8148628: TIFFDirectory(getAsMetaData) created with one TIFFField having a IFD pointer tag throws ClassCastException & other naming differences (JEP 262)
Summary: Clean up some handling of TIFFDirectory instances contained in TIFFFields and make a couple of minor changes to Exif and GeoTIFF tag names.
Reviewed-by: prr
#
# Copyright (c) 2011, 2012, 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.
#
# Support macro for PLATFORM_EXTRACT_TARGET_AND_BUILD.
# Converts autoconf style CPU name to OpenJDK style, into
# VAR_CPU, VAR_CPU_ARCH, VAR_CPU_BITS and VAR_CPU_ENDIAN.
AC_DEFUN([PLATFORM_EXTRACT_VARS_FROM_CPU],
[
# First argument is the cpu name from the trip/quad
case "$1" in
x86_64)
VAR_CPU=x86_64
VAR_CPU_ARCH=x86
VAR_CPU_BITS=64
VAR_CPU_ENDIAN=little
;;
i?86)
VAR_CPU=x86
VAR_CPU_ARCH=x86
VAR_CPU_BITS=32
VAR_CPU_ENDIAN=little
;;
arm*)
VAR_CPU=arm
VAR_CPU_ARCH=arm
VAR_CPU_BITS=32
VAR_CPU_ENDIAN=little
;;
aarch64)
VAR_CPU=aarch64
VAR_CPU_ARCH=aarch64
VAR_CPU_BITS=64
VAR_CPU_ENDIAN=little
;;
powerpc)
VAR_CPU=ppc
VAR_CPU_ARCH=ppc
VAR_CPU_BITS=32
VAR_CPU_ENDIAN=big
;;
powerpc64)
VAR_CPU=ppc64
VAR_CPU_ARCH=ppc
VAR_CPU_BITS=64
VAR_CPU_ENDIAN=big
;;
powerpc64le)
VAR_CPU=ppc64le
VAR_CPU_ARCH=ppc
VAR_CPU_BITS=64
VAR_CPU_ENDIAN=little
;;
s390)
VAR_CPU=s390
VAR_CPU_ARCH=s390
VAR_CPU_BITS=32
VAR_CPU_ENDIAN=big
;;
s390x)
VAR_CPU=s390x
VAR_CPU_ARCH=s390
VAR_CPU_BITS=64
VAR_CPU_ENDIAN=big
;;
sparc)
VAR_CPU=sparc
VAR_CPU_ARCH=sparc
VAR_CPU_BITS=32
VAR_CPU_ENDIAN=big
;;
sparcv9|sparc64)
VAR_CPU=sparcv9
VAR_CPU_ARCH=sparc
VAR_CPU_BITS=64
VAR_CPU_ENDIAN=big
;;
*)
AC_MSG_ERROR([unsupported cpu $1])
;;
esac
])
# Support macro for PLATFORM_EXTRACT_TARGET_AND_BUILD.
# Converts autoconf style OS name to OpenJDK style, into
# VAR_OS, VAR_OS_TYPE and VAR_OS_ENV.
AC_DEFUN([PLATFORM_EXTRACT_VARS_FROM_OS],
[
case "$1" in
*linux*)
VAR_OS=linux
VAR_OS_TYPE=unix
;;
*solaris*)
VAR_OS=solaris
VAR_OS_TYPE=unix
;;
*darwin*)
VAR_OS=macosx
VAR_OS_TYPE=unix
;;
*bsd*)
VAR_OS=bsd
VAR_OS_TYPE=unix
;;
*cygwin*)
VAR_OS=windows
VAR_OS_ENV=windows.cygwin
;;
*mingw*)
VAR_OS=windows
VAR_OS_ENV=windows.msys
;;
*aix*)
VAR_OS=aix
VAR_OS_TYPE=unix
;;
*)
AC_MSG_ERROR([unsupported operating system $1])
;;
esac
])
# Expects $host_os $host_cpu $build_os and $build_cpu
# and $with_target_bits to have been setup!
#
# Translate the standard triplet(quadruplet) definition
# of the target/build system into OPENJDK_TARGET_OS, OPENJDK_TARGET_CPU,
# OPENJDK_BUILD_OS, etc.
AC_DEFUN([PLATFORM_EXTRACT_TARGET_AND_BUILD],
[
# Copy the autoconf trip/quadruplet verbatim to OPENJDK_TARGET_AUTOCONF_NAME
# (from the autoconf "host") and OPENJDK_BUILD_AUTOCONF_NAME
# Note that we might later on rewrite e.g. OPENJDK_TARGET_CPU due to reduced build,
# but this will not change the value of OPENJDK_TARGET_AUTOCONF_NAME.
OPENJDK_TARGET_AUTOCONF_NAME="$host"
OPENJDK_BUILD_AUTOCONF_NAME="$build"
AC_SUBST(OPENJDK_TARGET_AUTOCONF_NAME)
AC_SUBST(OPENJDK_BUILD_AUTOCONF_NAME)
# Convert the autoconf OS/CPU value to our own data, into the VAR_OS/CPU variables.
PLATFORM_EXTRACT_VARS_FROM_OS($build_os)
PLATFORM_EXTRACT_VARS_FROM_CPU($build_cpu)
# ..and setup our own variables. (Do this explicitely to facilitate searching)
OPENJDK_BUILD_OS="$VAR_OS"
if test "x$VAR_OS_TYPE" != x; then
OPENJDK_BUILD_OS_TYPE="$VAR_OS_TYPE"
else
OPENJDK_BUILD_OS_TYPE="$VAR_OS"
fi
if test "x$VAR_OS_ENV" != x; then
OPENJDK_BUILD_OS_ENV="$VAR_OS_ENV"
else
OPENJDK_BUILD_OS_ENV="$VAR_OS"
fi
OPENJDK_BUILD_CPU="$VAR_CPU"
OPENJDK_BUILD_CPU_ARCH="$VAR_CPU_ARCH"
OPENJDK_BUILD_CPU_BITS="$VAR_CPU_BITS"
OPENJDK_BUILD_CPU_ENDIAN="$VAR_CPU_ENDIAN"
AC_SUBST(OPENJDK_BUILD_OS)
AC_SUBST(OPENJDK_BUILD_OS_TYPE)
AC_SUBST(OPENJDK_BUILD_OS_ENV)
AC_SUBST(OPENJDK_BUILD_CPU)
AC_SUBST(OPENJDK_BUILD_CPU_ARCH)
AC_SUBST(OPENJDK_BUILD_CPU_BITS)
AC_SUBST(OPENJDK_BUILD_CPU_ENDIAN)
AC_MSG_CHECKING([openjdk-build os-cpu])
AC_MSG_RESULT([$OPENJDK_BUILD_OS-$OPENJDK_BUILD_CPU])
# Convert the autoconf OS/CPU value to our own data, into the VAR_OS/CPU variables.
PLATFORM_EXTRACT_VARS_FROM_OS($host_os)
PLATFORM_EXTRACT_VARS_FROM_CPU($host_cpu)
# ... and setup our own variables. (Do this explicitely to facilitate searching)
OPENJDK_TARGET_OS="$VAR_OS"
if test "x$VAR_OS_TYPE" != x; then
OPENJDK_TARGET_OS_TYPE="$VAR_OS_TYPE"
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OPENJDK_TARGET_OS_TYPE="$VAR_OS"
fi
if test "x$VAR_OS_ENV" != x; then
OPENJDK_TARGET_OS_ENV="$VAR_OS_ENV"
else
OPENJDK_TARGET_OS_ENV="$VAR_OS"
fi
OPENJDK_TARGET_CPU="$VAR_CPU"
OPENJDK_TARGET_CPU_ARCH="$VAR_CPU_ARCH"
OPENJDK_TARGET_CPU_BITS="$VAR_CPU_BITS"
OPENJDK_TARGET_CPU_ENDIAN="$VAR_CPU_ENDIAN"
AC_SUBST(OPENJDK_TARGET_OS)
AC_SUBST(OPENJDK_TARGET_OS_TYPE)
AC_SUBST(OPENJDK_TARGET_OS_ENV)
AC_SUBST(OPENJDK_TARGET_CPU)
AC_SUBST(OPENJDK_TARGET_CPU_ARCH)
AC_SUBST(OPENJDK_TARGET_CPU_BITS)
AC_SUBST(OPENJDK_TARGET_CPU_ENDIAN)
AC_MSG_CHECKING([openjdk-target os-cpu])
AC_MSG_RESULT([$OPENJDK_TARGET_OS-$OPENJDK_TARGET_CPU])
])
# Check if a reduced build (32-bit on 64-bit platforms) is requested, and modify behaviour
# accordingly. Must be done after setting up build and target system, but before
# doing anything else with these values.
AC_DEFUN([PLATFORM_SETUP_TARGET_CPU_BITS],
[
AC_ARG_WITH(target-bits, [AS_HELP_STRING([--with-target-bits],
[build 32-bit or 64-bit binaries (for platforms that support it), e.g. --with-target-bits=32 @<:@guessed@:>@])])
# We have three types of compiles:
# native == normal compilation, target system == build system
# cross == traditional cross compilation, target system != build system; special toolchain needed
# reduced == using native compilers, but with special flags (e.g. -m32) to produce 32-bit builds on 64-bit machines
#
if test "x$OPENJDK_BUILD_AUTOCONF_NAME" != "x$OPENJDK_TARGET_AUTOCONF_NAME"; then
# We're doing a proper cross-compilation
COMPILE_TYPE="cross"
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COMPILE_TYPE="native"
fi
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if test "x$COMPILE_TYPE" = "xcross"; then
AC_MSG_ERROR([It is not possible to combine --with-target-bits=X and proper cross-compilation. Choose either.])
fi
if test "x$with_target_bits" = x32 && test "x$OPENJDK_TARGET_CPU_BITS" = x64; then
# A reduced build is requested
COMPILE_TYPE="reduced"
OPENJDK_TARGET_CPU_BITS=32
if test "x$OPENJDK_TARGET_CPU_ARCH" = "xx86"; then
OPENJDK_TARGET_CPU=x86
elif test "x$OPENJDK_TARGET_CPU_ARCH" = "xsparc"; then
OPENJDK_TARGET_CPU=sparc
else
AC_MSG_ERROR([Reduced build (--with-target-bits=32) is only supported on x86_64 and sparcv9])
fi
elif test "x$with_target_bits" = x64 && test "x$OPENJDK_TARGET_CPU_BITS" = x32; then
AC_MSG_ERROR([It is not possible to use --with-target-bits=64 on a 32 bit system. Use proper cross-compilation instead.])
elif test "x$with_target_bits" = "x$OPENJDK_TARGET_CPU_BITS"; then
AC_MSG_NOTICE([--with-target-bits are set to build platform address size; argument has no meaning])
else
AC_MSG_ERROR([--with-target-bits can only be 32 or 64, you specified $with_target_bits!])
fi
fi
AC_SUBST(COMPILE_TYPE)
AC_MSG_CHECKING([compilation type])
AC_MSG_RESULT([$COMPILE_TYPE])
])
# Setup the legacy variables, for controlling the old makefiles.
#
AC_DEFUN([PLATFORM_SETUP_LEGACY_VARS],
[
# Also store the legacy naming of the cpu.
# Ie i586 and amd64 instead of x86 and x86_64
OPENJDK_TARGET_CPU_LEGACY="$OPENJDK_TARGET_CPU"
if test "x$OPENJDK_TARGET_CPU" = xx86; then
OPENJDK_TARGET_CPU_LEGACY="i586"
elif test "x$OPENJDK_TARGET_OS" != xmacosx && test "x$OPENJDK_TARGET_CPU" = xx86_64; then
# On all platforms except MacOSX replace x86_64 with amd64.
OPENJDK_TARGET_CPU_LEGACY="amd64"
fi
AC_SUBST(OPENJDK_TARGET_CPU_LEGACY)
# And the second legacy naming of the cpu.
# Ie i386 and amd64 instead of x86 and x86_64.
OPENJDK_TARGET_CPU_LEGACY_LIB="$OPENJDK_TARGET_CPU"
if test "x$OPENJDK_TARGET_CPU" = xx86; then
OPENJDK_TARGET_CPU_LEGACY_LIB="i386"
elif test "x$OPENJDK_TARGET_CPU" = xx86_64; then
OPENJDK_TARGET_CPU_LEGACY_LIB="amd64"
fi
AC_SUBST(OPENJDK_TARGET_CPU_LEGACY_LIB)
# This is the name of the cpu (but using i386 and amd64 instead of
# x86 and x86_64, respectively), preceeded by a /, to be used when
# locating libraries. On macosx, it's empty, though.
OPENJDK_TARGET_CPU_LIBDIR="/$OPENJDK_TARGET_CPU_LEGACY_LIB"
if test "x$OPENJDK_TARGET_OS" = xmacosx; then
OPENJDK_TARGET_CPU_LIBDIR=""
fi
AC_SUBST(OPENJDK_TARGET_CPU_LIBDIR)
# OPENJDK_TARGET_CPU_ISADIR is normally empty. On 64-bit Solaris systems, it is set to
# /amd64 or /sparcv9. This string is appended to some library paths, like this:
# /usr/lib${OPENJDK_TARGET_CPU_ISADIR}/libexample.so
OPENJDK_TARGET_CPU_ISADIR=""
if test "x$OPENJDK_TARGET_OS" = xsolaris; then
if test "x$OPENJDK_TARGET_CPU" = xx86_64; then
OPENJDK_TARGET_CPU_ISADIR="/amd64"
elif test "x$OPENJDK_TARGET_CPU" = xsparcv9; then
OPENJDK_TARGET_CPU_ISADIR="/sparcv9"
fi
fi
AC_SUBST(OPENJDK_TARGET_CPU_ISADIR)
# Setup OPENJDK_TARGET_CPU_OSARCH, which is used to set the os.arch Java system property
OPENJDK_TARGET_CPU_OSARCH="$OPENJDK_TARGET_CPU"
if test "x$OPENJDK_TARGET_OS" = xlinux && test "x$OPENJDK_TARGET_CPU" = xx86; then
# On linux only, we replace x86 with i386.
OPENJDK_TARGET_CPU_OSARCH="i386"
elif test "x$OPENJDK_TARGET_OS" != xmacosx && test "x$OPENJDK_TARGET_CPU" = xx86_64; then
# On all platforms except macosx, we replace x86_64 with amd64.
OPENJDK_TARGET_CPU_OSARCH="amd64"
fi
AC_SUBST(OPENJDK_TARGET_CPU_OSARCH)
OPENJDK_TARGET_CPU_JLI="$OPENJDK_TARGET_CPU"
if test "x$OPENJDK_TARGET_CPU" = xx86; then
OPENJDK_TARGET_CPU_JLI="i386"
elif test "x$OPENJDK_TARGET_OS" != xmacosx && test "x$OPENJDK_TARGET_CPU" = xx86_64; then
# On all platforms except macosx, we replace x86_64 with amd64.
OPENJDK_TARGET_CPU_JLI="amd64"
fi
# Now setup the -D flags for building libjli.
OPENJDK_TARGET_CPU_JLI_CFLAGS="-DLIBARCHNAME='\"$OPENJDK_TARGET_CPU_JLI\"'"
if test "x$OPENJDK_TARGET_OS" = xsolaris; then
if test "x$OPENJDK_TARGET_CPU_ARCH" = xsparc; then
OPENJDK_TARGET_CPU_JLI_CFLAGS="$OPENJDK_TARGET_CPU_JLI_CFLAGS -DLIBARCH32NAME='\"sparc\"' -DLIBARCH64NAME='\"sparcv9\"'"
elif test "x$OPENJDK_TARGET_CPU_ARCH" = xx86; then
OPENJDK_TARGET_CPU_JLI_CFLAGS="$OPENJDK_TARGET_CPU_JLI_CFLAGS -DLIBARCH32NAME='\"i386\"' -DLIBARCH64NAME='\"amd64\"'"
fi
fi
AC_SUBST(OPENJDK_TARGET_CPU_JLI_CFLAGS)
if test "x$OPENJDK_TARGET_OS" = xmacosx; then
OPENJDK_TARGET_OS_EXPORT_DIR=macosx
else
OPENJDK_TARGET_OS_EXPORT_DIR=${OPENJDK_TARGET_OS_TYPE}
fi
AC_SUBST(OPENJDK_TARGET_OS_EXPORT_DIR)
if test "x$OPENJDK_TARGET_CPU_BITS" = x64; then
A_LP64="LP64:="
# -D_LP64=1 is only set on linux and mac. Setting on windows causes diff in
# unpack200.exe
if test "x$OPENJDK_TARGET_OS" = xlinux || test "x$OPENJDK_TARGET_OS" = xmacosx; then
ADD_LP64="-D_LP64=1"
fi
fi
AC_SUBST(LP64,$A_LP64)
if test "x$COMPILE_TYPE" = "xcross"; then
# FIXME: ... or should this include reduced builds..?
DEFINE_CROSS_COMPILE_ARCH="CROSS_COMPILE_ARCH:=$OPENJDK_TARGET_CPU_LEGACY"
else
DEFINE_CROSS_COMPILE_ARCH=""
fi
AC_SUBST(DEFINE_CROSS_COMPILE_ARCH)
# ZERO_ARCHDEF is used to enable architecture-specific code
case "${OPENJDK_TARGET_CPU}" in
ppc) ZERO_ARCHDEF=PPC32 ;;
ppc64) ZERO_ARCHDEF=PPC64 ;;
s390*) ZERO_ARCHDEF=S390 ;;
sparc*) ZERO_ARCHDEF=SPARC ;;
x86_64*) ZERO_ARCHDEF=AMD64 ;;
x86) ZERO_ARCHDEF=IA32 ;;
*) ZERO_ARCHDEF=$(echo "${OPENJDK_TARGET_CPU_LEGACY_LIB}" | tr a-z A-Z)
esac
AC_SUBST(ZERO_ARCHDEF)
])
AC_DEFUN([PLATFORM_SET_RELEASE_FILE_OS_VALUES],
[
if test "x$OPENJDK_TARGET_OS" = "xsolaris"; then
REQUIRED_OS_NAME=SunOS
REQUIRED_OS_VERSION=5.10
fi
if test "x$OPENJDK_TARGET_OS" = "xlinux"; then
REQUIRED_OS_NAME=Linux
REQUIRED_OS_VERSION=2.6
fi
if test "x$OPENJDK_TARGET_OS" = "xwindows"; then
REQUIRED_OS_NAME=Windows
if test "x$OPENJDK_TARGET_CPU_BITS" = "x64"; then
REQUIRED_OS_VERSION=5.2
else
REQUIRED_OS_VERSION=5.1
fi
fi
if test "x$OPENJDK_TARGET_OS" = "xmacosx"; then
REQUIRED_OS_NAME=Darwin
REQUIRED_OS_VERSION=11.2
fi
AC_SUBST(REQUIRED_OS_NAME)
AC_SUBST(REQUIRED_OS_VERSION)
])
#%%% Build and target systems %%%
AC_DEFUN_ONCE([PLATFORM_SETUP_OPENJDK_BUILD_AND_TARGET],
[
# Figure out the build and target systems. # Note that in autoconf terminology, "build" is obvious, but "target"
# is confusing; it assumes you are cross-compiling a cross-compiler (!) and "target" is thus the target of the
# product you're building. The target of this build is called "host". Since this is confusing to most people, we
# have not adopted that system, but use "target" as the platform we are building for. In some places though we need
# to use the configure naming style.
AC_CANONICAL_BUILD
AC_CANONICAL_HOST
AC_CANONICAL_TARGET
PLATFORM_EXTRACT_TARGET_AND_BUILD
PLATFORM_SETUP_TARGET_CPU_BITS
PLATFORM_SET_RELEASE_FILE_OS_VALUES
PLATFORM_SETUP_LEGACY_VARS
])
AC_DEFUN_ONCE([PLATFORM_SETUP_OPENJDK_BUILD_OS_VERSION],
[
###############################################################################
# Note that this is the build platform OS version!
OS_VERSION="`uname -r | ${SED} 's!\.! !g' | ${SED} 's!-! !g'`"
OS_VERSION_MAJOR="`${ECHO} ${OS_VERSION} | ${CUT} -f 1 -d ' '`"
OS_VERSION_MINOR="`${ECHO} ${OS_VERSION} | ${CUT} -f 2 -d ' '`"
OS_VERSION_MICRO="`${ECHO} ${OS_VERSION} | ${CUT} -f 3 -d ' '`"
AC_SUBST(OS_VERSION_MAJOR)
AC_SUBST(OS_VERSION_MINOR)
AC_SUBST(OS_VERSION_MICRO)
])
# Support macro for PLATFORM_SETUP_OPENJDK_TARGET_BITS.
# Add -mX to various FLAGS variables.
AC_DEFUN([PLATFORM_SET_COMPILER_TARGET_BITS_FLAGS],
[
# When we add flags to the "official" CFLAGS etc, we need to
# keep track of these additions in ADDED_CFLAGS etc. These
# will later be checked to make sure only controlled additions
# have been made to CFLAGS etc.
ADDED_CFLAGS=" ${COMPILER_TARGET_BITS_FLAG}${OPENJDK_TARGET_CPU_BITS}"
ADDED_CXXFLAGS=" ${COMPILER_TARGET_BITS_FLAG}${OPENJDK_TARGET_CPU_BITS}"
ADDED_LDFLAGS=" ${COMPILER_TARGET_BITS_FLAG}${OPENJDK_TARGET_CPU_BITS}"
CFLAGS="${CFLAGS}${ADDED_CFLAGS}"
CXXFLAGS="${CXXFLAGS}${ADDED_CXXFLAGS}"
LDFLAGS="${LDFLAGS}${ADDED_LDFLAGS}"
CFLAGS_JDK="${CFLAGS_JDK}${ADDED_CFLAGS}"
CXXFLAGS_JDK="${CXXFLAGS_JDK}${ADDED_CXXFLAGS}"
LDFLAGS_JDK="${LDFLAGS_JDK}${ADDED_LDFLAGS}"
])
AC_DEFUN_ONCE([PLATFORM_SETUP_OPENJDK_TARGET_BITS],
[
###############################################################################
#
# Now we check if libjvm.so will use 32 or 64 bit pointers for the C/C++ code.
# (The JVM can use 32 or 64 bit Java pointers but that decision
# is made at runtime.)
#
if test "x$OPENJDK_TARGET_OS" = xsolaris || test "x$OPENJDK_TARGET_OS" = xaix; then
# Always specify -m flag on Solaris
# And -q on AIX because otherwise the compiler produces 32-bit objects by default
PLATFORM_SET_COMPILER_TARGET_BITS_FLAGS
elif test "x$COMPILE_TYPE" = xreduced; then
if test "x$OPENJDK_TARGET_OS_TYPE" = xunix; then
# Specify -m if running reduced on unix platforms
PLATFORM_SET_COMPILER_TARGET_BITS_FLAGS
fi
fi
# Make compilation sanity check
AC_CHECK_HEADERS([stdio.h], , [
AC_MSG_NOTICE([Failed to compile stdio.h. This likely implies missing compile dependencies.])
if test "x$COMPILE_TYPE" = xreduced; then
HELP_MSG_MISSING_DEPENDENCY([reduced])
AC_MSG_NOTICE([You are doing a reduced build. Check that you have 32-bit libraries installed. $HELP_MSG])
elif test "x$COMPILE_TYPE" = xcross; then
AC_MSG_NOTICE([You are doing a cross-compilation. Check that you have all target platform libraries installed.])
fi
AC_MSG_ERROR([Cannot continue.])
])
AC_CHECK_SIZEOF([int *], [1111])
# AC_CHECK_SIZEOF defines 'ac_cv_sizeof_int_p' to hold the number of bytes used by an 'int*'
if test "x$ac_cv_sizeof_int_p" = x; then
# The test failed, lets stick to the assumed value.
AC_MSG_WARN([The number of bits in the target could not be determined, using $OPENJDK_TARGET_CPU_BITS.])
else
TESTED_TARGET_CPU_BITS=`expr 8 \* $ac_cv_sizeof_int_p`
if test "x$TESTED_TARGET_CPU_BITS" != "x$OPENJDK_TARGET_CPU_BITS"; then
# This situation may happen on 64-bit platforms where the compiler by default only generates 32-bit objects
# Let's try to implicitely set the compilers target architecture and retry the test
AC_MSG_NOTICE([The tested number of bits in the target ($TESTED_TARGET_CPU_BITS) differs from the number of bits expected to be found in the target ($OPENJDK_TARGET_CPU_BITS).])
AC_MSG_NOTICE([Retrying with platforms compiler target bits flag to ${COMPILER_TARGET_BITS_FLAG}${OPENJDK_TARGET_CPU_BITS}])
PLATFORM_SET_COMPILER_TARGET_BITS_FLAGS
# We have to unset 'ac_cv_sizeof_int_p' first, otherwise AC_CHECK_SIZEOF will use the previously cached value!
unset ac_cv_sizeof_int_p
# And we have to undef the definition of SIZEOF_INT_P in confdefs.h by the previous invocation of AC_CHECK_SIZEOF
cat >>confdefs.h <<_ACEOF
#undef SIZEOF_INT_P
_ACEOF
AC_CHECK_SIZEOF([int *], [1111])
TESTED_TARGET_CPU_BITS=`expr 8 \* $ac_cv_sizeof_int_p`
if test "x$TESTED_TARGET_CPU_BITS" != "x$OPENJDK_TARGET_CPU_BITS"; then
AC_MSG_NOTICE([The tested number of bits in the target ($TESTED_TARGET_CPU_BITS) differs from the number of bits expected to be found in the target ($OPENJDK_TARGET_CPU_BITS)])
if test "x$COMPILE_TYPE" = xreduced; then
HELP_MSG_MISSING_DEPENDENCY([reduced])
AC_MSG_NOTICE([You are doing a reduced build. Check that you have 32-bit libraries installed. $HELP_MSG])
elif test "x$COMPILE_TYPE" = xcross; then
AC_MSG_NOTICE([You are doing a cross-compilation. Check that you have all target platform libraries installed.])
fi
AC_MSG_ERROR([Cannot continue.])
fi
fi
fi
AC_MSG_CHECKING([for target address size])
AC_MSG_RESULT([$OPENJDK_TARGET_CPU_BITS bits])
])
AC_DEFUN_ONCE([PLATFORM_SETUP_OPENJDK_TARGET_ENDIANNESS],
[
###############################################################################
#
# Is the target little of big endian?
#
AC_C_BIGENDIAN([ENDIAN="big"],[ENDIAN="little"],[ENDIAN="unknown"],[ENDIAN="universal_endianness"])
if test "x$ENDIAN" = xuniversal_endianness; then
AC_MSG_ERROR([Building with both big and little endianness is not supported])
fi
if test "x$ENDIAN" != "x$OPENJDK_TARGET_CPU_ENDIAN"; then
AC_MSG_ERROR([The tested endian in the target ($ENDIAN) differs from the endian expected to be found in the target ($OPENJDK_TARGET_CPU_ENDIAN)])
fi
])