local left_element="${left_array[${index}]}"
if [[ ${left_element} -gt 0 ]]; then
return 0
fi
((++index))
done
# If there are more components on the right than on the left, continue
# comparing, assuming 0 for each of the missing components on the left.
while [[ ${index} -lt ${right_count} ]]; do
local right_element="${right_array[${index}]}"
if [[ ${right_element} -gt 0 ]]; then
return 1
fi
((++index))
done
# Upon reaching this point, the two version numbers are semantically equal.
return 0
}
# Prints the OS version, as reported by sw_vers -productVersion, to stdout.
# This function operates with "static" variables: it will only check the OS
# version once per script run.
g_checked_os_version=
g_os_version=
os_version() {
if [[ -z "${g_checked_os_version}" ]]; then
g_checked_os_version="y"
g_os_version="$(sw_vers -productVersion)"
note "g_os_version = ${g_os_version}"
fi
echo "${g_os_version}"
return 0
}
# Compares the running OS version against a supplied version number,
# |check_version|, and returns 0 (true) if the running OS version is greater
# than or equal to |check_version| according to a piece-wise comparison.
# Returns 1 (false) if the running OS version number cannot be determined or
# if |check_version| is greater than the running OS version. |check_version|
# should be a string of the form "major.minor" or "major.minor.micro".
is_os_version_ge() {
local check_version="${1}"
local os_version="$(os_version)"
is_version_ge "${os_version}" "${check_version}"
# The return value of is_version_ge is used as this function's return value.
}
# Returns 0 (true) if xattr supports -r for recursive operation.
os_xattr_supports_r() {
# xattr -r is supported in Mac OS X 10.6.
is_os_version_ge 10.6
# The return value of is_os_version_ge is used as this function's return
# value.
}
# Prints the version of ksadmin, as reported by ksadmin --ksadmin-version, to
# stdout. This function operates with "static" variables: it will only check
# the ksadmin version once per script run. If ksadmin is old enough to not
# support --ksadmin-version, or another error occurs, this function prints an
# empty string.
g_checked_ksadmin_version=
g_ksadmin_version=
ksadmin_version() {
if [[ -z "${g_checked_ksadmin_version}" ]]; then
g_checked_ksadmin_version="y"
g_ksadmin_version="$(ksadmin --ksadmin-version || true)"
note "g_ksadmin_version = ${g_ksadmin_version}"
fi
echo "${g_ksadmin_version}"
return 0
}
# Compares the installed ksadmin version against a supplied version number,
# |check_version|, and returns 0 (true) if the installed Keystone version is
# greater than or equal to |check_version| according to a piece-wise
# comparison. Returns 1 (false) if the installed Keystone version number
# cannot be determined or if |check_version| is greater than the installed
# Keystone version. |check_version| should be a string of the form
# "major.minor.micro.build".
is_ksadmin_version_ge() {
local check_version="${1}"
local ksadmin_version="$(ksadmin_version)"
is_version_ge "${ksadmin_version}" "${check_version}"
# The return value of is_version_ge is used as this function's return value.
}
# Returns 0 (true) if ksadmin supports --tag.
ksadmin_supports_tag() {
local ksadmin_version
ksadmin_version="$(ksadmin_version)"
if [[ -n "${ksadmin_version}" ]]; then
# A ksadmin that recognizes --ksadmin-version and provides a version
# number is new enough to recognize --tag.
return 0
fi
return 1
}
# Returns 0 (true) if ksadmin supports --tag-path and --tag-key.
ksadmin_supports_tagpath_tagkey() {
# --tag-path and --tag-key were introduced in Keystone 1.0.7.1306.
is_ksadmin_version_ge 1.0.7.1306
# The return value of is_ksadmin_version_ge is used as this function's
# return value.
}
# Returns 0 (true) if ksadmin supports --brand-path and --brand-key.
ksadmin_supports_brandpath_brandkey() {
# --brand-path and --brand-key were introduced in Keystone 1.0.8.1620.
is_ksadmin_version_ge 1.0.8.1620
# The return value of is_ksadmin_version_ge is used as this function's
# return value.
}
# Returns 0 (true) if ksadmin supports --version-path and --version-key.
ksadmin_supports_versionpath_versionkey() {
# --version-path and --version-key were introduced in Keystone 1.0.9.2318.
is_ksadmin_version_ge 1.0.9.2318
# The return value of is_ksadmin_version_ge is used as this function's
# return value.
}
has_32_bit_only_cpu() {
local cpu_64_bit_capable="$(sysctl -n hw.cpu64bit_capable 2>/dev/null)"
[[ -z "${cpu_64_bit_capable}" || "${cpu_64_bit_capable}" -eq 0 ]]
# The return value of the comparison is used as this function's return
# value.
}
# Runs "defaults read" to obtain the value of a key in a property list. As
# with "defaults read", an absolute path to a plist is supplied, without the
# ".plist" extension.
#
# As of Mac OS X 10.8, defaults (and NSUserDefaults and CFPreferences)
# normally communicates with cfprefsd to read and write plists. Changes to a
# plist file aren't necessarily reflected immediately via this API family when
# not made through this API family, because cfprefsd may return cached data
# from a former on-disk version of a plist file instead of reading the current
# version from disk. The old behavior can be restored by setting the
# __CFPREFERENCES_AVOID_DAEMON environment variable, although extreme care
# should be used because portions of the system that use this API family
# normally and thus use cfprefsd and its cache will become unsynchronized with
# the on-disk state.
#
# This function is provided to set __CFPREFERENCES_AVOID_DAEMON when calling
# "defaults read" and thus avoid cfprefsd and its on-disk cache, and is
# intended only to be used to read values from Info.plist files, which are not
# preferences. The use of "defaults" for this purpose has always been
# questionable, but there's no better option to interact with plists from
# shell scripts. Definitely don't use infoplist_read to read preference
# plists.
#
# This function exists because the update process delivers new copies of
# Info.plist files to the disk behind cfprefsd's back, and if cfprefsd becomes
# aware of the original version of the file for any reason (such as this
# script reading values from it via "defaults read"), the new version of the
# file will not be immediately effective or visible via cfprefsd after the
# update is applied.
infoplist_read() {
__CFPREFERENCES_AVOID_DAEMON=1 defaults read "${@}"
}
# Adjust the tag to contain the -32bit tag suffix. This is intended to be used
# as a last resort, if sanity checks show that a non-32-bit update is about to
# be applied to a 32-bit-only system. If this happens, it means that the
# server delivered a non-32-bit update to a 32-bit-only system, most likely
# because the tag was never updated to include the -32bit tag suffix.
#
# This mechanism takes a heavy-handed approach, clearing --tag-path and
# --tag-key so that the channel identity will no longer follow the installed
# application. However, it's expected that once -32bit is added to the tag,
# the server will deliver a 32-bit update (possibly the final 32-bit version),
# and once installed, that update will restore the --tag-path and --tag-key.
# In any event, channel identity in this case may be moot, if 32-bit builds
# are no longer being produced.
#
# This provides some resilience in the update system for old 32-bit-only
# systems that aren't used during the window between when the -32bit tag
# suffix begins being used and 32-bit releases end.
mark_32_bit_only_system() {
local product_id="${1}"
# This step isn't critical.
local set_e=
if [[ "${-}" =~ e ]]; then
set_e="y"
set +e
fi
note "marking 32-bit-only system"
if ! ksadmin_supports_tagpath_tagkey; then
note "couldn't mark 32-bit-only system, no ksadmin support"
if [[ -n "${set_e}" ]]; then
set -e
fi
return 0
fi
local current_tag="$(ksadmin --productid "${product_id}" --print-tag)"
note "current_tag = ${current_tag}"
if grep -Eq -- '-32bit(-|$)' <<< "${current_tag}"; then
note "current tag already has -32bit"
if [[ -n "${set_e}" ]]; then
set -e
fi
return 0
fi
# This clears any other tag suffix, but that shouldn't be a problem. The
# only other currently-defined tag suffix component is -full, but -full and
# -32bit were introduced at the same time, so if -full appears, whatever set
# it would have already had enough knowledge to set -32bit as well, and this
# codepath wouldn't be entered.
local current_channel="$(sed -e 's/-.*//' <<< "${current_tag}")"
local new_tag="${current_channel}-32bit"
note "new_tag = ${new_tag}"
# Using ksadmin without --register only updates specified values in the
# ticket, without changing other existing values. Giving empty values for
# --tag-path and --tag-key clears those fields.
if ! ksadmin --productid "${product_id}" \
--tag "${new_tag}" --tag-path '' --tag-key ''; then
err "ksadmin failed to mark 32-bit-only system"
else
note "marked 32-bit-only system"
fi
# Go back to how things were.
if [[ -n "${set_e}" ]]; then
set -e
fi
}
# When a patch update fails because the old installed copy doesn't match the
# expected state, mark_failed_patch_update updates the Keystone ticket by
# adding "-full" to the tag. The server will see this on a subsequent update
# attempt and will provide a full update (as opposed to a patch) to the
# client.
#
# Even if mark_failed_patch_update fails to modify the tag, the user will
# eventually be updated. Patch updates are only provided for successive
# releases on a particular channel, to update version o to version o+1. If a
# patch update fails in this case, eventually version o+2 will be released,
# and no patch update will exist to update o to o+2, so the server will
# provide a full update package.
mark_failed_patch_update() {
local product_id="${1}"
local want_full_installer_path="${2}"
local old_ks_plist="${3}"
local old_version_app="${4}"
local system_ticket="${5}"
# This step isn't critical.
local set_e=
if [[ "${-}" =~ e ]]; then
set_e="y"
set +e
fi
note "marking failed patch update"
local channel
channel="$(infoplist_read "${old_ks_plist}" "${KS_CHANNEL_KEY}" 2> /dev/null)"
local tag="${channel}"
local tag_key="${KS_CHANNEL_KEY}"
if has_32_bit_only_cpu; then
tag="${tag}-32bit"
tag_key="${tag_key}-32bit"
fi
tag="${tag}-full"
tag_key="${tag_key}-full"
note "tag = ${tag}"
note "tag_key = ${tag_key}"
# ${old_ks_plist}, used for --tag-path, is the Info.plist for the old
# version of Chrome. It may not contain the keys for the "-full" tag suffix.
# If it doesn't, just bail out without marking the patch update as failed.
local read_tag="$(infoplist_read "${old_ks_plist}" "${tag_key}" 2> /dev/null)"
note "read_tag = ${read_tag}"
if [[ -z "${read_tag}" ]]; then
note "couldn't mark failed patch update"
if [[ -n "${set_e}" ]]; then
set -e
fi
return 0
fi
# Chrome can't easily read its Keystone ticket prior to registration, and
# when Chrome registers with Keystone, it obliterates old tag values in its
# ticket. Therefore, an alternative mechanism is provided to signal to
# Chrome that a full installer is desired. If the .want_full_installer file
# is present and it contains Chrome's current version number, Chrome will
# include "-full" in its tag when it registers with Keystone. This allows
# "-full" to persist in the tag even after Chrome is relaunched, which on a
# user ticket, triggers a re-registration.
#
# .want_full_installer is placed immediately inside the .app bundle as a
# sibling to the Contents directory. In this location, it's outside of the
# view of the code signing and code signature verification machinery. This
# file can safely be added, modified, and removed without affecting the
# signature.
rm -f "${want_full_installer_path}" 2> /dev/null
echo "${old_version_app}" > "${want_full_installer_path}"
# See the comment below in the "setting permissions" section for an
# explanation of the groups and modes selected here.
local chmod_mode="644"
if [[ -z "${system_ticket}" ]] &&
[[ "${want_full_installer_path:0:14}" = "/Applications/" ]] &&
chgrp admin "${want_full_installer_path}" 2> /dev/null; then
chmod_mode="664"
fi
note "chmod_mode = ${chmod_mode}"
chmod "${chmod_mode}" "${want_full_installer_path}" 2> /dev/null
local old_ks_plist_path="${old_ks_plist}.plist"
# Using ksadmin without --register only updates specified values in the
# ticket, without changing other existing values.
local ksadmin_args=(
--productid "${product_id}"
)
if ksadmin_supports_tag; then
ksadmin_args+=(
--tag "${tag}"
)
fi
if ksadmin_supports_tagpath_tagkey; then
ksadmin_args+=(
--tag-path "${old_ks_plist_path}"
--tag-key "${tag_key}"
)
fi
note "ksadmin_args = ${ksadmin_args[*]}"
if ! ksadmin "${ksadmin_args[@]}"; then
err "ksadmin failed to mark failed patch update"
else
note "marked failed patch update"
fi
# Go back to how things were.
if [[ -n "${set_e}" ]]; then
set -e
fi
}
usage() {
echo "usage: ${ME} update_dmg_mount_point" >& 2
}
main() {
local update_dmg_mount_point="${1}"
# Early steps are critical. Don't continue past any failure.
set -e
trap cleanup EXIT HUP INT QUIT TERM
readonly PRODUCT_NAME="Google Chrome"
readonly APP_DIR="${PRODUCT_NAME}.app"
readonly ALTERNATE_APP_DIR="${PRODUCT_NAME} Canary.app"
readonly FRAMEWORK_NAME="${PRODUCT_NAME} Framework"
readonly FRAMEWORK_DIR="${FRAMEWORK_NAME}.framework"
readonly PATCH_DIR=".patch"
readonly CONTENTS_DIR="Contents"
readonly APP_PLIST="${CONTENTS_DIR}/Info"
readonly VERSIONS_DIR="${CONTENTS_DIR}/Versions"
readonly UNROOTED_BRAND_PLIST="Library/Google/Google Chrome Brand"
readonly UNROOTED_DEBUG_FILE="Library/Google/Google Chrome Updater Debug"
readonly APP_VERSION_KEY="CFBundleShortVersionString"
readonly APP_BUNDLEID_KEY="CFBundleIdentifier"
readonly KS_VERSION_KEY="KSVersion"
readonly KS_PRODUCT_KEY="KSProductID"
readonly KS_URL_KEY="KSUpdateURL"
readonly KS_BRAND_KEY="KSBrandID"
readonly QUARANTINE_ATTR="com.apple.quarantine"
# Don't use rsync -a, because -a expands to -rlptgoD. -g and -o copy owners
# and groups, respectively, from the source, and that is undesirable in this
# case. -D copies devices and special files; copying devices only works
# when running as root, so for consistency between privileged and
# unprivileged operation, this option is omitted as well.
# -I, --ignore-times don't skip files that match in size and mod-time
# -l, --links copy symlinks as symlinks
# -r, --recursive recurse into directories
# -p, --perms preserve permissions
# -t, --times preserve times
readonly RSYNC_FLAGS="-Ilprt"
# It's difficult to get GOOGLE_CHROME_UPDATER_DEBUG set in the environment
# when this script is called from Keystone. If a "debug file" exists in
# either the root directory or the home directory of the user who owns the
# ticket, turn on verbosity. This may aid debugging.
if [[ -e "/${UNROOTED_DEBUG_FILE}" ]] ||
[[ -e ~/"${UNROOTED_DEBUG_FILE}" ]]; then
export GOOGLE_CHROME_UPDATER_DEBUG="y"
fi
note "update_dmg_mount_point = ${update_dmg_mount_point}"
# The argument should be the disk image path. Make sure it exists and that
# it's an absolute path.
note "checking update"
if [[ -z "${update_dmg_mount_point}" ]] ||
[[ "${update_dmg_mount_point:0:1}" != "/" ]] ||
! [[ -d "${update_dmg_mount_point}" ]]; then
err "update_dmg_mount_point must be an absolute path to a directory"
usage
exit 2
fi
local patch_dir="${update_dmg_mount_point}/${PATCH_DIR}"
if [[ "${patch_dir:0:1}" != "/" ]]; then
note "patch_dir = ${patch_dir}"
err "patch_dir must be an absolute path"
exit 2
fi
# Figure out if this is an ordinary installation disk image being used as a
# full update, or a patch. A patch will have a .patch directory at the root
# of the disk image containing information about the update, tools to apply
# it, and the update contents.
local is_patch=
local dirpatcher=
if [[ -d "${patch_dir}" ]]; then
# patch_dir exists and is a directory - this is a patch update.
is_patch="y"
dirpatcher="${patch_dir}/dirpatcher.sh"
if ! [[ -x "${dirpatcher}" ]]; then
err "couldn't locate dirpatcher"
exit 6
fi
elif [[ -e "${patch_dir}" ]]; then
# patch_dir exists, but is not a directory - what's that mean?
note "patch_dir = ${patch_dir}"
err "patch_dir must be a directory"
exit 2
else
# patch_dir does not exist - this is a full "installer."
patch_dir=
fi
note "patch_dir = ${patch_dir}"
note "is_patch = ${is_patch}"
note "dirpatcher = ${dirpatcher}"
# The update to install.
# update_app is the path to the new version of the .app. It will only be
# set at this point for a non-patch update. It is not yet set for a patch
# update because no such directory exists yet; it will be set later when
# dirpatcher creates it.
local update_app=
# update_version_app_old, patch_app_dir, and patch_versioned_dir will only
# be set for patch updates.
local update_version_app_old=
local patch_app_dir=
local patch_versioned_dir=
local update_version_app update_version_ks product_id
if [[ -z "${is_patch}" ]]; then
update_app="${update_dmg_mount_point}/${APP_DIR}"
note "update_app = ${update_app}"
# Make sure that it's an absolute path.
if [[ "${update_app:0:1}" != "/" ]]; then
err "update_app must be an absolute path"
exit 2
fi
# Make sure there's something to copy from.
if ! [[ -d "${update_app}" ]]; then
update_app="${update_dmg_mount_point}/${ALTERNATE_APP_DIR}"
note "update_app = ${update_app}"
if [[ "${update_app:0:1}" != "/" ]]; then
err "update_app (alternate) must be an absolute path"
exit 2
fi
if ! [[ -d "${update_app}" ]]; then
err "update_app must be a directory"
exit 2
fi
fi
# Get some information about the update.
note "reading update values"
local update_app_plist="${update_app}/${APP_PLIST}"
note "update_app_plist = ${update_app_plist}"
if ! update_version_app="$(infoplist_read "${update_app_plist}" \
"${APP_VERSION_KEY}")" ||
[[ -z "${update_version_app}" ]]; then
err "couldn't determine update_version_app"
exit 2
fi
note "update_version_app = ${update_version_app}"
local update_ks_plist="${update_app_plist}"
note "update_ks_plist = ${update_ks_plist}"
if ! update_version_ks="$(infoplist_read "${update_ks_plist}" \
"${KS_VERSION_KEY}")" ||
[[ -z "${update_version_ks}" ]]; then
err "couldn't determine update_version_ks"
exit 2
fi
note "update_version_ks = ${update_version_ks}"
if ! product_id="$(infoplist_read "${update_ks_plist}" \
"${KS_PRODUCT_KEY}")" ||
[[ -z "${product_id}" ]]; then
err "couldn't determine product_id"
exit 2
fi
note "product_id = ${product_id}"
else # [[ -n "${is_patch}" ]]
# Get some information about the update.
note "reading update values"
if ! update_version_app_old=$(<"${patch_dir}/old_app_version") ||
[[ -z "${update_version_app_old}" ]]; then
err "couldn't determine update_version_app_old"
exit 2
fi
note "update_version_app_old = ${update_version_app_old}"
if ! update_version_app=$(<"${patch_dir}/new_app_version") ||
[[ -z "${update_version_app}" ]]; then
err "couldn't determine update_version_app"
exit 2
fi
note "update_version_app = ${update_version_app}"
if ! update_version_ks=$(<"${patch_dir}/new_ks_version") ||
[[ -z "${update_version_ks}" ]]; then
err "couldn't determine update_version_ks"
exit 2
fi
note "update_version_ks = ${update_version_ks}"
if ! product_id=$(<"${patch_dir}/ks_product") ||
[[ -z "${product_id}" ]]; then
err "couldn't determine product_id"
exit 2
fi
note "product_id = ${product_id}"
patch_app_dir="${patch_dir}/application.dirpatch"
if ! [[ -d "${patch_app_dir}" ]]; then
err "couldn't locate patch_app_dir"
exit 6
fi
note "patch_app_dir = ${patch_app_dir}"
patch_versioned_dir=\
"${patch_dir}/version_${update_version_app_old}_${update_version_app}.dirpatch"
if ! [[ -d "${patch_versioned_dir}" ]]; then
err "couldn't locate patch_versioned_dir"
exit 6
fi
note "patch_versioned_dir = ${patch_versioned_dir}"
fi
# ksadmin is required. Keystone should have set a ${PATH} that includes it.
# Check that here, so that more useful feedback can be offered in the
# unlikely event that ksadmin is missing.
note "checking Keystone"
local ksadmin_path
if ! ksadmin_path="$(type -p ksadmin)" || [[ -z "${ksadmin_path}" ]]; then
err "couldn't locate ksadmin_path"
exit 3
fi
note "ksadmin_path = ${ksadmin_path}"
# Call ksadmin_version once to prime the global state. This is needed
# because subsequent calls to ksadmin_version that occur in $(...)
# expansions will not affect the global state (although they can read from
# the already-initialized global state) and thus will cause a new ksadmin
# --ksadmin-version process to run for each check unless the globals have
# been properly initialized beforehand.
ksadmin_version >& /dev/null || true
local ksadmin_version_string
ksadmin_version_string="$(ksadmin_version 2> /dev/null || true)"
note "ksadmin_version_string = ${ksadmin_version_string}"
# Figure out where to install.
local installed_app
if ! installed_app="$(ksadmin -pP "${product_id}" | sed -Ene \
"s%^[[:space:]]+xc=<KSPathExistenceChecker:.* path=(/.+)>\$%\\1%p")" ||
[[ -z "${installed_app}" ]]; then
err "couldn't locate installed_app"
exit 3
fi
note "installed_app = ${installed_app}"
local want_full_installer_path="${installed_app}/.want_full_installer"
note "want_full_installer_path = ${want_full_installer_path}"
if [[ "${installed_app:0:1}" != "/" ]] ||
! [[ -d "${installed_app}" ]]; then
err "installed_app must be an absolute path to a directory"
exit 3
fi
# If this script is running as root, it's being driven by a system ticket.
# Otherwise, it's being driven by a user ticket.
local system_ticket=
if [[ ${EUID} -eq 0 ]]; then
system_ticket="y"
fi
note "system_ticket = ${system_ticket}"
# If this script is being driven by a user ticket, but a system ticket is
# also present, there's a potential for the two to collide. Both ticket
# types might be present if another user on the system promoted the ticket
# to system: the other user could not have removed this user's user ticket.
# Handle that case here by deleting the user ticket and exiting early with
# a discrete exit code.
#
# Current versions of ksadmin will exit 1 (false) when asked to print tickets
# and given a specific product ID to print. Older versions of ksadmin would
# exit 0 (true), but those same versions did not support -S (meaning to check
# the system ticket store) and would exit 1 (false) with this invocation due
# to not understanding the question. Therefore, the usage here will only
# delete the existing user ticket when running as non-root with access to a
# sufficiently recent ksadmin. Older ksadmins are tolerated: the update will
# likely fail for another reason and the user ticket will hang around until
# something is eventually able to remove it.
if [[ -z "${system_ticket}" ]] &&
ksadmin -S --print-tickets --productid "${product_id}" >& /dev/null; then
ksadmin --delete --productid "${product_id}" || true
err "can't update on a user ticket when a system ticket is also present"
exit 4
fi
# Figure out what the existing installed application is using for its
# versioned directory. This will be used later, to avoid removing the
# existing installed version's versioned directory in case anything is still
# using it.
note "reading install values"
local installed_app_plist="${installed_app}/${APP_PLIST}"
note "installed_app_plist = ${installed_app_plist}"
local installed_app_plist_path="${installed_app_plist}.plist"
note "installed_app_plist_path = ${installed_app_plist_path}"
local old_version_app
old_version_app="$(infoplist_read "${installed_app_plist}" \
"${APP_VERSION_KEY}" || true)"
note "old_version_app = ${old_version_app}"
# old_version_app is not required, because it won't be present in skeleton
# bootstrap installations, which just have an empty .app directory. Only
# require it when doing a patch update, and use it to validate that the
# patch applies to the old installed version. By definition, skeleton
# bootstraps can't be installed with patch updates. They require the full
# application on the disk image.
if [[ -n "${is_patch}" ]]; then
if [[ -z "${old_version_app}" ]]; then
err "old_version_app required for patch"
exit 6
elif [[ "${old_version_app}" != "${update_version_app_old}" ]]; then
err "this patch does not apply to the installed version"
exit 6
fi
fi
local installed_versions_dir="${installed_app}/${VERSIONS_DIR}"
note "installed_versions_dir = ${installed_versions_dir}"
# If the installed application is incredibly old, old_versioned_dir may not
# exist.
local old_versioned_dir
if [[ -n "${old_version_app}" ]]; then
old_versioned_dir="${installed_versions_dir}/${old_version_app}"
fi
note "old_versioned_dir = ${old_versioned_dir}"
# Collect the installed application's brand code, it will be used later. It
# is not an error for the installed application to not have a brand code.
local old_ks_plist="${installed_app_plist}"
note "old_ks_plist = ${old_ks_plist}"
local old_brand
old_brand="$(infoplist_read "${old_ks_plist}" \
"${KS_BRAND_KEY}" 2> /dev/null ||
true)"
note "old_brand = ${old_brand}"
local update_versioned_dir=
if [[ -z "${is_patch}" ]]; then
update_versioned_dir="${update_app}/${VERSIONS_DIR}/${update_version_app}"
note "update_versioned_dir = ${update_versioned_dir}"
fi
if has_32_bit_only_cpu; then
# On a 32-bit-only system, make sure that the update contains 32-bit code.
note "system is 32-bit-only"
local test_binary
if [[ -z "${is_patch}" ]]; then
# For a full installer, the framework is available, so check it for
# 32-bit code.
local update_framework_dir="${update_versioned_dir}/${FRAMEWORK_DIR}"
test_binary="${update_framework_dir}/${FRAMEWORK_NAME}"
else
# No application code is guaranteed to be available at this point for a
# patch updater, but goobspatch is built alongside and will have the
# same bitness of the product that this updater will install, so it's a
# reasonable proxy.
test_binary="${patch_dir}/goobspatch"
fi
note "test_binary = ${test_binary}"
if ! file "${test_binary}" | grep -q 'i386$'; then
err "can't install non-32-bit update on 32-bit-only system"
mark_32_bit_only_system "${product_id}"
exit 14
else
note "update will run on a 32-bit-only system"
fi
fi
ensure_writable_symlinks_recursive "${installed_app}"
# By copying to ${installed_app}, the existing application name will be
# preserved, if the user has renamed the application on disk. Respecting
# the user's changes is friendly.
# Make sure that ${installed_versions_dir} exists, so that it can receive
# the versioned directory. It may not exist if updating from an older
# version that did not use the versioned layout on disk. Later, during the
# rsync to copy the application directory, the mode bits and timestamp on
# ${installed_versions_dir} will be set to conform to whatever is present in
# the update.
#
# ${installed_app} is guaranteed to exist at this point, but
# ${installed_app}/${CONTENTS_DIR} may not if things are severely broken or
# if this update is actually an initial installation from a Keystone
# skeleton bootstrap. The mkdir creates ${installed_app}/${CONTENTS_DIR} if
# it doesn't exist; its mode bits will be fixed up in a subsequent rsync.
note "creating installed_versions_dir"
if ! mkdir -p "${installed_versions_dir}"; then
err "mkdir of installed_versions_dir failed"
exit 5
fi
local new_versioned_dir
new_versioned_dir="${installed_versions_dir}/${update_version_app}"
note "new_versioned_dir = ${new_versioned_dir}"
# If there's an entry at ${new_versioned_dir} but it's not a directory
# (or it's a symbolic link, whether or not it points to a directory), rsync
# won't get rid of it. It's never correct to have a non-directory in place
# of the versioned directory, so toss out whatever's there. Don't treat
# this as a critical step: if removal fails, operation can still proceed to
# to the dirpatcher or rsync, which will likely fail.
if [[ -e "${new_versioned_dir}" ]] &&
([[ -L "${new_versioned_dir}" ]] ||
! [[ -d "${new_versioned_dir}" ]]); then
note "removing non-directory in place of versioned directory"
rm -f "${new_versioned_dir}" 2> /dev/null || true
fi
if [[ -n "${is_patch}" ]]; then
# dirpatcher won't patch into a directory that already exists. Doing so
# would be a bad idea, anyway. If ${new_versioned_dir} already exists,
# it may be something left over from a previous failed or incomplete
# update attempt, or it may be the live versioned directory if this is a
# same-version update intended only to change channels. Since there's no
# way to tell, this case is handled by having dirpatcher produce the new
# versioned directory in a temporary location and then having rsync copy
# it into place as an ${update_versioned_dir}, the same as in a non-patch
# update. If ${new_versioned_dir} doesn't exist, dirpatcher can place the
# new versioned directory at that location directly.
local versioned_dir_target
if ! [[ -e "${new_versioned_dir}" ]]; then
versioned_dir_target="${new_versioned_dir}"
note "versioned_dir_target = ${versioned_dir_target}"
else
ensure_temp_dir
versioned_dir_target="${g_temp_dir}/${update_version_app}"
note "versioned_dir_target = ${versioned_dir_target}"
update_versioned_dir="${versioned_dir_target}"
note "update_versioned_dir = ${update_versioned_dir}"
fi
note "dirpatching versioned directory"
if ! "${dirpatcher}" "${old_versioned_dir}" \
"${patch_versioned_dir}" \
"${versioned_dir_target}"; then
err "dirpatcher of versioned directory failed, status ${PIPESTATUS[0]}"
mark_failed_patch_update "${product_id}" \
"${want_full_installer_path}" \
"${old_ks_plist}" \
"${old_version_app}" \
"${system_ticket}"
exit 12
fi
fi
# Copy the versioned directory. The new versioned directory should have a
# different name than any existing one, so this won't harm anything already
# present in ${installed_versions_dir}, including the versioned directory
# being used by any running processes. If this step is interrupted, there
# will be an incomplete versioned directory left behind, but it won't
# won't interfere with anything, and it will be replaced or removed during a
# future update attempt.
#
# In certain cases, same-version updates are distributed to move users
# between channels; when this happens, the contents of the versioned
# directories are identical and rsync will not render the versioned
# directory unusable even for an instant.
#
# ${update_versioned_dir} may be empty during a patch update (${is_patch})
# if the dirpatcher above was able to write it into place directly. In
# that event, dirpatcher guarantees that ${new_versioned_dir} is already in
# place.
if [[ -n "${update_versioned_dir}" ]]; then
note "rsyncing versioned directory"
if ! rsync ${RSYNC_FLAGS} --delete-before "${update_versioned_dir}/" \
"${new_versioned_dir}"; then
err "rsync of versioned directory failed, status ${PIPESTATUS[0]}"
exit 7
fi
fi
if [[ -n "${is_patch}" ]]; then
# If the versioned directory was prepared in a temporary directory and
# then rsynced into place, remove the temporary copy now that it's no
# longer needed.
if [[ -n "${update_versioned_dir}" ]]; then
rm -rf "${update_versioned_dir}" 2> /dev/null || true
update_versioned_dir=
note "update_versioned_dir = ${update_versioned_dir}"
fi
# Prepare ${update_app}. This always needs to be done in a temporary
# location because dirpatcher won't write to a directory that already
# exists, and ${installed_app} needs to be used as input to dirpatcher
# in any event. The new application will be rsynced into place once
# dirpatcher creates it.
ensure_temp_dir
update_app="${g_temp_dir}/${APP_DIR}"
note "update_app = ${update_app}"
note "dirpatching app directory"
if ! "${dirpatcher}" "${installed_app}" \
"${patch_app_dir}" \
"${update_app}"; then
err "dirpatcher of app directory failed, status ${PIPESTATUS[0]}"
mark_failed_patch_update "${product_id}" \
"${want_full_installer_path}" \
"${old_ks_plist}" \
"${old_version_app}" \
"${system_ticket}"
exit 13
fi
fi
# See if the timestamp of what's currently on disk is newer than the
# update's outer .app's timestamp. rsync will copy the update's timestamp
# over, but if that timestamp isn't as recent as what's already on disk, the
# .app will need to be touched.
local needs_touch=
if [[ "${installed_app}" -nt "${update_app}" ]]; then
needs_touch="y"
fi
note "needs_touch = ${needs_touch}"
# Copy the unversioned files into place, leaving everything in
# ${installed_versions_dir} alone. If this step is interrupted, the
# application will at least remain in a usable state, although it may not
# pass signature validation. Depending on when this step is interrupted,
# the application will either launch the old or the new version. The
# critical point is when the main executable is replaced. There isn't very
# much to copy in this step, because most of the application is in the
# versioned directory. This step only accounts for around 50 files, most of
# which are small localized InfoPlist.strings files. Note that
# ${VERSIONS_DIR} is included to copy its mode bits and timestamp, but its
# contents are excluded, having already been installed above.
note "rsyncing app directory"
if ! rsync ${RSYNC_FLAGS} --delete-after --exclude "/${VERSIONS_DIR}/*" \
"${update_app}/" "${installed_app}"; then
err "rsync of app directory failed, status ${PIPESTATUS[0]}"
exit 8
fi
note "rsyncs complete"
if [[ -n "${is_patch}" ]]; then
# update_app has been rsynced into place and is no longer needed.
rm -rf "${update_app}" 2> /dev/null || true
update_app=
note "update_app = ${update_app}"
fi
if [[ -n "${g_temp_dir}" ]]; then
# The temporary directory, if any, is no longer needed.
rm -rf "${g_temp_dir}" 2> /dev/null || true
g_temp_dir=
note "g_temp_dir = ${g_temp_dir}"
fi
# Clean up any old .want_full_installer files from previous dirpatcher
# failures. This is not considered a critical step, because this file
# normally does not exist at all.
rm -f "${want_full_installer_path}" || true
# If necessary, touch the outermost .app so that it appears to the outside
# world that something was done to the bundle. This will cause
# LaunchServices to invalidate the information it has cached about the
# bundle even if lsregister does not run. This is not done if rsync already
# updated the timestamp to something newer than what had been on disk. This
# is not considered a critical step, and if it fails, this script will not
# exit.
if [[ -n "${needs_touch}" ]]; then
touch -cf "${installed_app}" || true
fi
# Read the new values, such as the version.
note "reading new values"
local new_version_app
if ! new_version_app="$(infoplist_read "${installed_app_plist}" \
"${APP_VERSION_KEY}")" ||
[[ -z "${new_version_app}" ]]; then
err "couldn't determine new_version_app"
exit 9
fi
note "new_version_app = ${new_version_app}"
local new_versioned_dir="${installed_versions_dir}/${new_version_app}"
note "new_versioned_dir = ${new_versioned_dir}"
local new_ks_plist="${installed_app_plist}"
note "new_ks_plist = ${new_ks_plist}"
local new_version_ks
if ! new_version_ks="$(infoplist_read "${new_ks_plist}" \
"${KS_VERSION_KEY}")" ||
[[ -z "${new_version_ks}" ]]; then
err "couldn't determine new_version_ks"
exit 9
fi
note "new_version_ks = ${new_version_ks}"
local update_url
if ! update_url="$(infoplist_read "${new_ks_plist}" "${KS_URL_KEY}")" ||
[[ -z "${update_url}" ]]; then
err "couldn't determine update_url"
exit 9
fi
note "update_url = ${update_url}"
# The channel ID is optional. Suppress stderr to prevent Keystone from
# seeing possible error output.
local channel
channel="$(infoplist_read "${new_ks_plist}" \
"${KS_CHANNEL_KEY}" 2> /dev/null || true)"
note "channel = ${channel}"
local tag="${channel}"
local tag_key="${KS_CHANNEL_KEY}"
if has_32_bit_only_cpu; then
tag="${tag}-32bit"
tag_key="${tag_key}-32bit"
fi
note "tag = ${tag}"
note "tag_key = ${tag_key}"
# Make sure that the update was successful by comparing the version found in
# the update with the version now on disk.
if [[ "${new_version_ks}" != "${update_version_ks}" ]]; then
err "new_version_ks and update_version_ks do not match"
exit 10
fi
# Notify LaunchServices. This is not considered a critical step, and
# lsregister's exit codes shouldn't be confused with this script's own.
# Redirect stdout to /dev/null to suppress the useless "ThrottleProcessIO:
# throttling disk i/o" messages that lsregister might print.
note "notifying LaunchServices"
local coreservices="/System/Library/Frameworks/CoreServices.framework"
local launchservices="${coreservices}/Frameworks/LaunchServices.framework"
local lsregister="${launchservices}/Support/lsregister"
note "coreservices = ${coreservices}"
note "launchservices = ${launchservices}"
note "lsregister = ${lsregister}"
"${lsregister}" -f "${installed_app}" > /dev/null || true
# The brand information is stored differently depending on whether this is
# running for a system or user ticket.
note "handling brand code"
local set_brand_file_access=
local brand_plist
if [[ -n "${system_ticket}" ]]; then
# System ticket.
set_brand_file_access="y"
brand_plist="/${UNROOTED_BRAND_PLIST}"
else
# User ticket.
brand_plist=~/"${UNROOTED_BRAND_PLIST}"
fi
local brand_plist_path="${brand_plist}.plist"
note "set_brand_file_access = ${set_brand_file_access}"
note "brand_plist = ${brand_plist}"
note "brand_plist_path = ${brand_plist_path}"
local ksadmin_brand_plist_path
local ksadmin_brand_key
# Only the stable channel, identified by an empty channel string, has a
# brand code. On the beta and dev channels, remove the brand plist if
# present. Its presence means that the ticket used to manage a
# stable-channel Chrome but the user has since replaced it with a beta or
# dev channel version. Since the canary channel can run side-by-side with
# another Chrome installation, don't remove the brand plist on that channel,
# but skip the rest of the brand logic.
if [[ "${channel}" = "beta" ]] || [[ "${channel}" = "dev" ]]; then
note "defeating brand code on channel ${channel}"
rm -f "${brand_plist_path}" 2>/dev/null || true
elif [[ -n "${channel}" ]]; then
# Canary channel.
note "skipping brand code on channel ${channel}"
else
# Stable channel.
# If the user manually updated their copy of Chrome, there might be new
# brand information in the app bundle, and that needs to be copied out
# into the file Keystone looks at.
if [[ -n "${old_brand}" ]]; then
local brand_dir
brand_dir="$(dirname "${brand_plist_path}")"
note "brand_dir = ${brand_dir}"
if ! mkdir -p "${brand_dir}"; then
err "couldn't mkdir brand_dir, continuing"
else
if ! defaults write "${brand_plist}" "${KS_BRAND_KEY}" \
-string "${old_brand}"; then
err "couldn't write brand_plist, continuing"
elif [[ -n "${set_brand_file_access}" ]]; then
if ! chown "root:wheel" "${brand_plist_path}"; then
err "couldn't chown brand_plist_path, continuing"
else
if ! chmod 644 "${brand_plist_path}"; then
err "couldn't chmod brand_plist_path, continuing"
fi
fi
fi
fi
fi
# Confirm that the brand file exists. It's optional.
ksadmin_brand_plist_path="${brand_plist_path}"
ksadmin_brand_key="${KS_BRAND_KEY}"
if [[ ! -f "${ksadmin_brand_plist_path}" ]]; then
# Clear any branding information.
ksadmin_brand_plist_path=
ksadmin_brand_key=
fi
fi
note "ksadmin_brand_plist_path = ${ksadmin_brand_plist_path}"
note "ksadmin_brand_key = ${ksadmin_brand_key}"
note "notifying Keystone"
local ksadmin_args=(
--register
--productid "${product_id}"
--version "${new_version_ks}"
--xcpath "${installed_app}"
--url "${update_url}"
)
if ksadmin_supports_tag; then
ksadmin_args+=(
--tag "${tag}"
)
fi
if ksadmin_supports_tagpath_tagkey; then
ksadmin_args+=(
--tag-path "${installed_app_plist_path}"
--tag-key "${tag_key}"
)
fi
if ksadmin_supports_brandpath_brandkey; then
ksadmin_args+=(
--brand-path "${ksadmin_brand_plist_path}"
--brand-key "${ksadmin_brand_key}"
)
fi
if ksadmin_supports_versionpath_versionkey; then
ksadmin_args+=(
--version-path "${installed_app_plist_path}"
--version-key "${KS_VERSION_KEY}"
)
fi
note "ksadmin_args = ${ksadmin_args[*]}"
if ! ksadmin "${ksadmin_args[@]}"; then
err "ksadmin failed"
exit 11
fi
# The remaining steps are not considered critical.
set +e
# Try to clean up old versions that are not in use. The strategy is to keep
# the versioned directory corresponding to the update just applied
# (obviously) and the version that was just replaced, and to use ps and lsof
# to see if it looks like any processes are currently using any other old
# directories. Directories not in use are removed. Old versioned
# directories that are in use are left alone so as to not interfere with
# running processes. These directories can be cleaned up by this script on
# future updates.
#
# To determine which directories are in use, both ps and lsof are used.
# Each approach has limitations.
#
# The ps check looks for processes within the versioned directory. Only
# helper processes, such as renderers, are within the versioned directory.
# Browser processes are not, so the ps check will not find them, and will
# assume that a versioned directory is not in use if a browser is open
# without any windows. The ps mechanism can also only detect processes
# running on the system that is performing the update. If network shares
# are involved, all bets are off.
#
# The lsof check looks to see what processes have the framework dylib open.
# Browser processes will have their versioned framework dylib open, so this
# check is able to catch browsers even if there are no associated helper
# processes. Like the ps check, the lsof check is limited to processes on
# the system that is performing the update. Finally, unless running as
# root, the lsof check can only find processes running as the effective user
# performing the update.
#
# These limitations are motivations to additionally preserve the versioned
# directory corresponding to the version that was just replaced.
note "cleaning up old versioned directories"
local versioned_dir
for versioned_dir in "${installed_versions_dir}/"*; do
note "versioned_dir = ${versioned_dir}"
if [[ "${versioned_dir}" = "${new_versioned_dir}" ]] || \
[[ "${versioned_dir}" = "${old_versioned_dir}" ]]; then
# This is the versioned directory corresponding to the update that was
# just applied or the version that was previously in use. Leave it
# alone.
note "versioned_dir is new_versioned_dir or old_versioned_dir, skipping"
continue
fi
# Look for any processes whose executables are within this versioned
# directory. They'll be helper processes, such as renderers. Their
# existence indicates that this versioned directory is currently in use.
local ps_string="${versioned_dir}/"
note "ps_string = ${ps_string}"
# Look for any processes using the framework dylib. This will catch
# browser processes where the ps check will not, but it is limited to
# processes running as the effective user.
local lsof_file="${versioned_dir}/${FRAMEWORK_DIR}/${FRAMEWORK_NAME}"
note "lsof_file = ${lsof_file}"
# ps -e displays all users' processes, -ww causes ps to not truncate
# lines, -o comm instructs it to only print the command name, and the =
# tells it to not print a header line.
# The cut invocation filters the ps output to only have at most the number
# of characters in ${ps_string}. This is done so that grep can look for
# an exact match.
# grep -F tells grep to look for lines that are exact matches (not regular
# expressions), -q tells it to not print any output and just indicate
# matches by exit status, and -x tells it that the entire line must match
# ${ps_string} exactly, as opposed to matching a substring. A match
# causes grep to exit zero (true).
#
# lsof will exit nonzero if ${lsof_file} does not exist or is open by any
# process. If the file exists and is open, it will exit zero (true).
if (! ps -ewwo comm= | \
cut -c "1-${#ps_string}" | \
grep -Fqx "${ps_string}") &&
(! lsof "${lsof_file}" >& /dev/null); then
# It doesn't look like anything is using this versioned directory. Get
# rid of it.
note "versioned_dir doesn't appear to be in use, removing"
rm -rf "${versioned_dir}"
else
note "versioned_dir is in use, skipping"
fi
done
# If this script is being driven by a user Keystone ticket, it is not
# running as root. If the application is installed somewhere under
# /Applications, try to make it writable by all admin users. This will
# allow other admin users to update the application from their own user
# Keystone instances.
#
# If the script is being driven by a user Keystone ticket (not running as
# root) and the application is not installed under /Applications, it might
# not be in a system-wide location, and it probably won't be something that
# other users on the system are running, so err on the side of safety and
# don't make it group-writable.
#
# If this script is being driven by a system ticket (running as root), it's
# future updates can be expected to be applied the same way, so admin-
# writability is not a concern. Set the entire thing to be owned by root
# in that case, regardless of where it's installed, and drop any group and
# other write permission.
#
# If this script is running as a user that is not a member of the admin
# group, the chgrp operation will not succeed. Tolerate that case, because
# it's better than the alternative, which is to make the application
# world-writable.
note "setting permissions"
local chmod_mode="a+rX,u+w,go-w"
if [[ -z "${system_ticket}" ]]; then
if [[ "${installed_app:0:14}" = "/Applications/" ]] &&
chgrp -Rh admin "${installed_app}" 2> /dev/null; then
chmod_mode="a+rX,ug+w,o-w"
fi
else
chown -Rh root:wheel "${installed_app}" 2> /dev/null
fi
note "chmod_mode = ${chmod_mode}"
chmod -R "${chmod_mode}" "${installed_app}" 2> /dev/null
# On the Mac, or at least on HFS+, symbolic link permissions are significant,
# but chmod -R and -h can't be used together. Do another pass to fix the
# permissions on any symbolic links.
find "${installed_app}" -type l -exec chmod -h "${chmod_mode}" {} + \
2> /dev/null
# If an update is triggered from within the application itself, the update
# process inherits the quarantine bit (LSFileQuarantineEnabled). Any files
# or directories created during the update will be quarantined in that case,
# which may cause Launch Services to display quarantine UI. That's bad,
# especially if it happens when the outer .app launches a quarantined inner
# helper. If the application is already on the system and is being updated,
# then it can be assumed that it should not be quarantined. Use xattr to
# drop the quarantine attribute.
#
# TODO(mark): Instead of letting the quarantine attribute be set and then
# dropping it here, figure out a way to get the update process to run
# without LSFileQuarantineEnabled even when triggering an update from within
# the application.
note "lifting quarantine"
if os_xattr_supports_r; then
# On 10.6, xattr supports -r for recursive operation.
xattr -d -r "${QUARANTINE_ATTR}" "${installed_app}" 2> /dev/null
else
# On earlier systems, xattr doesn't support -r, so run xattr via find.
find "${installed_app}" -exec xattr -d "${QUARANTINE_ATTR}" {} + \
2> /dev/null
fi
# Great success!
note "done!"
trap - EXIT
return 0
}
# Check "less than" instead of "not equal to" in case Keystone ever changes to
# pass more arguments.
if [[ ${#} -lt 1 ]]; then
usage
exit 2
fi
main "${@}"
exit ${?}