#!/bin/sh -ef # shellcheck source=/dev/null # # This is a simple package manager written in POSIX 'sh' for use # in KISS Linux (https://k1ss.org). # # This script runs with '-ef' meaning: # '-e': Abort on any non-zero exit code. # '-f': Disable globbing globally. # # [1] Warnings related to word splitting and globbing are disabled. # All word splitting in this script is *safe* and intentional. # # Dylan Araps. log() { # Print a message prettily. # # All messages are printed to stderr to allow the user to hide build # output which is the only thing printed to stdout. # # '\033[1;32m' Set text to color '2' and make it bold. # '\033[m': Reset text formatting. # '${3:-->}': If the 3rd argument is missing, set prefix to '->'. # '${2:+\033[1;3Xm}': If the 2nd argument exists, set text style of '$1'. printf '\033[1;33m%s \033[m%b%s\033[m %s\n' \ "${3:-->}" "${2:+"\033[1;36m"}" "$1" "$2" >&2 } die() { # Print a message and exit with '1' (error). log "$1" "$2" "!>" exit 1 } warn() { # Print a warning message log "WARN" "$1" "${2:-!>}" } contains() { # Check if a "string list" contains a word. case " $1 " in *" $2 "*) return 0; esac; return 1 } prompt() { # If a KISS_NOPROMPT variable is set, continue. # This can be useful for installation scripts and # bootstrapping. [ "$KISS_NOPROMPT" ] && return 0 # Ask the user for some input. [ "$1" ] && log "$1" log "Continue?: Press Enter to continue or Ctrl+C to abort here" # POSIX 'read' has none of the "nice" options like '-n', '-p' # etc etc. This is the most basic usage of 'read'. # '_' is used as 'dash' errors when no variable is given to 'read'. read -r _ || return 1 } as_root() { # Simple function to run a command as root using either 'sudo', # 'doas' or 'su'. Hurrah for choice. [ "$uid" = 0 ] || log "Using '${su:-su}' (to become ${user:=root})" case $su in *sudo) sudo -E -u "$user" -- "$@" ;; *doas) doas -u "$user" -- "$@" ;; *) su -pc "$* <&3" "$user" 3<&0 /dev/null || sha256 -r "$1" 2>/dev/null || openssl dgst -r -sha256 "$1" || die "No sha256 program could be run." ;} | while read -r hash _; do printf '%s %s\n' "$hash" "$1"; done } pkg_lint() { # Check that each mandatory file in the package entry exists. log "$1" "Checking repository files" repo_dir=$(pkg_find "$1") cd "$repo_dir" || die "'$repo_dir' not accessible" [ -f sources ] || die "$1" "Sources file not found" [ -x build ] || die "$1" "Build file not found or not executable" [ -s version ] || die "$1" "Version file not found or empty" read -r _ release 2>/dev/null < version || die "Version file not found" [ "$release" ] || die "Release field not found in version file" [ "$2" ] || [ -f checksums ] || die "$pkg" "Checksums are missing" } pkg_find() { # Use a SEARCH_PATH variable so that we can get the sys_db into # the same variable as KISS_PATH. This makes it easier when we are # searching for executables instead of KISS_PATH. : "${SEARCH_PATH:=$KISS_PATH:$sys_db}" # Figure out which repository a package belongs to by # searching for directories matching the package name # in $KISS_PATH/*. query=$1 match=$2 type=$3 IFS=:; set -- # Word splitting is intentional here. # shellcheck disable=2086 for path in $SEARCH_PATH ; do set +f for path2 in "$path/"$query; do test "${type:--d}" "$path2" && set -f -- "$@" "$path2" done done unset IFS # A package may also not be found due to a repository not being # readable by the current user. Either way, we need to die here. [ "$1" ] || die "Package '$query' not in any repository" # Show all search results if called from 'kiss search', else # print only the first match. [ "$match" ] && printf '%s\n' "$@" || printf '%s\n' "$1" } pkg_list() { # List installed packages. As the format is files and # directories, this just involves a simple for loop and # file read. # Change directories to the database. This allows us to # avoid having to 'basename' each path. If this fails, # set '$1' to mimic a failed glob which indicates that # nothing is installed. cd "$sys_db" 2>/dev/null || set -- "$sys_db/"\* # Optional arguments can be passed to check for specific # packages. If no arguments are passed, list all. As we # loop over '$@', if there aren't any arguments we can # just set the directory contents to the argument list. [ "$1" ] || { set +f; set -f -- *; } # If the 'glob' above failed, exit early as there are no # packages installed. [ "$1" = "$sys_db/"\* ] && return 1 # Loop over each package and print its name and version. for pkg do [ -d "$pkg" ] || { log "$pkg" "not installed"; return 1; } read -r version 2>/dev/null < "$pkg/version" || version=null printf '%s\n' "$pkg $version" done } pkg_cache() { read -r version release 2>/dev/null < "$(pkg_find "$1")/version" set +f; set -f -- "$bin_dir/$1#$version-$release.tar."* tar_file=$1 [ -f "$tar_file" ] } pkg_sources() { # Download any remote package sources. The existence of local # files is also checked. log "$1" "Downloading sources" # Store each downloaded source in a directory named after the # package it belongs to. This avoid conflicts between two packages # having a source of the same name. mkdir -p "$src_dir/$1" && cd "$src_dir/$1" repo_dir=$(pkg_find "$1") while read -r src dest || [ "$src" ]; do # Comment. if [ -z "${src##\#*}" ]; then : # Remote source (cached). elif [ -f "${src##*/}" ]; then log "$1" "Found cached source '${src##*/}'" # Remote git repository. elif [ -z "${src##git+*}" ]; then # This is a checksums check, skip it. [ "$2" ] && continue mkdir -p "$mak_dir/$1/$dest" # Run in a subshell to keep the variables, path and # argument list local to each loop iteration. ( repo_src=${src##git+} log "$1" "Cloning ${repo_src%[@#]*}" # Git has no option to clone a repository to a # specific location so we must do it ourselves # beforehand. cd "$mak_dir/$1/$dest" 2>/dev/null || die # Clear the argument list as we'll be overwriting # it below based on what kind of checkout we're # dealing with. set -- "$repo_src" # If a branch was given, shallow clone it directly. # This speeds things up as we don't have to grab # a lot of unneeded commits. [ "${src##*@*}" ] || set -- -b "${src##*@}" "${repo_src%@*}" # Maintain compatibility with older versions of # kiss by shallow cloning all branches. This has # the added benefit of allowing checkouts of # specific commits in specific branches. [ "${src##*#*}" ] || set -- --no-single-branch "${repo_src%#*}" # Always do a shallow clone as we will unshallow it if # needed later (when a commit is desired). git clone --depth=1 "$@" . ) || die "$1" "Failed to clone $src" # Remote source. elif [ -z "${src##*://*}" ]; then log "$1" "Downloading $src" curl "$src" -fLo "${src##*/}" || { rm -f "${src##*/}" die "$1" "Failed to download $src" } # Local source. elif [ -f "$repo_dir/$src" ]; then log "$1" "Found local file '$src'" else die "$1" "No local file '$src'" fi done < "$repo_dir/sources" } pkg_extract() { # Extract all source archives to the build directory and copy over # any local repository files. log "$1" "Extracting sources" repo_dir=$(pkg_find "$1") while read -r src dest || [ "$src" ]; do mkdir -p "$mak_dir/$1/$dest" && cd "$mak_dir/$1/$dest" case $src in # Git repository with supplied commit hash. git+*\#*) log "Checking out ${src##*#}" # A commit was requested, unshallow the repository. # This will convert it to a regular repository with # full history. git fetch --unshallow # Try to checkout the repository. If we fail here, # the requested commit doesn't exist. git -c advice.detachedHead=false checkout "${src##*#}" || die "Commit hash ${src##*#} doesn't exist" ;; # Git repository, comment or blank line. git+*|\#*|'') continue ;; # Only 'tar' an 'zip' archives are currently supported for # extraction. Other filetypes are simply copied to '$mak_dir' # which allows for manual extraction. *://*.tar|*://*.tar.??|*://*.tar.???|*://*.tar.????|*://*.tgz|*://*.txz) decompress "$src_dir/$1/${src##*/}" > .ktar "$tar" xf .ktar || die "$1" "Couldn't extract ${src##*/}" # We now list the contents of the tarball so we can do our # version of 'strip-components'. "$tar" tf .ktar | while read -r file; do printf '%s\n' "${file%%/*}"; done | # Do not repeat files. uniq | # For every directory in the base we move each file # inside it to the upper directory. while read -r dir ; do # Skip if we are not dealing with a directory here. # This way we don't remove files on the upper directory # if a tar archive doesn't need directory stripping. [ -d "${dir#.}" ] || continue # Change into the directory in a subshell so we don't # need to cd back to the upper directory. ( cd "$dir" # We use find because we want to move hidden files # as well. # # Skip the file if it has the same name as the directory. # We will deal with it later. # # Word splitting is intentional here. # shellcheck disable=2046 find . \( ! -name . -prune \) ! -name "$dir" \ -exec mv -f {} .. \; # If a file/directory with the same name as the directory # exists, append a '.kissbak' to it and move it to the # upper directory. ! [ -e "$dir" ] || mv "$dir" "../${dir}.kissbak" ) rmdir "$dir" # If a backup file exists, move it into the original location. ! [ -e "${dir}.kissbak" ] || mv "${dir}.kissbak" "$dir" done # Clean up the temporary tarball. rm -f .ktar ;; *://*.zip) unzip "$src_dir/$1/${src##*/}" || die "$1" "Couldn't extract ${src##*/}" ;; *) # Local file. if [ -f "$repo_dir/$src" ]; then cp -f "$repo_dir/$src" . # Remote file. elif [ -f "$src_dir/$1/${src##*/}" ]; then cp -f "$src_dir/$1/${src##*/}" . else die "$1" "Local file $src not found" fi ;; esac done < "$repo_dir/sources" } pkg_depends() { # Resolve all dependencies and generate an ordered list. # This does a depth-first search. The deepest dependencies are # listed first and then the parents in reverse order. contains "$deps" "$1" || { # Filter out non-explicit, aleady installed dependencies. # Only filter installed if called from 'pkg_build()'. [ "$pkg_build" ] && [ -z "$2" ] && (pkg_list "$1" >/dev/null) && return # Recurse through the dependencies of the child packages. while read -r dep _ || [ "$dep" ]; do [ "${dep##\#*}" ] && pkg_depends "$dep" done 2>/dev/null < "$(pkg_find "$1")/depends" ||: # After child dependencies are added to the list, # add the package which depends on them. [ "$2" = explicit ] || deps="$deps $1 " } } pkg_order() { # Order a list of packages based on dependence and # take into account pre-built tarballs if this is # to be called from 'kiss i'. order=; redro=; deps= for pkg do case $pkg in *.tar.*) deps="$deps $pkg " ;; *) pkg_depends "$pkg" raw esac done # Filter the list, only keeping explicit packages. # The purpose of these two loops is to order the # argument list based on dependence. for pkg in $deps; do ! contains "$*" "$pkg" || { order="$order $pkg " redro=" $pkg $redro" } done deps= } pkg_strip() { # Strip package binaries and libraries. This saves space on the # system as well as on the tarballs we ship for installation. # Package has stripping disabled, stop here. [ -f "$mak_dir/$pkg/nostrip" ] && return log "$1" "Stripping binaries and libraries" # Strip only files matching the below ELF types. # NOTE: 'readelf' is used in place of 'file' as # it allows us to remove 'file' from the # core repositories altogether. find "$pkg_dir/$1" -type f | while read -r file; do case $(readelf -h "$file") in *" DYN "*) strip_opt=unneeded ;; *" EXEC "*) strip_opt=all ;; *" REL "*) strip_opt=debug ;; *) continue esac strip "--strip-$strip_opt" "$file" && printf 'Stripped %10s %s\n' "($strip_opt)" "${file##$pkg_dir/$1}" done 2>/dev/null ||: } pkg_fixdeps() { # Dynamically look for missing runtime dependencies by checking # each binary and library with 'ldd'. This catches any extra # libraries and or dependencies pulled in by the package's # build suite. log "$1" "Checking for missing dependencies" # Go to the directory containing the built package to # simplify path building. cd "$pkg_dir/$1/$pkg_db/$1" # Make a copy of the depends file if it exists to have a # reference to 'diff' against. if [ -f depends ]; then cp -f depends "$mak_dir/d" dep_file=$mak_dir/d else dep_file=/dev/null fi # Generate a list of all installed manifests. pkg_name=$1 set +f; set -f -- "$sys_db/"*/manifest # Get a list of binaries and libraries, false files # will be found, however it's faster to get 'ldd' to check # them anyway than to filter them out. find "$pkg_dir/$pkg_name/" -type f 2>/dev/null | while read -r file; do # Run 'ldd' on the file and parse each line. The code # then checks to see which packages own the linked # libraries and it prints the result. ldd "$file" 2>/dev/null | while read -r dep; do # Skip lines containing 'ldd'. [ "${dep##*ldd*}" ] || continue # Extract the file path from 'ldd' output, and # canonicalize the path. dep=${dep#* => } dep=${dep% *} dep=$(kiss-readlink "$dep") # Figure out which package owns the file. own=$("$grep" -lFx "${dep#$KISS_ROOT}" "$@") # If the package wasn't found, retry by removing # the '/usr' prefix. if [ -z "$own" ] && [ -z "${dep##$KISS_ROOT/usr*}" ]; then own=$("$grep" -lFx "${dep#$KISS_ROOT/usr}" "$@") dep=${dep#/usr} fi # Extract package name from 'grep' match. own=${own%/*} own=${own##*/} case $own in musl|gcc|"$pkg_name"|"") continue ; esac printf 'Found %s (%s) in (%s)\n' "$own" "$dep" \ "${file##$pkg_dir/$pkg_name}" >/dev/tty printf '%s\n' "$own" done ||: done >> depends # Remove duplicate entries from the new depends file. # This removes duplicate lines looking *only* at the # first column. sort -uk1,1 -o depends depends 2>/dev/null ||: # Display a diff of the new dependencies against the old ones. diff -U 3 "$dep_file" depends 2>/dev/null ||: # Remove the depends file if it is empty. [ -s depends ] || rm -f depends } pkg_manifest() ( # Generate the package's manifest file. This is a list of each file # and directory inside the package. The file is used when uninstalling # packages, checking for package conflicts and for general debugging. log "$1" "Generating manifest" # This function runs as a sub-shell to avoid having to 'cd' back to the # prior directory before being able to continue. cd "${2:-$pkg_dir}/$1" # find: Print all files and directories and append '/' to directories. # sort: Sort the output in *reverse*. Directories appear *after* their # contents. # sed: Remove the first character in each line (./dir -> /dir) and # remove all lines which only contain '.'. find . -type d -exec printf '%s/\n' {} + -o -print | sort -r | sed '/^\.\/$/d;ss.ss' > "${2:-$pkg_dir}/$1/$pkg_db/$1/manifest" ) pkg_etcsums() ( # This function runs as a sub-shell to avoid having to 'cd' back to the # prior directory before being able to continue. cd "$pkg_dir/$1/etc" 2>/dev/null || return 0; cd .. # Generate checksums for each configuration file in the package's # /etc/ directory for use in "smart" handling of these files. log "$1" "Generating etcsums" find etc -type f | while read -r file; do hashcheck "$file" done > "$pkg_dir/$1/$pkg_db/$1/etcsums" ) pkg_tar() { # Create a tarball from the built package's files. # This tarball also contains the package's database entry. log "$1" "Creating tarball" # Read the version information to name the package. read -r version release < "$(pkg_find "$1")/version" # Create a tarball from the contents of the built package. "$tar" cf - -C "$pkg_dir/$1" . | case ${KISS_COMPRESS:=gz} in bz2) bzip2 -z ;; xz) xz -zT 0 ;; gz) gzip -6 ;; zst) zstd -3 ;; *) gzip -6 ;; # Fallback to gzip esac \ > "$bin_dir/$1#$version-$release.tar.${KISS_COMPRESS:=gz}" log "$1" "Successfully created tarball" } pkg_build() { # Build packages and turn them into packaged tarballs. This function # also checks checksums, downloads sources and ensure all dependencies # are installed. pkg_build=1 log "Resolving dependencies" for pkg do contains "$explicit" "$pkg" || { pkg_depends "$pkg" explicit # Mark packages passed on the command-line # separately from those detected as dependencies. explicit="$explicit $pkg " } done [ "$pkg_update" ] || explicit_build=$explicit # If an explicit package is a dependency of another explicit # package, remove it from the explicit list as it needs to be # installed as a dependency. # shellcheck disable=2086 for pkg do contains "$deps" "$pkg" && explicit=$(pop "$pkg" from $explicit) done # See [1] at top of script. # shellcheck disable=2046,2086 set -- $deps $explicit log "Building: $*" # Only ask for confirmation if more than one package needs to be built. [ $# -gt 1 ] || [ "$pkg_update" ] && { prompt || exit 0 ;} log "Checking for pre-built dependencies" for pkg do pkg_lint "$pkg"; done # Install any pre-built dependencies if they exist in the binary # directory and are up to date. for pkg do ! contains "$explicit_build" "$pkg" && pkg_cache "$pkg" && { log "$pkg" "Found pre-built binary, installing" (KISS_FORCE=1 args i "$tar_file") # Remove the now installed package from the build list. # See [1] at top of script. # shellcheck disable=2046,2086 set -- $(pop "$pkg" from "$@") } done for pkg do pkg_sources "$pkg"; done pkg_verify "$@" # Finally build and create tarballs for all passed packages and # dependencies. for pkg do log "$pkg" "Building package ($((in = in + 1))/$#)" pkg_extract "$pkg" repo_dir=$(pkg_find "$pkg") # Install built packages to a directory under the package name # to avoid collisions with other packages. mkdir -p "$pkg_dir/$pkg/$pkg_db" # Move to the build directory. cd "$mak_dir/$pkg" log "$pkg" "Starting build" run_hook pre-build "$pkg" "$pkg_dir/$pkg" # Call the build script, log the output to the terminal # and to a file. There's no PIPEFAIL in POSIX shelll so # we must resort to tricks like killing the script ourselves. { "$repo_dir/build" "$pkg_dir/$pkg" 2>&1 || { log "$pkg" "Build failed" log "$pkg" "Log stored to $log_dir/$pkg-$time-$pid" run_hook build-fail "$pkg" "$pkg_dir/$pkg" pkg_clean kill 0 } } | tee "$log_dir/$pkg-$time-$pid" # Delete the log file if the build succeeded to prevent # the directory from filling very quickly with useless logs. [ "$KISS_KEEPLOG" = 1 ] || rm -f "$log_dir/$pkg-$time-$pid" # Copy the repository files to the package directory. # This acts as the database entry. cp -LRf "$repo_dir" "$pkg_dir/$pkg/$pkg_db/" # We never ever want this. Let's end the endless conflicts # and remove it. This will be the only exception for a # specific removal of this kind. rm -f "$pkg_dir/$pkg/usr/lib/charset.alias" log "$pkg" "Successfully built package" run_hook post-build "$pkg" "$pkg_dir/$pkg" # Create the manifest file early and make it empty. # This ensures that the manifest is added to the manifest. : > "$pkg_dir/$pkg/$pkg_db/$pkg/manifest" # If the package contains '/etc', add a file called # 'etcsums' to the manifest. See comment directly above. [ -d "$pkg_dir/$pkg/etc" ] && : > "$pkg_dir/$pkg/$pkg_db/$pkg/etcsums" pkg_strip "$pkg" pkg_fixdeps "$pkg" pkg_manifest "$pkg" pkg_etcsums "$pkg" pkg_tar "$pkg" # Install only dependencies of passed packages. # Skip this check if this is a package update. contains "$explicit" "$pkg" && [ -z "$pkg_update" ] && continue log "$pkg" "Needed as a dependency or has an update, installing" (KISS_FORCE=1 args i "$pkg") done # End here as this was a system update and all packages have been installed. [ "$pkg_update" ] && return log "Successfully built package(s)" # Turn the explicit packages into a 'list'. # See [1] at top of script. # shellcheck disable=2046,2086 set -- $explicit # Only ask for confirmation if more than one package needs to be installed. [ $# -gt 1 ] && prompt "Install built packages? [$*]" && { args i "$@" return } log "Run 'kiss i $*' to install the package(s)" } pkg_checksums() { # Generate checksums for packages. repo_dir=$(pkg_find "$1") while read -r src _ || [ "$src" ]; do # Comment. if [ -z "${src##\#*}" ]; then continue # File is local to the package. elif [ -f "$repo_dir/$src" ]; then src_path=$repo_dir/${src%/*} # File is remote and was downloaded. elif [ -f "$src_dir/$1/${src##*/}" ]; then src_path=$src_dir/$1 # File is a git repository. elif [ -z "${src##git+*}" ]; then printf 'git %s\n' "$src" continue # Die here if source for some reason, doesn't exist. else die "$1" "Couldn't find source '$src'" fi # An easy way to get 'sha256sum' to print with the 'basename' # of files is to 'cd' to the file's directory beforehand. (cd "$src_path" && hashcheck "${src##*/}") || die "$1" "Failed to generate checksums" done < "$repo_dir/sources" } pkg_verify() { # Verify all package checksums. This is achieved by generating # a new set of checksums and then comparing those with the old # set. for pkg do pkg_checksums "$pkg" | diff - "$(pkg_find "$pkg")/checksums" || { log "$pkg" "Checksum mismatch" # Instead of dying above, log it to the terminal. Also define a # variable so we *can* die after all checksum files have been # checked. mismatch="$mismatch$pkg " } done [ -z "$mismatch" ] || die "Checksum mismatch with: ${mismatch% }" } pkg_conflicts() { # Check to see if a package conflicts with another. log "$1" "Checking for package conflicts" # Filter the tarball's manifest and select only files # and any files they resolve to on the filesystem # (/bin/ls -> /usr/bin/ls). while read -r file; do case $file in */) continue; esac # Use $KISS_ROOT in filename so that we follow its symlinks. file=$KISS_ROOT/${file#/} # We will only follow the symlinks of the directories, so we # reserve the directory name in this 'dirname' value. kiss-readlink # functions in a similar fashion to 'readlink -f', it makes sure # every component except for the first one to be available on # the directory structure. If we cannot find it in the system, # we don't need to make this much more complex by trying so # hard to find it. Simply use the original directory name. dirname="$(kiss-readlink "${file%/*}" 2>/dev/null)" || dirname="${file%/*}" # Combine the dirname and file values, and print them into the # temporary manifest to be parsed. printf '%s/%s\n' "${dirname#$KISS_ROOT}" "${file##*/}" done < "$tar_dir/$1/$pkg_db/$1/manifest" > "$KISS_TMPDIR/$pid-m" p_name=$1 # Generate a list of all installed package manifests # and remove the current package from the list. # shellcheck disable=2046,2086 set -- $(set +f; pop "$sys_db/$p_name/manifest" from "$sys_db"/*/manifest) [ -s "$KISS_TMPDIR/$pid-m" ] || return 0 # In rare cases where the system only has one package installed # and you are reinstalling that package, grep will try to read from # standard input if we continue here. # # Also, if we don't have any packages installed grep will give an # error. This will not cause the installation to fail, but we don't # need to check for conflicts if that's the case anyway. If we have # only zero packages or one package, just stop wasting time and continue # with the installation. [ "$1" ] && [ -f "$1" ] || return 0 # Store the list of found conflicts in a file as we will be using the # information multiple times. Storing it in the cache dir allows us # to be lazy as they'll be automatically removed on script end. "$grep" -Fxf "$KISS_TMPDIR/$pid-m" -- "$@" > "$KISS_TMPDIR/$pid-c" ||: # Enable alternatives automatically if it is safe to do so. # This checks to see that the package that is about to be installed # doesn't overwrite anything it shouldn't in '/var/db/kiss/installed'. "$grep" -q ":/var/db/kiss/installed/" "$KISS_TMPDIR/$pid-c" || choice_auto=1 # Use 'grep' to list matching lines between the to # be installed package's manifest and the above filtered # list. if [ "$KISS_CHOICE" != 0 ] && [ "$choice_auto" = 1 ]; then # This is a novel way of offering an "alternatives" system. # It is entirely dynamic and all "choices" are created and # destroyed on the fly. # # When a conflict is found between two packages, the file # is moved to a directory called "choices" and its name # changed to store its parent package and its intended # location. # # The package's manifest is then updated to reflect this # new location. # # The 'kiss choices' command parses this directory and # offers you the CHOICE of *swapping* entries in this # directory for those on the filesystem. # # The choices command does the same thing we do here, # it rewrites manifests and moves files around to make # this work. # # Pretty nifty huh? while IFS=: read -r _ con; do printf '%s\n' "Found conflict $con" # Create the "choices" directory inside of the tarball. # This directory will store the conflicting file. mkdir -p "$tar_dir/$p_name/${cho_dir:=var/db/kiss/choices}" # Construct the file name of the "db" entry of the # conflicting file. (pkg_name>usr>bin>ls) con_name=$(printf %s "$con" | sed 's|/|>|g') # Move the conflicting file to the choices directory # and name it according to the format above. mv -f "$tar_dir/$p_name/$con" \ "$tar_dir/$p_name/$cho_dir/$p_name$con_name" 2>/dev/null || { log "File must be in ${con%/*} and not a symlink to it" log "This usually occurs when a binary is installed to" log "/sbin instead of /usr/bin (example)" log "Before this package can be used as an alternative," log "this must be fixed in $p_name. Contact the maintainer" die "by checking 'git log' or by running 'kiss-maintainer'" } done < "$KISS_TMPDIR/$pid-c" # Rewrite the package's manifest to update its location # to its new spot (and name) in the choices directory. pkg_manifest "$p_name" "$tar_dir" 2>/dev/null elif [ -s "$KISS_TMPDIR/$pid-c" ]; then log "Package '$p_name' conflicts with another package" "" "!>" log "Run 'KISS_CHOICE=1 kiss i $p_name' to add conflicts" "" "!>" die "as alternatives." fi } pkg_swap() { # Swap between package alternatives. pkg_list "$1" >/dev/null alt=$(printf %s "$1$2" | sed 's|/|>|g') cd "$sys_db/../choices" [ -f "$alt" ] || [ -h "$alt" ] || die "Alternative '$1 $2' doesn't exist" if [ -f "$2" ]; then # Figure out which package owns the file we are going to # swap for another package's. # # Print the full path to the manifest file which contains # the match to our search. pkg_owns=$(set +f; "$grep" -lFx "$2" "$sys_db/"*/manifest) ||: # Extract the package name from the path above. pkg_owns=${pkg_owns%/*} pkg_owns=${pkg_owns##*/} [ "$pkg_owns" ] || die "File '$2' exists on filesystem but isn't owned" log "Swapping '$2' from '$pkg_owns' to '$1'" # Convert the current owner to an alternative and rewrite # its manifest file to reflect this. We then resort this file # so no issues arise when removing packages. cp -Pf "$KISS_ROOT/$2" "$pkg_owns>${alt#*>}" sed "s#^$2#${PWD#$KISS_ROOT}/$pkg_owns>${alt#*>}#" \ "../installed/$pkg_owns/manifest" | sort -r -o "../installed/$pkg_owns/manifest" fi # Convert the desired alternative to a real file and rewrite # the manifest file to reflect this. The reverse of above. mv -f "$alt" "$KISS_ROOT/$2" sed "s#^${PWD#$KISS_ROOT}/$alt#$2#" "../installed/$1/manifest" | sort -r -o "../installed/$1/manifest" } pkg_etc() { [ -d "$tar_dir/$pkg_name/etc" ] || return 0 (cd "$tar_dir/$pkg_name" # Create all directories beforehand. find etc -type d | while read -r dir; do mkdir -p "$KISS_ROOT/$dir" done # Handle files in /etc/ based on a 3-way checksum check. find etc ! -type d | while read -r file; do { sum_new=$(hashcheck "$file") sum_sys=$(cd "$KISS_ROOT/"; hashcheck "$file") sum_old=$("$grep" "$file$" "$mak_dir/c"); } 2>/dev/null ||: log "$pkg_name" "Doing 3-way handshake for $file" printf '%s\n' "Previous: ${sum_old:-null}" printf '%s\n' "System: ${sum_sys:-null}" printf '%s\n' "New: ${sum_new:-null}" # Use a case statement to easily compare three strings at # the same time. Pretty nifty. case ${sum_old:-null}${sum_sys:-null}${sum_new} in # old = Y, sys = X, new = Y "${sum_new}${sum_sys}${sum_old}") log "Skipping $file" continue ;; # old = X, sys = X, new = X # old = X, sys = Y, new = Y # old = X, sys = X, new = Y "${sum_old}${sum_old}${sum_old}"|\ "${sum_old:-null}${sum_sys}${sum_sys}"|\ "${sum_sys}${sum_old}"*) log "Installing $file" new= ;; # All other cases. *) warn "($pkg_name) saving /$file as /$file.new" "->" new=.new ;; esac cp -fPp "$file" "$KISS_ROOT/${file}${new}" chown root:root "$KISS_ROOT/${file}${new}" 2>/dev/null done) ||: } pkg_remove() { # Remove a package and all of its files. The '/etc' directory # is handled differently and configuration files are *not* # overwritten. pkg_list "$1" >/dev/null || return set +f # Make sure that nothing depends on this package. [ "$2" = check ] && for file in "$sys_db/"*; do # Check each depends file for the package and if it's # a run-time dependency, append to the $required_by string. "$grep" -qFx "$1" "$file/depends" 2>/dev/null && required_by="$required_by'${file##*/}', " done [ "$required_by" ] && die "$1" "Package is required by ${required_by%, }" set -f # Block being able to abort the script with 'Ctrl+C' during removal. # Removes all risk of the user aborting a package removal leaving # an incomplete package installed. trap '' INT if [ -x "$sys_db/$1/pre-remove" ]; then log "$1" "Running pre-remove script" "$sys_db/$1/pre-remove" ||: fi while read -r file; do # The file is in '/etc' skip it. This prevents the package # manager from removing user edited configuration files. [ "${file##/etc/*}" ] || continue if [ -d "$KISS_ROOT/$file" ]; then rmdir "$KISS_ROOT/$file" 2>/dev/null || continue else rm -f "$KISS_ROOT/$file" fi done < "$sys_db/$1/manifest" # Reset 'trap' to its original value. Removal is done so # we no longer need to block 'Ctrl+C'. trap pkg_clean EXIT INT log "$1" "Removed successfully" } pkg_install() { # Install a built package tarball. # Install can also take the full path to a tarball. # We don't need to check the repository if this is the case. if [ -f "$1" ] && [ -z "${1%%*.tar*}" ] ; then tar_file=$1 pkg_name=${1##*/} pkg_name=${pkg_name%#*} else pkg_cache "$1" || die "package has not been built, run 'kiss b pkg'" pkg_name=$1 fi mkdir -p "$tar_dir/$pkg_name" log "$pkg_name" "Extracting $tar_file" # Extract the tarball to catch any errors before installation begins. decompress "$tar_file" | "$tar" xf - -C "$tar_dir/$pkg_name" [ -f "$tar_dir/$pkg_name/$pkg_db/$pkg_name/manifest" ] || die "'${tar_file##*/}' is not a valid KISS package" # Ensure that the tarball's manifest is correct by checking that # each file and directory inside of it actually exists. [ -z "$KISS_FORCE" ] && log "$pkg_name" "Checking package manifest" && while read -r line; do # Skip symbolic links [ -h "$tar_dir/$pkg_name/$line" ] || [ -e "$tar_dir/$pkg_name/$line" ] || { log "File $line missing from tarball but mentioned in manifest" "" "!>" TARBALL_FAIL=1 } done < "$tar_dir/$pkg_name/$pkg_db/$pkg_name/manifest" [ "$TARBALL_FAIL" ] && { log "You can still install this package by setting KISS_FORCE variable" die "$pkg_name" "Missing files in manifest" } log "$pkg_name" "Checking that all dependencies are installed" # Make sure that all run-time dependencies are installed prior to # installing the package. [ -f "$tar_dir/$pkg_name/$pkg_db/$pkg_name/depends" ] && [ -z "$KISS_FORCE" ] && while read -r dep dep_type || [ "$dep" ]; do [ "${dep##\#*}" ] || continue [ "$dep_type" ] || pkg_list "$dep" >/dev/null || install_dep="$install_dep'$dep', " done < "$tar_dir/$pkg_name/$pkg_db/$pkg_name/depends" [ "$install_dep" ] && die "$1" "Package requires ${install_dep%, }" run_hook pre-install "$pkg_name" "$tar_dir/$pkg_name" pkg_conflicts "$pkg_name" log "$pkg_name" "Installing package incrementally" # Block being able to abort the script with Ctrl+C during installation. # Removes all risk of the user aborting a package installation leaving # an incomplete package installed. trap '' INT # If the package is already installed (and this is an upgrade) make a # backup of the manifest and etcsums files. cp -f "$sys_db/$pkg_name/manifest" "$mak_dir/m" 2>/dev/null ||: cp -f "$sys_db/$pkg_name/etcsums" "$mak_dir/c" 2>/dev/null ||: # This is repeated multiple times. Better to make it a function. pkg_rsync() { rsync "--chown=$USER:$USER" --chmod=Du-s,Dg-s,Do-s \ -WhHKa --no-compress --exclude /etc "${1:---}" \ "$tar_dir/$pkg_name/" "$KISS_ROOT/" } # Install the package by using 'rsync' and overwrite any existing files # (excluding '/etc/'). pkg_rsync --info=progress2 pkg_etc # Remove any leftover files if this is an upgrade. "$grep" -vFxf "$sys_db/$pkg_name/manifest" "$mak_dir/m" 2>/dev/null | while read -r file; do file=$KISS_ROOT/$file # Skip deleting some leftover files. case $file in /etc/*) continue; esac # Remove files. if [ -f "$file" ] && [ ! -L "$file" ]; then rm -f "$file" # Remove file symlinks. elif [ -h "$file" ] && [ ! -d "$file" ]; then unlink "$file" ||: # Skip directory symlinks. elif [ -h "$file" ] && [ -d "$file" ]; then : # Remove directories if empty. elif [ -d "$file" ]; then rmdir "$file" 2>/dev/null ||: fi done ||: log "$pkg_name" "Verifying installation" { pkg_rsync; pkg_rsync; } ||: # Reset 'trap' to its original value. Installation is done so # we no longer need to block 'Ctrl+C'. trap pkg_clean EXIT INT if [ -x "$sys_db/$pkg_name/post-install" ]; then log "$pkg_name" "Running post-install script" "$sys_db/$pkg_name/post-install" ||: fi run_hook post-install "$pkg_name" "$sys_db/$pkg_name" log "$pkg_name" "Installed successfully" } pkg_fetch() { log "Updating repositories" # Create a list of all repositories. # See [1] at top of script. # shellcheck disable=2046,2086 { IFS=:; set -- $KISS_PATH; unset IFS; } # Update each repository in '$KISS_PATH'. It is assumed that # each repository is 'git' tracked. for repo do # Go to the root of the repository (if it exists). cd "$repo" cd "$(git rev-parse --show-toplevel 2>/dev/null)" 2>/dev/null ||: [ -d .git ] || { log "$repo" " " printf '%s\n' "Not a git repository, skipping." continue } [ "$(git remote 2>/dev/null)" ] || { log "$repo" " " printf '%s\n' "No remote, skipping." continue } contains "$repos" "$PWD" || { repos="$repos $PWD " # Display a tick if signing is enabled for this # repository. case $(git config merge.verifySignatures) in true) log "$PWD" "[signed ✓] " ;; *) log "$PWD" " " ;; esac if [ -w "$PWD" ] && [ "$uid" != 0 ]; then git fetch git merge ! [ -e .gitmodules ] || { git submodule init git submodule update } else [ "$uid" = 0 ] || log "$PWD" "Need root to update" # Find out the owner of the repository and spawn # git as this user below. # # This prevents 'git' from changing the original # ownership of files and directories in the rare # case that the repository is owned by a 3rd user. ( user=$(kiss-stat "$PWD") || user=root id -u "$user" >/dev/null 2>&1 || user=root [ "$user" = root ] || log "Dropping permissions to $user for pull" case $su in su) "$su" -c "git fetch && git merge && { ! [ -e .gitmodules ] || { git submodule init ; git submodule update ;} ;}" "$user" ;; *) "$su" -u "$user" git fetch "$su" -u "$user" git merge ! [ -e .gitmodules ] || { "$su" -u "$user" git submodule init "$su" -u "$user" git submodule update } esac ) fi } done } pkg_updates(){ # Check all installed packages for updates. So long as the installed # version and the version in the repositories differ, it's considered # an update. pkg_fetch log "Checking for new package versions" set +f for pkg in "$sys_db/"*; do pkg_name=${pkg##*/} # Read version and release information from the installed packages # and repository. read -r db_ver db_rel < "$pkg/version" read -r re_ver re_rel < "$(pkg_find "$pkg_name")/version" # Compare installed packages to repository packages. [ "$db_ver-$db_rel" != "$re_ver-$re_rel" ] && { printf '%s\n' "$pkg_name $db_ver-$db_rel ==> $re_ver-$re_rel" outdated="$outdated$pkg_name " } done set -f # If the download option is specified only download the outdated packages # and exit. [ "$download" ] && { for pkg in $outdated; do pkg_sources "$pkg" done exit 0 } contains "$outdated" kiss && { log "Detected package manager update" log "The package manager will be updated first" prompt || exit 0 pkg_build kiss args i kiss log "Updated the package manager" log "Re-run 'kiss update' to update your system" exit 0 } [ "$outdated" ] || { log "Everything is up to date" return } log "Packages to update: ${outdated% }" # Tell 'pkg_build' to always prompt before build. pkg_update=1 # Build all packages requiring an update. # See [1] at top of script. # shellcheck disable=2046,2086 { pkg_order $outdated pkg_build $order } log "Updated all packages" } pkg_clean() { # Clean up on exit or error. This removes everything related # to the build. [ "$KISS_DEBUG" != 1 ] || return # Block 'Ctrl+C' while cache is being cleaned. trap '' INT # Remove temporary items. rm -rf -- "$mak_dir" "$pkg_dir" "$tar_dir" \ "$KISS_TMPDIR/$pid-c" "$KISS_TMPDIR/$pid-m" } args() { # Parse script arguments manually. This is rather easy to do in # our case since the first argument is always an "action" and # the arguments that follow are all package names. action=$1 # 'dash' gives an error when shift is used without any arguments. [ "$1" ] && shift # Unless this is a search, sanitize the user's input. The call to # 'pkg_find()' supports basic globbing, ensure input doesn't expand # to anything except for when this behavior is needed. # # This handles the globbing characters '*', '!', '[' and ']' as per: # https://pubs.opengroup.org/onlinepubs/009695399/utilities/xcu_chap02.html [ "${action##[as]*}" ] && case $* in *\**|*\!*|*\[*|*\]*) die "Arguments contain invalid characters: '!*[]'" esac # Parse some arguments earlier to remove the need to duplicate code. case $action in s|search) [ "$1" ] || die "'kiss $action' requires an argument" ;; a|alternatives) # Rerun the script with 'su' if the user isn't root. # Cheeky but 'su' can't be used on shell functions themselves. [ -z "$1" ] || [ -w "$KISS_ROOT/" ] || [ "$uid" = 0 ] || { as_root "$0" "$action" "$@" return } ;; i|install|r|remove) # Rerun the script with 'su' if the user does not have write # permissions for the root. Cheeky but 'su' can't be used on # shell functions themselves. [ -w "$KISS_ROOT/" ] || [ "$uid" = 0 ] || { KISS_FORCE="$KISS_FORCE" as_root "$0" "$action" "$@" return } ;; esac case $action in b|build|c|checksum|i|install|r|remove) [ "$1" ] || { # We are exporting the KISS_PATH, so if another # instance of 'kiss' is spawned from the current # one, they continue to use the same KISS_PATH export KISS_PATH="${PWD%/*}:$KISS_PATH" set -- "${PWD##*/}" } ; esac # Actions can be abbreviated to their first letter. This saves # keystrokes once you memorize the commands. # # This is to fix a shellcheck warning when using $PATH # in kiss extensions help string. # shellcheck disable=2016 case $action in a|alternatives) if [ "$1" = - ]; then while read -r pkg path; do pkg_swap "$pkg" "$path" done elif [ "$1" ]; then pkg_swap "$@" else # Go over each alternative and format the file # name for listing. (pkg_name>usr>bin>ls) set +f; for pkg in "$sys_db/../choices"/*; do printf '%s\n' "${pkg##*/}" done | sed 's|>| /|; s|>|/|g; /\*/d' fi ;; c|checksum) for pkg do pkg_lint "$pkg" c; done for pkg do pkg_sources "$pkg" c; done for pkg do pkg_checksums "$pkg" | { repo_dir=$(pkg_find "$pkg") if [ -w "$repo_dir" ]; then tee "$repo_dir/checksums" else log "$pkg" "Need permissions to generate checksums" user=$(kiss-stat "$repo_dir") as_root tee "$repo_dir/checksums" fi } log "$pkg" "Generated checksums" done ;; f|fetch) pkg_fetch ;; i|install) pkg_order "$@" for pkg in $order; do pkg_install "$pkg"; done # After installation is complete, show a list # of messages from packages. log "Retrieving post-installation message queue" unset msg for pkg in $order; do if [ -f "$sys_db/$pkg/message" ]; then printf '%s\n%b%s%b\n%s\n\n' \ "==============================" \ "${color:+"\033[1m"}" "$pkg" "${color:+"\033[m"}" \ "==============================" >&2 cat "$sys_db/$pkg/message" >&2 msg=1 fi [ "$msg" ] || log "No message in queue" done ;; e|extension) exec 2>&1 log "Installed extensions" set -- for path in $(SEARCH_PATH=$PATH pkg_find kiss-* all -x); do set -- "${path#*/kiss-}" "$@" max=$((${#1} > max ? ${#1} : max)) done for path do # These are binary files so they should be ignored contains "readlink stat" "$path" && continue printf '%b->%b %-*s ' "${color:+"\033[1;31m"}" "${color:+"\033[m"}" \ "$max" "${path#*/kiss-}" sed -n 's/^# *//;2p' "$(command -v "kiss-$path")" done | sort -uk1 >&2 ;; r|remove) pkg_order "$@" for pkg in $redro; do pkg_remove "$pkg" "${KISS_FORCE:-check}" done ;; d|download) # If no arguments are given, download the sources # for outdated packages. [ "$1" ] || { download=1; pkg_updates ;} # Acquire sources for all given packages. for pkg do pkg_sources "$pkg"; done ;; b|build) pkg_build "${@:?No packages installed}" ;; l|list) pkg_list "$@" ;; u|update) pkg_updates ;; s|search) for pkg do pkg_find "$pkg" all; done ;; v|version) log kiss 1.22.2 ;; h|help|-h|--help|'') exec 2>&1 log 'kiss [a|b|c|d|e|f|i|l|r|s|u|v] [pkg] [pkg] [pkg]' log 'alternatives List and swap to alternatives' log 'build Build a package' log 'checksum Generate checksums' log 'download Download sources for the given package' log 'extension List available kiss extensions (kiss-* in $PATH)' log 'fetch Fetch repositories' log 'install Install a package' log 'list List installed packages' log 'remove Remove a package' log 'search Search for a package' log 'update Check for updates' log 'version Package manager version' ;; *) util=$(SEARCH_PATH=$PATH pkg_find "kiss-$action"* "" -x 2>/dev/null) || die "'kiss $action' is not a valid command" "$util" "$@" ;; esac } main() { # Die here if the user has no set KISS_PATH. This is a rare occurance # as the environment variable should always be defined. [ "$KISS_PATH" ] || die "\$KISS_PATH needs to be set" # Set the location to the repository and package database. pkg_db=var/db/kiss/installed # The PID of the current shell process is used to isolate directories # to each specific KISS instance. This allows multiple package manager # instances to be run at once. Store the value in another variable so # that it doesn't change beneath us. pid=${KISS_PID:-$$} # Force the C locale to speed up things like 'grep' which disable unicode # etc when this is set. We don't need unicode and a speed up is always # welcome. export LC_ALL=C LANG=C # Catch errors and ensure that build files and directories are cleaned # up before we die. This occurs on 'Ctrl+C' as well as success and error. trap pkg_clean EXIT INT # Prefer GNU grep if installed as it is much much faster than busybox's # implementation. Very much worth it if you value performance over # POSIX correctness (grep quoted to avoid shellcheck false-positive). grep=$(command -v ggrep) || grep='grep' # Prefer libarchive tar or GNU tar if installed as they are much # much faster than busybox's implementation. Very much worth it if # you value performance. tar=$(command -v bsdtar || command -v gtar) || tar=tar # Figure out which 'sudo' command to use based on the user's choice or # what is available on the system. su=${KISS_SU:-$(command -v sudo || command -v doas)} || su=su # Store the date and time of script invocation to be used as the name # of the log files the package manager creates uring builds. time=$(date '+%Y-%m-%d-%H:%M') # Make note of the user's current ID to do root checks later on. # This is used enough to warrant a place here. uid=$(id -u) # Make sure that the KISS_ROOT doesn't end with a '/'. This might # break some operations. [ -z "$KISS_ROOT" ] || [ "${KISS_ROOT##*/}" ] || { warn "Your KISS_ROOT variable shouldn't end with '/'" KISS_ROOT=${KISS_ROOT%/} } # Define this variable but don't create its directory structure from # the get go. It will be created as needed by package installation. sys_db=$KISS_ROOT/$pkg_db # This allows for automatic setup of a KISS chroot and will # do nothing on a normal system. mkdir -p "$KISS_ROOT/" 2>/dev/null ||: # A temporary directory can be specified apart from the cache # directory in order to build in a user specified directory. # /tmp could be used in order to build on ram, useful on SSDs. # The user can specify KISS_TMPDIR for this. # # Create the required temporary directories and set the variables # which point to them. mkdir -p "${cac_dir:=${XDG_CACHE_HOME:-$HOME/.cache}/kiss}" \ "${KISS_TMPDIR:=$cac_dir}" \ "${mak_dir:=$KISS_TMPDIR/build-$pid}" \ "${pkg_dir:=$KISS_TMPDIR/pkg-$pid}" \ "${tar_dir:=$KISS_TMPDIR/extract-$pid}" \ "${src_dir:=$cac_dir/sources}" \ "${log_dir:=$cac_dir/logs}" \ "${bin_dir:=$cac_dir/bin}" # Disable color escape sequences if running in a subshell. # This behaviour can be changed by adding a KISS_COLOR # variable to the environment. If it is set to 1 it will # always enable color escapes, and if set to 0 it will # always disable color escapes. if [ "$KISS_COLOR" = 1 ]; then color=1 elif [ "$KISS_COLOR" = 0 ] || ! [ -t 1 ]; then log() { printf '%s %s %s\n' "${3:-->}" "$1" "$2" >&2 ;} else color=1 fi args "$@" } main "$@"