# Copyright 1999-2015 Gentoo Foundation # Distributed under the terms of the GNU General Public License v2 # @ECLASS: multilib.eclass # @MAINTAINER: # amd64@gentoo.org # toolchain@gentoo.org # @BLURB: This eclass is for all functions pertaining to handling multilib configurations. # @DESCRIPTION: # This eclass is for all functions pertaining to handling multilib configurations. if [[ -z ${_MULTILIB_ECLASS} ]]; then _MULTILIB_ECLASS=1 inherit toolchain-funcs # Defaults: export MULTILIB_ABIS=${MULTILIB_ABIS:-"default"} export DEFAULT_ABI=${DEFAULT_ABI:-"default"} export CFLAGS_default export LDFLAGS_default export CHOST_default=${CHOST_default:-${CHOST}} export CTARGET_default=${CTARGET_default:-${CTARGET:-${CHOST_default}}} export LIBDIR_default=${CONF_LIBDIR:-"lib"} export KERNEL_ABI=${KERNEL_ABI:-${DEFAULT_ABI}} # @FUNCTION: has_multilib_profile # @DESCRIPTION: # Return true if the current profile is a multilib profile and lists more than # one abi in ${MULTILIB_ABIS}. When has_multilib_profile returns true, that # profile should enable the 'multilib' use flag. This is so you can DEPEND on # a package only for multilib or not multilib. has_multilib_profile() { [ -n "${MULTILIB_ABIS}" -a "${MULTILIB_ABIS}" != "${MULTILIB_ABIS/ /}" ] } # @FUNCTION: get_libdir # @RETURN: the libdir for the selected ABI # @DESCRIPTION: # This function simply returns the desired lib directory. With portage # 2.0.51, we now have support for installing libraries to lib32/lib64 # to accomidate the needs of multilib systems. It's no longer a good idea # to assume all libraries will end up in lib. Replace any (sane) instances # where lib is named directly with $(get_libdir) if possible. # # Jeremy Huddleston <eradicator@gentoo.org> (23 Dec 2004): # Added support for ${ABI} and ${DEFAULT_ABI}. If they're both not set, # fall back on old behavior. Any profile that has these set should also # depend on a newer version of portage (not yet released) which uses these # over CONF_LIBDIR in econf, dolib, etc... if has "${EAPI:-0}" 0 1 2 3 4 5; then get_libdir() { local CONF_LIBDIR if [ -n "${CONF_LIBDIR_OVERRIDE}" ] ; then # if there is an override, we want to use that... always. echo ${CONF_LIBDIR_OVERRIDE} else get_abi_LIBDIR fi } fi # @FUNCTION: get_abi_var # @USAGE: <VAR> [ABI] # @RETURN: returns the value of ${<VAR>_<ABI>} which should be set in make.defaults # @INTERNAL # @DESCRIPTION: # ex: # CFLAGS=$(get_abi_var CFLAGS sparc32) # CFLAGS=-m32 # # Note that the prefered method is to set CC="$(tc-getCC) $(get_abi_CFLAGS)" # This will hopefully be added to portage soon... # # If <ABI> is not specified, ${ABI} is used. # If <ABI> is not specified and ${ABI} is not defined, ${DEFAULT_ABI} is used. # If <ABI> is not specified and ${ABI} and ${DEFAULT_ABI} are not defined, we return an empty string. get_abi_var() { local flag=$1 local abi=${2:-${ABI:-${DEFAULT_ABI:-default}}} local var="${flag}_${abi}" echo ${!var} } # @FUNCTION: get_abi_CFLAGS # @USAGE: [ABI] # @DESCRIPTION: # Alias for 'get_abi_var CFLAGS' get_abi_CFLAGS() { get_abi_var CFLAGS "$@"; } # @FUNCTION: get_abi_LDFLAGS # @USAGE: [ABI] # @DESCRIPTION: # Alias for 'get_abi_var LDFLAGS' get_abi_LDFLAGS() { get_abi_var LDFLAGS "$@"; } # @FUNCTION: get_abi_CHOST # @USAGE: [ABI] # @DESCRIPTION: # Alias for 'get_abi_var CHOST' get_abi_CHOST() { get_abi_var CHOST "$@"; } # @FUNCTION: get_abi_CTARGET # @USAGE: [ABI] # @DESCRIPTION: # Alias for 'get_abi_var CTARGET' get_abi_CTARGET() { get_abi_var CTARGET "$@"; } # @FUNCTION: get_abi_FAKE_TARGETS # @USAGE: [ABI] # @DESCRIPTION: # Alias for 'get_abi_var FAKE_TARGETS' get_abi_FAKE_TARGETS() { get_abi_var FAKE_TARGETS "$@"; } # @FUNCTION: get_abi_LIBDIR # @USAGE: [ABI] # @DESCRIPTION: # Alias for 'get_abi_var LIBDIR' get_abi_LIBDIR() { get_abi_var LIBDIR "$@"; } # @FUNCTION: get_install_abis # @DESCRIPTION: # Return a list of the ABIs we want to install for with # the last one in the list being the default. get_install_abis() { local x order="" if [[ -z ${MULTILIB_ABIS} ]] ; then echo "default" return 0 fi if [[ ${EMULTILIB_PKG} == "true" ]] ; then for x in ${MULTILIB_ABIS} ; do if [[ ${x} != "${DEFAULT_ABI}" ]] ; then has ${x} ${ABI_DENY} || order="${order} ${x}" fi done has ${DEFAULT_ABI} ${ABI_DENY} || order="${order} ${DEFAULT_ABI}" if [[ -n ${ABI_ALLOW} ]] ; then local ordera="" for x in ${order} ; do if has ${x} ${ABI_ALLOW} ; then ordera="${ordera} ${x}" fi done order=${ordera} fi else order=${DEFAULT_ABI} fi if [[ -z ${order} ]] ; then die "The ABI list is empty. Are you using a proper multilib profile? Perhaps your USE flags or MULTILIB_ABIS are too restrictive for this package." fi echo ${order} return 0 } # @FUNCTION: get_all_abis # @DESCRIPTION: # Return a list of the ABIs supported by this profile. # the last one in the list being the default. get_all_abis() { local x order="" mvar dvar mvar="MULTILIB_ABIS" dvar="DEFAULT_ABI" if [[ -n $1 ]] ; then mvar="$1_${mvar}" dvar="$1_${dvar}" fi if [[ -z ${!mvar} ]] ; then echo "default" return 0 fi for x in ${!mvar}; do if [[ ${x} != ${!dvar} ]] ; then order="${order:+${order} }${x}" fi done order="${order:+${order} }${!dvar}" echo ${order} return 0 } # @FUNCTION: get_all_libdirs # @DESCRIPTION: # Returns a list of all the libdirs used by this profile. This includes # those that might not be touched by the current ebuild and always includes # "lib". get_all_libdirs() { local libdirs abi for abi in ${MULTILIB_ABIS}; do libdirs+=" $(get_abi_LIBDIR ${abi})" done [[ " ${libdirs} " != *" lib "* ]] && libdirs+=" lib" echo "${libdirs}" } # @FUNCTION: is_final_abi # @DESCRIPTION: # Return true if ${ABI} is the last ABI on our list (or if we're not # using the new multilib configuration. This can be used to determine # if we're in the last (or only) run through src_{unpack,compile,install} is_final_abi() { has_multilib_profile || return 0 set -- $(get_install_abis) local LAST_ABI=$# [[ ${!LAST_ABI} == ${ABI} ]] } # @FUNCTION: number_abis # @DESCRIPTION: # echo the number of ABIs we will be installing for number_abis() { set -- `get_install_abis` echo $# } # @FUNCTION: get_exeext # @DESCRIPTION: # Returns standard executable program suffix (null, .exe, etc.) # for the current platform identified by CHOST. # # Example: # get_exeext # Returns: null string (almost everywhere) || .exe (mingw*) || ... get_exeext() { case ${CHOST} in *-cygwin*|mingw*|*-mingw*) echo ".exe";; esac } # @FUNCTION: get_libname # @USAGE: [version] # @DESCRIPTION: # Returns libname with proper suffix {.so,.dylib,.dll,etc} and optionally # supplied version for the current platform identified by CHOST. # # Example: # get_libname ${PV} # Returns: .so.${PV} (ELF) || .${PV}.dylib (MACH) || ... get_libname() { local libname local ver=$1 case ${CHOST} in *-cygwin*) libname="dll.a";; # import lib mingw*|*-mingw*) libname="dll";; *-darwin*) libname="dylib";; *-mint*) libname="irrelevant";; hppa*-hpux*) libname="sl";; *) libname="so";; esac if [[ -z $* ]] ; then echo ".${libname}" else for ver in "$@" ; do case ${CHOST} in *-cygwin*) echo ".${ver}.${libname}";; *-darwin*) echo ".${ver}.${libname}";; *-mint*) echo ".${libname}";; *) echo ".${libname}.${ver}";; esac done fi } # @FUNCTION: get_modname # @USAGE: # @DESCRIPTION: # Returns modulename with proper suffix {.so,.bundle,etc} for the current # platform identified by CHOST. # # Example: # libfoo$(get_modname) # Returns: libfoo.so (ELF) || libfoo.bundle (MACH) || ... get_modname() { local modname local ver=$1 case ${CHOST} in *-darwin*) modname="bundle";; *) modname="so";; esac echo ".${modname}" } # This is for the toolchain to setup profile variables when pulling in # a crosscompiler (and thus they aren't set in the profile) multilib_env() { local CTARGET=${1:-${CTARGET}} local cpu=${CTARGET%%*-} case ${cpu} in aarch64*) # Not possible to do multilib with aarch64 and a single toolchain. export CFLAGS_arm=${CFLAGS_arm-} case ${cpu} in aarch64*be) export CHOST_arm="armv8b-${CTARGET#*-}";; *) export CHOST_arm="armv8l-${CTARGET#*-}";; esac CHOST_arm=${CHOST_arm/%-gnu/-gnueabi} export CTARGET_arm=${CHOST_arm} export LIBDIR_arm="lib" export CFLAGS_arm64=${CFLAGS_arm64-} export CHOST_arm64=${CTARGET} export CTARGET_arm64=${CHOST_arm64} export LIBDIR_arm64="lib64" : ${MULTILIB_ABIS=arm64} : ${DEFAULT_ABI=arm64} ;; x86_64*) export CFLAGS_x86=${CFLAGS_x86--m32} export CHOST_x86=${CTARGET/x86_64/i686} CHOST_x86=${CHOST_x86/%-gnux32/-gnu} export CTARGET_x86=${CHOST_x86} if [[ ${SYMLINK_LIB} == "yes" ]] ; then export LIBDIR_x86="lib32" else export LIBDIR_x86="lib" fi export CFLAGS_amd64=${CFLAGS_amd64--m64} export CHOST_amd64=${CTARGET/%-gnux32/-gnu} export CTARGET_amd64=${CHOST_amd64} export LIBDIR_amd64="lib64" export CFLAGS_x32=${CFLAGS_x32--mx32} export CHOST_x32=${CTARGET/%-gnu/-gnux32} export CTARGET_x32=${CHOST_x32} export LIBDIR_x32="libx32" case ${CTARGET} in *-gnux32) : ${MULTILIB_ABIS=x32 amd64 x86} : ${DEFAULT_ABI=x32} ;; *) : ${MULTILIB_ABIS=amd64 x86} : ${DEFAULT_ABI=amd64} ;; esac ;; mips64*) export CFLAGS_o32=${CFLAGS_o32--mabi=32} export CHOST_o32=${CTARGET/mips64/mips} export CTARGET_o32=${CHOST_o32} export LIBDIR_o32="lib" export CFLAGS_n32=${CFLAGS_n32--mabi=n32} export CHOST_n32=${CTARGET} export CTARGET_n32=${CHOST_n32} export LIBDIR_n32="lib32" export CFLAGS_n64=${CFLAGS_n64--mabi=64} export CHOST_n64=${CTARGET} export CTARGET_n64=${CHOST_n64} export LIBDIR_n64="lib64" : ${MULTILIB_ABIS=n64 n32 o32} : ${DEFAULT_ABI=n32} ;; powerpc64*) export CFLAGS_ppc=${CFLAGS_ppc--m32} export CHOST_ppc=${CTARGET/powerpc64/powerpc} export CTARGET_ppc=${CHOST_ppc} export LIBDIR_ppc="lib" export CFLAGS_ppc64=${CFLAGS_ppc64--m64} export CHOST_ppc64=${CTARGET} export CTARGET_ppc64=${CHOST_ppc64} export LIBDIR_ppc64="lib64" : ${MULTILIB_ABIS=ppc64 ppc} : ${DEFAULT_ABI=ppc64} ;; s390x*) export CFLAGS_s390=${CFLAGS_s390--m31} # the 31 is not a typo export CHOST_s390=${CTARGET/s390x/s390} export CTARGET_s390=${CHOST_s390} export LIBDIR_s390="lib" export CFLAGS_s390x=${CFLAGS_s390x--m64} export CHOST_s390x=${CTARGET} export CTARGET_s390x=${CHOST_s390x} export LIBDIR_s390x="lib64" : ${MULTILIB_ABIS=s390x s390} : ${DEFAULT_ABI=s390x} ;; sparc64*) export CFLAGS_sparc32=${CFLAGS_sparc32--m32} export CHOST_sparc32=${CTARGET/sparc64/sparc} export CTARGET_sparc32=${CHOST_sparc32} export LIBDIR_sparc32="lib" export CFLAGS_sparc64=${CFLAGS_sparc64--m64} export CHOST_sparc64=${CTARGET} export CTARGET_sparc64=${CHOST_sparc64} export LIBDIR_sparc64="lib64" : ${MULTILIB_ABIS=sparc64 sparc32} : ${DEFAULT_ABI=sparc64} ;; *) : ${MULTILIB_ABIS=default} : ${DEFAULT_ABI=default} ;; esac export MULTILIB_ABIS DEFAULT_ABI } # @FUNCTION: multilib_toolchain_setup # @DESCRIPTION: # Hide multilib details here for packages which are forced to be compiled for a # specific ABI when run on another ABI (like x86-specific packages on amd64) multilib_toolchain_setup() { local v vv export ABI=$1 # First restore any saved state we have laying around. if [[ ${_DEFAULT_ABI_SAVED} == "true" ]] ; then for v in CHOST CBUILD AS CC CXX F77 FC LD PKG_CONFIG_{LIBDIR,PATH} ; do vv="_abi_saved_${v}" [[ ${!vv+set} == "set" ]] && export ${v}="${!vv}" || unset ${v} unset ${vv} done unset _DEFAULT_ABI_SAVED fi # We want to avoid the behind-the-back magic of gcc-config as it # screws up ccache and distcc. See #196243 for more info. if [[ ${ABI} != ${DEFAULT_ABI} ]] ; then # Back that multilib-ass up so we can restore it later for v in CHOST CBUILD AS CC CXX F77 FC LD PKG_CONFIG_{LIBDIR,PATH} ; do vv="_abi_saved_${v}" [[ ${!v+set} == "set" ]] && export ${vv}="${!v}" || unset ${vv} done export _DEFAULT_ABI_SAVED="true" # Set CBUILD only if not cross-compiling. if [[ ${CBUILD} == "${CHOST}" ]]; then export CBUILD=$(get_abi_CHOST $1) fi # Set the CHOST native first so that we pick up the native # toolchain and not a cross-compiler by accident #202811. export CHOST=$(get_abi_CHOST ${DEFAULT_ABI}) export CC="$(tc-getCC) $(get_abi_CFLAGS)" export CXX="$(tc-getCXX) $(get_abi_CFLAGS)" export F77="$(tc-getF77) $(get_abi_CFLAGS)" export FC="$(tc-getFC) $(get_abi_CFLAGS)" export LD="$(tc-getLD) $(get_abi_LDFLAGS)" export CHOST=$(get_abi_CHOST $1) export PKG_CONFIG_LIBDIR=${EPREFIX}/usr/$(get_libdir)/pkgconfig export PKG_CONFIG_PATH=${EPREFIX}/usr/share/pkgconfig fi } fi