# # Copyright (c) 2011, 2022, Oracle and/or its affiliates. All rights reserved. # DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. # # This code is free software; you can redistribute it and/or modify it # under the terms of the GNU General Public License version 2 only, as # published by the Free Software Foundation. Oracle designates this # particular file as subject to the "Classpath" exception as provided # by Oracle in the LICENSE file that accompanied this code. # # This code is distributed in the hope that it will be useful, but WITHOUT # ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or # FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License # version 2 for more details (a copy is included in the LICENSE file that # accompanied this code). # # You should have received a copy of the GNU General Public License version # 2 along with this work; if not, write to the Free Software Foundation, # Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. # # Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA # or visit www.oracle.com if you need additional information or have any # questions. #
######################################################################## # This file is responsible for detecting, verifying and setting up the # toolchain, i.e. the compiler, linker and related utilities. It will setup # proper paths to the binaries, but it will not setup any flags. # # The binaries used is determined by the toolchain type, which is the family of # compilers and related tools that are used. ########################################################################
m4_include([toolchain_microsoft.m4])
# All valid toolchains, regardless of platform (used by help.m4)
VALID_TOOLCHAINS_all="gcc clang xlc microsoft"
# These toolchains are valid on different platforms
VALID_TOOLCHAINS_linux="gcc clang"
VALID_TOOLCHAINS_macosx="clang"
VALID_TOOLCHAINS_aix="xlc"
VALID_TOOLCHAINS_windows="microsoft"
# Minimum supported linker versions, empty means unspecified
TOOLCHAIN_MINIMUM_LD_VERSION_gcc="2.18"
# Prepare the system so that TOOLCHAIN_CHECK_COMPILER_VERSION can be called. # Must have CC_VERSION_NUMBER and CXX_VERSION_NUMBER. # $1 - optional variable prefix for compiler and version variables (BUILD_) # $2 - optional variable prefix for comparable variable (OPENJDK_BUILD_) # $3 - optional human readable description for the type of compilers ("build " or "")
AC_DEFUN([TOOLCHAIN_PREPARE_FOR_VERSION_COMPARISONS],
[ if test "x[$]$1CC_VERSION_NUMBER" != "x[$]$1CXX_VERSION_NUMBER"; then
AC_MSG_WARN([The $3C and C++ compilers have different version numbers, [$]$1CC_VERSION_NUMBER vs [$]$1CXX_VERSION_NUMBER.])
AC_MSG_WARN([This typically indicates a broken setup, and is not supported]) fi
# We only check CC_VERSION_NUMBER since we assume CXX_VERSION_NUMBER is equal. if [ [[ "[$]$1CC_VERSION_NUMBER" =~ (.*\.){4} ]] ]; then
AC_MSG_WARN([C compiler version number has more than four parts (W.X.Y.Z): [$]$1CC_VERSION_NUMBER. Comparisons might be wrong.]) fi
if [ [[ "[$]$1CC_VERSION_NUMBER" =~ [0-9]{6} ]] ]; then
AC_MSG_WARN([C compiler version number has a part larger than 99999: [$]$1CC_VERSION_NUMBER. Comparisons might be wrong.]) fi
# Check if the configured compiler (C and C++) is of a specific version or # newer. TOOLCHAIN_PREPARE_FOR_VERSION_COMPARISONS must have been called before. # # Arguments: # VERSION: The version string to check against the found version # IF_AT_LEAST: block to run if the compiler is at least this version (>=) # IF_OLDER_THAN: block to run if the compiler is older than this version (<) # PREFIX: Optional variable prefix for compiler to compare version for (OPENJDK_BUILD_)
UTIL_DEFUN_NAMED([TOOLCHAIN_CHECK_COMPILER_VERSION],
[*VERSION PREFIX IF_AT_LEAST IF_OLDER_THAN], [$@],
[ # Need to assign to a variable since m4 is blocked from modifying parts in [].
REFERENCE_VERSION=ARG_VERSION
if [ [[ "$REFERENCE_VERSION" =~ (.*\.){4} ]] ]; then
AC_MSG_ERROR([Internal error: Cannot compare to ARG_VERSION, only four parts (W.X.Y.Z) is supported]) fi
if [ [[ "$REFERENCE_VERSION" =~ [0-9]{6} ]] ]; then
AC_MSG_ERROR([Internal error: Cannot compare to ARG_VERSION, only parts < 99999 is supported]) fi
# Version comparison method inspired by http://stackoverflow.com/a/24067243
COMPARABLE_REFERENCE_VERSION=`$AWK -F. '{ printf("%05d%05d%05d%05d\n", [$]1, [$]2, [$]3, [$]4) }' <<< "$REFERENCE_VERSION"`
if test [$]ARG_PREFIX[COMPARABLE_ACTUAL_VERSION] -ge $COMPARABLE_REFERENCE_VERSION ; then
:
ARG_IF_AT_LEAST else
:
ARG_IF_OLDER_THAN fi
])
# Prepare the system so that TOOLCHAIN_CHECK_COMPILER_VERSION can be called. # Must have LD_VERSION_NUMBER. # $1 - optional variable prefix for compiler and version variables (BUILD_) # $2 - optional variable prefix for comparable variable (OPENJDK_BUILD_)
AC_DEFUN([TOOLCHAIN_PREPARE_FOR_LD_VERSION_COMPARISONS],
[ if [ [[ "[$]$1LD_VERSION_NUMBER" =~ (.*\.){4} ]] ]; then
AC_MSG_WARN([Linker version number has more than four parts (W.X.Y.Z): [$]$1LD_VERSION_NUMBER. Comparisons might be wrong.]) fi
if [ [[ "[$]$1LD_VERSION_NUMBER" =~ [0-9]{6} ]] ]; then
AC_MSG_WARN([Linker version number has a part larger than 99999: [$]$1LD_VERSION_NUMBER. Comparisons might be wrong.]) fi
# Check if the configured linker is of a specific version or # newer. TOOLCHAIN_PREPARE_FOR_LD_VERSION_COMPARISONS must have been called before. # # Arguments: # VERSION: The version string to check against the found version # IF_AT_LEAST: block to run if the compiler is at least this version (>=) # IF_OLDER_THAN: block to run if the compiler is older than this version (<) # PREFIX: Optional variable prefix for compiler to compare version for (OPENJDK_BUILD_)
UTIL_DEFUN_NAMED([TOOLCHAIN_CHECK_LINKER_VERSION],
[*VERSION PREFIX IF_AT_LEAST IF_OLDER_THAN], [$@],
[ # Need to assign to a variable since m4 is blocked from modifying parts in [].
REFERENCE_VERSION=ARG_VERSION
if [ [[ "$REFERENCE_VERSION" =~ (.*\.){4} ]] ]; then
AC_MSG_ERROR([Internal error: Cannot compare to ARG_VERSION, only four parts (W.X.Y.Z) is supported]) fi
if [ [[ "$REFERENCE_VERSION" =~ [0-9]{6} ]] ]; then
AC_MSG_ERROR([Internal error: Cannot compare to ARG_VERSION, only parts < 99999 is supported]) fi
# Version comparison method inspired by http://stackoverflow.com/a/24067243
COMPARABLE_REFERENCE_VERSION=`$AWK -F. '{ printf("%05d%05d%05d%05d\n", [$]1, [$]2, [$]3, [$]4) }' <<< "$REFERENCE_VERSION"`
if test [$]ARG_PREFIX[COMPARABLE_ACTUAL_LD_VERSION] -ge $COMPARABLE_REFERENCE_VERSION ; then
:
ARG_IF_AT_LEAST else
:
ARG_IF_OLDER_THAN fi
])
# Setup a number of variables describing how native output files are # named on this platform/toolchain.
AC_DEFUN([TOOLCHAIN_SETUP_FILENAME_PATTERNS],
[ # Define filename patterns if test "x$OPENJDK_TARGET_OS" = xwindows; then
LIBRARY_PREFIX=
SHARED_LIBRARY_SUFFIX='.dll'
STATIC_LIBRARY_SUFFIX='.lib'
SHARED_LIBRARY='[$]1.dll'
STATIC_LIBRARY='[$]1.lib'
OBJ_SUFFIX='.obj'
EXECUTABLE_SUFFIX='.exe' else
LIBRARY_PREFIX=lib
SHARED_LIBRARY_SUFFIX='.so'
STATIC_LIBRARY_SUFFIX='.a'
SHARED_LIBRARY='lib[$]1.so'
STATIC_LIBRARY='lib[$]1.a'
OBJ_SUFFIX='.o'
EXECUTABLE_SUFFIX='' if test "x$OPENJDK_TARGET_OS" = xmacosx; then # For full static builds, we're overloading the SHARED_LIBRARY # variables in order to limit the amount of changes required. # It would be better to remove SHARED and just use LIBRARY and # LIBRARY_SUFFIX for libraries that can be built either # shared or static and use STATIC_* for libraries that are # always built statically. if test "x$STATIC_BUILD" = xtrue; then
SHARED_LIBRARY='lib[$]1.a'
SHARED_LIBRARY_SUFFIX='.a' else
SHARED_LIBRARY='lib[$]1.dylib'
SHARED_LIBRARY_SUFFIX='.dylib' fi fi fi
# Determine which toolchain type to use, and make sure it is valid for this # platform. Setup various information about the selected toolchain.
AC_DEFUN_ONCE([TOOLCHAIN_DETERMINE_TOOLCHAIN_TYPE],
[
AC_ARG_WITH(toolchain-type, [AS_HELP_STRING([--with-toolchain-type],
[the toolchain type (or family) to use, use '--help' to show possible values @<:@platform dependent@:>@])])
# Linux x86_64 needs higher binutils after 8265783 # (this really is a dependency on as version, but we take ld as a check for a general binutils version) if test "x$OPENJDK_TARGET_CPU" = "xx86_64"; then
TOOLCHAIN_MINIMUM_LD_VERSION_gcc="2.25" fi
# Use indirect variable referencing
toolchain_var_name=VALID_TOOLCHAINS_$OPENJDK_BUILD_OS
VALID_TOOLCHAINS=${!toolchain_var_name}
# First toolchain type in the list is the default
DEFAULT_TOOLCHAIN=${VALID_TOOLCHAINS%% *}
if test "x$with_toolchain_type" = xlist; then # List all toolchains
AC_MSG_NOTICE([The following toolchains are valid on this platform:]) for toolchain in $VALID_TOOLCHAINS; do
toolchain_var_name=TOOLCHAIN_DESCRIPTION_$toolchain
TOOLCHAIN_DESCRIPTION=${!toolchain_var_name}
$PRINTF " %-10s %s\n" $toolchain "$TOOLCHAIN_DESCRIPTION" done
exit 0 elif test "x$with_toolchain_type" != x; then # User override; check that it is valid if test "x${VALID_TOOLCHAINS/$with_toolchain_type/}" = "x${VALID_TOOLCHAINS}"; then
AC_MSG_NOTICE([Toolchain type $with_toolchain_type is not valid on this platform.])
AC_MSG_NOTICE([Valid toolchains: $VALID_TOOLCHAINS.])
AC_MSG_ERROR([Cannot continue.]) fi
TOOLCHAIN_TYPE=$with_toolchain_type else # No flag given, use default
TOOLCHAIN_TYPE=$DEFAULT_TOOLCHAIN fi
AC_SUBST(TOOLCHAIN_TYPE)
# on AIX, check for xlclang++ on the PATH and TOOLCHAIN_PATH and use it if it is available if test "x$OPENJDK_TARGET_OS" = xaix; then if test "x$TOOLCHAIN_PATH" != x; then
XLC_TEST_PATH=${TOOLCHAIN_PATH}/ fi
XLCLANG_VERSION_OUTPUT=`${XLC_TEST_PATH}xlclang++ -qversion 2>&1 | $HEAD -n 1`
$ECHO"$XLCLANG_VERSION_OUTPUT" | $GREP "IBM XL C/C++ for AIX" > /dev/null if test $? -eq 0; then
AC_MSG_NOTICE([xlclang++ output: $XLCLANG_VERSION_OUTPUT]) else
AC_MSG_ERROR([xlclang++ version output check failed, output: $XLCLANG_VERSION_OUTPUT]) fi fi
if test "x$TOOLCHAIN_TYPE" = "x$DEFAULT_TOOLCHAIN"; then
AC_MSG_NOTICE([Using default toolchain $TOOLCHAIN_TYPE ($TOOLCHAIN_DESCRIPTION)]) else
AC_MSG_NOTICE([Using user selected toolchain $TOOLCHAIN_TYPE ($TOOLCHAIN_DESCRIPTION). Default toolchain is $DEFAULT_TOOLCHAIN.]) fi
])
# Before we start detecting the toolchain executables, we might need some # special setup, e.g. additional paths etc.
AC_DEFUN_ONCE([TOOLCHAIN_PRE_DETECTION],
[ # Store the CFLAGS etc passed to the configure script.
ORG_CFLAGS="$CFLAGS"
ORG_CXXFLAGS="$CXXFLAGS"
# autoconf magic only relies on PATH, so update it if tools dir is specified
OLD_PATH="$PATH"
if test "x$OPENJDK_BUILD_OS" = "xmacosx"; then if test "x$XCODEBUILD" != x; then
XCODE_VERSION_OUTPUT=`"$XCODEBUILD" -version 2> /dev/null | $HEAD -n 1`
$ECHO"$XCODE_VERSION_OUTPUT" | $GREP "^Xcode " > /dev/null if test $? -ne 0; then
AC_MSG_NOTICE([xcodebuild -version output: $XCODE_VERSION_OUTPUT])
AC_MSG_ERROR([Failed to determine Xcode version]) fi
# For Xcode, we set the Xcode version as TOOLCHAIN_VERSION
TOOLCHAIN_VERSION=`$ECHO $XCODE_VERSION_OUTPUT | $CUT -f 2 -d ' '`
TOOLCHAIN_DESCRIPTION="$TOOLCHAIN_DESCRIPTION from Xcode $TOOLCHAIN_VERSION" fi fi
AC_SUBST(TOOLCHAIN_VERSION)
# Finally prepend TOOLCHAIN_PATH to the PATH, to allow --with-tools-dir to # override all other locations. if test "x$TOOLCHAIN_PATH" != x; then export PATH=$TOOLCHAIN_PATH:$PATH fi
])
# Restore path, etc
AC_DEFUN_ONCE([TOOLCHAIN_POST_DETECTION],
[ # Restore old path, except for the microsoft toolchain, which requires the # toolchain path to remain in place. Otherwise the compiler will not work in # some siutations in later configure checks. if test "x$TOOLCHAIN_TYPE" != "xmicrosoft"; then
PATH="$OLD_PATH" fi
# Restore the flags to the user specified values. # This is necessary since AC_PROG_CC defaults CFLAGS to "-g -O2"
CFLAGS="$ORG_CFLAGS"
CXXFLAGS="$ORG_CXXFLAGS"
])
# Check if a compiler is of the toolchain type we expect, and save the version # information from it. If the compiler does not match the expected type, # this function will abort using AC_MSG_ERROR. If it matches, the version will # be stored in CC_VERSION_NUMBER/CXX_VERSION_NUMBER (as a dotted number), and # the full version string in CC_VERSION_STRING/CXX_VERSION_STRING. # # $1 = compiler to test (CC or CXX) # $2 = human readable name of compiler (C or C++)
AC_DEFUN([TOOLCHAIN_EXTRACT_COMPILER_VERSION],
[
COMPILER=[$]$1
COMPILER_NAME=$2
if test "x$TOOLCHAIN_TYPE" = xxlc; then # xlc -qversion output typically looks like # IBM XL C/C++ for AIX, V11.1 (5724-X13) # Version: 11.01.0000.0015
COMPILER_VERSION_OUTPUT=`$COMPILER -qversion 2>&1` # Check that this is likely to be the IBM XL C compiler.
$ECHO"$COMPILER_VERSION_OUTPUT" | $GREP "IBM XL C" > /dev/null if test $? -ne 0; then
ALT_VERSION_OUTPUT=`$COMPILER --version 2>&1`
AC_MSG_NOTICE([The $COMPILER_NAME compiler (located as $COMPILER) does not seem to be the required $TOOLCHAIN_TYPE compiler.])
AC_MSG_NOTICE([The result from running with -qversion was: "$COMPILER_VERSION_OUTPUT"])
AC_MSG_NOTICE([The result from running with --version was: "$ALT_VERSION_OUTPUT"])
AC_MSG_ERROR([A $TOOLCHAIN_TYPE compiler is required. Try setting --with-tools-dir.]) fi # Collapse compiler output into a single line
COMPILER_VERSION_STRING=`$ECHO $COMPILER_VERSION_OUTPUT`
COMPILER_VERSION_NUMBER=`$ECHO $COMPILER_VERSION_OUTPUT | \
$SED -e 's/^.*, V\(@<:@1-9@:>@@<:@0-9.@:>@*\).*$/\1/'` elif test "x$TOOLCHAIN_TYPE" = xmicrosoft; then # There is no specific version flag, but all output starts with a version string. # First line typically looks something like: # Microsoft (R) 32-bit C/C++ Optimizing Compiler Version 16.00.40219.01 for 80x86 # but the compiler name may vary depending on locale.
COMPILER_VERSION_OUTPUT=`$COMPILER 2>&1 1>/dev/null | $HEAD -n 1 | $TR -d '\r'` # Check that this is likely to be Microsoft CL.EXE.
$ECHO"$COMPILER_VERSION_OUTPUT" | $GREP "Microsoft" > /dev/null if test $? -ne 0; then
AC_MSG_NOTICE([The $COMPILER_NAME compiler (located as $COMPILER) does not seem to be the required $TOOLCHAIN_TYPE compiler.])
AC_MSG_NOTICE([The result from running it was: "$COMPILER_VERSION_OUTPUT"])
AC_MSG_ERROR([A $TOOLCHAIN_TYPE compiler is required. Try setting --with-tools-dir.]) fi # Collapse compiler output into a single line
COMPILER_VERSION_STRING=`$ECHO $COMPILER_VERSION_OUTPUT`
COMPILER_VERSION_NUMBER=`$ECHO $COMPILER_VERSION_OUTPUT | \
$SED -e 's/^.*ersion.\(@<:@1-9@:>@@<:@0-9.@:>@*\) .*$/\1/'` elif test "x$TOOLCHAIN_TYPE" = xgcc; then # gcc --version output typically looks like # gcc (Ubuntu/Linaro 4.8.1-10ubuntu9) 4.8.1 # Copyright (C) 2013 Free Software Foundation, Inc. # This is free software; see the source for copying conditions. There is NO # warranty; not even for MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
COMPILER_VERSION_OUTPUT=`$COMPILER --version 2>&1` # Check that this is likely to be GCC.
$ECHO"$COMPILER_VERSION_OUTPUT" | $GREP "Free Software Foundation" > /dev/null if test $? -ne 0; then
AC_MSG_NOTICE([The $COMPILER_NAME compiler (located as $COMPILER) does not seem to be the required $TOOLCHAIN_TYPE compiler.])
AC_MSG_NOTICE([The result from running with --version was: "$COMPILER_VERSION"])
AC_MSG_ERROR([A $TOOLCHAIN_TYPE compiler is required. Try setting --with-tools-dir.]) fi # Remove Copyright and legalese from version string, and # collapse into a single line
COMPILER_VERSION_STRING=`$ECHO $COMPILER_VERSION_OUTPUT | \
$SED -e 's/ *Copyright .*//'`
COMPILER_VERSION_NUMBER=`$ECHO $COMPILER_VERSION_OUTPUT | \
$SED -e 's/^.* \(@<:@1-9@:>@<:@0-9@:>@*\.@<:@0-9.@:>@*\)@<:@^0-9.@:>@.*$/\1/'` elif test "x$TOOLCHAIN_TYPE" = xclang; then # clang --version output typically looks like # Apple LLVM version 5.0 (clang-500.2.79) (based on LLVM 3.3svn) # clang version 3.3 (tags/RELEASE_33/final) # or # Debian clang version 3.2-7ubuntu1 (tags/RELEASE_32/final) (based on LLVM 3.2) # Target: x86_64-pc-linux-gnu # Thread model: posix
COMPILER_VERSION_OUTPUT=`$COMPILER --version 2>&1` # Check that this is likely to be clang
$ECHO"$COMPILER_VERSION_OUTPUT" | $GREP "clang" > /dev/null if test $? -ne 0; then
AC_MSG_NOTICE([The $COMPILER_NAME compiler (located as $COMPILER) does not seem to be the required $TOOLCHAIN_TYPE compiler.])
AC_MSG_NOTICE([The result from running with --version was: "$COMPILER_VERSION_OUTPUT"])
AC_MSG_ERROR([A $TOOLCHAIN_TYPE compiler is required. Try setting --with-tools-dir.]) fi # Collapse compiler output into a single line
COMPILER_VERSION_STRING=`$ECHO $COMPILER_VERSION_OUTPUT`
COMPILER_VERSION_NUMBER=`$ECHO $COMPILER_VERSION_OUTPUT | \
$SED -e 's/^.* version \(@<:@1-9@:>@@<:@0-9.@:>@*\).*$/\1/'` else
AC_MSG_ERROR([Unknown toolchain type $TOOLCHAIN_TYPE.]) fi # This sets CC_VERSION_NUMBER or CXX_VERSION_NUMBER. (This comment is a grep marker)
$1_VERSION_NUMBER="$COMPILER_VERSION_NUMBER" # This sets CC_VERSION_STRING or CXX_VERSION_STRING. (This comment is a grep marker)
$1_VERSION_STRING="$COMPILER_VERSION_STRING"
AC_MSG_NOTICE([Using $TOOLCHAIN_TYPE $COMPILER_NAME compiler version $COMPILER_VERSION_NUMBER @<:@$COMPILER_VERSION_STRING@:>@])
])
# Try to locate the given C or C++ compiler in the path, or otherwise. # # $1 = compiler to test (CC or CXX) # $2 = human readable name of compiler (C or C++) # $3 = compiler name to search for
AC_DEFUN([TOOLCHAIN_FIND_COMPILER],
[
COMPILER_NAME=$2
SEARCH_LIST="$3"
if test "x[$]$1" != x; then # User has supplied compiler name already, always let that override.
AC_MSG_NOTICE([Will use user supplied compiler $1=[$]$1]) if test "x`basename [$]$1`" = "x[$]$1"; then # A command without a complete path is provided, search $PATH.
UTIL_LOOKUP_PROGS(POTENTIAL_$1, [$]$1) if test "x$POTENTIAL_$1" != x; then
$1=$POTENTIAL_$1 else
AC_MSG_ERROR([User supplied compiler $1=[$]$1 could not be found]) fi else # Otherwise it might already be a complete path if test ! -x "[$]$1"; then
AC_MSG_ERROR([User supplied compiler $1=[$]$1 does not exist]) fi fi else # No user supplied value. Locate compiler ourselves.
# If we are cross compiling, assume cross compilation tools follows the # cross compilation standard where they are prefixed with the autoconf # standard name for the target. For example the binary # i686-sun-solaris2.10-gcc will cross compile for i686-sun-solaris2.10. # If we are not cross compiling, then the default compiler name will be # used.
UTIL_LOOKUP_TOOLCHAIN_PROGS(POTENTIAL_$1, $SEARCH_LIST) if test "x$POTENTIAL_$1" != x; then
$1=$POTENTIAL_$1 else
HELP_MSG_MISSING_DEPENDENCY([devkit])
AC_MSG_ERROR([Could not find a $COMPILER_NAME compiler. $HELP_MSG]) fi fi
# Now we have a compiler binary in $1. Make sure it's okay.
TEST_COMPILER="[$]$1"
AC_MSG_CHECKING([resolved symbolic links for $1])
SYMLINK_ORIGINAL="$TEST_COMPILER"
UTIL_REMOVE_SYMBOLIC_LINKS(SYMLINK_ORIGINAL) if test "x$TEST_COMPILER" = "x$SYMLINK_ORIGINAL"; then
AC_MSG_RESULT([no symlink]) else
AC_MSG_RESULT([$SYMLINK_ORIGINAL])
# We can't handle ccache by gcc wrappers, since we need to know if we're # using ccache. Instead ccache usage must be controlled by a configure option.
COMPILER_BASENAME=`$BASENAME "$SYMLINK_ORIGINAL"` if test "x$COMPILER_BASENAME" = "xccache"; then
AC_MSG_NOTICE([Please use --enable-ccache instead of providing a wrapped compiler.])
AC_MSG_ERROR([$TEST_COMPILER is a symbolic link to ccache. This is not supported.]) fi fi
# Retrieve the linker version number and store it in LD_VERSION_NUMBER # (as a dotted number), and # the full version string in LD_VERSION_STRING. # # $1 = linker to test (LD or BUILD_LD) # $2 = human readable name of linker (Linker or BuildLinker)
AC_DEFUN([TOOLCHAIN_EXTRACT_LD_VERSION],
[
LINKER=[$]$1
LINKER_NAME="$2"
if test "x$TOOLCHAIN_TYPE" = xxlc; then
LINKER_VERSION_STRING="Unknown"
LINKER_VERSION_NUMBER="0.0" elif test "x$TOOLCHAIN_TYPE" = xmicrosoft; then # There is no specific version flag, but all output starts with a version string. # First line typically looks something like: # Microsoft (R) Incremental Linker Version 12.00.31101.0
LINKER_VERSION_STRING=`$LINKER 2>&1 | $HEAD -n 1 | $TR -d '\r'` # Extract version number
[ LINKER_VERSION_NUMBER=`$ECHO $LINKER_VERSION_STRING | \
$SED -e 's/.* \([0-9][0-9]*\(\.[0-9][0-9]*\)*\).*/\1/'` ] elif test "x$TOOLCHAIN_TYPE" = xgcc; then # gcc -Wl,-version output typically looks like: # GNU ld (GNU Binutils for Ubuntu) 2.26.1 # Copyright (C) 2015 Free Software Foundation, Inc. # This program is free software; [...] # If using gold it will look like: # GNU gold (GNU Binutils 2.30) 1.15
LINKER_VERSION_STRING=`$LINKER -Wl,--version 2> /dev/null | $HEAD -n 1` # Extract version number if [ [[ "$LINKER_VERSION_STRING" == *gold* ]] ]; then
[ LINKER_VERSION_NUMBER=`$ECHO $LINKER_VERSION_STRING | \
$SED -e 's/.* \([0-9][0-9]*\(\.[0-9][0-9]*\)*\).*) .*/\1/'` ] else
[ LINKER_VERSION_NUMBER=`$ECHO $LINKER_VERSION_STRING | \
$SED -e 's/.* \([0-9][0-9]*\(\.[0-9][0-9]*\)*\).*/\1/'` ] fi elif test "x$TOOLCHAIN_TYPE" = xclang; then # clang -Wl,-v output typically looks like # @(#)PROGRAM:ld PROJECT:ld64-305 # configured to support archs: armv6 armv7 armv7s arm64 i386 x86_64 x86_64h armv6m armv7k armv7m armv7em (tvOS) # Library search paths: [...] # or # GNU ld (GNU Binutils for Ubuntu) 2.26.1
LINKER_VERSION_STRING=`$LINKER -Wl,-v 2>&1 | $HEAD -n 1` # Check if we're using the GNU ld
$ECHO"$LINKER_VERSION_STRING" | $GREP "GNU" > /dev/null if test $? -eq 0; then # Extract version number
[ LINKER_VERSION_NUMBER=`$ECHO $LINKER_VERSION_STRING | \
$SED -e 's/.* \([0-9][0-9]*\(\.[0-9][0-9]*\)*\).*/\1/'` ] else # Extract version number
[ LINKER_VERSION_NUMBER=`$ECHO $LINKER_VERSION_STRING | \
$SED -e 's/.*-\([0-9][0-9]*\)/\1/'` ] fi fi
AC_MSG_NOTICE([Using $TOOLCHAIN_TYPE $LINKER_NAME version $LINKER_VERSION_NUMBER @<:@$LINKER_VERSION_STRING@:>@])
])
# Make sure we did not pick up /usr/bin/link, which is the unix-style link # executable. # # $1 = linker to test (LD or BUILD_LD)
AC_DEFUN(TOOLCHAIN_VERIFY_LINK_BINARY,
[
LINKER=[$]$1
AC_MSG_CHECKING([if the found link.exe is actually the Visual Studio linker])
$LINKER --version > /dev/null if test $? -eq 0 ; then
AC_MSG_RESULT([no])
AC_MSG_ERROR([$LINKER is the winenv link tool. Please check your PATH and rerun configure.]) else
AC_MSG_RESULT([yes]) fi
]) # Detect the core components of the toolchain, i.e. the compilers (CC and CXX), # preprocessor (CPP and CXXCPP), the linker (LD), the assembler (AS) and the # archiver (AR). Verify that the compilers are correct according to the # toolchain type.
AC_DEFUN_ONCE([TOOLCHAIN_DETECT_TOOLCHAIN_CORE],
[ # # Setup the compilers (CC and CXX) #
TOOLCHAIN_FIND_COMPILER([CC], [C], $TOOLCHAIN_CC_BINARY) # Now that we have resolved CC ourself, let autoconf have its go at it
AC_PROG_CC([$CC])
TOOLCHAIN_FIND_COMPILER([CXX], [C++], $TOOLCHAIN_CXX_BINARY) # Now that we have resolved CXX ourself, let autoconf have its go at it
AC_PROG_CXX([$CXX])
# This is the compiler version number on the form X.Y[.Z]
AC_SUBST(CC_VERSION_NUMBER)
AC_SUBST(CXX_VERSION_NUMBER)
TOOLCHAIN_PREPARE_FOR_VERSION_COMPARISONS
if test "x$TOOLCHAIN_MINIMUM_VERSION" != x; then
TOOLCHAIN_CHECK_COMPILER_VERSION(VERSION: $TOOLCHAIN_MINIMUM_VERSION,
IF_OLDER_THAN: [
AC_MSG_WARN([You are using $TOOLCHAIN_TYPE older than $TOOLCHAIN_MINIMUM_VERSION. This is not a supported configuration.])
]
) fi
# # Setup the preprocessor (CPP and CXXCPP) #
AC_PROG_CPP
UTIL_FIXUP_EXECUTABLE(CPP)
AC_PROG_CXXCPP
UTIL_FIXUP_EXECUTABLE(CXXCPP)
# # Setup the linker (LD) # if test "x$TOOLCHAIN_TYPE" = xmicrosoft; then # In the Microsoft toolchain we have a separate LD command "link".
UTIL_LOOKUP_TOOLCHAIN_PROGS(LD, link)
TOOLCHAIN_VERIFY_LINK_BINARY(LD)
LDCXX="$LD" else # All other toolchains use the compiler to link.
LD="$CC"
LDCXX="$CXX" fi
AC_SUBST(LD) # FIXME: it should be CXXLD, according to standard (cf CXXCPP)
AC_SUBST(LDCXX)
if test "x$TOOLCHAIN_MINIMUM_LD_VERSION" != x; then
AC_MSG_NOTICE([comparing linker version to minimum version $TOOLCHAIN_MINIMUM_LD_VERSION])
TOOLCHAIN_CHECK_LINKER_VERSION(VERSION: $TOOLCHAIN_MINIMUM_LD_VERSION,
IF_OLDER_THAN: [
AC_MSG_ERROR([You are using a linker older than $TOOLCHAIN_MINIMUM_LD_VERSION. This is not a supported configuration.])
]
) fi
# # Setup the assembler (AS) # if test "x$TOOLCHAIN_TYPE" != xmicrosoft; then
AS="$CC -c" else if test "x$OPENJDK_TARGET_CPU_BITS" = "x64"; then # On 64 bit windows, the assembler is "ml64.exe"
UTIL_LOOKUP_TOOLCHAIN_PROGS(AS, ml64) else # otherwise, the assembler is "ml.exe"
UTIL_LOOKUP_TOOLCHAIN_PROGS(AS, ml) fi fi
AC_SUBST(AS)
# # Setup the archiver (AR) # if test "x$TOOLCHAIN_TYPE" = xmicrosoft; then # The corresponding ar tool is lib.exe (used to create static libraries)
UTIL_LOOKUP_TOOLCHAIN_PROGS(AR, lib) elif test "x$TOOLCHAIN_TYPE" = xgcc; then
UTIL_LOOKUP_TOOLCHAIN_PROGS(AR, ar gcc-ar) else
UTIL_LOOKUP_TOOLCHAIN_PROGS(AR, ar) fi
])
# Setup additional tools that is considered a part of the toolchain, but not the # core part. Many of these are highly platform-specific and do not exist, # and/or are not needed on all platforms.
AC_DEFUN_ONCE([TOOLCHAIN_DETECT_TOOLCHAIN_EXTRA],
[ if test "x$OPENJDK_TARGET_OS" = "xmacosx"; then
UTIL_LOOKUP_PROGS(LIPO, lipo)
UTIL_REQUIRE_PROGS(OTOOL, otool)
UTIL_REQUIRE_PROGS(INSTALL_NAME_TOOL, install_name_tool)
UTIL_LOOKUP_TOOLCHAIN_PROGS(METAL, metal) if test "x$METAL" = x; then
AC_MSG_CHECKING([if metal can be run using xcrun])
METAL="xcrun -sdk macosx metal"
test_metal=`$METAL --version 2>&1` if test $? -ne 0; then
AC_MSG_RESULT([no])
AC_MSG_ERROR([XCode tool 'metal' neither found in path nor with xcrun]) else
AC_MSG_RESULT([yes, will be using '$METAL']) fi fi
UTIL_LOOKUP_TOOLCHAIN_PROGS(METALLIB, metallib) if test "x$METALLIB" = x; then
AC_MSG_CHECKING([if metallib can be run using xcrun])
METALLIB="xcrun -sdk macosx metallib"
test_metallib=`$METALLIB --version 2>&1` if test $? -ne 0; then
AC_MSG_RESULT([no])
AC_MSG_ERROR([XCode tool 'metallib' neither found in path nor with xcrun]) else
AC_MSG_RESULT([yes, will be using '$METALLIB']) fi fi fi
if test "x$TOOLCHAIN_TYPE" = xmicrosoft; then # Setup the manifest tool (MT)
UTIL_LOOKUP_TOOLCHAIN_PROGS(MT, mt) # Setup the resource compiler (RC)
UTIL_LOOKUP_TOOLCHAIN_PROGS(RC, rc)
UTIL_LOOKUP_TOOLCHAIN_PROGS(DUMPBIN, dumpbin) fi
if test "x$OPENJDK_TARGET_OS" != xwindows; then
UTIL_LOOKUP_TOOLCHAIN_PROGS(STRIP, strip) if test "x$TOOLCHAIN_TYPE" = xgcc; then
UTIL_LOOKUP_TOOLCHAIN_PROGS(NM, nm gcc-nm) else
UTIL_LOOKUP_TOOLCHAIN_PROGS(NM, nm) fi fi
# objcopy is used for moving debug symbols to separate files when # full debug symbols are enabled. if test "x$OPENJDK_TARGET_OS" = xlinux; then
UTIL_LOOKUP_TOOLCHAIN_PROGS(OBJCOPY, gobjcopy objcopy) fi
case $TOOLCHAIN_TYPE in
gcc|clang)
UTIL_REQUIRE_TOOLCHAIN_PROGS(CXXFILT, c++filt)
;;
esac
])
# Setup the build tools (i.e, the compiler and linker used to build programs # that should be run on the build platform, not the target platform, as a build # helper). Since the non-cross-compile case uses the normal, target compilers # for this, we can only do this after these have been setup.
AC_DEFUN_ONCE([TOOLCHAIN_SETUP_BUILD_COMPILERS],
[ if test "x$COMPILE_TYPE" = "xcross"; then # Now we need to find a C/C++ compiler that can build executables for the # build platform. We can't use the AC_PROG_CC macro, since it can only be # used once. Also, we need to do this without adding a tools dir to the # path, otherwise we might pick up cross-compilers which don't use standard # naming.
OLDPATH="$PATH"
AC_ARG_WITH(build-devkit, [AS_HELP_STRING([--with-build-devkit],
[Devkit to use for the build platform toolchain])]) if test "x$with_build_devkit" = "xyes"; then
AC_MSG_ERROR([--with-build-devkit must have a value]) elif test -n "$with_build_devkit"; then if test ! -d "$with_build_devkit"; then
AC_MSG_ERROR([--with-build-devkit points to non existing dir: $with_build_devkit]) else
UTIL_FIXUP_PATH([with_build_devkit])
BUILD_DEVKIT_ROOT="$with_build_devkit" # Check for a meta data info file in the root of the devkit if test -f "$BUILD_DEVKIT_ROOT/devkit.info"; then # Process devkit.info so that existing devkit variables are not # modified by this
$SED -e "s/^DEVKIT_/BUILD_DEVKIT_/g" \
-e "s/\$DEVKIT_ROOT/\$BUILD_DEVKIT_ROOT/g" \
-e "s/\$host/\$build/g" \
$BUILD_DEVKIT_ROOT/devkit.info \
> $CONFIGURESUPPORT_OUTPUTDIR/build-devkit.info
. $CONFIGURESUPPORT_OUTPUTDIR/build-devkit.info # This potentially sets the following: # A descriptive name of the devkit
BASIC_EVAL_BUILD_DEVKIT_VARIABLE([BUILD_DEVKIT_NAME]) # Corresponds to --with-extra-path
BASIC_EVAL_BUILD_DEVKIT_VARIABLE([BUILD_DEVKIT_EXTRA_PATH]) # Corresponds to --with-toolchain-path
BASIC_EVAL_BUILD_DEVKIT_VARIABLE([BUILD_DEVKIT_TOOLCHAIN_PATH]) # Corresponds to --with-sysroot
BASIC_EVAL_BUILD_DEVKIT_VARIABLE([BUILD_DEVKIT_SYSROOT])
if test "x$TOOLCHAIN_TYPE" = xmicrosoft; then
BASIC_EVAL_BUILD_DEVKIT_VARIABLE([BUILD_DEVKIT_VS_INCLUDE])
BASIC_EVAL_BUILD_DEVKIT_VARIABLE([BUILD_DEVKIT_VS_LIB]) fi fi
AC_MSG_CHECKING([for build platform devkit]) if test "x$BUILD_DEVKIT_NAME" != x; then
AC_MSG_RESULT([$BUILD_DEVKIT_NAME in $BUILD_DEVKIT_ROOT]) else
AC_MSG_RESULT([$BUILD_DEVKIT_ROOT]) fi
# Fallback default of just /bin if DEVKIT_PATH is not defined if test "x$BUILD_DEVKIT_TOOLCHAIN_PATH" = x; then
BUILD_DEVKIT_TOOLCHAIN_PATH="$BUILD_DEVKIT_ROOT/bin" fi
PATH="$BUILD_DEVKIT_TOOLCHAIN_PATH:$BUILD_DEVKIT_EXTRA_PATH"
BUILD_SYSROOT="$BUILD_DEVKIT_SYSROOT"
if test "x$TOOLCHAIN_TYPE" = xmicrosoft; then # For historical reasons, paths are separated by ; in devkit.info
BUILD_VS_INCLUDE="${BUILD_DEVKIT_VS_INCLUDE//;/:}"
BUILD_VS_LIB="${BUILD_DEVKIT_VS_LIB//;/:}"
TOOLCHAIN_SETUP_VISUAL_STUDIO_SYSROOT_FLAGS(BUILD_, BUILD_) fi fi else if test "x$TOOLCHAIN_TYPE" = xmicrosoft; then # If we got no devkit, we need to go hunting for the proper env
TOOLCHAIN_FIND_VISUAL_STUDIO_BAT_FILE($OPENJDK_BUILD_CPU, [$TOOLCHAIN_VERSION])
TOOLCHAIN_EXTRACT_VISUAL_STUDIO_ENV($OPENJDK_BUILD_CPU, BUILD_)
# We cannot currently export the VS_PATH to spec.gmk. This is probably # strictly not correct, but seems to work anyway.
# Convert VS_INCLUDE and VS_LIB into sysroot flags
TOOLCHAIN_SETUP_VISUAL_STUDIO_SYSROOT_FLAGS(BUILD_) fi fi
if test "x$TOOLCHAIN_TYPE" = xmicrosoft; then
UTIL_REQUIRE_PROGS(BUILD_CC, cl, [$VS_PATH])
UTIL_REQUIRE_PROGS(BUILD_CXX, cl, [$VS_PATH])
# On windows, the assembler is "ml.exe". We currently don't need this so # do not require. if test "x$OPENJDK_BUILD_CPU_BITS" = "x64"; then # On 64 bit windows, the assembler is "ml64.exe"
UTIL_LOOKUP_PROGS(BUILD_AS, ml64, [$VS_PATH]) else # otherwise the assembler is "ml.exe"
UTIL_LOOKUP_PROGS(BUILD_AS, ml, [$VS_PATH]) fi
# On windows, the ar tool is lib.exe (used to create static libraries). # We currently don't need this so do not require.
UTIL_LOOKUP_PROGS(BUILD_AR, lib, [$VS_PATH])
# In the Microsoft toolchain we have a separate LD command "link".
UTIL_REQUIRE_PROGS(BUILD_LD, link, [$VS_PATH])
TOOLCHAIN_VERIFY_LINK_BINARY(BUILD_LD)
BUILD_LDCXX="$BUILD_LD" else if test "x$OPENJDK_BUILD_OS" = xmacosx; then
UTIL_REQUIRE_PROGS(BUILD_CC, clang)
UTIL_REQUIRE_PROGS(BUILD_CXX, clang++) else
UTIL_REQUIRE_PROGS(BUILD_CC, cc gcc)
UTIL_REQUIRE_PROGS(BUILD_CXX, CC g++) fi
UTIL_LOOKUP_PROGS(BUILD_NM, nm gcc-nm)
UTIL_LOOKUP_PROGS(BUILD_AR, ar gcc-ar lib)
UTIL_LOOKUP_PROGS(BUILD_OBJCOPY, objcopy)
UTIL_LOOKUP_PROGS(BUILD_STRIP, strip) # Assume the C compiler is the assembler
BUILD_AS="$BUILD_CC -c" # Just like for the target compiler, use the compiler as linker
BUILD_LD="$BUILD_CC"
BUILD_LDCXX="$BUILD_CXX" fi
PATH="$OLDPATH"
TOOLCHAIN_EXTRACT_COMPILER_VERSION(BUILD_CC, [BuildC])
TOOLCHAIN_EXTRACT_COMPILER_VERSION(BUILD_CXX, [BuildC++])
TOOLCHAIN_PREPARE_FOR_VERSION_COMPARISONS([BUILD_], [OPENJDK_BUILD_], [build ])
TOOLCHAIN_EXTRACT_LD_VERSION(BUILD_LD, [build linker])
TOOLCHAIN_PREPARE_FOR_LD_VERSION_COMPARISONS([BUILD_], [OPENJDK_BUILD_]) else # If we are not cross compiling, use the normal target compilers for # building the build platform executables.
BUILD_CC="$CC"
BUILD_CXX="$CXX"
BUILD_LD="$LD"
BUILD_LDCXX="$LDCXX"
BUILD_NM="$NM"
BUILD_AS="$AS"
BUILD_OBJCOPY="$OBJCOPY"
BUILD_STRIP="$STRIP"
BUILD_AR="$AR"
TOOLCHAIN_PREPARE_FOR_VERSION_COMPARISONS([], [OPENJDK_BUILD_], [build ])
TOOLCHAIN_PREPARE_FOR_LD_VERSION_COMPARISONS([BUILD_], [OPENJDK_BUILD_]) fi
# Do some additional checks on the detected tools.
AC_DEFUN_ONCE([TOOLCHAIN_MISC_CHECKS],
[ # Check for extra potential brokenness. if test "x$TOOLCHAIN_TYPE" = xmicrosoft; then # On Windows, double-check that we got the right compiler.
CC_VERSION_OUTPUT=`$CC 2>&1 1>/dev/null | $HEAD -n 1 | $TR -d '\r'`
COMPILER_CPU_TEST=`$ECHO $CC_VERSION_OUTPUT | $SED -n "s/^.* \(.*\)$/\1/p"` if test "x$OPENJDK_TARGET_CPU" = "xx86"; then if test "x$COMPILER_CPU_TEST" != "x80x86" -a "x$COMPILER_CPU_TEST" != "xx86"; then
AC_MSG_ERROR([Target CPU mismatch. We are building for $OPENJDK_TARGET_CPU but CL is for"$COMPILER_CPU_TEST"; expected "80x86" or "x86".]) fi elif test "x$OPENJDK_TARGET_CPU" = "xx86_64"; then if test "x$COMPILER_CPU_TEST" != "xx64"; then
AC_MSG_ERROR([Target CPU mismatch. We are building for $OPENJDK_TARGET_CPU but CL is for"$COMPILER_CPU_TEST"; expected "x64".]) fi elif test "x$OPENJDK_TARGET_CPU" = "xaarch64"; then if test "x$COMPILER_CPU_TEST" != "xARM64"; then
AC_MSG_ERROR([Target CPU mismatch. We are building for $OPENJDK_TARGET_CPU but CL is for"$COMPILER_CPU_TEST"; expected "arm64".]) fi fi fi
if test "x$TOOLCHAIN_TYPE" = xgcc || test "x$TOOLCHAIN_TYPE" = xclang; then # Check if linker has -z noexecstack.
HAS_NOEXECSTACK=`$CC -Wl,--help 2>/dev/null | $GREP 'z noexecstack'` # This is later checked when setting flags. fi
# Setup hotspot lecagy names for toolchains
HOTSPOT_TOOLCHAIN_TYPE=$TOOLCHAIN_TYPE if test "x$TOOLCHAIN_TYPE" = xclang; then
HOTSPOT_TOOLCHAIN_TYPE=gcc elif test "x$TOOLCHAIN_TYPE" = xmicrosoft; then
HOTSPOT_TOOLCHAIN_TYPE=visCPP fi
AC_SUBST(HOTSPOT_TOOLCHAIN_TYPE)
])
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