crosstool-ng/scripts/build/cc/gcc.sh

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# This file adds the function to build the gcc C compiler
# Copyright 2007 Yann E. MORIN
# Licensed under the GPL v2. See COPYING in the root of this package
# Download gcc
do_cc_get() {
local linaro_version=""
local linaro_series=""
CT_Fetch GCC
# Starting with GCC 4.3, ecj is used for Java, and will only be
# built if the configure script finds ecj.jar at the top of the
# GCC source tree, which will not be there unless we get it and
# put it there ourselves
if [ "${CT_CC_LANG_JAVA_USE_ECJ}" = "y" ]; then
if ! CT_GetFile package=ecj basename=ecj-latest extensions=.jar dir_name=gcc \
mirrors="$(CT_Mirrors sourceware java)"; then
# Should be a package, too - but with Java retirement in GCC,
# it may not make sense.
CT_Abort "Failed to download ecj-latest.jar"
fi
fi
}
# Extract gcc
do_cc_extract() {
CT_ExtractPatch GCC
# Copy ecj-latest.jar to ecj.jar at the top of the GCC source tree
if [ "${CT_CC_LANG_JAVA_USE_ECJ}" = "y" -a ! -f "${CT_SRC_DIR}/gcc/ecj.jar" ]; then
CT_DoExecLog ALL cp -v "${CT_TARBALLS_DIR}/ecj-latest.jar" "${CT_SRC_DIR}/gcc/ecj.jar"
fi
}
#------------------------------------------------------------------------------
# This function builds up the set of languages to enable
# No argument expected, returns the comma-separated language list on stdout
cc_gcc_lang_list() {
local lang_list
lang_list="c"
[ "${CT_CC_LANG_CXX}" = "y" ] && lang_list+=",c++"
[ "${CT_CC_LANG_FORTRAN}" = "y" ] && lang_list+=",fortran"
[ "${CT_CC_LANG_ADA}" = "y" ] && lang_list+=",ada"
[ "${CT_CC_LANG_JAVA}" = "y" ] && lang_list+=",java"
[ "${CT_CC_LANG_OBJC}" = "y" ] && lang_list+=",objc"
[ "${CT_CC_LANG_OBJCXX}" = "y" ] && lang_list+=",obj-c++"
[ "${CT_CC_LANG_GOLANG}" = "y" ] && lang_list+=",go"
lang_list+="${CT_CC_LANG_OTHERS:+,${CT_CC_LANG_OTHERS}}"
printf "%s" "${lang_list}"
}
multilib: Determine which options may pass through. On some arches (e.g. MIPS) the options like -mabi do not work if specified more than once (see the comment in 100-gcc.sh). Therefore, we need to determine which of the options produced by <arch>.sh can be passed to multilib builds and which must be removed (i.e., which options vary among the multilibs). This presents a chicken-and-egg problem. GCC developers, in their infinite wisdom, do not allow arbitrary multilib specification to be supplied to GCC's configure. Instead, the target (and sometimes some extra options) determine the set of multilibs - which may include different CPUs, different ABIs, different endianness, different FPUs, different floating-point ABIs, ... That is, we don't know which parts vary until we build GCC and ask it. So, the solution implemented here is: - For multilib builds, start with empty CT_ARCH_TARGET_CFLAGS/LDFLAGS. - For multilib builds, require core pass 1. Pass 1 does not build any target binaries, so at that point, our target options have not been used yet. - Provide an API to modify the environment variables for the steps that follow the current one. - As a part of multilib-related housekeeping, determine the variable part of multilibs and filter out these options; pass the rest into CT_TARGET_CFLAGS/LDFLAGS. This still does not handle extra dependencies between GCC options (like -ma implying -mcpu=X -mtune=Y, etc.) but I feel that would complicate matters too much. Let's leave this until there's a compelling case for it. Also, query GCC's sysroot suffix for targets that use it (SuperH, for example) - the default multilib may not work if the command line specifies the default option explicitly (%sysroot_suffix_spec is not aware of multilib defaults). Signed-off-by: Alexey Neyman <stilor@att.net>
2016-03-30 19:15:54 +00:00
#------------------------------------------------------------------------------
# Report the type of a GCC option
cc_gcc_classify_opt() {
# Options present in multiple architectures
case "${1}" in
-march=*) echo "arch"; return;;
-mabi=*) echo "abi"; return;;
-mcpu=*|-mmcu=*) echo "cpu"; return;;
-mtune=*) echo "tune"; return;;
-mfpu=*) echo "fpu"; return;;
-mhard-float|-msoft-float|-mno-soft-float|-mno-float|-mfloat-abi=*|\
-mfpu|-mno-fpu) echo "float"; return;;
-EB|-EL|-mbig-endian|-mlittle-endian|-mbig|-mlittle|-meb|-mel|-mb|-ml) echo "endian"; return;;
-mthumb|-marm) echo "mode"; return;;
esac
# Arch-specific options and aliases
case "${CT_ARCH}" in
m68k)
case "${1}" in
-m68881) echo "float"; return;;
-m5[234]*|-mcfv4e) echo "cpu"; return;;
-m68*|-mc68*) echo "arch"; return;;
esac
;;
mips)
case "${1}" in
-mips[1234]|-mips32|-mips32r*|-mips64|-mips64r*) echo "cpu"; return;;
esac
;;
sh)
case "${1}" in
-m[12345]*) echo "cpu"; return;;
esac
esac
# All tried and failed
echo "unknown"
}
evaluate_multilib_cflags()
{
local multi_dir multi_os_dir multi_os_dir_gcc multi_root multi_flags multi_index multi_count
local mdir mdir_os dirtop
local f
for arg in "$@"; do
eval "${arg// /\\ }"
done
mdir="lib/${multi_dir}"
mdir_os="lib/${multi_os_dir_gcc}"
CT_SanitizeVarDir mdir mdir_os
CT_DoLog EXTRA " '${multi_flags}' --> ${mdir} (gcc) ${mdir_os} (os)"
for f in ${multi_flags}; do
eval ml_`cc_gcc_classify_opt ${f}`=seen
done
if [ "${CT_DEMULTILIB}" = "y" -a "${CT_USE_SYSROOT}" = "y" ]; then
case "${mdir_os}" in
lib/*)
;;
*)
dirtop="${mdir_os%%/*}"
if [ ! -e "${multi_root}/${mdir_os}" ]; then
CT_DoExecLog ALL ln -sfv lib "${multi_root}/${mdir_os}"
fi
if [ ! -e "${multi_root}/usr/${mdir_os}" ]; then
CT_DoExecLog ALL ln -sfv lib "${multi_root}/usr/${mdir_os}"
fi
;;
esac
fi
}
multilib: Determine which options may pass through. On some arches (e.g. MIPS) the options like -mabi do not work if specified more than once (see the comment in 100-gcc.sh). Therefore, we need to determine which of the options produced by <arch>.sh can be passed to multilib builds and which must be removed (i.e., which options vary among the multilibs). This presents a chicken-and-egg problem. GCC developers, in their infinite wisdom, do not allow arbitrary multilib specification to be supplied to GCC's configure. Instead, the target (and sometimes some extra options) determine the set of multilibs - which may include different CPUs, different ABIs, different endianness, different FPUs, different floating-point ABIs, ... That is, we don't know which parts vary until we build GCC and ask it. So, the solution implemented here is: - For multilib builds, start with empty CT_ARCH_TARGET_CFLAGS/LDFLAGS. - For multilib builds, require core pass 1. Pass 1 does not build any target binaries, so at that point, our target options have not been used yet. - Provide an API to modify the environment variables for the steps that follow the current one. - As a part of multilib-related housekeeping, determine the variable part of multilibs and filter out these options; pass the rest into CT_TARGET_CFLAGS/LDFLAGS. This still does not handle extra dependencies between GCC options (like -ma implying -mcpu=X -mtune=Y, etc.) but I feel that would complicate matters too much. Let's leave this until there's a compelling case for it. Also, query GCC's sysroot suffix for targets that use it (SuperH, for example) - the default multilib may not work if the command line specifies the default option explicitly (%sysroot_suffix_spec is not aware of multilib defaults). Signed-off-by: Alexey Neyman <stilor@att.net>
2016-03-30 19:15:54 +00:00
#------------------------------------------------------------------------------
# This function lists the multilibs configured in the compiler (even if multilib
# is disabled - so that it lists the default GCC/OS directory, which may differ
# from the default 'lib'). It then performs a few multilib checks/quirks:
#
# 1. On MIPS target, gcc (or rather, ld, which it invokes under the hood) chokes
multilib: Determine which options may pass through. On some arches (e.g. MIPS) the options like -mabi do not work if specified more than once (see the comment in 100-gcc.sh). Therefore, we need to determine which of the options produced by <arch>.sh can be passed to multilib builds and which must be removed (i.e., which options vary among the multilibs). This presents a chicken-and-egg problem. GCC developers, in their infinite wisdom, do not allow arbitrary multilib specification to be supplied to GCC's configure. Instead, the target (and sometimes some extra options) determine the set of multilibs - which may include different CPUs, different ABIs, different endianness, different FPUs, different floating-point ABIs, ... That is, we don't know which parts vary until we build GCC and ask it. So, the solution implemented here is: - For multilib builds, start with empty CT_ARCH_TARGET_CFLAGS/LDFLAGS. - For multilib builds, require core pass 1. Pass 1 does not build any target binaries, so at that point, our target options have not been used yet. - Provide an API to modify the environment variables for the steps that follow the current one. - As a part of multilib-related housekeeping, determine the variable part of multilibs and filter out these options; pass the rest into CT_TARGET_CFLAGS/LDFLAGS. This still does not handle extra dependencies between GCC options (like -ma implying -mcpu=X -mtune=Y, etc.) but I feel that would complicate matters too much. Let's leave this until there's a compelling case for it. Also, query GCC's sysroot suffix for targets that use it (SuperH, for example) - the default multilib may not work if the command line specifies the default option explicitly (%sysroot_suffix_spec is not aware of multilib defaults). Signed-off-by: Alexey Neyman <stilor@att.net>
2016-03-30 19:15:54 +00:00
# if supplied with two -mabi=* options. I.e., 'gcc -mabi=n32' and 'gcc -mabi=32' both
# work, but 'gcc -mabi=32 -mabi=n32' produces an internal error in ld. Thus we do
# not supply target's CFLAGS in multilib builds - and after compiling pass-1 gcc,
# attempt to determine which CFLAGS need to be filtered out.
#
# 2. If "demultilibing" is in effect, create top-level directories for any
# multilibs not in lib/ as symlinks to lib.
multilib: Determine which options may pass through. On some arches (e.g. MIPS) the options like -mabi do not work if specified more than once (see the comment in 100-gcc.sh). Therefore, we need to determine which of the options produced by <arch>.sh can be passed to multilib builds and which must be removed (i.e., which options vary among the multilibs). This presents a chicken-and-egg problem. GCC developers, in their infinite wisdom, do not allow arbitrary multilib specification to be supplied to GCC's configure. Instead, the target (and sometimes some extra options) determine the set of multilibs - which may include different CPUs, different ABIs, different endianness, different FPUs, different floating-point ABIs, ... That is, we don't know which parts vary until we build GCC and ask it. So, the solution implemented here is: - For multilib builds, start with empty CT_ARCH_TARGET_CFLAGS/LDFLAGS. - For multilib builds, require core pass 1. Pass 1 does not build any target binaries, so at that point, our target options have not been used yet. - Provide an API to modify the environment variables for the steps that follow the current one. - As a part of multilib-related housekeeping, determine the variable part of multilibs and filter out these options; pass the rest into CT_TARGET_CFLAGS/LDFLAGS. This still does not handle extra dependencies between GCC options (like -ma implying -mcpu=X -mtune=Y, etc.) but I feel that would complicate matters too much. Let's leave this until there's a compelling case for it. Also, query GCC's sysroot suffix for targets that use it (SuperH, for example) - the default multilib may not work if the command line specifies the default option explicitly (%sysroot_suffix_spec is not aware of multilib defaults). Signed-off-by: Alexey Neyman <stilor@att.net>
2016-03-30 19:15:54 +00:00
cc_gcc_multilib_housekeeping() {
local cc host
local ml_arch ml_abi ml_cpu ml_tune ml_fpu ml_float ml_endian ml_mode ml_unknown ml
local new_cflags
for arg in "$@"; do
eval "${arg// /\\ }"
done
if [ \( "${CT_CANADIAN}" = "y" -o "${CT_CROSS_NATIVE}" = "y" \) -a "${host}" = "${CT_HOST}" ]; then
CT_DoLog EXTRA "Canadian Cross/Cross-native unable to confirm multilibs configuration "\
"directly; will use build-compiler for housekeeping."
# Since we cannot run the desired compiler, substitute build-CC with the assumption
# that the host-CC is configured in the same way.
cc="${CT_BUILDTOOLS_PREFIX_DIR}/bin/${CT_TARGET}-${CT_CC}"
multilib: Determine which options may pass through. On some arches (e.g. MIPS) the options like -mabi do not work if specified more than once (see the comment in 100-gcc.sh). Therefore, we need to determine which of the options produced by <arch>.sh can be passed to multilib builds and which must be removed (i.e., which options vary among the multilibs). This presents a chicken-and-egg problem. GCC developers, in their infinite wisdom, do not allow arbitrary multilib specification to be supplied to GCC's configure. Instead, the target (and sometimes some extra options) determine the set of multilibs - which may include different CPUs, different ABIs, different endianness, different FPUs, different floating-point ABIs, ... That is, we don't know which parts vary until we build GCC and ask it. So, the solution implemented here is: - For multilib builds, start with empty CT_ARCH_TARGET_CFLAGS/LDFLAGS. - For multilib builds, require core pass 1. Pass 1 does not build any target binaries, so at that point, our target options have not been used yet. - Provide an API to modify the environment variables for the steps that follow the current one. - As a part of multilib-related housekeeping, determine the variable part of multilibs and filter out these options; pass the rest into CT_TARGET_CFLAGS/LDFLAGS. This still does not handle extra dependencies between GCC options (like -ma implying -mcpu=X -mtune=Y, etc.) but I feel that would complicate matters too much. Let's leave this until there's a compelling case for it. Also, query GCC's sysroot suffix for targets that use it (SuperH, for example) - the default multilib may not work if the command line specifies the default option explicitly (%sysroot_suffix_spec is not aware of multilib defaults). Signed-off-by: Alexey Neyman <stilor@att.net>
2016-03-30 19:15:54 +00:00
fi
CT_IterateMultilibs evaluate_multilib_cflags evaluate_cflags
multilib: Determine which options may pass through. On some arches (e.g. MIPS) the options like -mabi do not work if specified more than once (see the comment in 100-gcc.sh). Therefore, we need to determine which of the options produced by <arch>.sh can be passed to multilib builds and which must be removed (i.e., which options vary among the multilibs). This presents a chicken-and-egg problem. GCC developers, in their infinite wisdom, do not allow arbitrary multilib specification to be supplied to GCC's configure. Instead, the target (and sometimes some extra options) determine the set of multilibs - which may include different CPUs, different ABIs, different endianness, different FPUs, different floating-point ABIs, ... That is, we don't know which parts vary until we build GCC and ask it. So, the solution implemented here is: - For multilib builds, start with empty CT_ARCH_TARGET_CFLAGS/LDFLAGS. - For multilib builds, require core pass 1. Pass 1 does not build any target binaries, so at that point, our target options have not been used yet. - Provide an API to modify the environment variables for the steps that follow the current one. - As a part of multilib-related housekeeping, determine the variable part of multilibs and filter out these options; pass the rest into CT_TARGET_CFLAGS/LDFLAGS. This still does not handle extra dependencies between GCC options (like -ma implying -mcpu=X -mtune=Y, etc.) but I feel that would complicate matters too much. Let's leave this until there's a compelling case for it. Also, query GCC's sysroot suffix for targets that use it (SuperH, for example) - the default multilib may not work if the command line specifies the default option explicitly (%sysroot_suffix_spec is not aware of multilib defaults). Signed-off-by: Alexey Neyman <stilor@att.net>
2016-03-30 19:15:54 +00:00
if [ -n "${CT_MULTILIB}" ]; then
# Filtering out some of the options provided in CT-NG config. Then *prepend*
# them to CT_TARGET_CFLAGS, like scripts/crosstool-NG.sh does. Zero out
# the stashed MULTILIB flags so that we don't process them again in the passes
# that follow.
CT_DoLog DEBUG "Configured target CFLAGS: '${CT_ARCH_TARGET_CFLAGS_MULTILIB}'"
ml_unknown= # Pass through anything we don't know about
for f in ${CT_ARCH_TARGET_CFLAGS_MULTILIB}; do
eval ml=\$ml_`cc_gcc_classify_opt ${f}`
if [ "${ml}" != "seen" ]; then
new_cflags="${new_cflags} ${f}"
fi
done
CT_DoLog DEBUG "Filtered target CFLAGS: '${new_cflags}'"
CT_EnvModify CT_ALL_TARGET_CFLAGS "${new_cflags} ${CT_TARGET_CFLAGS}"
CT_EnvModify CT_ARCH_TARGET_CFLAGS_MULTILIB ""
# Currently, the only LDFLAGS are endianness-related
CT_DoLog DEBUG "Configured target LDFLAGS: '${CT_ARCH_TARGET_LDFLAGS_MULTILIB}'"
if [ "${ml_endian}" != "seen" ]; then
CT_EnvModify CT_ALL_TARGET_LDFLAGS "${CT_ARCH_TARGET_LDFLAGS_MULTILIB} ${CT_TARGET_LDFLAGS}"
CT_EnvModify CT_ARCH_TARGET_LDFLAGS_MULTILIB ""
multilib: Determine which options may pass through. On some arches (e.g. MIPS) the options like -mabi do not work if specified more than once (see the comment in 100-gcc.sh). Therefore, we need to determine which of the options produced by <arch>.sh can be passed to multilib builds and which must be removed (i.e., which options vary among the multilibs). This presents a chicken-and-egg problem. GCC developers, in their infinite wisdom, do not allow arbitrary multilib specification to be supplied to GCC's configure. Instead, the target (and sometimes some extra options) determine the set of multilibs - which may include different CPUs, different ABIs, different endianness, different FPUs, different floating-point ABIs, ... That is, we don't know which parts vary until we build GCC and ask it. So, the solution implemented here is: - For multilib builds, start with empty CT_ARCH_TARGET_CFLAGS/LDFLAGS. - For multilib builds, require core pass 1. Pass 1 does not build any target binaries, so at that point, our target options have not been used yet. - Provide an API to modify the environment variables for the steps that follow the current one. - As a part of multilib-related housekeeping, determine the variable part of multilibs and filter out these options; pass the rest into CT_TARGET_CFLAGS/LDFLAGS. This still does not handle extra dependencies between GCC options (like -ma implying -mcpu=X -mtune=Y, etc.) but I feel that would complicate matters too much. Let's leave this until there's a compelling case for it. Also, query GCC's sysroot suffix for targets that use it (SuperH, for example) - the default multilib may not work if the command line specifies the default option explicitly (%sysroot_suffix_spec is not aware of multilib defaults). Signed-off-by: Alexey Neyman <stilor@att.net>
2016-03-30 19:15:54 +00:00
fi
CT_DoLog DEBUG "Filtered target LDFLAGS: '${CT_ARCH_TARGET_LDFLAGS_MULTILIB}'"
multilib: Determine which options may pass through. On some arches (e.g. MIPS) the options like -mabi do not work if specified more than once (see the comment in 100-gcc.sh). Therefore, we need to determine which of the options produced by <arch>.sh can be passed to multilib builds and which must be removed (i.e., which options vary among the multilibs). This presents a chicken-and-egg problem. GCC developers, in their infinite wisdom, do not allow arbitrary multilib specification to be supplied to GCC's configure. Instead, the target (and sometimes some extra options) determine the set of multilibs - which may include different CPUs, different ABIs, different endianness, different FPUs, different floating-point ABIs, ... That is, we don't know which parts vary until we build GCC and ask it. So, the solution implemented here is: - For multilib builds, start with empty CT_ARCH_TARGET_CFLAGS/LDFLAGS. - For multilib builds, require core pass 1. Pass 1 does not build any target binaries, so at that point, our target options have not been used yet. - Provide an API to modify the environment variables for the steps that follow the current one. - As a part of multilib-related housekeeping, determine the variable part of multilibs and filter out these options; pass the rest into CT_TARGET_CFLAGS/LDFLAGS. This still does not handle extra dependencies between GCC options (like -ma implying -mcpu=X -mtune=Y, etc.) but I feel that would complicate matters too much. Let's leave this until there's a compelling case for it. Also, query GCC's sysroot suffix for targets that use it (SuperH, for example) - the default multilib may not work if the command line specifies the default option explicitly (%sysroot_suffix_spec is not aware of multilib defaults). Signed-off-by: Alexey Neyman <stilor@att.net>
2016-03-30 19:15:54 +00:00
fi
}
#------------------------------------------------------------------------------
# Core gcc pass 1
do_cc_core_pass_1() {
local -a core_opts
if [ "${CT_CC_CORE_PASS_1_NEEDED}" != "y" ]; then
return 0
fi
core_opts+=( "mode=static" )
core_opts+=( "host=${CT_BUILD}" )
core_opts+=( "complibs=${CT_BUILDTOOLS_PREFIX_DIR}" )
core_opts+=( "prefix=${CT_BUILDTOOLS_PREFIX_DIR}" )
core_opts+=( "cflags=${CT_CFLAGS_FOR_BUILD}" )
core_opts+=( "ldflags=${CT_LDFLAGS_FOR_BUILD}" )
core_opts+=( "lang_list=c" )
core_opts+=( "build_step=core1" )
CT_DoStep INFO "Installing pass-1 core C gcc compiler"
CT_mkdir_pushd "${CT_BUILD_DIR}/build-cc-gcc-core-pass-1"
do_gcc_core_backend "${core_opts[@]}"
CT_Popd
CT_EndStep
}
# Core gcc pass 2
do_cc_core_pass_2() {
local -a core_opts
if [ "${CT_CC_CORE_PASS_2_NEEDED}" != "y" ]; then
return 0
fi
# Common options:
core_opts+=( "host=${CT_BUILD}" )
core_opts+=( "prefix=${CT_BUILDTOOLS_PREFIX_DIR}" )
core_opts+=( "complibs=${CT_BUILDTOOLS_PREFIX_DIR}" )
core_opts+=( "cflags=${CT_CFLAGS_FOR_BUILD}" )
core_opts+=( "ldflags=${CT_LDFLAGS_FOR_BUILD}" )
core_opts+=( "lang_list=c" )
core_opts+=( "build_step=core2" )
# Different conditions are at stake here:
# - In case the threading model is NPTL, we need a shared-capable core
# gcc; in all other cases, we need a static-only core gcc.
# - In case the threading model is NPTL or win32, or gcc is 4.3 or
# later, we need to build libgcc
case "${CT_THREADS}" in
nptl)
if [ "${CT_SHARED_LIBS}" = "y" ]; then
core_opts+=( "mode=shared" )
else
core_opts+=( "mode=static" )
fi
core_opts+=( "build_libgcc=yes" )
;;
win32)
core_opts+=( "mode=static" )
core_opts+=( "build_libgcc=yes" )
;;
*)
core_opts+=( "mode=static" )
core_opts+=( "build_libgcc=yes" )
;;
esac
CT_DoStep INFO "Installing pass-2 core C gcc compiler"
CT_mkdir_pushd "${CT_BUILD_DIR}/build-cc-gcc-core-pass-2"
do_gcc_core_backend "${core_opts[@]}"
CT_Popd
CT_EndStep
}
#------------------------------------------------------------------------------
# Build core gcc
# This function is used to build the core C compiler.
# Usage: do_gcc_core_backend param=value [...]
# Parameter : Definition : Type : Default
# mode : build a 'static', 'shared' or 'baremetal' : string : (none)
# host : the machine the core will run on : tuple : (none)
# prefix : dir prefix to install into : dir : (none)
# complibs : dir where complibs are installed : dir : (none)
# lang_list : the list of languages to build : string : (empty)
# build_libgcc : build libgcc or not : bool : no
# build_libstdcxx : build libstdc++ or not : bool : no
# build_libgfortran : build libgfortran or not : bool : no
# build_staticlinked : build statically linked or not : bool : no
# build_manuals : whether to build manuals or not : bool : no
# cflags : cflags to use : string : (empty)
# ldflags : ldflags to use : string : (empty)
# build_step : build step 'core1', 'core2', 'gcc_build',
# 'libstdcxx'
# or 'gcc_host' : string : (none)
# Usage: do_gcc_core_backend mode=[static|shared|baremetal] build_libgcc=[yes|no] build_staticlinked=[yes|no]
do_gcc_core_backend() {
local mode
local build_libgcc=no
local build_libstdcxx=no
local build_libgfortran=no
local build_staticlinked=no
local build_manuals=no
local host
local prefix
local enable_optspace
local complibs
local lang_list
local cflags cflags_for_build cxxflags_for_build cflags_for_target cxxflags_for_target
local extra_cxxflags_for_target
local ldflags
local build_step
local log_txt
local tmp
local exec_prefix
local header_dir
local libstdcxx_name
local -a host_libstdcxx_flags
local -a extra_config
local -a core_LDFLAGS
local -a core_targets
local -a core_targets_all
local -a core_targets_install
local -a extra_user_config
local arg
for arg in "$@"; do
eval "${arg// /\\ }"
done
# This function gets called in case of a bare metal compiler for the final gcc, too.
case "${build_step}" in
core1|core2)
CT_DoLog EXTRA "Configuring core C gcc compiler"
log_txt="gcc"
extra_config+=( "${CT_CC_CORE_SYSROOT_ARG[@]}" )
extra_user_config=( "${CT_CC_GCC_CORE_EXTRA_CONFIG_ARRAY[@]}" )
;;
gcc_build|gcc_host)
CT_DoLog EXTRA "Configuring final gcc compiler"
extra_config+=( "${CT_CC_SYSROOT_ARG[@]}" )
extra_user_config=( "${CT_CC_GCC_EXTRA_CONFIG_ARRAY[@]}" )
log_txt="final gcc compiler"
# to inhibit the libiberty and libgcc tricks later on
build_libgcc=no
;;
libstdcxx)
CT_DoLog EXTRA "Configuring libstdc++ for ${libstdcxx_name}"
if [ "${header_dir}" = "" ]; then
header_dir="${CT_PREFIX_DIR}/${libstdcxx_name}/include"
fi
if [ "${exec_prefix}" = "" ]; then
exec_prefix="${CT_PREFIX_DIR}/${libstdcxx_name}"
fi
extra_config+=( "${CT_CC_SYSROOT_ARG[@]}" )
extra_config+=( "--with-headers=${header_dir}" )
extra_user_config=( "${CT_CC_GCC_EXTRA_CONFIG_ARRAY[@]}" )
log_txt="libstdc++ ${libstdcxx_name} library"
# to inhibit the libiberty and libgcc tricks later on
build_libgcc=no
;;
*)
CT_Abort "Internal Error: 'build_step' must be one of: 'core1', 'core2', 'gcc_build', 'gcc_host' or 'libstdcxx', not '${build_step:-(empty)}'"
;;
esac
if [ "${exec_prefix}" = "" ]; then
exec_prefix="${prefix}"
fi
case "${mode}" in
static)
extra_config+=("--with-newlib")
extra_config+=("--enable-threads=no")
extra_config+=("--disable-shared")
;;
shared)
extra_config+=("--enable-shared")
Introduce a new EXPERIMENTAL feature: BARE_METAL. This should ultimately llow to build bare-metal compilers, for targets that have no kernel and no C library. Move the C library build script to their own sub-directory; introduce an empty build script for bare-metal. Move the compiler build script to its own sub-directory. Move the kernel build script to its own sub-directory; introduce an empty build script for bare-metal. Update the ARM target tuples to enable bare-metal targets. Add two ARM bare-metal samples. Add latest Linux kernel versions. /trunk/scripts/build/kernel/none.sh | 77 6 71 0 +---- /trunk/scripts/build/cc/gcc.sh | 58 41 17 0 ++- /trunk/scripts/build/libc/none.sh | 513 9 504 0 +----------------------------- /trunk/scripts/crosstool.sh | 17 9 8 0 + /trunk/scripts/functions | 6 4 2 0 + /trunk/scripts/showSamples.sh | 6 3 3 0 /trunk/samples/arm-unknown-elf/crosstool.config | 225 225 0 0 +++++++++++++ /trunk/samples/arm-unknown-eabi/crosstool.config | 223 223 0 0 +++++++++++++ /trunk/config/kernel/linux_headers_install.in | 64 27 37 0 ++-- /trunk/config/kernel.in | 9 8 1 0 + /trunk/config/toolchain.in | 1 1 0 0 + /trunk/config/cc/gcc.in | 3 3 0 0 + /trunk/config/debug/dmalloc.in | 1 1 0 0 + /trunk/config/debug/gdb.in | 4 3 1 0 + /trunk/config/debug/strace.in | 1 1 0 0 + /trunk/config/debug/duma.in | 1 1 0 0 + /trunk/config/cc.in | 8 8 0 0 + /trunk/config/target.in | 13 13 0 0 + /trunk/config/binutils.in | 1 1 0 0 + /trunk/config/gmp_mpfr.in | 1 1 0 0 + /trunk/config/libc.in | 17 11 6 0 + /trunk/arch/arm/functions | 3 1 2 0 - 22 files changed, 600 insertions(+), 652 deletions(-)
2008-09-14 16:21:07 +00:00
;;
baremetal)
extra_config+=("--with-newlib")
extra_config+=("--enable-threads=no")
extra_config+=("--disable-shared")
;;
*)
CT_Abort "Internal Error: 'mode' must be one of: 'static', 'shared' or 'baremetal', not '${mode:-(empty)}'"
;;
esac
for tmp in ARCH ABI CPU CPU_32 CPU_64 TUNE FPU FLOAT ENDIAN; do
eval tmp="\${CT_ARCH_WITH_${tmp}}"
if [ -n "${tmp}" ]; then
extra_config+=("${tmp}")
fi
done
[ -n "${CT_PKGVERSION}" ] && extra_config+=("--with-pkgversion=${CT_PKGVERSION}")
[ -n "${CT_TOOLCHAIN_BUGURL}" ] && extra_config+=("--with-bugurl=${CT_TOOLCHAIN_BUGURL}")
# Hint GCC we'll use a bit special version of Newlib
if [ "${CT_LIBC_NEWLIB_NANO_FORMATTED_IO}" = "y" ]; then
extra_config+=("--enable-newlib-nano-formatted-io")
fi
if [ "${CT_CC_CXA_ATEXIT}" = "y" ]; then
extra_config+=("--enable-__cxa_atexit")
else
extra_config+=("--disable-__cxa_atexit")
fi
case "${CT_CC_GCC_TM_CLONE_REGISTRY}" in
y) extra_config+=("--enable-tm-clone-registry");;
m) ;;
"") extra_config+=("--disable-tm-clone-registry");;
esac
if [ -n "${CT_CC_GCC_ENABLE_CXX_FLAGS}" \
-a "${mode}" = "baremetal" ]; then
extra_config+=("--enable-cxx-flags=${CT_CC_GCC_ENABLE_CXX_FLAGS}")
fi
extra_config+=(--disable-libgomp)
extra_config+=(--disable-libmudflap)
extra_config+=(--disable-libmpx)
case "${CT_CC_GCC_LIBSSP}" in
y) extra_config+=(--enable-libssp);;
m) ;;
"") extra_config+=(--disable-libssp);;
esac
if [ "${CT_CC_GCC_LIBQUADMATH}" = "y" ]; then
extra_config+=(--enable-libquadmath)
extra_config+=(--enable-libquadmath-support)
else
extra_config+=(--disable-libquadmath)
extra_config+=(--disable-libquadmath-support)
fi
if [ "${build_libstdcxx}" = "no" ]; then
extra_config+=(--disable-libstdcxx)
fi
core_LDFLAGS+=("${ldflags}")
# *** WARNING ! ***
# Keep this full if-else-if-elif-fi-fi block in sync
# with the same block in do_gcc_backend, below.
if [ "${build_staticlinked}" = "yes" ]; then
core_LDFLAGS+=("-static")
if [ "${CT_GCC_older_than_6}" = "y" ]; then
host_libstdcxx_flags+=("-static-libgcc")
host_libstdcxx_flags+=("-Wl,-Bstatic,-lstdc++")
host_libstdcxx_flags+=("-lm")
fi
# Companion libraries are build static (eg !shared), so
# the libstdc++ is not pulled automatically, although it
# is needed. Shoe-horn it in our LDFLAGS
# Ditto libm on some Fedora boxen
core_LDFLAGS+=("-lstdc++")
core_LDFLAGS+=("-lm")
else
if [ "${CT_CC_GCC_STATIC_LIBSTDCXX}" = "y" -a "${CT_GCC_older_than_6}" = "y" ]; then
# this is from CodeSourcery arm-2010q1-202-arm-none-linux-gnueabi.src.tar.bz2
# build script
# INFO: if the host gcc is gcc-4.5 then presumably we could use -static-libstdc++,
# see http://gcc.gnu.org/ml/gcc-patches/2009-06/msg01635.html
host_libstdcxx_flags+=("-static-libgcc")
host_libstdcxx_flags+=("-Wl,-Bstatic,-lstdc++,-Bdynamic")
host_libstdcxx_flags+=("-lm")
fi
# When companion libraries are build static (eg !shared),
# the libstdc++ is not pulled automatically, although it
# is needed. Shoe-horn it in our LDFLAGS
# Ditto libm on some Fedora boxen
core_LDFLAGS+=("-lstdc++")
core_LDFLAGS+=("-lm")
fi
extra_config+=("--with-gmp=${complibs}")
extra_config+=("--with-mpfr=${complibs}")
extra_config+=("--with-mpc=${complibs}")
if [ "${CT_CC_GCC_USE_GRAPHITE}" = "y" ]; then
if [ "${CT_ISL}" = "y" ]; then
extra_config+=("--with-isl=${complibs}")
fi
if [ "${CT_CLOOG}" = "y" ]; then
extra_config+=("--with-cloog=${complibs}")
fi
else
extra_config+=("--with-isl=no")
extra_config+=("--with-cloog=no")
fi
if [ "${CT_CC_GCC_USE_LTO}" = "y" ]; then
extra_config+=("--enable-lto")
else
extra_config+=("--disable-lto")
fi
if [ ${#host_libstdcxx_flags[@]} -ne 0 ]; then
extra_config+=("--with-host-libstdcxx=${host_libstdcxx_flags[*]}")
fi
if [ "${CT_CC_GCC_ENABLE_TARGET_OPTSPACE}" = "y" ] || \
[ "${enable_optspace}" = "yes" ]; then
extra_config+=("--enable-target-optspace")
fi
if [ "${CT_CC_GCC_DISABLE_PCH}" = "y" ]; then
extra_config+=("--disable-libstdcxx-pch")
fi
if [ "${CT_LIBC_GLIBC}" = "y" ]; then
# Report GLIBC's version to GCC, it affects the defaults on other options.
# Pass-2 should be able to get it from the headers, but for some options
# (such as --with-long-double-128) we need to get it right even in pass-1.
# GCC expects just two numbers separated by a dot.
local glibc_version
CT_GetPkgVersion GLIBC glibc_version
case "${glibc_version}" in
new) glibc_version=99.99;;
old) glibc_version=1.0;;
*) glibc_version=`echo "${glibc_version}" | sed 's/\([1-9][0-9]*\.[1-9][0-9]*\).*/\1/'`;;
esac
extra_config+=("--with-glibc-version=${glibc_version}")
fi
case "${CT_CC_GCC_LDBL_128}" in
y) extra_config+=("--with-long-double-128");;
m) ;;
"") extra_config+=("--without-long-double-128");;
esac
if [ "${CT_CC_GCC_BUILD_ID}" = "y" ]; then
extra_config+=( --enable-linker-build-id )
fi
case "${CT_CC_GCC_LNK_HASH_STYLE}" in
"") ;;
*) extra_config+=( "--with-linker-hash-style=${CT_CC_GCC_LNK_HASH_STYLE}" );;
esac
case "${CT_CC_GCC_DEC_FLOATS}" in
"") ;;
*) extra_config+=( "--enable-decimal-float=${CT_CC_GCC_DEC_FLOATS}" );;
esac
case "${CT_ARCH}" in
mips)
case "${CT_CC_GCC_mips_llsc}" in
y) extra_config+=( --with-llsc );;
m) ;;
*) extra_config+=( --without-llsc );;
esac
case "${CT_CC_GCC_mips_synci}" in
y) extra_config+=( --with-synci );;
m) ;;
*) extra_config+=( --without-synci );;
esac
if [ "${CT_CC_GCC_mips_plt}" ]; then
extra_config+=( --with-mips-plt )
fi
;; # ARCH is mips
esac
if [ "${CT_TOOLCHAIN_ENABLE_NLS}" = "y" ]; then
extra_config+=("--with-libintl-prefix=${complibs}")
else
extra_config+=("--disable-nls")
fi
if [ "${CT_CC_GCC_SYSTEM_ZLIB}" = "y" ]; then
extra_config+=("--with-system-zlib")
fi
case "${CT_CC_GCC_CONFIG_TLS}" in
y) extra_config+=("--enable-tls");;
m) ;;
"") extra_config+=("--disable-tls");;
esac
# Some versions of gcc have a defective --enable-multilib.
# Since that's the default, only pass --disable-multilib. For multilib,
# also enable multiarch. Without explicit --enable-multiarch, pass-1
# compiler is configured as multilib/no-multiarch and pass-2/final
# are multilib/multiarch (because gcc autodetects multiarch based on
# multiple instances of crt*.o in the install directory - which do
# not exist in pass-1).
if [ "${CT_MULTILIB}" != "y" ]; then
extra_config+=("--disable-multilib")
else
extra_config+=("--enable-multiarch")
if [ -n "${CT_CC_GCC_MULTILIB_LIST}" ]; then
extra_config+=("--with-multilib-list=${CT_CC_GCC_MULTILIB_LIST}")
fi
fi
CT_DoLog DEBUG "Extra config passed: '${extra_config[*]}'"
# We may need to modify host/build/target CFLAGS separately below. Note
# that ${cflags} may refer either to build or host CFLAGS; they are provided
# by the caller.
cflags_for_build="${CT_CFLAGS_FOR_BUILD}"
cxxflags_for_build="${CT_CXXFLAGS_FOR_BUILD}"
cflags_for_target="${CT_TARGET_CFLAGS}"
# Clang's default bracket-depth is 256, and building GCC
# requires somewhere between 257 and 512.
if [ "${host}" = "${CT_BUILD}" ]; then
if ${CT_BUILD}-gcc --version 2>&1 | grep clang; then
cflags="$cflags -fbracket-depth=512"
cflags_for_build="$cflags_for_build -fbracket-depth=512"
fi
else
# FIXME we currently don't support clang as host compiler, only as build
if ${CT_BUILD}-gcc --version 2>&1 | grep clang; then
cflags_for_build="$cflags_for_build -fbracket-depth=512"
fi
fi
# For non-sysrooted toolchain, GCC doesn't search except at the installation
# prefix; in core-1/2 stage we use a temporary installation prefix - but
# we may have installed something into the final prefix. This is less than ideal:
# in the installation prefix GCC also handles subdirectories for multilibs
# (e.g. first trying ${prefix}/include/${arch-triplet}) but
# we can only pass the top level directory, so non-sysrooted build with libc
# selection that doesn't merge the headers (i.e. musl, uClibc-ng) may not
# work. Better suggestions welcome.
if [ "${CT_USE_SYSROOT}" != "y" ]; then
cflags_for_target="${cflags_for_target} -idirafter ${CT_HEADERS_DIR}"
fi
# Assume '-O2' by default for building target libraries.
cflags_for_target="-g -O2 ${cflags_for_target}"
# Set target CXXFLAGS to CFLAGS if none is provided.
if [ -z "${cxxflags_for_target}" ]; then
cxxflags_for_target="${cflags_for_target}"
fi
# Append extra CXXFLAGS if provided.
if [ -n "${extra_cxxflags_for_target}" ]; then
cxxflags_for_target="${cxxflags_for_target} ${extra_cxxflags_for_target}"
fi
# Use --with-local-prefix so older gccs don't look in /usr/local (http://gcc.gnu.org/PR10532).
# Pass only user-specified CFLAGS/LDFLAGS in CFLAGS_FOR_TARGET/LDFLAGS_FOR_TARGET: during
# the build of, for example, libatomic, GCC tried to compile multiple variants for runtime
# selection and passing architecture/CPU selectors, as detemined by crosstool-NG, may
# miscompile or outright fail.
CT_DoExecLog CFG \
CC_FOR_BUILD="${CT_BUILD}-gcc" \
CFLAGS="${cflags}" \
CFLAGS_FOR_BUILD="${cflags_for_build}" \
CXXFLAGS="${cflags} ${cxxflags_for_build}" \
CXXFLAGS_FOR_BUILD="${cflags_for_build} ${cxxflags_for_build}" \
LDFLAGS="${core_LDFLAGS[*]}" \
CFLAGS_FOR_TARGET="${cflags_for_target}" \
CXXFLAGS_FOR_TARGET="${cxxflags_for_target}" \
LDFLAGS_FOR_TARGET="${CT_TARGET_LDFLAGS}" \
${CONFIG_SHELL} \
"${CT_SRC_DIR}/gcc/configure" \
--build=${CT_BUILD} \
--host=${host} \
--target=${CT_TARGET} \
--prefix="${prefix}" \
--exec_prefix="${exec_prefix}" \
--with-local-prefix="${CT_SYSROOT_DIR}" \
"${extra_config[@]}" \
--enable-languages="${lang_list}" \
"${extra_user_config[@]}"
if [ "${build_libgcc}" = "yes" ]; then
# HACK: we need to override SHLIB_LC from gcc/config/t-slibgcc-elf-ver or
# gcc/config/t-libunwind so -lc is removed from the link for
# libgcc_s.so, as we do not have a target -lc yet.
# This is not as ugly as it appears to be ;-) All symbols get resolved
# during the glibc build, and we provide a proper libgcc_s.so for the
# cross toolchain during the final gcc build.
#
# As we cannot modify the source tree, nor override SHLIB_LC itself
# during configure or make, we have to edit the resultant
# gcc/libgcc.mk itself to remove -lc from the link.
# This causes us to have to jump through some hoops...
#
# To produce libgcc.mk to edit we firstly require libiberty.a,
# so we configure then build it.
# Next we have to configure gcc, create libgcc.mk then edit it...
# So much easier if we just edit the source tree, but hey...
if [ ! -f "${CT_SRC_DIR}/gcc/gcc/BASE-VER" ]; then
CT_DoExecLog CFG make ${CT_JOBSFLAGS} configure-libiberty
CT_DoExecLog ALL make ${CT_JOBSFLAGS} -C libiberty libiberty.a
CT_DoExecLog CFG make ${CT_JOBSFLAGS} configure-gcc configure-libcpp
CT_DoExecLog ALL make ${CT_JOBSFLAGS} all-libcpp
else
CT_DoExecLog CFG make ${CT_JOBSFLAGS} configure-gcc configure-libcpp configure-build-libiberty
CT_DoExecLog ALL make ${CT_JOBSFLAGS} all-libcpp all-build-libiberty
fi
# HACK: gcc-4.2 uses libdecnumber to build libgcc.mk, so build it here.
if [ -d "${CT_SRC_DIR}/gcc/libdecnumber" ]; then
CT_DoExecLog CFG make ${CT_JOBSFLAGS} configure-libdecnumber
CT_DoExecLog ALL make ${CT_JOBSFLAGS} -C libdecnumber libdecnumber.a
fi
# HACK: gcc-4.8 uses libbacktrace to make libgcc.mvars, so make it here.
if [ -d "${CT_SRC_DIR}/gcc/libbacktrace" ]; then
CT_DoExecLog CFG make ${CT_JOBSFLAGS} configure-libbacktrace
CT_DoExecLog ALL make ${CT_JOBSFLAGS} -C libbacktrace
fi
libgcc_rule="libgcc.mvars"
core_targets=( gcc target-libgcc )
# On bare metal and canadian build the host-compiler is used when
# actually the build-system compiler is required. Choose the correct
# compilers for canadian build and use the defaults on other
# configurations.
if [ "${CT_BARE_METAL},${CT_CANADIAN}" = "y,y" ]; then
repair_cc="CC_FOR_BUILD=${CT_BUILD}-gcc \
CXX_FOR_BUILD=${CT_BUILD}-g++ \
GCC_FOR_TARGET=${CT_TARGET}-${CT_CC}"
else
repair_cc=""
fi
CT_DoExecLog ALL make ${CT_JOBSFLAGS} -C gcc ${libgcc_rule} \
${repair_cc}
sed -r -i -e 's@-lc@@g' gcc/${libgcc_rule}
else # build_libgcc
core_targets=( gcc )
fi # ! build libgcc
if [ "${build_libstdcxx}" = "yes" \
-a "${CT_CC_LANG_CXX}" = "y" \
]; then
core_targets+=( target-libstdc++-v3 )
fi
if [ "${build_libgfortran}" = "yes" \
-a "${CT_CC_LANG_FORTRAN}" = "y" \
]; then
core_targets+=( target-libgfortran )
fi
core_targets_all="${core_targets[@]/#/all-}"
core_targets_install="${core_targets[@]/#/install-}"
case "${build_step}" in
gcc_build|gcc_host)
core_targets_all=all
core_targets_install=install
;;
libstdcxx)
core_targets=( target-libstdc++-v3 )
core_targets_all="${core_targets[@]/#/all-}"
core_targets_install="${core_targets[@]/#/install-}"
;;
esac
CT_DoLog EXTRA "Building ${log_txt}"
CT_DoExecLog ALL make ${CT_JOBSFLAGS} ${core_targets_all}
# Do not pass ${CT_JOBSFLAGS} here: recent GCC builds have been failing
# in parallel 'make install' at random locations: libitm, libcilk,
# always for the files that are installed more than once to the same
# location (such as libitm.info).
# The symptom is that the install command fails with "File exists"
# error; running the same command manually succeeds. It looks like
# attempts to remove the destination and re-create it, but another
# install gets in the way.
CT_DoLog EXTRA "Installing ${log_txt}"
CT_DoExecLog ALL make ${core_targets_install}
# Remove the libtool "pseudo-libraries": having them in the installed
# tree makes the libtoolized utilities that are built next assume
# that, for example, libsupc++ is an "accessory library", and not include
# -lsupc++ to the link flags. That breaks ltrace, for example.
multilib: Determine which options may pass through. On some arches (e.g. MIPS) the options like -mabi do not work if specified more than once (see the comment in 100-gcc.sh). Therefore, we need to determine which of the options produced by <arch>.sh can be passed to multilib builds and which must be removed (i.e., which options vary among the multilibs). This presents a chicken-and-egg problem. GCC developers, in their infinite wisdom, do not allow arbitrary multilib specification to be supplied to GCC's configure. Instead, the target (and sometimes some extra options) determine the set of multilibs - which may include different CPUs, different ABIs, different endianness, different FPUs, different floating-point ABIs, ... That is, we don't know which parts vary until we build GCC and ask it. So, the solution implemented here is: - For multilib builds, start with empty CT_ARCH_TARGET_CFLAGS/LDFLAGS. - For multilib builds, require core pass 1. Pass 1 does not build any target binaries, so at that point, our target options have not been used yet. - Provide an API to modify the environment variables for the steps that follow the current one. - As a part of multilib-related housekeeping, determine the variable part of multilibs and filter out these options; pass the rest into CT_TARGET_CFLAGS/LDFLAGS. This still does not handle extra dependencies between GCC options (like -ma implying -mcpu=X -mtune=Y, etc.) but I feel that would complicate matters too much. Let's leave this until there's a compelling case for it. Also, query GCC's sysroot suffix for targets that use it (SuperH, for example) - the default multilib may not work if the command line specifies the default option explicitly (%sysroot_suffix_spec is not aware of multilib defaults). Signed-off-by: Alexey Neyman <stilor@att.net>
2016-03-30 19:15:54 +00:00
CT_DoLog EXTRA "Housekeeping for core gcc compiler"
CT_Pushd "${prefix}"
find . -type f -name "*.la" -exec rm {} \; |CT_DoLog ALL
CT_Popd
if [ "${build_manuals}" = "yes" ]; then
CT_DoLog EXTRA "Building the GCC manuals"
CT_DoExecLog ALL make pdf html
CT_DoLog EXTRA "Installing the GCC manuals"
CT_DoExecLog ALL make install-{pdf,html}-gcc
fi
# Create a symlink ${CT_TARGET}-cc to ${CT_TARGET}-${CT_CC} to always be able
# to call the C compiler with the same, somewhat canonical name.
# check whether compiler has an extension
file="$( ls -1 "${prefix}/bin/${CT_TARGET}-${CT_CC}."* 2>/dev/null || true )"
[ -z "${file}" ] || ext=".${file##*.}"
if [ -f "${prefix}/bin/${CT_TARGET}-${CT_CC}${ext}" ]; then
CT_DoExecLog ALL ln -sfv "${CT_TARGET}-${CT_CC}${ext}" "${prefix}/bin/${CT_TARGET}-cc${ext}"
fi
cc_gcc_multilib_housekeeping cc="${prefix}/bin/${CT_TARGET}-${CT_CC}" \
multilib: Determine which options may pass through. On some arches (e.g. MIPS) the options like -mabi do not work if specified more than once (see the comment in 100-gcc.sh). Therefore, we need to determine which of the options produced by <arch>.sh can be passed to multilib builds and which must be removed (i.e., which options vary among the multilibs). This presents a chicken-and-egg problem. GCC developers, in their infinite wisdom, do not allow arbitrary multilib specification to be supplied to GCC's configure. Instead, the target (and sometimes some extra options) determine the set of multilibs - which may include different CPUs, different ABIs, different endianness, different FPUs, different floating-point ABIs, ... That is, we don't know which parts vary until we build GCC and ask it. So, the solution implemented here is: - For multilib builds, start with empty CT_ARCH_TARGET_CFLAGS/LDFLAGS. - For multilib builds, require core pass 1. Pass 1 does not build any target binaries, so at that point, our target options have not been used yet. - Provide an API to modify the environment variables for the steps that follow the current one. - As a part of multilib-related housekeeping, determine the variable part of multilibs and filter out these options; pass the rest into CT_TARGET_CFLAGS/LDFLAGS. This still does not handle extra dependencies between GCC options (like -ma implying -mcpu=X -mtune=Y, etc.) but I feel that would complicate matters too much. Let's leave this until there's a compelling case for it. Also, query GCC's sysroot suffix for targets that use it (SuperH, for example) - the default multilib may not work if the command line specifies the default option explicitly (%sysroot_suffix_spec is not aware of multilib defaults). Signed-off-by: Alexey Neyman <stilor@att.net>
2016-03-30 19:15:54 +00:00
host="${host}"
# If binutils want the LTO plugin, point them to it
if [ -d "${CT_PREFIX_DIR}/lib/bfd-plugins" -a "${build_step}" = "gcc_host" ]; then
local gcc_version=$(cat "${CT_SRC_DIR}/gcc/gcc/BASE-VER" )
CT_DoExecLog ALL ln -sfv "../../libexec/gcc/${CT_TARGET}/${gcc_version}/liblto_plugin.so" \
"${CT_PREFIX_DIR}/lib/bfd-plugins/liblto_plugin.so"
fi
}
#------------------------------------------------------------------------------
# Build complete gcc to run on build
do_cc_for_build() {
local -a build_final_opts
local build_final_backend
# If native or simple cross toolchain is being built, then build==host;
# nothing to do.
case "${CT_TOOLCHAIN_TYPE}" in
native|cross) return 0;;
esac
build_final_opts+=( "host=${CT_BUILD}" )
build_final_opts+=( "prefix=${CT_BUILDTOOLS_PREFIX_DIR}" )
build_final_opts+=( "complibs=${CT_BUILDTOOLS_PREFIX_DIR}" )
build_final_opts+=( "cflags=${CT_CFLAGS_FOR_BUILD}" )
build_final_opts+=( "ldflags=${CT_LDFLAGS_FOR_BUILD}" )
build_final_opts+=( "lang_list=$( cc_gcc_lang_list )" )
build_final_opts+=( "build_step=gcc_build" )
if [ "${CT_BARE_METAL}" = "y" ]; then
# In the tests I've done, bare-metal was not impacted by the
# lack of such a compiler, but better safe than sorry...
build_final_opts+=( "mode=baremetal" )
build_final_opts+=( "build_libgcc=yes" )
if [ "${CT_LIBC_NONE}" != "y" ]; then
build_final_opts+=( "build_libstdcxx=yes" )
fi
build_final_opts+=( "build_libgfortran=yes" )
if [ "${CT_STATIC_TOOLCHAIN}" = "y" ]; then
build_final_opts+=( "build_staticlinked=yes" )
fi
build_final_backend=do_gcc_core_backend
else
build_final_backend=do_gcc_backend
fi
CT_DoStep INFO "Installing final gcc compiler for build"
CT_mkdir_pushd "${CT_BUILD_DIR}/build-cc-gcc-final-build-${CT_BUILD}"
"${build_final_backend}" "${build_final_opts[@]}"
CT_Popd
CT_EndStep
}
gcc_movelibs()
{
local multi_flags multi_dir multi_os_dir multi_os_dir_gcc multi_root multi_index multi_count
local gcc_dir dst_dir canon_root canon_prefix
local rel
for arg in "$@"; do
eval "${arg// /\\ }"
done
# GCC prints the sysroot in canonicalized form, which may be different if there
# is a symlink in the path. Since we need textual match to obtain a relative
# subdirectory path, canonicalize the prefix directory. Since GCC's behavior
# is not documented and hence may change at any time, canonicalize it too just
# for the good measure.
canon_root=$( cd "${multi_root}" && pwd -P )
canon_prefix=$( cd "${CT_PREFIX_DIR}" && pwd -P )
# Move only files, directories are for other multilibs. We're looking inside
# GCC's directory structure, thus use unmangled multi_os_dir that GCC reports.
gcc_dir="${CT_PREFIX_DIR}/${CT_TARGET}/lib/${multi_os_dir_gcc}"
if [ ! -d "${gcc_dir}" ]; then
# GCC didn't install anything outside of sysroot
return
fi
# Depending on the selected libc, we may or may not have the ${multi_os_dir_gcc}
# created by libc installation. If we do, use it. If we don't, use ${multi_os_dir}
# to avoid creating an otherwise empty directory.
dst_dir="${canon_root}/lib/${multi_os_dir_gcc}"
if [ ! -d "${dst_dir}" ]; then
dst_dir="${canon_root}/lib/${multi_os_dir}"
fi
CT_SanitizeVarDir dst_dir gcc_dir
rel=$( echo "${gcc_dir#${CT_PREFIX_DIR}/}" | sed 's#[^/]\{1,\}#..#g' )
ls "${gcc_dir}" | while read f; do
case "${f}" in
*.ld)
# Linker scripts remain in GCC's directory; elf2flt insists on
# finding them there.
continue
;;
esac
if [ -f "${gcc_dir}/${f}" ]; then
CT_DoExecLog ALL mkdir -p "${dst_dir}"
CT_DoExecLog ALL mv "${gcc_dir}/${f}" "${dst_dir}/${f}"
CT_DoExecLog ALL ln -sf "${rel}/${dst_dir#${canon_prefix}/}/${f}" "${gcc_dir}/${f}"
fi
done
}
#------------------------------------------------------------------------------
# Build final gcc to run on host
do_cc_for_host() {
local -a final_opts
local final_backend
final_opts+=( "host=${CT_HOST}" )
final_opts+=( "prefix=${CT_PREFIX_DIR}" )
final_opts+=( "complibs=${CT_HOST_COMPLIBS_DIR}" )
final_opts+=( "cflags=${CT_CFLAGS_FOR_HOST}" )
final_opts+=( "ldflags=${CT_LDFLAGS_FOR_HOST}" )
final_opts+=( "lang_list=$( cc_gcc_lang_list )" )
final_opts+=( "build_step=gcc_host" )
if [ "${CT_BUILD_MANUALS}" = "y" ]; then
final_opts+=( "build_manuals=yes" )
fi
if [ "${CT_BARE_METAL}" = "y" ]; then
final_opts+=( "mode=baremetal" )
final_opts+=( "build_libgcc=yes" )
if [ "${CT_LIBC_NONE}" != "y" ]; then
final_opts+=( "build_libstdcxx=yes" )
fi
final_opts+=( "build_libgfortran=yes" )
if [ "${CT_STATIC_TOOLCHAIN}" = "y" ]; then
final_opts+=( "build_staticlinked=yes" )
fi
final_backend=do_gcc_core_backend
else
final_backend=do_gcc_backend
fi
CT_DoStep INFO "Installing final gcc compiler"
CT_mkdir_pushd "${CT_BUILD_DIR}/build-cc-gcc-final"
"${final_backend}" "${final_opts[@]}"
CT_Popd
# GCC installs stuff (including libgcc) into its own /lib dir,
# outside of sysroot, breaking linking with -static-libgcc.
# Fix up by moving the libraries into the sysroot.
if [ "${CT_USE_SYSROOT}" = "y" ]; then
CT_mkdir_pushd "${CT_BUILD_DIR}/build-cc-gcc-final-movelibs"
CT_IterateMultilibs gcc_movelibs movelibs
CT_Popd
fi
CT_EndStep
}
#------------------------------------------------------------------------------
# Build the final gcc
# Usage: do_gcc_backend param=value [...]
# Parameter : Definition : Type : Default
# host : the host we run onto : tuple : (none)
# prefix : the runtime prefix : dir : (none)
# exec_prefix : prefix for executables : dir : (none)
# complibs : the companion libraries prefix : dir : (none)
# cflags : cflags to use : string : (empty)
# ldflags : ldflags to use : string : (empty)
# lang_list : the list of languages to build : string : (empty)
# build_manuals : whether to build manuals or not : bool : no
# build_step : build step 'gcc_build', 'gcc_host'
# or 'libstdcxx' : string : (none)
do_gcc_backend() {
local host
local prefix
local exec_prefix
local complibs
local lang_list
local cflags
local cflags_for_build
local cxxflags_for_build
local cflags_for_target
local cxxflags_for_target
local extra_cxxflags_for_target
local ldflags
local build_manuals
local exec_prefix
local header_dir
local libstdcxx_name
local -a host_libstdcxx_flags
local -a extra_config
local -a final_LDFLAGS
local tmp
local arg
for arg in "$@"; do
eval "${arg// /\\ }"
done
if [ "${exec_prefix}" = "" ]; then
exec_prefix="${prefix}"
fi
# This function gets called for final gcc and libstdcxx.
case "${build_step}" in
gcc_build|gcc_host)
log_txt="final gcc compiler"
;;
libstdcxx)
log_txt="libstdc++ library for ${libstdcxx_name}"
;;
*)
CT_Abort "Internal Error: 'build_step' must be one of: 'gcc_build', 'gcc_host' or 'libstdcxx', not '${build_step:-(empty)}'"
;;
esac
CT_DoLog EXTRA "Configuring ${log_txt}"
# Enable selected languages
extra_config+=("--enable-languages=${lang_list}")
for tmp in ARCH ARCH_32 ARCH_64 ABI CPU CPU_32 CPU_64 TUNE TUNE_32 TUNE_64 FPU FLOAT; do
eval tmp="\${CT_ARCH_WITH_${tmp}}"
if [ -n "${tmp}" ]; then
extra_config+=("${tmp}")
fi
done
[ -n "${CT_PKGVERSION}" ] && extra_config+=("--with-pkgversion=${CT_PKGVERSION}")
[ -n "${CT_TOOLCHAIN_BUGURL}" ] && extra_config+=("--with-bugurl=${CT_TOOLCHAIN_BUGURL}")
if [ "${CT_SHARED_LIBS}" != "y" ]; then
extra_config+=("--disable-shared")
fi
case "${CT_CC_GCC_SJLJ_EXCEPTIONS}" in
y) extra_config+=("--enable-sjlj-exceptions");;
m) ;;
"") extra_config+=("--disable-sjlj-exceptions");;
esac
if [ "${CT_CC_CXA_ATEXIT}" = "y" ]; then
extra_config+=("--enable-__cxa_atexit")
else
extra_config+=("--disable-__cxa_atexit")
fi
case "${CT_CC_GCC_TM_CLONE_REGISTRY}" in
y) extra_config+=("--enable-tm-clone-registry");;
m) ;;
"") extra_config+=("--disable-tm-clone-registry");;
esac
if [ -n "${CT_CC_GCC_ENABLE_CXX_FLAGS}" ]; then
extra_config+=("--enable-cxx-flags=${CT_CC_GCC_ENABLE_CXX_FLAGS}")
/devel/gcc-4.4: - add gcc-4.4.0 patches, vampirised from the Gentoo patchset - gcc-4.4.0 auto-selects and uses appropriate companion linraries -------- diffstat follows -------- /devel/gcc-4.4/scripts/build/cc/gcc.sh | 20 18 2 0 + /devel/gcc-4.4/patches/gcc/4.4.0/280-freebsd.patch | 188 188 0 0 ++++++++++ /devel/gcc-4.4/patches/gcc/4.4.0/140-default-format-security.patch | 98 98 0 0 +++++ /devel/gcc-4.4/patches/gcc/4.4.0/290-freebsd.patch | 128 128 0 0 +++++++ /devel/gcc-4.4/patches/gcc/4.4.0/310-uclibc-conf.patch | 70 70 0 0 ++++ /devel/gcc-4.4/patches/gcc/4.4.0/240-libstdc++-pic.patch | 106 106 0 0 ++++++ /devel/gcc-4.4/patches/gcc/4.4.0/260-sh-libgcc-stacks.patch | 50 50 0 0 +++ /devel/gcc-4.4/patches/gcc/4.4.0/100-alpha-mieee-default.patch | 48 48 0 0 +++ /devel/gcc-4.4/patches/gcc/4.4.0/180-libgomp-no-werror.patch | 24 24 0 0 + /devel/gcc-4.4/patches/gcc/4.4.0/170-sparc64-bsd.patch | 58 58 0 0 +++ /devel/gcc-4.4/patches/gcc/4.4.0/200-libiberty.h-asprintf.patch | 30 30 0 0 ++ /devel/gcc-4.4/patches/gcc/4.4.0/220-libiberty-pic.patch | 22 22 0 0 + /devel/gcc-4.4/patches/gcc/4.4.0/110-trampolinewarn.patch | 54 54 0 0 +++ /devel/gcc-4.4/patches/gcc/4.4.0/160-netbsd-symbolic.patch | 22 22 0 0 + /devel/gcc-4.4/patches/gcc/4.4.0/190-flatten-switch-stmt-00.patch | 48 48 0 0 +++ /devel/gcc-4.4/patches/gcc/4.4.0/150-default-fortify-source.patch | 52 52 0 0 +++ /devel/gcc-4.4/patches/gcc/4.4.0/340-libmudflap-susv3-legacy.patch | 96 96 0 0 +++++ /devel/gcc-4.4/patches/gcc/4.4.0/120-java-nomulti.patch | 92 92 0 0 +++++ /devel/gcc-4.4/patches/gcc/4.4.0/270-sh-pr24836.patch | 48 48 0 0 +++ /devel/gcc-4.4/patches/gcc/4.4.0/330-c99-snprintf.patch | 24 24 0 0 + /devel/gcc-4.4/patches/gcc/4.4.0/230-superh-default-multilib.patch | 24 24 0 0 + /devel/gcc-4.4/patches/gcc/4.4.0/250-ia64-noteGNUstack.patch | 158 158 0 0 +++++++++ /devel/gcc-4.4/patches/gcc/4.4.0/300-pr40105.patch | 360 360 0 0 ++++++++++++++++++++ /devel/gcc-4.4/patches/gcc/4.4.0/210-arm-unbreak-armv4t.patch | 24 24 0 0 + /devel/gcc-4.4/patches/gcc/4.4.0/130-cross-compile.patch | 78 78 0 0 ++++ /devel/gcc-4.4/patches/gcc/4.4.0/320-missing-execinfo_h.patch | 24 24 0 0 + /devel/gcc-4.4/config/cc/gcc.in | 1 1 0 0 + 27 files changed, 1945 insertions(+), 2 deletions(-)
2009-05-27 21:16:01 +00:00
fi
if [ "${CT_THREADS}" = "none" ]; then
extra_config+=(--disable-libatomic)
fi
if [ "${CT_CC_GCC_LIBMUDFLAP}" = "y" ]; then
extra_config+=(--enable-libmudflap)
else
extra_config+=(--disable-libmudflap)
fi
if [ "${CT_CC_GCC_LIBGOMP}" = "y" ]; then
extra_config+=(--enable-libgomp)
else
extra_config+=(--disable-libgomp)
fi
case "${CT_CC_GCC_LIBSSP}" in
y) extra_config+=(--enable-libssp);;
m) ;;
"") extra_config+=(--disable-libssp);;
esac
if [ "${CT_CC_GCC_LIBQUADMATH}" = "y" ]; then
extra_config+=(--enable-libquadmath)
extra_config+=(--enable-libquadmath-support)
else
extra_config+=(--disable-libquadmath)
extra_config+=(--disable-libquadmath-support)
fi
if [ "${CT_CC_GCC_LIBSANITIZER}" = "y" ]; then
extra_config+=(--enable-libsanitizer)
else
extra_config+=(--disable-libsanitizer)
fi
if [ "${CT_CC_GCC_HAS_LIBMPX}" = "y" ]; then
if [ "${CT_CC_GCC_LIBMPX}" = "y" ]; then
extra_config+=(--enable-libmpx)
else
extra_config+=(--disable-libmpx)
fi
fi
if [ "${build_libstdcxx}" = "no" ]; then
extra_config+=(--disable-libstdcxx)
fi
final_LDFLAGS+=("${ldflags}")
# *** WARNING ! ***
# Keep this full if-else-if-elif-fi-fi block in sync
# with the same block in do_gcc_core_backend, above.
if [ "${CT_STATIC_TOOLCHAIN}" = "y" ]; then
final_LDFLAGS+=("-static")
if [ "${CT_GCC_older_than_6}" = "y" ]; then
host_libstdcxx_flags+=("-static-libgcc")
host_libstdcxx_flags+=("-Wl,-Bstatic,-lstdc++")
host_libstdcxx_flags+=("-lm")
fi
# Companion libraries are build static (eg !shared), so
# the libstdc++ is not pulled automatically, although it
# is needed. Shoe-horn it in our LDFLAGS
# Ditto libm on some Fedora boxen
final_LDFLAGS+=("-lstdc++")
final_LDFLAGS+=("-lm")
else
if [ "${CT_CC_GCC_STATIC_LIBSTDCXX}" = "y" -a "${CT_GCC_older_than_6}" = "y" ]; then
# this is from CodeSourcery arm-2010q1-202-arm-none-linux-gnueabi.src.tar.bz2
# build script
# INFO: if the host gcc is gcc-4.5 then presumably we could use -static-libstdc++,
# see http://gcc.gnu.org/ml/gcc-patches/2009-06/msg01635.html
host_libstdcxx_flags+=("-static-libgcc")
host_libstdcxx_flags+=("-Wl,-Bstatic,-lstdc++,-Bdynamic")
host_libstdcxx_flags+=("-lm")
fi
# When companion libraries are build static (eg !shared),
# the libstdc++ is not pulled automatically, although it
# is needed. Shoe-horn it in our LDFLAGS
# Ditto libm on some Fedora boxen
final_LDFLAGS+=("-lstdc++")
final_LDFLAGS+=("-lm")
fi
extra_config+=("--with-gmp=${complibs}")
extra_config+=("--with-mpfr=${complibs}")
extra_config+=("--with-mpc=${complibs}")
if [ "${CT_CC_GCC_USE_GRAPHITE}" = "y" ]; then
if [ "${CT_ISL}" = "y" ]; then
extra_config+=("--with-isl=${complibs}")
fi
if [ "${CT_CLOOG}" = "y" ]; then
extra_config+=("--with-cloog=${complibs}")
fi
else
extra_config+=("--with-isl=no")
extra_config+=("--with-cloog=no")
2010-03-05 17:55:25 +00:00
fi
if [ "${CT_CC_GCC_USE_LTO}" = "y" ]; then
extra_config+=("--enable-lto")
else
extra_config+=("--disable-lto")
fi
case "${CT_CC_GCC_LTO_ZSTD}" in
y) extra_config+=("--with-zstd");;
m) ;;
*) extra_config+=("--without-zstd");;
esac
if [ ${#host_libstdcxx_flags[@]} -ne 0 ]; then
extra_config+=("--with-host-libstdcxx=${host_libstdcxx_flags[*]}")
fi
if [ "${CT_THREADS}" = "none" ]; then
extra_config+=("--disable-threads")
else
if [ "${CT_THREADS}" = "win32" ]; then
extra_config+=("--enable-threads=win32")
extra_config+=("--disable-win32-registry")
else
extra_config+=("--enable-threads=posix")
fi
fi
if [ "${CT_CC_GCC_ENABLE_TARGET_OPTSPACE}" = "y" ] || \
[ "${enable_optspace}" = "yes" ]; then
extra_config+=("--enable-target-optspace")
fi
if [ "${CT_CC_GCC_DISABLE_PCH}" = "y" ]; then
extra_config+=("--disable-libstdcxx-pch")
fi
case "${CT_CC_GCC_LDBL_128}" in
y) extra_config+=("--with-long-double-128");;
m) ;;
"") extra_config+=("--without-long-double-128");;
esac
if [ "${CT_CC_GCC_BUILD_ID}" = "y" ]; then
extra_config+=( --enable-linker-build-id )
fi
case "${CT_CC_GCC_LNK_HASH_STYLE}" in
"") ;;
*) extra_config+=( "--with-linker-hash-style=${CT_CC_GCC_LNK_HASH_STYLE}" );;
esac
case "${CT_CC_GCC_DEC_FLOATS}" in
"") ;;
*) extra_config+=( "--enable-decimal-float=${CT_CC_GCC_DEC_FLOATS}" );;
esac
if [ "${CT_CC_GCC_ENABLE_PLUGINS}" = "y" ]; then
extra_config+=( --enable-plugin )
else
extra_config+=( --disable-plugin )
fi
if [ "${CT_CC_GCC_GOLD}" = "y" ]; then
extra_config+=( --enable-gold )
fi
case "${CT_ARCH}" in
mips)
case "${CT_CC_GCC_mips_llsc}" in
y) extra_config+=( --with-llsc );;
m) ;;
*) extra_config+=( --without-llsc );;
esac
case "${CT_CC_GCC_mips_synci}" in
y) extra_config+=( --with-synci );;
m) ;;
*) extra_config+=( --without-synci );;
esac
if [ "${CT_CC_GCC_mips_plt}" ]; then
extra_config+=( --with-mips-plt )
fi
;; # ARCH is mips
esac
if [ "${CT_TOOLCHAIN_ENABLE_NLS}" = "y" ]; then
extra_config+=("--with-libintl-prefix=${complibs}")
else
extra_config+=("--disable-nls")
fi
if [ "${CT_CC_GCC_SYSTEM_ZLIB}" = "y" ]; then
extra_config+=("--with-system-zlib")
fi
case "${CT_CC_GCC_CONFIG_TLS}" in
y) extra_config+=("--enable-tls");;
m) ;;
"") extra_config+=("--disable-tls");;
esac
# Some versions of gcc have a defective --enable-multilib.
# Since that's the default, only pass --disable-multilib.
if [ "${CT_MULTILIB}" != "y" ]; then
extra_config+=("--disable-multilib")
else
extra_config+=("--enable-multiarch")
if [ -n "${CT_CC_GCC_MULTILIB_LIST}" ]; then
extra_config+=("--with-multilib-list=${CT_CC_GCC_MULTILIB_LIST}")
fi
fi
CT_DoLog DEBUG "Extra config passed: '${extra_config[*]}'"
# We may need to modify host/build/target CFLAGS separately below
cflags_for_build="${cflags}"
cxxflags_for_build="${CT_CXXFLAGS_FOR_BUILD}"
cflags_for_target="${CT_TARGET_CFLAGS}"
# Clang's default bracket-depth is 256, and building GCC
# requires somewhere between 257 and 512.
if [ "${host}" = "${CT_BUILD}" ]; then
if ${CT_BUILD}-gcc --version 2>&1 | grep clang; then
cflags="$cflags "-fbracket-depth=512
cflags_for_build="$cflags_for_build "-fbracket-depth=512
fi
else
# FIXME we currently don't support clang as host compiler, only as build
if ${CT_BUILD}-gcc --version 2>&1 | grep clang; then
cflags_for_build="$cflags_for_build "-fbracket-depth=512
fi
fi
# Assume '-O2' by default for building target libraries.
cflags_for_target="-g -O2 ${cflags_for_target}"
# Set target CXXFLAGS to CFLAGS if none is provided.
if [ -z "${cxxflags_for_target}" ]; then
cxxflags_for_target="${cflags_for_target}"
fi
# Append extra CXXFLAGS if provided.
if [ -n "${extra_cxxflags_for_target}" ]; then
cxxflags_for_target="${cxxflags_for_target} ${extra_cxxflags_for_target}"
fi
# NB: not using CT_ALL_TARGET_CFLAGS/CT_ALL_TARGET_LDFLAGS here!
# See do_gcc_core_backend for explanation.
CT_DoExecLog CFG \
CC_FOR_BUILD="${CT_BUILD}-gcc" \
CFLAGS="${cflags}" \
CFLAGS_FOR_BUILD="${cflags_for_build}" \
CXXFLAGS="${cflags} ${cxxflags_for_build}" \
CXXFLAGS_FOR_BUILD="${cflags_for_build} ${cxxflags_for_build}" \
LDFLAGS="${final_LDFLAGS[*]}" \
CFLAGS_FOR_TARGET="${cflags_for_target}" \
CXXFLAGS_FOR_TARGET="${cxxflags_for_target}" \
LDFLAGS_FOR_TARGET="${CT_TARGET_LDFLAGS}" \
${CONFIG_SHELL} \
"${CT_SRC_DIR}/gcc/configure" \
--build=${CT_BUILD} \
--host=${host} \
--target=${CT_TARGET} \
--prefix="${prefix}" \
--exec_prefix="${exec_prefix}" \
${CT_CC_SYSROOT_ARG} \
"${extra_config[@]}" \
--with-local-prefix="${CT_SYSROOT_DIR}" \
--enable-long-long \
"${CT_CC_GCC_EXTRA_CONFIG_ARRAY[@]}"
if [ "${CT_CANADIAN}" = "y" ]; then
CT_DoLog EXTRA "Building libiberty"
CT_DoExecLog ALL make ${CT_JOBSFLAGS} all-build-libiberty
fi
CT_DoLog EXTRA "Building final gcc compiler"
CT_DoExecLog ALL make ${CT_JOBSFLAGS} all
# See the note on issues with parallel 'make install' in GCC above.
CT_DoLog EXTRA "Installing final gcc compiler"
if [ "${CT_STRIP_TARGET_TOOLCHAIN_EXECUTABLES}" = "y" ]; then
CT_DoExecLog ALL make install-strip
else
CT_DoExecLog ALL make install
fi
# Remove the libtool "pseudo-libraries": having them in the installed
# tree makes the libtoolized utilities that are built next assume
# that, for example, libsupc++ is an "accessory library", and not include
# -lsupc++ to the link flags. That breaks ltrace, for example.
CT_DoLog EXTRA "Housekeeping for final gcc compiler"
CT_Pushd "${prefix}"
find . -type f -name "*.la" -exec rm {} \; |CT_DoLog ALL
CT_Popd
if [ "${build_manuals}" = "yes" ]; then
CT_DoLog EXTRA "Building the GCC manuals"
CT_DoExecLog ALL make pdf html
CT_DoLog EXTRA "Installing the GCC manuals"
CT_DoExecLog ALL make install-{pdf,html}-gcc
fi
# Create a symlink ${CT_TARGET}-cc to ${CT_TARGET}-${CT_CC} to always be able
# to call the C compiler with the same, somewhat canonical name.
# check whether compiler has an extension
file="$( ls -1 "${CT_PREFIX_DIR}/bin/${CT_TARGET}-${CT_CC}."* 2>/dev/null || true )"
[ -z "${file}" ] || ext=".${file##*.}"
if [ -f "${CT_PREFIX_DIR}/bin/${CT_TARGET}-${CT_CC}${ext}" ]; then
CT_DoExecLog ALL ln -sfv "${CT_TARGET}-${CT_CC}${ext}" "${prefix}/bin/${CT_TARGET}-cc${ext}"
fi
cc_gcc_multilib_housekeeping cc="${prefix}/bin/${CT_TARGET}-${CT_CC}" \
multilib: Determine which options may pass through. On some arches (e.g. MIPS) the options like -mabi do not work if specified more than once (see the comment in 100-gcc.sh). Therefore, we need to determine which of the options produced by <arch>.sh can be passed to multilib builds and which must be removed (i.e., which options vary among the multilibs). This presents a chicken-and-egg problem. GCC developers, in their infinite wisdom, do not allow arbitrary multilib specification to be supplied to GCC's configure. Instead, the target (and sometimes some extra options) determine the set of multilibs - which may include different CPUs, different ABIs, different endianness, different FPUs, different floating-point ABIs, ... That is, we don't know which parts vary until we build GCC and ask it. So, the solution implemented here is: - For multilib builds, start with empty CT_ARCH_TARGET_CFLAGS/LDFLAGS. - For multilib builds, require core pass 1. Pass 1 does not build any target binaries, so at that point, our target options have not been used yet. - Provide an API to modify the environment variables for the steps that follow the current one. - As a part of multilib-related housekeeping, determine the variable part of multilibs and filter out these options; pass the rest into CT_TARGET_CFLAGS/LDFLAGS. This still does not handle extra dependencies between GCC options (like -ma implying -mcpu=X -mtune=Y, etc.) but I feel that would complicate matters too much. Let's leave this until there's a compelling case for it. Also, query GCC's sysroot suffix for targets that use it (SuperH, for example) - the default multilib may not work if the command line specifies the default option explicitly (%sysroot_suffix_spec is not aware of multilib defaults). Signed-off-by: Alexey Neyman <stilor@att.net>
2016-03-30 19:15:54 +00:00
host="${host}"
# If binutils want the LTO plugin, point them to it
if [ -d "${CT_PREFIX_DIR}/lib/bfd-plugins" -a "${build_step}" = "gcc_host" ]; then
local gcc_version=$(cat "${CT_SRC_DIR}/gcc/gcc/BASE-VER" )
CT_DoExecLog ALL ln -sfv "../../libexec/gcc/${CT_TARGET}/${gcc_version}/liblto_plugin.so" \
"${CT_PREFIX_DIR}/lib/bfd-plugins/liblto_plugin.so"
fi
}