#!/bin/sh # shellcheck source=/dev/null # # Simple package manager written in POSIX shell for https://kisslinux.xyz # # The MIT License (MIT) # # Copyright (c) 2019-2021 Dylan Araps # # Permission is hereby granted, free of charge, to any person obtaining a copy # of this software and associated documentation files (the "Software"), to deal # in the Software without restriction, including without limitation the rights # to use, copy, modify, merge, publish, distribute, sublicense, and/or sell # copies of the Software, and to permit persons to whom the Software is # furnished to do so, subject to the following conditions: # # The above copyright notice and this permission notice shall be included in all # copies or substantial portions of the Software. # # THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR # IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, # FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE # AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER # LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, # OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE # SOFTWARE. log() { printf '%b%s %b%s%b %s\n' \ "$c1" "${3:-->}" "${c3}${2:+$c2}" "$1" "$c3" "$2" >&2 } war() { log "$1" "$2" "${3:-WARNING}" } die() { log "$1" "$2" "${3:-ERROR}" exit 1 } contains() { # Check if a "string list" contains a word. case " $1 " in *" $2 "*) return 0; esac; return 1 } tmp_file() { # Create a uniquely named temporary file and store its absolute path # in a variable (_tmp_file). # # To prevent subshell usage and to handle cases where multiple files # are needed, this saves the last two temporary files to variables # for access by the caller (allowing 3 files at once). _tmp_file_pre_pre=$_tmp_file_pre _tmp_file_pre=$_tmp_file _tmp_file=$tmp_dir/$KISS_PID-$1-$2 : > "$_tmp_file" || die "$1" "Failed to create temporary file" } tmp_file_copy() { # Create a uniquely named temporary file and make a duplicate of # the file in '$3' if it exists. tmp_file "$1" "$2" ! [ -f "$3" ] || cp -f "$3" "$_tmp_file" } prompt() { [ "$1" ] && log "$1" log "Continue?: Press Enter to continue or Ctrl+C to abort" # korn-shell does not exit on interrupt of read. [ "$KISS_PROMPT" = 0 ] || read -r _ || exit 1 } mkcd() { mkdir -p "$@" && cd "$1" } as_root() { case $uid/${user:=root}/${cmd_su##*/} in 0/root/*) "$@" ;; */doas|*/sudo|*/ssu) log "Using '$cmd_su' (to become $user)" "$cmd_su" -u "$user" -- "$@" ;; */su) log "Using 'su' (to become $user)" printf 'Note: su will ask for password every time.\n%s\n' \ ' Use doas, sudo or ssu for more control.' "$cmd_su" -c "$* <&3" "$user" 3<&0 /dev/null 2>&1 || user=root } pkg_owner() { set +f [ "$3" ] || set -- "$1" "$2" "$sys_db"/*/manifest pkg_owner=$(grep "$@") pkg_owner=${pkg_owner%/*} pkg_owner=${pkg_owner##*/} set -f [ "$pkg_owner" ] } run_hook() { # Run all hooks in KISS_HOOK (a colon separated # list of absolute file paths). IFS=: for hook in ${KISS_HOOK:-}; do case $hook in *?*) "$hook" "$@" || die "$1 hook failed: '$hook'" esac done unset IFS } run_hook_pkg() { # Run a hook from the package's database files. if [ -x "$sys_db/$2/$1" ]; then log "$2" "Running $1 hook" "$sys_db/$2/$1" elif [ -f "$sys_db/$2/$1" ]; then war "$2" "skipping $1 hook: not executable" fi } decompress() { case $1 in *.tbz|*.bz2) bzip2 -d ;; *.lzma) lzma -dc ;; *.lz) lzip -dc ;; *.tar) cat ;; *.tgz|*.gz) gzip -d ;; *.xz|*.txz) xz -dcT0 ;; *.zst) zstd -dc ;; esac < "$1" } sh256() { # There's no standard utility to generate sha256 checksums. # This is a simple wrapper around sha256sum, sha256, shasum, # openssl, digest, ... which will use whatever is available. # # All utilities must match 'sha256sum' output. # # Example: ' ' hash= if [ ! -d "$1" ] && [ -e "$1" ]; then hash=$( openssl dgst -sha256 -r "$1" || sha256sum "$1" || sha256 -r "$1" || shasum -a 256 "$1" || digest -a sha256 "$1" ) 2>/dev/null || die "Failed to generate checksums for '$1'" hash=${hash%% *} printf '%s\n' "$hash" fi } pkg_lint() { pkg_find_version "$1" [ "$repo_rel" ] || die "$1" "Release field not found in version file" [ -x "$repo_dir/build" ] || die "$1" "Build file not found or not executable" [ -f "$repo_dir/sources" ] || war "$1" "Sources file not found" } pkg_find_version() { pkg_find_die "$1" read -r repo_ver repo_rel 2>/dev/null < "$repo_dir/version" || die "$1" "Failed to read version file ($repo_dir/version)" # Split the version on '.+-_' to obtain individual components. IFS=.+-_ read -r repo_major repo_minor repo_patch repo_ident </dev/null < "$_list_pkg/version" || version=null printf '%s\n' "${_list_pkg##*/} $version" done } pkg_cache() { # Find the tarball of a package using a glob. Use the user's set compression # method if found or first match of the below glob. pkg_find_version "$1" set +f -- "$bin_dir/$1@$repo_ver-$repo_rel.tar." set -f -- "$1$KISS_COMPRESS" "$1"* tar_file=$1 # Found tarball matching KISS_COMPRESS. ! [ -f "$1" ] || return 0 tar_file=$2 # Use result of glob. [ -f "$2" ] } source_resolve_vars() { # Replace all occurrences of markers with their respective values # if found in the source string. _src_sub() { _src_res=${_src_res%"$1"*}${2}${_src_res##*"$1"}; } _src_res=$1 # Loop until no identifiers are found and all have been removed. # This works backwards replacing each identifier with its value. while :; do case $_src_res in *VERSION*) _src_sub VERSION "$repo_ver" ;; *RELEASE*) _src_sub RELEASE "$repo_rel" ;; *MAJOR*) _src_sub MAJOR "$repo_major" ;; *MINOR*) _src_sub MINOR "$repo_minor" ;; *PATCH*) _src_sub PATCH "$repo_patch" ;; *IDENT*) _src_sub IDENT "$repo_ident" ;; *PKG*) _src_sub PKG "${repo_dir##*/}" ;; *) break esac done } pkg_source_resolve() { # Given a line of input from the sources file, return an absolute # path to the source if it already exists, error if not. source_resolve_vars "${2%"${2##*[!/]}"}" set -- "$1" "$_src_res" "${3%"${3##*[!/]}"}" "$4" if [ -z "${2##\#*}" ]; then _res= return # Git repository. elif [ -z "${2##git+*}" ]; then _res=$2 # Remote source (cached). elif [ -f "$src_dir/$1/${3:+"$3/"}${2##*/}" ]; then _res=$src_dir/$1/${3:+"$3/"}${2##*/} # Remote source. elif [ -z "${2##*://*}" ]; then _res=url+$2 _des=$src_dir/$1/${3:+"$3/"}${2##*/} # Local relative dir. elif [ -d "$repo_dir/$2" ]; then _res=$repo_dir/$2/. # Local absolute dir. elif [ -d "/${2##/}" ]; then _res=/${2##/}/. # Local relative file. elif [ -f "$repo_dir/$2" ]; then _res=$repo_dir/$2 # Local absolute file. elif [ -f "/${2##/}" ]; then _res=/${2##/} else die "$1" "No local file '$src'" fi [ "$4" ] || printf 'found %s\n' "$_res" } pkg_source() { # Download any remote package sources. The existence of local files is # also checked. pkg_find_version "$1" # Support packages without sources. Simply do nothing. [ -f "$repo_dir/sources" ] || return 0 log "$1" "Checking sources" mkcd "$src_dir/$1" while read -r src dest || [ "$src" ]; do pkg_source_resolve "$1" "$src" "$dest" "$2" case $_res in url+*) log "$1" "Downloading ${_res##url+}" mkdir -p "$PWD/$dest" curl -fLo "$_des" "${_res##url+}" || { rm -f "$_des" die "$1" "Failed to download ${_res##url+}" } esac done < "$repo_dir/sources" } pkg_extract_tar_hack() { # This is a portable shell implementation of GNU tar's # '--strip-components 1'. Use of this function denotes a # performance penalty. tmp_file "$1" tarball tmp_file "$1" tarball-manifest decompress "$2" > "$_tmp_file_pre" || die "$1" "Failed to decompress $2" tar xf "$_tmp_file_pre" || die "$1" "Failed to extract $2" tar tf "$_tmp_file_pre" > "$_tmp_file" || die "$1" "Failed to extract manifest" # Iterate over all directories in the first level of the # tarball's manifest. Each directory is moved up a level. while IFS=/ read -r dir _; do case ${dir#.} in *?*) # Skip duplicate directories. ! contains "$_seen" "$dir" || continue && _seen="$_seen $dir" # Move the parent directory to prevent naming conflicts # with the to-be-moved children. mv -f "$dir" "$KISS_PID-$dir" # Move all children up a directory level. If the mv command # fails, fallback to copying the remainder of the files. # # We can't use '-exec {} +' with any arguments between # the '{}' and '+' as this is not POSIX. We must also # use '$0' and '$@' to reference all arguments. find "$KISS_PID-$dir/." ! -name . -prune \ -exec sh -c 'mv -f "$0" "$@" .' {} + 2>/dev/null || find "$KISS_PID-$dir/." ! -name . -prune \ -exec sh -c 'cp -fRp "$0" "$@" .' {} + # Remove the directory now that all files have been # transferred out of it. This can't be a simple 'rmdir' # as we may leave files in here if any were copied. rm -rf "$KISS_PID-$dir" esac done < "$_tmp_file" # Remove the tarball now that we are done with it. rm -f "$_tmp_file_pre" } pkg_extract() { # Extract all source archives to the build directory and copy over any # local repository files. # # NOTE: repo_dir comes from caller. # Support packages without sources. Simply do nothing. [ -f "$repo_dir/sources" ] || return 0 log "$1" "Extracting sources" while read -r src dest || [ "$src" ]; do pkg_source_resolve "$1" "$src" "$dest" >/dev/null # Create the source's directories if not null. case $_res in *?*) mkcd "$mak_dir/$1/$dest" esac case $_res in '') ;; git+*) # Split the source into URL + OBJECT (branch or commit). url=${_res##git+} com=${url##*[@#]} com=${com#${url%[#@]*}} # This magic will shallow clone branches, commits or the # regular repository. It correctly handles cases where a # shallow clone is not possible. log "$1" "Cloning ${url%[#@]*}" git init git remote add origin "${url%[#@]*}" git fetch -t --filter=tree:0 origin "$com" || git fetch -t git -c advice.detachedHead=0 checkout "${com:-FETCH_HEAD}" ;; *.tar|*.tar.??|*.tar.???|*.tar.????|*.t?z) pkg_extract_tar_hack "$1" "$_res" ;; *.zip) unzip "$_res" ;; *) cp -Rf "$_res" . ;; esac done < "$repo_dir/sources" || die "$1" "Failed to extract $_res" } pkg_depends() { # Resolve all dependencies and generate an ordered list. The deepest # dependencies are listed first and then the parents in reverse order. contains "$deps" "$1" || { # Filter out non-explicit, already installed packages. [ -z "$3" ] || [ "$2" ] || contains "$explicit" "$1" || ! pkg_list "$1" >/dev/null 2>&1 || return # Detect circular dependencies and bail out. # Looks for multiple repeating patterns of (dep dep_parent) (5 is max). case " $4 " in *" ${4##* } "*" $1 "\ *" ${4##* } "*" $1 "\ *" ${4##* } "*" $1 "\ *" ${4##* } "*" $1 "\ *" ${4##* } "*" $1 "\ *) die "Circular dependency detected $1 <> ${4##* }" esac ! "${6:-pkg_find}" "$1" || ! [ -e "$repo_dir/depends" ] || # Recurse through the dependencies of the child packages. while read -r dep dep_type || [ "$dep" ]; do [ "${dep##\#*}" ] || continue pkg_depends "$dep" '' "$3" "$4 $1" "$dep_type" "$6" done < "$repo_dir/depends" || : # Add parent to dependencies list. if [ "$2" != expl ] || { [ "$5" = make ] && ! pkg_cache "$1"; }; then deps="$deps $1" fi } } 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'. unset order redro deps for pkg do case $pkg in /*@*.tar.*) deps="$deps $pkg" ;; *@*.tar.*) deps="$deps $ppwd/$pkg" ;; */*) die "Not a package' ($pkg)" ;; *) pkg_depends "$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 case " $* " in *" $pkg "* | *" ${pkg##"$ppwd/"} "*) order="$order $pkg" redro="$pkg $redro" esac done unset deps } pkg_strip() { # Strip package binaries and libraries. This saves space on the system as # well as on the tarballs we ship for installation. [ -f "$mak_dir/$pkg/nostrip" ] || [ "$KISS_STRIP" = 0 ] && return log "$1" "Stripping binaries and libraries" # Strip only files matching the below ELF types. This uses 'od' to print # the first 18 bytes of the file. This is the location of the ELF header # (up to the ELF type) and contains the type information we need. # # Static libraries (.a) are in reality AR archives which contain ELF # objects. We simply read from the same 18 bytes and assume that the AR # header equates to an archive containing objects (.o). # # Example ELF output ('003' is ELF type): # 0000000 177 E L F 002 001 001 \0 \0 \0 \0 \0 \0 \0 \0 \0 # 0000020 003 \0 # 0000022 # # Example AR output (.a): # 0000000 ! < a r c h > \n / # 0000020 # 0000022 find "$pkg_dir/$1" -type f | while read -r file; do case $(od -A o -t c -N 18 "$file") in # REL (object files (.o), static libraries (.a)). *177*E*L*F*0000020\ 001\ *|*\!*\<*a*r*c*h*\>*) strip -g -R .comment -R .note "$file" ;; # EXEC (binaries), DYN (shared libraries). # Shared libraries keep global symbols in a separate ELF section # called '.dynsym'. '--strip-all/-s' does not touch the dynamic # symbol entries which makes this safe to do. *177*E*L*F*0000020\ 00[23]\ *) strip -s -R .comment -R .note "$file" ;; esac done 2>/dev/null || : } pkg_fix_deps() { # 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" "looking for dependencies (using ${cmd_elf##*/})" cd "$pkg_dir/$1/$pkg_db/$1" set +f set -f -- "$sys_db/"*/manifest tmp_file_copy "${PWD##*/}" depends depends tmp_file "${PWD##*/}" depends-fixed find "$pkg_dir/${PWD##*/}/" -type f 2>/dev/null | while read -r _fix_file; do ldd_buf=$(ldd -- "$_fix_file" 2>/dev/null) || continue elf_buf=$("$cmd_elf" -d "$_fix_file" 2>/dev/null) || elf_buf=$ldd_buf while read -r line || [ "$line" ]; do case $line in *NEEDED*\[*\] | *'=>'*) # readelf: 0x0000 (NEEDED) Shared library: [libjson-c.so.5] line=${line##*\[} line=${line%%\]*} # Resolve library path. # ldd: libjson-c.so.5 => /lib/libjson-c.so.5 ... case $cmd_elf in *readelf) line=${ldd_buf#*" $line => "} ;; *) line=${line##*=> } ;; esac line=${line%% *} # Skip files owned by libc and POSIX. case ${line##*/} in ld-* |\ lib[cm].so* |\ libcrypt.so* |\ libdl.so* |\ libmvec.so* |\ libpthread.so* |\ libresolv.so* |\ librt.so* |\ libtrace.so* |\ libutil.so* |\ libxnet.so* |\ ldd) continue ;; *) # Skip file if owned by current package pkg_owner -l "/${line#/}\$" "$PWD/manifest" && continue pkg_owner -l "/${line#/}\$" "$@" && printf '%s\n' "$pkg_owner" ;; esac esac done < "$_tmp_file" # If the depends file was modified, show a diff and replace it. ! [ -s "$_tmp_file" ] || { diff -U 3 "$_tmp_file_pre" "$_tmp_file" 2>/dev/null || : mv -f "$_tmp_file" depends pkg_manifest "${PWD##*/}" } } 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 "$1" "Generating manifest" cd "${2:-$pkg_dir}/$1" # Create a list of all files and directories. Append '/' to the end of # directories so they can be easily filtered out later. find . -type d -exec printf '%s/\n' {} + -o ! -type d -print | # sort: Sort the output in *reverse*. Directories appear *after* their # contents. # sed: Remove the first character in each line (./dir -> /dir) and # remove all lines which only contain '.'. sort -r | sed '/^\.\/$/d;ss.ss' > "$PWD/$pkg_db/$1/manifest" cd "$OLDPWD" } pkg_manifest_validate() { log "$1" "Checking if manifest valid" while read -r line; do [ -e "$tar_dir/$1$line" ] || [ -h "$tar_dir/$1$line" ] || { printf '%s\n' "$line" set -- "$@" "$line" } done < "$pkg_db/$1/manifest" case $# in [2-9]|[1-9][0-9]*) die "$1" "manifest contains $(($# - 1)) non-existent files" esac } pkg_etcsums() { # Generate checksums for each configuration file in the package's /etc/ # directory for use in "smart" handling of these files. log "$1" "Generating etcsums" ! [ -d "$pkg_dir/$1/etc" ] || # This can't be a simple 'find -exec' as 'sh256' is a shell function # and not a real command of any kind. This is the shell equivalent. find "$pkg_dir/$1/etc" ! -type d | sort | while read -r line; do sh256 "$line" 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. # # NOTE: repo_ comes from caller. log "$1" "Creating tarball" # Use 'cd' to avoid needing tar's '-C' flag which may not be portable # across implementations. cd "$pkg_dir/$1" _tar_file=$bin_dir/$1@$repo_ver-$repo_rel.tar.$KISS_COMPRESS # Create a tarball from the contents of the built package. tar cf - . | case $KISS_COMPRESS in bz2) bzip2 -z ;; gz) gzip -6 ;; lzma) lzma -z ;; lz) lzip -z ;; xz) xz -zT0 ;; zst) zstd -z ;; esac > "$_tar_file" log "$1" "Successfully created tarball" # arg1: post-package # arg2: package name # arg3: path to tarball run_hook post-package "$1" "$_tar_file" ) pkg_build_all() { # Build packages and turn them into packaged tarballs. # Order the argument list and filter out duplicates. # Mark packages passed on the command-line explicit. # Also resolve dependencies for all explicit packages. for pkg do pkg_depends "$pkg" expl filter '' '' pkg_lint explicit="$explicit $pkg " done # If this is an update, don't always build explicitly passsed packages # and instead install pre-built binaries if they exist. [ "$pkg_update" ] || explicit_build=$explicit set -- # If an explicit package is a dependency of another explicit package, # remove it from the explicit list. for pkg in $explicit; do contains "$deps" "$pkg" || set -- "$@" "$pkg" done explicit_cnt=$# explicit=$* log "Building: explicit: $*${deps:+, implicit: ${deps## }}" # Intentional, globbing disabled. # shellcheck disable=2046,2086 set -- $deps "$@" # Ask for confirmation if extra packages need to be built. [ "$#" = "$explicit_cnt" ] || prompt log "Checking for pre-built dependencies" # Install any pre-built dependencies if they exist in the binary # directory and are up to date. for pkg in "$@"; do if ! contains "$explicit_build" "$pkg" && pkg_cache "$pkg"; then log "$pkg" "Found pre-built binary" # Intended behavior. # shellcheck disable=2030,2031 (export KISS_FORCE=1; args i "$tar_file") else set -- "$@" "$pkg" fi shift done for pkg do pkg_source "$pkg" pkg_verify "$pkg" done # Finally build and create tarballs for all passed packages and # dependencies. for pkg do log "$pkg" "Building package ($((_build_cur+=1))/${_build_tot:=$#})" pkg_find_version "$pkg" # arg1: queue-status # arg2: package name # arg3: number in queue # arg4: total in queue run_hook queue "$pkg" "$((_build_cur += 1))" "$#" # arg1: pre-extract # arg2: package name # arg3: path to DESTDIR run_hook pre-extract "$pkg" "$pkg_dir/$pkg" pkg_extract "$pkg" pkg_build "$pkg" pkg_strip "$pkg" pkg_manifest "$pkg" pkg_fix_deps "$pkg" pkg_etcsums "$pkg" pkg_tar "$pkg" if [ "$pkg_update" ] || ! contains "$explicit" "$pkg"; then log "$pkg" "Needed as a dependency or has an update, installing" # Intended behavior. # shellcheck disable=2030,2031 (export KISS_FORCE=1; args i "$pkg") fi done case $pkg_update in '') # Intentional, globbing disabled. # shellcheck disable=2046,2086 ! prompt "Install built packages? [$explicit]" || (args i $explicit) esac } pkg_build() { # Install built packages to a directory under the package name to # avoid collisions with other packages. mkcd "$mak_dir/$1" "$pkg_dir/$1/$pkg_db" log "$1" "Starting build" # arg1: pre-build # arg2: package name # arg3: path to build directory run_hook pre-build "$1" "$mak_dir/$1" # Attempt to create the log file early so any permissions errors are caught # before the build starts. 'tee' is run in a pipe and POSIX shell has no # pipe-fail causing confusing behavior when tee fails. : > "$log_dir/$1-$time-$KISS_PID" # Call the build script, log the output to the terminal and to a file. # There's no PIPEFAIL in POSIX shell so we must resort to tricks like kill. { # Give the script a modified environment. Define toolchain program # environment variables assuming a generic environment by default. # # Define DESTDIR, PREFIX and GOPATH to sane defaults as their use is # mandatory in anything using autotools, meson, cmake, etc. # # Define KISS_ROOT as the sanitized value used internally by the # package manager. This is safe to join with other paths. AR="${AR:-ar}" \ CC="${CC:-cc}" \ CXX="${CXX:-c++}" \ NM="${NM:-nm}" \ RANLIB="${RANLIB:-ranlib}" \ DESTDIR="$pkg_dir/$1" \ GOPATH="$PWD/go" \ KISS_ROOT="$KISS_ROOT" \ PREFIX=/usr \ \ "$repo_dir/build" "$pkg_dir/$1" "$repo_ver" 2>&1 || { log "$1" "Build failed" log "$1" "Log stored to $log_dir/$1-$time-$KISS_PID" # arg1: build-fail # arg2: package name # arg3: path to build directory run_hook build-fail "$pkg" "$mak_dir/$1" pkg_clean kill 0 } } | tee "$log_dir/$1-$time-$KISS_PID" # Delete the log file if the build succeeded to prevent the directory # from filling very quickly with useless logs. [ "$KISS_KEEPLOG" = 1 ] || rm -f "$log_dir/$1-$time-$KISS_PID" # Copy the repository files to the package directory. cp -LRf "$repo_dir" "$pkg_dir/$1/$pkg_db/" log "$1" "Successfully built package" # arg1: post-build # arg2: package name # arg3: path to DESTDIR run_hook post-build "$1" "$pkg_dir/$1" # Remove all .la files from package. find "$pkg_dir/$1/usr/lib" \ -name \*.la -exec rm -f {} + 2>/dev/null || : # Remove unneeded file from all packages. rm -f "$pkg_dir/$1/usr/lib/charset.alias" # Ensure manifest is added to manfiest. : > "$pkg_dir/$1/$pkg_db/$1/manifest" # Ensure etcsums is added to manifest if /etc/ exists in package. ! [ -d "$pkg_dir/$1/etc" ] || : > "$pkg_dir/$1/$pkg_db/$1/etcsums" } pkg_checksums() { # Generate checksums for packages. # # NOTE: repo_dir comes from caller. unset _hash while read -r src dest || [ "$src" ]; do pkg_source_resolve "$1" "$src" "$dest" >/dev/null case $_res in */*[!.]) sh256 "$_res" # Store the generated checksums in a string for use internally # without the need for subshells. _hash="$_hash${_hash:+"$newline"}$hash" esac done < "$repo_dir/sources" || die "$1" "Failed to generate checksums" } pkg_verify() { # Verify all package checksums. This is achieved by generating a new set # of checksums and then comparing those with the old set. # # NOTE: repo_dir comes from caller. log "$1" "Checking sources" [ -f "$repo_dir/sources" ] || return 0 # Generate a new set of checksums to compare against. pkg_checksums "$1" > /dev/null # Intentional, globbing disabled. # shellcheck disable=2038,2086 set -- $_hash # Check that the first column (separated by whitespace) match in both # checksum files. If any part of either file differs, mismatch. Abort. while read -r chk _ || [ "$1" ]; do printf '%s\n%s\n' "- ${chk:-missing}" "+ ${1:-no source}" case $1-${chk:-null} in "$chk-$1"|"$1-SKIP") ;; "$_hash"-*|*) die "${repo_dir##*/}" "Checksum mismatch" esac shift "$(($# != 0))" done < "$repo_dir/checksums" } pkg_conflicts() { # Check to see if a package conflicts with another. log "$1" "Checking for package conflicts" tmp_file "$1" manifest-files tmp_file "$1" found-conflicts # Filter the tarball's manifest and select only files. Resolve all # symlinks in file paths as well. while read -r file; do # Skip all directories. case $file in */) continue; esac file=$KISS_ROOT/${file#/} # Attempt to resolve symlinks by using 'cd'. # If this fails, fallback to the file's parent # directory. cd -P "${file%/*}" 2>/dev/null || PWD=${file%/*} # Print the file with all symlinks in its path # resolved to their real locations. printf '%s\n' "${PWD#"$KISS_ROOT"}/${file##*/}" done < "$tar_dir/$1/$pkg_db/$1/manifest" > "$_tmp_file_pre" cd "$tar_dir/$1" p_name=$1 set +f set -f "$sys_db"/*/manifest # Generate a list of all installed package manifests and remove the # current package from the list. This is the simplest method of # dropping an item from the argument list. The one downside is that # it cannot live in a function due to scoping of arguments. for manifest do shift case $manifest in "$sys_db/$p_name/manifest") continue esac set -- "$@" "$manifest" done # Return here if there is nothing to check conflicts against. [ "$#" != 0 ] || return 0 # Store the list of found conflicts in a file as we'll be using the # information multiple times. Storing things in the cache dir allows # us to be lazy as they'll be automatically removed on script end. grep -Fxf "$_tmp_file_pre" -- "$@" 2>/dev/null > "$_tmp_file" || : # Enable alternatives automatically if it is safe to do so. # This checks to see that the package that is about to be installed # doesn't overwrite anything it shouldn't in '/var/db/kiss/installed'. grep -q ":/var/db/kiss/installed/" "$_tmp_file" || choice_auto=1 if [ "$KISS_CHOICE" != 0 ] && [ "$choice_auto" = 1 ] && [ -s "$_tmp_file" ]; 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 alternatives' command parses this directory and # offers you the CHOICE of *swapping* entries in this # directory for those on the filesystem. # # The alternatives 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 $p_name. Contact the maintainer" die "by finding their details via 'kiss-maintainer'" "" "!>" } done < "$_tmp_file" log "$p_name" "Converted all conflicts to choices (kiss a)" # Rewrite the package's manifest to update its location # to its new spot (and name) in the choices directory. pkg_manifest "$p_name" "$tar_dir" 2>/dev/null elif [ -s "$_tmp_file" ]; 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##*/} # Ensure that the file we're going to swap is actually owned by a # package. If it is not, we have to die here. [ "$pkg_owns" ] || die "File '$2' exists on filesystem but isn't owned" log "Swapping '$2' from '$pkg_owns' to '$1'" tmp_file "$pkg_owns" from-alt # Convert the current owner to an alternative and rewrite its manifest # file to reflect this. cp -Pf "$KISS_ROOT/$2" "$pkg_owns>${alt#*>}" # Replace the matching line in the manifest with the desired replacement. # This used to be a 'sed' call which turned out to be a little # error-prone in some cases. This new method is a tad slower but ensures # we never wipe the file due to a command error. while read -r line; do case $line in "$2") printf '%s\n' "${PWD#"$KISS_ROOT"}/$pkg_owns>${alt#*>}" ;; *) printf '%s\n' "$line" ;; esac done < "../installed/$pkg_owns/manifest" | sort -r > "$_tmp_file" mv -f "$_tmp_file" "../installed/$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/$2" tmp_file "$pkg_owns" to-alt # Replace the matching line in the manifest with the desired replacement. # This used to be a 'sed' call which turned out to be a little error-prone # in some cases. This new method is a tad slower but ensures we never wipe # the file due to a command error. while read -r line; do case $line in "${PWD#"$KISS_ROOT"}/$alt") printf '%s\n' "$2" ;; *) printf '%s\n' "$line" ;; esac done < "../installed/$1/manifest" | sort -r > "$_tmp_file" mv -f "$_tmp_file" "../installed/$1/manifest" } file_rwx() { # Grab the octal permissions from 'ls -l' so that we can retain # directory permissions and strip setuid/setgid if found. rwx=$(ls -ld "$1") oct='' o=0 # Convert the output of 'ls' (rwxrwx---) to octal. This is simply # a 1-9 loop with the second digit being the value of the field. for c in 14 22 31 44 52 61 74 82 91; do rwx=${rwx#?} case $rwx in [rwx]*): "$((o+=${c#?}))" ;; [st]*): "$((o+=1))" ;; [ST]*) ;; esac case $((${c%?} % 3)) in 0) oct=$oct$o o=0 esac done } pkg_install_files() { while read -r file; do _file=$KISS_ROOT$file # Copy files and create directories (preserving permissions), # skipping anything located in /etc/. # # The 'test' will run with '-e' for no-overwrite and '-z' # for overwrite. case $file in /etc/*) ;; */) # Skip directories if they already exist in the file system. # (Think /usr/bin, /usr/lib, etc). [ -d "$_file" ] || { file_rwx "$2/${file#/}" mkdir -m "$oct" "$_file" } ;; *) if [ -d "$_file" ] || test "$1" "$_file"; then # Skip directories as they're likely symlinks in this case. # Pure directories in manifests have a suffix of '/'. continue elif [ -h "$_file" ]; then # Copy the file to the destination directory overwriting # any existing file. cp -fP "$2$file" "${_file%/*}/." else # Construct a temporary filename which is a) unique and # b) identifiable as related to the package manager. __tmp=${_file%/*}/__kiss-tmp-$pkg_name-${file##*/}-$KISS_PID # Copy the file to the destination directory with the # temporary name created above. cp -fP "$2$file" "$__tmp" && # Atomically move the temporary file to its final # destination. The running processes will either get # the old file or the new one. mv -f "$__tmp" "$_file" fi esac || return 1 done } pkg_remove_files() { # Remove a file list from the system. This function runs during package # installation and package removal. Combining the removals in these two # functions allows us to stop duplicating code. while read -r file; do case $file in /etc/?*[!/]) sh256 "$KISS_ROOT/$file" >/dev/null sum_old=$(grep -F "${hash:-null}" "$1") [ "${hash:-null}" = "$sum_old" ] || { printf 'Skipping %s (modified)\n' "$file" continue } esac 2>/dev/null || : _file=${KISS_ROOT:+"$KISS_ROOT/"}${file%%/} # Queue all directory symlinks for later removal. if [ -h "$_file" ] && [ -d "$_file" ]; then case $file in /*/*/) set -- "$@" "$_file" esac # Remove empty directories. elif [ -d "$_file" ]; then rmdir "$_file" 2>/dev/null || : # Remove everything else. else rm -f "$_file" fi done # First argument needs to be dropped. shift # Remove all broken directory symlinks. for sym do [ -e "$sym" ] || rm -f "$sym" done } pkg_etc() ( [ -d "$tar_dir/$1/etc" ] || return 0 cd "$tar_dir/$1" # Create all directories beforehand. find etc -type d | while read -r dir; do mkdir -p "$KISS_ROOT/$dir" done # Handle files in /etc/ based on a 3-way checksum check. find etc ! -type d | sort | while read -r file; do i=$((i + 1)) { sh256 "$file"; sum_new=$hash sh256 "$KISS_ROOT/$file"; sum_sys=$hash sum_old=$(awk "NR == $i" "$2"); } >/dev/null 2>&1 || : log "$1" "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. *) war "$1" "saving /$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_removable() { # Check if a package is removable and die if it is not. # A package is removable when it has no dependents. log "$1" "Checking if package removable" cd "$sys_db" set +f ! grep -lFx -- "$1" */depends || die "$1" "Not removable, has dependents" set -f cd "$OLDPWD" } pkg_remove() { # Remove a package and all of its files. The '/etc' directory is handled # differently and configuration files are *not* overwritten. pkg_list "$1" >/dev/null || return # Intended behavior. # shellcheck disable=2030,2031 [ "${KISS_FORCE:=0}" = 1 ] || pkg_removable "$1" # 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 # arg1: pre-remove # arg2: package name # arg3: path to installed database run_hook_pkg pre-remove "$1" run_hook pre-remove "$1" "$sys_db/$1" # Make a backup of any etcsums if they exist. tmp_file_copy "$1" etcsums-copy "$sys_db/$1/etcsums" log "$1" "Removing package" pkg_remove_files "$_tmp_file" < "$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_installable() { # Check if a package is removable and die if it is not. # A package is removable when all of its dependencies # are satisfied. log "$1" "Checking if package installable" # False positive. # shellcheck disable=2094 ! [ -f "$2" ] || while read -r dep dep_type || [ "$dep" ]; do case $dep-$dep_type in \#*-*) continue ;; *-) pkg_list "$dep" >/dev/null 2>&1 || { printf '%s %s\n' "$dep" "$dep_type" set -- "$1" "$2" "$(($3 + 1))" } ;; esac done < "$2" case ${3:-0} in [1-9]*) die "$1" "Package not installable, missing $3 package(s)" esac } pkg_install() { # Install a built package tarball. # # Package installation works similarly to the method used by Slackware in # some of their tooling. It's not the obvious solution to the problem, # however it is the best solution at this given time. # # When an installation is an update to an existing package, instead of # removing the old version first we do something different. # # The new version is installed overwriting any files which it has in # common with the previously installed version of the package. # # A "diff" is then generated between the old and new versions and contains # any files existing in the old version but not the new version. # # The package manager then goes and removes these files which leaves us # with the new package version in the file system and all traces of the # old version gone. # # For good measure the package manager will then install the new package # an additional time. This is to ensure that the above diff didn't contain # anything incorrect. # # This is the better method as it is "seamless". An update to busybox won't # create a window in which there is no access to all of its utilities. # Install can also take the full path to a tarball. We don't need to check # the repository if this is the case. case $1 in *.tar.*) [ -f "$1" ] || die "File '$1' does not exist" tar_file=$1 pkg_name=${1##*/} pkg_name=${pkg_name%@*} ;; *) pkg_cache "$1" || die "$1" "Not yet built" pkg_name=$1 ;; esac mkcd "$tar_dir/$pkg_name" # The tarball is extracted to a temporary directory where its contents are # then "installed" to the filesystem. Running this step as soon as possible # allows us to also check the validity of the tarball and bail out early # if needed. decompress "$tar_file" | tar xf - # Naively assume that the existence of a manifest file is all that # determines a valid KISS package from an invalid one. This should be a # fine assumption to make in 99.99% of cases. [ -f "./$pkg_db/$pkg_name/manifest" ] || die "Not a valid KISS package" [ "$KISS_FORCE" = 1 ] || { pkg_manifest_validate "$pkg_name" pkg_installable "$pkg_name" "$tar_dir/$pkg_name/$pkg_db/$pkg_name/depends" } # arg1: pre-install # arg2: package name # arg3: path to extracted package run_hook pre-install "$pkg_name" "$tar_dir/$pkg_name" pkg_conflicts "$pkg_name" log "$pkg_name" "Installing package (${tar_file##*/})" # If the package is already installed (and this is an upgrade) make a # backup of the manifest and etcsums files. tmp_file_copy "$pkg_name" manifest-copy "$sys_db/$pkg_name/manifest" tmp_file_copy "$pkg_name" etcsums-copy "$sys_db/$pkg_name/etcsums" tmp_file "$pkg_name" manifest-diff tar_man=$tar_dir/$pkg_name/$pkg_db/$pkg_name/manifest # Generate a list of files which exist in the currently installed manifest # but not in the newer (to be installed) manifest. grep -vFxf "$tar_man" "$_tmp_file_pre_pre" > "$_tmp_file" 2>/dev/null ||: # Reverse the manifest file so that we start shallow and go deeper as we # iterate over each item. This is needed so that directories are created # going down the tree. tmp_file "$pkg_name" manifest-reverse sort "$tar_man" > "$_tmp_file" # 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 # Install the package's files by iterating over its manifest. pkg_install_files -z "$tar_dir/$pkg_name" < "$_tmp_file" && # Handle /etc/ files in a special way (via a 3-way checksum) to # determine how these files should be installed. Do we overwrite the # existing file? Do we install it as $file.new to avoid deleting user # configuration? etc. # # This is more or less similar to Arch Linux's Pacman with the user # manually handling the .new files when and if they appear. pkg_etc "$pkg_name" "$_tmp_file_pre_pre" && # This is the aforementioned step removing any files from the old # version of the package if the installation is an update. Each file # type has to be specially handled to ensure no system breakage occurs. pkg_remove_files "$_tmp_file_pre_pre" < "$_tmp_file_pre" && # Install the package's files a second time to fix any mess caused by # the above removal of the previous version of the package. pkg_install_files -e "$tar_dir/$pkg_name" < "$_tmp_file" then # Reset 'trap' to its original value. Installation is done so we no longer # need to block 'Ctrl+C'. trap pkg_clean EXIT INT # arg1: post-install # arg2: package name # arg3: path to installed package database run_hook_pkg post-install "$pkg_name" run_hook post-install "$pkg_name" "$sys_db/$pkg_name" log "$pkg_name" "Installed successfully" else pkg_clean log "$pkg_name" "Failed to install package." ERROR die "$pkg_name" "Filesystem now dirty, manual repair needed." fi } pkg_update() { # Check all installed packages for updates. So long as the installed # version and the version in the repositories differ, it's considered # an update. log "Updating repositories" # Create a list of all repositories. # Intentional, globbing disabled. # shellcheck disable=2046,2086 { IFS=:; set -- $KISS_PATH; unset IFS; } # Update each repository in '$KISS_PATH'. for repo do # Handle null repositories (KISS_PATH=repo:::::repo). [ "$repo" ] || continue [ -d "$repo" ] || { log "$repo" " " printf 'Skipping repository, not a directory\n' continue } cd "$repo" git remote >/dev/null 2>&1 || { log "$repo" " " printf 'Skipping git pull, not a repository\n' continue } # Go to the repository's root directory. git_root=$(git rev-parse --show-toplevel) cd "${git_root:?"failed to find git root for '$PWD'"}" # Go to the real root directory if this is a submodule. git_root=$(git rev-parse --show-superproject-working-tree) cd "${git_root:-"$PWD"}" contains "$repos" "$PWD" || { repos="$repos $PWD " # arg1: pre-update # env: PWD is path to repository run_hook pre-update # 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" ] && [ "$uid" != 0 ]; then git pull git submodule update --remote --init -f else [ "$uid" = 0 ] || log "$PWD" "Need root to update" # Find out the owner of the repository and spawn # git as this user below. # # This prevents 'git' from changing the original # ownership of files and directories in the rare # case that the repository is owned by a 3rd user. file_owner "$PWD" # We're in a repository which is owned by a 3rd # user. Not root or the current user. [ "$user" = root ] || log "Dropping to $user for pull" as_root git pull as_root git submodule update --remote --init -f unset user fi # arg1: post-update # env: PWD is path to repository run_hook post-update } done log "Checking for new package versions" set +f -- for pkg in "$sys_db/"*; do read -r db_ver db_rel < "$pkg/version" || die "${pkg##*/}" "Failed to read installed version" pkg_find_version "${pkg##*/}" # Detect repository orphans (installed packages with no # associated repository). case $repo_dir in */var/db/kiss/installed/*) _repo_orp="$_repo_orp$newline${pkg##*/}" esac # Compare installed packages to repository packages. [ "$db_ver-$db_rel" = "$repo_ver-$repo_rel" ] || { printf '%s\n' "${pkg##*/} $db_ver-$db_rel ==> $repo_ver-$repo_rel" set -- "$@" "${pkg##*/}" } done log "Checking for orphaned repository packages" case $_repo_orp in *?*) war "Packages without repository$_repo_orp" esac set -f pkg_update=1 case " $* " in *" kiss "*) log "Detected package manager update" log "The package manager will be updated first" prompt pkg_build_all kiss log "Updated the package manager" log "Re-run 'kiss update' to update your system" ;; " ") log "Everything is up to date" ;; *) log "Packages to update: $*" prompt pkg_order "$@" # Intentional, globbing disabled. # shellcheck disable=2046,2086 pkg_build_all $order log "Updated all packages" ;; esac } pkg_clean() { # Clean up on exit or error. This removes everything related to the build. case ${KISS_DEBUG:-0}-${_KISS_LVL:-1} in 0-1) # If we are exiting the top-level package manager process, wipe # the entire temporary directory. rm -rf "$proc" ;; 0-*) # If we are exiting a nested package manager process, wipe only # the tar temporary directory. Files in this directory may not # be owned by user of the top-level process and therefore cannot # be removed. rm -rf "$tar_dir" ;; esac } 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=$1 shift "$(($# != 0))" # Ensure that arguments do not contain invalid characters. Wildcards can # not be used here as they would conflict with kiss extensions. case $action in a|alternatives) case $1 in *\**|*\!*|*\[*|*\ *|*\]*|*/*) die "Invalid argument: '!*[ ]/' ($1)" esac ;; b|build|c|checksum|d|download|i|install|l|list|r|remove) for _arg do case ${action%%"${action#?}"}-$_arg in i-*\!*|i-*\**|i-*\[*|i-*\ *|i-*\]*) die "Argument contains invalid characters: '!*[ ]' ('$_arg')" ;; [!i]-*\!*|[!i]-*\**|[!i]-*\[*|[!i]-*\ *|[!i]-*\]*|[!i]-*/*) die "Argument contains invalid characters: '!*[ ]/' ('$_arg')" ;; esac done # When no arguments are given on the command-line, use the basename of # the current directory as the package name and add the parent directory # to the running process' KISS_PATH. case ${action%%"${action#?}"}-$# in [!l]-0) export KISS_PATH=${PWD%/*}:$KISS_PATH set -- "${PWD##*/}" esac # Order the argument list based on dependence. pkg_order "$@" # Intentional, globbing disabled. # shellcheck disable=2046,2086 set -- $order ;; esac # Need to increment _KISS_LVL here to ensure we don't wipe the cache # early by non-asroot invocations. export _KISS_LVL=$((_KISS_LVL + 1)) # Rerun the script as root with a fixed environment if needed. We sadly # can't run singular functions as root so this is needed. case $action in a|alternatives|i|install|r|remove) [ -z "$1" ] || [ -w "$KISS_ROOT/" ] || [ "$uid" = 0 ] || { as_root env \ HOME="$HOME" \ XDG_CACHE_HOME="$XDG_CACHE_HOME" \ KISS_COMPRESS="$KISS_COMPRESS" \ KISS_PATH="$KISS_PATH" \ KISS_FORCE="$KISS_FORCE" \ KISS_ROOT="$KISS_ROOT" \ KISS_CHOICE="$KISS_CHOICE" \ KISS_COLOR="$KISS_COLOR" \ KISS_TMPDIR="$KISS_TMPDIR" \ KISS_PID="$KISS_PID" \ _KISS_LVL="$_KISS_LVL" \ "$0" "$action" "$@" return } esac # Actions can be abbreviated to their first letter. This saves keystrokes # once you memorize the commands. 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_source "$pkg" c; done for pkg do pkg_find_version "$pkg" [ -f "$repo_dir/sources" ] || { log "$pkg" "No sources file, skipping checksums" continue } pkg_checksums "$pkg" [ "$_hash" ] || { log "$pkg" "No sources needing checksums" continue } printf '%s\n' "$_hash" > "$repo_dir/checksums" log "$pkg" "Generated checksums" done ;; i|install) for pkg do pkg_install "$pkg"; done ;; b|build) pkg_build_all "${@:?No packages installed}" ;; d|download) for pkg do pkg_source "$pkg"; done ;; l|list) pkg_list "$@" ;; r|remove) for pkg in $redro; do pkg_remove "$pkg"; done ;; s|search) for pkg do pkg_find_die "$pkg" all; done ;; u|update) pkg_update ;; v|version) printf '5.5.6\n' ;; '') log 'kiss [a|b|c|d|i|l|r|s|u|v] [pkg]...' log 'alternatives List and swap to alternatives' log 'build Build a package' log 'checksum Generate checksums' log 'download Pre-download all sources' log 'install Install a package' log 'list List installed packages' log 'remove Remove a package' log 'search Search for a package' log 'update Update the system' log 'version Package manager version' printf '\nRun "kiss help-ext" to see all actions\n' ;; help-ext) log 'Installed extensions (kiss-* in PATH)' # Intentional, globbing disabled. # shellcheck disable=2046,2030,2031 set -- $(pkg_find kiss-\* all -x "$PATH") # To align descriptions figure out which extension has the longest # name by doing a simple 'name > max ? name : max' on the basename # of the path with 'kiss-' stripped as well. # # This also removes any duplicates found in '$PATH', picking the # first match. for path do p=${path#*/kiss-} case " $seen " in *" $p "*) shift ;; *) seen=" $seen $p " max=$((${#p} > max ? ${#p}+1 : max)) esac done # Print each extension, grab its description from the second line # in the file and align the output based on the above max. for path do printf "%b->%b %-${max}s " "$c1" "$c3" "${path#*/kiss-}" sed -n 's/^# *//;2p' "$path" done >&2 ;; *) pkg_find_die "kiss-$action*" "" -x "$PATH" "$repo_dir" "$@" ;; esac } create_tmp_dirs() { # Root directory. KISS_ROOT=${KISS_ROOT%"${KISS_ROOT##*[!/]}"} # This allows for automatic setup of a KISS chroot and will # do nothing on a normal system. mkdir -p "$KISS_ROOT/" 2>/dev/null || : # System package database. sys_db=$KISS_ROOT/${pkg_db:=var/db/kiss/installed} # Top-level cache directory. cac_dir=${XDG_CACHE_HOME:-"${HOME%"${HOME##*[!/]}"}/.cache"} cac_dir=${cac_dir%"${cac_dir##*[!/]}"}/kiss # Persistent cache directories. src_dir=$cac_dir/sources log_dir=$cac_dir/logs/${time%-*} bin_dir=$cac_dir/bin # Top-level Temporary cache directory. proc=${KISS_TMPDIR:="$cac_dir/proc"} proc=${proc%"${proc##*[!/]}"}/$KISS_PID # Temporary cache directories. mak_dir=$proc/build pkg_dir=$proc/pkg tar_dir=$proc/extract tmp_dir=$proc/tmp mkdir -p "$src_dir" "$log_dir" "$bin_dir" \ "$mak_dir" "$pkg_dir" "$tar_dir" "$tmp_dir" # 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 } main() { # Globally disable globbing and enable exit-on-error. set -ef # Color can be disabled via the environment variable KISS_COLOR. Colors are # also automatically disabled if output is being used in a pipe/redirection. [ "$KISS_COLOR" = 0 ] || ! [ -t 2 ] || c1='\033[1;33m' c2='\033[1;34m' c3='\033[m' # Store the original working directory to ensure that relative paths # passed by the user on the command-line properly resolve to locations # in the filesystem. ppwd=$PWD # Never know when you're gonna need one of these. newline=" " # Defaults for environment variables. : "${KISS_COMPRESS:=gz}" : "${KISS_PID:=$$}" # Figure out which 'sudo' command to use based on the user's choice or what # is available on the system. cmd_su=${KISS_SU:-"$( command -v sudo || command -v doas || command -v ssu || command -v su )"} || cmd_su=su # Figure out which utility is available to dump elf information. cmd_elf=${KISS_ELF:-"$( command -v readelf || command -v eu-readelf || command -v llvm-readelf )"} || cmd_elf=ldd # 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) create_tmp_dirs args "$@" } main "$@"