autoconf/aclang.m4
Akim Demaille 55d7dff046 * acfunctions.m4 (_AC_LIBOBJ_ALLOCA, AC_REPLACE_FUNCS): Simplify
${foo} into $foo.
* aclang.m4 (AC_LANG(C), AC_LANG(C++)): Move some internal
comments into the header comment.
* acgeneral.m4 (AC_TRY_CPP): Likewise.
2000-08-07 12:33:17 +00:00

1654 lines
47 KiB
Plaintext

# This file is part of Autoconf. -*- Autoconf -*-
# Programming languages support.
# Copyright (C) 1992, 93, 94, 95, 96, 98, 99, 2000
# Free Software Foundation, Inc.
#
# This program is free software; you can redistribute it and/or modify
# it under the terms of the GNU General Public License as published by
# the Free Software Foundation; either version 2, or (at your option)
# any later version.
#
# This program 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 for more details.
#
# You should have received a copy of the GNU General Public License
# along with this program; if not, write to the Free Software
# Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA
# 02111-1307, USA.
#
# As a special exception, the Free Software Foundation gives unlimited
# permission to copy, distribute and modify the configure scripts that
# are the output of Autoconf. You need not follow the terms of the GNU
# General Public License when using or distributing such scripts, even
# though portions of the text of Autoconf appear in them. The GNU
# General Public License (GPL) does govern all other use of the material
# that constitutes the Autoconf program.
#
# Certain portions of the Autoconf source text are designed to be copied
# (in certain cases, depending on the input) into the output of
# Autoconf. We call these the "data" portions. The rest of the Autoconf
# source text consists of comments plus executable code that decides which
# of the data portions to output in any given case. We call these
# comments and executable code the "non-data" portions. Autoconf never
# copies any of the non-data portions into its output.
#
# This special exception to the GPL applies to versions of Autoconf
# released by the Free Software Foundation. When you make and
# distribute a modified version of Autoconf, you may extend this special
# exception to the GPL to apply to your modified version as well, *unless*
# your modified version has the potential to copy into its output some
# of the text that was the non-data portion of the version that you started
# with. (In other words, unless your change moves or copies text from
# the non-data portions to the data portions.) If your modification has
# such potential, you must delete any notice of this special exception
# to the GPL from your modified version.
#
# Written by David MacKenzie, with help from
# Franc,ois Pinard, Karl Berry, Richard Pixley, Ian Lance Taylor,
# Roland McGrath, Noah Friedman, david d zuhn, and many others.
# Table of Contents:
#
# 1. Language selection
# and routines to produce programs in a given language.
# a. generic routines
# b. C
# c. C++
# d. Fortran 77
#
# 2. Producing programs in a given language.
# a. generic routines
# b. C
# c. C++
# d. Fortran 77
#
# 3. Looking for a compiler
# And possibly the associated preprocessor.
# a. Generic routines.
# b. C
# c. C++
# d. Fortran 77
#
# 4. Compilers' characteristics.
# a. Generic routines.
# b. C
# c. C++
# d. Fortran 77
## ----------------------- ##
## 1. Language selection. ##
## ----------------------- ##
# -------------------------------- #
# 1a. Generic language selection. #
# -------------------------------- #
# AC_LANG_CASE(LANG1, IF-LANG1, LANG2, IF-LANG2, ..., DEFAULT)
# ------------------------------------------------------------
# Expand into IF-LANG1 if the current language is LANG1 etc. else
# into default.
define([AC_LANG_CASE],
[m4_case(_AC_LANG, $@)])
# _AC_LANG_DISPATCH(MACRO, LANG, ARGS)
# ------------------------------------
# Call the specialization of MACRO for LANG with ARGS. Complain if
# unavailable.
define([_AC_LANG_DISPATCH],
[ifdef([$1($2)],
[indir([$1($2)], m4_shiftn(2, $@))],
[AC_FATAL([$1: unknown language: $2])])])
# AC_LANG(LANG)
# -------------
# Set the current language to LANG.
#
# Do *not* write AC_LANG([$1]), because this pair of parens does not
# correspond to an evaluation, rather, they are just part of the name.
# If you add quotes here, they will be part of the name too, yielding
# `AC_LANG([C])' for instance, which does not exist.
AC_DEFUN([AC_LANG],
[define([_AC_LANG], [$1])dnl
_AC_LANG_DISPATCH([$0], _AC_LANG, $@)])
# AC_LANG_PUSH(LANG)
# ------------------
# Save the current language, and use LANG.
define([AC_LANG_PUSH],
[pushdef([_AC_LANG])dnl
AC_LANG([$1])])
# AC_LANG_POP
# -----------
# Restore the previous language.
define([AC_LANG_POP],
[popdef([_AC_LANG])dnl
ifelse(_AC_LANG, [_AC_LANG],
[AC_FATAL([too many $0])])dnl
AC_LANG(_AC_LANG)])
# AC_LANG_SAVE
# ------------
# Save the current language, but don't change language.
AU_DEFUN([AC_LANG_SAVE],
[AC_DIAGNOSE([obsolete],
[instead of using `AC_LANG', `AC_LANG_SAVE',
and `AC_LANG_RESTORE', you should use `AC_LANG_PUSH' and `AC_LANG_POP'.])
pushdef([_AC_LANG], _AC_LANG)])
# AC_LANG_RESTORE
# ---------------
# Restore the current language from the stack.
AU_DEFUN([AC_LANG_RESTORE], [AC_LANG_POP($@)])
# -------------------- #
# 1b. The C language. #
# -------------------- #
# AC_LANG(C)
# ----------
# CFLAGS is not in ac_cpp because -g, -O, etc. are not valid cpp options.
define([AC_LANG(C)],
[ac_ext=c
ac_cpp='$CPP $CPPFLAGS'
ac_compile='${CC-cc} -c $CFLAGS $CPPFLAGS conftest.$ac_ext >&AC_FD_LOG'
ac_link='${CC-cc} -o conftest$ac_exeext $CFLAGS $CPPFLAGS $LDFLAGS conftest.$ac_ext $LIBS >&AC_FD_LOG'
ac_gnu_compiler=$ac_cv_prog_gcc
])
# AC_LANG_C
# ---------
AU_DEFUN([AC_LANG_C], [AC_LANG(C)])
# ---------------------- #
# 1c. The C++ language. #
# ---------------------- #
# AC_LANG(C++)
# ------------
# CXXFLAGS is not in ac_cpp because -g, -O, etc. are not valid cpp options.
define([AC_LANG(C++)],
[ac_ext=cc
ac_cpp='$CXXCPP $CPPFLAGS'
ac_compile='${CXX-g++} -c $CXXFLAGS $CPPFLAGS conftest.$ac_ext >&AC_FD_LOG'
ac_link='${CXX-g++} -o conftest$ac_exeext $CXXFLAGS $CPPFLAGS $LDFLAGS conftest.$ac_ext $LIBS >&AC_FD_LOG'
ac_gnu_compiler=$ac_cv_prog_gxx
])
# AC_LANG_CPLUSPLUS
# -----------------
AU_DEFUN([AC_LANG_CPLUSPLUS], [AC_LANG(C++)])
# ----------------------------- #
# 1d. The Fortran 77 language. #
# ----------------------------- #
# AC_LANG(Fortran 77)
# -------------------
define([AC_LANG(Fortran 77)],
[ac_ext=f
ac_compile='${F77-f77} -c $FFLAGS conftest.$ac_ext >&AC_FD_LOG'
ac_link='${F77-f77} -o conftest$ac_exeext $FFLAGS $LDFLAGS conftest.$ac_ext $LIBS >&AC_FD_LOG'
ac_gnu_compiler=$ac_cv_prog_g77
])
# AC_LANG_FORTRAN77
# -----------------
AU_DEFUN([AC_LANG_FORTRAN77], [AC_LANG(Fortran 77)])
## ---------------------- ##
## 2.Producing programs. ##
## ---------------------- ##
# ---------------------- #
# 2a. Generic routines. #
# ---------------------- #
# AC_LANG_CONFTEST(BODY)
# ---------------------
# Save the BODY in `conftest.$acext'. Add a trailing new line.
define([AC_LANG_CONFTEST],
[cat >conftest.$ac_ext <<_ACEOF
$1
_ACEOF])
# AC_LANG_SOURCE(BODY)
# --------------------
# Produce a valid source for the current language, which includes the
# BODY, and as much as possible `confdefs.h' and the `#line' sync
# lines.
AC_DEFUN([AC_LANG_SOURCE],
[_AC_LANG_DISPATCH([$0], _AC_LANG, $@)])
# AC_LANG_PROGRAM([PROLOGUE], [BODY])
# -----------------------------------
# Produce a valid source for the current language. Prepend the
# PROLOGUE (typically CPP directives and/or declarations) to an
# execution the BODY (typically glued inside the `main' function, or
# equivalent).
AC_DEFUN([AC_LANG_PROGRAM],
[AC_LANG_SOURCE([_AC_LANG_DISPATCH([$0], _AC_LANG, $@)])])
# AC_LANG_CALL(PROLOGUE, FUNCTION)
# --------------------------------
# Call the FUNCTION.
AC_DEFUN([AC_LANG_CALL],
[_AC_LANG_DISPATCH([$0], _AC_LANG, $@)])
# AC_LANG_FUNC_LINK_TRY(FUNCTION)
# -------------------------------
# Produce a source which links correctly iff the FUNCTION exists.
AC_DEFUN([AC_LANG_FUNC_LINK_TRY],
[_AC_LANG_DISPATCH([$0], _AC_LANG, $@)])
# AC_LANG_BOOL_COMPILE_TRY(PROLOGUE, EXPRESSION)
# ----------------------------------------------
# Produce a program that compiles with success iff the boolean EXPRESSION
# evaluates to true at compile time.
AC_DEFUN([AC_LANG_BOOL_COMPILE_TRY],
[_AC_LANG_DISPATCH([$0], _AC_LANG, $@)])
# AC_LANG_INT_SAVE(PROLOGUE, EXPRESSION)
# --------------------------------------
# Produce a program that saves the runtime evaluation of the integer
# EXPRESSION into `conftestval'.
AC_DEFUN([AC_LANG_INT_SAVE],
[_AC_LANG_DISPATCH([$0], _AC_LANG, $@)])
# --------------- #
# 2b. C sources. #
# --------------- #
# AC_LANG_SOURCE(C)(BODY)
# -----------------------
# This sometimes fails to find confdefs.h, for some reason.
# #line __oline__ "$[0]"
define([AC_LANG_SOURCE(C)],
[#line __oline__ "configure"
#include "confdefs.h"
$1])
# AC_LANG_PROGRAM(C)([PROLOGUE], [BODY])
# --------------------------------------
define([AC_LANG_PROGRAM(C)],
[$1
int
main ()
{
dnl Do *not* indent the following line: there may be CPP directives.
dnl Don't move the `;' right after for the same reason.
$2
;
return 0;
}])
# AC_LANG_CALL(C)(PROLOGUE, FUNCTION)
# -----------------------------------
# Avoid conflicting decl of main.
define([AC_LANG_CALL(C)],
[AC_LANG_PROGRAM([$1
ifelse([$2], [main], ,
[/* Override any gcc2 internal prototype to avoid an error. */
#ifdef __cplusplus
extern "C"
#endif
/* We use char because int might match the return type of a gcc2
builtin and then its argument prototype would still apply. */
char $2 ();])], [$2 ();])])
# AC_LANG_FUNC_LINK_TRY(C)(FUNCTION)
# ----------------------------------
# Don't include <ctype.h> because on OSF/1 3.0 it includes
# <sys/types.h> which includes <sys/select.h> which contains a
# prototype for select. Similarly for bzero.
define([AC_LANG_FUNC_LINK_TRY(C)],
[AC_LANG_PROGRAM(
[/* System header to define __stub macros and hopefully few prototypes,
which can conflict with char $1 (); below. */
#include <assert.h>
/* Override any gcc2 internal prototype to avoid an error. */
#ifdef __cplusplus
extern "C"
#endif
/* We use char because int might match the return type of a gcc2
builtin and then its argument prototype would still apply. */
char $1 ();
char (*f) ();
],
[/* The GNU C library defines this for functions which it implements
to always fail with ENOSYS. Some functions are actually named
something starting with __ and the normal name is an alias. */
#if defined (__stub_$1) || defined (__stub___$1)
choke me
#else
f = $1;
#endif
])])
# AC_LANG_BOOL_COMPILE_TRY(C)(PROLOGUE, EXPRESSION)
# -------------------------------------------------
define([AC_LANG_BOOL_COMPILE_TRY(C)],
[AC_LANG_PROGRAM([$1], [int _array_ @<:@1 - 2 * !($2)@:>@])])
# AC_LANG_INT_SAVE(C)(PROLOGUE, EXPRESSION)
# -----------------------------------------
# We need `stdio.h' to open a `FILE', so the prologue defaults to the
# inclusion of `stdio.h'.
define([AC_LANG_INT_SAVE(C)],
[AC_LANG_PROGRAM([m4_default([$1], [@%:@include "stdio.h"])],
[FILE *f = fopen ("conftestval", "w");
if (!f)
exit (1);
fprintf (f, "%d\n", ($2));])])
# ----------------- #
# 2c. C++ sources. #
# ----------------- #
# AC_LANG_SOURCE(C++)(BODY)
# -------------------------
define([AC_LANG_SOURCE(C++)],
[#line __oline__ "configure"
#include "confdefs.h"
#ifdef __cplusplus
extern "C" void exit (int);
#endif
$1])
# AC_LANG_PROGRAM(C++)([PROLOGUE], [BODY])
# ----------------------------------------
# Same as C.
define([AC_LANG_PROGRAM(C++)], defn([AC_LANG_PROGRAM(C)]))
# AC_LANG_CALL(C++)(PROLOGUE, FUNCTION)
# -------------------------------------
# Same as C.
define([AC_LANG_CALL(C++)], defn([AC_LANG_CALL(C)]))
# AC_LANG_FUNC_LINK_TRY(C++)(FUNCTION)
# ------------------------------------
# Same as C.
define([AC_LANG_FUNC_LINK_TRY(C++)], defn([AC_LANG_FUNC_LINK_TRY(C)]))
# AC_LANG_BOOL_COMPILE_TRY(C++)(PROLOGUE, EXPRESSION)
# ---------------------------------------------------
# Same as C.
define([AC_LANG_BOOL_COMPILE_TRY(C++)], defn([AC_LANG_BOOL_COMPILE_TRY(C)]))
# AC_LANG_INT_SAVE(C++)(PROLOGUE, EXPRESSION)
# -------------------------------------------
# Same as C.
define([AC_LANG_INT_SAVE(C++)], defn([AC_LANG_INT_SAVE(C)]))
# ------------------------ #
# 2d. Fortran 77 sources. #
# ------------------------ #
# AC_LANG_SOURCE(Fortran 77)(BODY)
# --------------------------------
# FIXME: Apparently, according to former AC_TRY_COMPILER, the CPP
# directives must not be included. But AC_TRY_RUN_NATIVE was not
# avoiding them, so?
define([AC_LANG_SOURCE(Fortran 77)],
[$1])
# AC_LANG_PROGRAM(Fortran 77)([PROLOGUE], [BODY])
# -----------------------------------------------
# Yes, we discard the PROLOGUE.
define([AC_LANG_PROGRAM(Fortran 77)],
[ program main
$2
end])
# AC_LANG_CALL(Fortran 77)(PROLOGUE, FUNCTION)
# --------------------------------------------
# FIXME: This is a guess, help!
define([AC_LANG_CALL(Fortran 77)],
[AC_LANG_PROGRAM([$1],
[ call $2])])
## -------------------------------------------- ##
## 3. Looking for Compilers and Preprocessors. ##
## -------------------------------------------- ##
# ----------------------------------------------------- #
# 3a. Generic routines in compilers and preprocessors. #
# ----------------------------------------------------- #
# AC_REQUIRE_CPP
# --------------
# Require finding the C or C++ preprocessor, whichever is the
# current language.
AC_DEFUN([AC_REQUIRE_CPP],
[AC_LANG_CASE(C, [AC_REQUIRE([AC_PROG_CPP])],
[AC_REQUIRE([AC_PROG_CXXCPP])])])
# AC_LANG_COMPILER_WORKS
# ----------------------
define([_AC_LANG_COMPILER_WORKS],
[AC_MSG_CHECKING([whether the _AC_LANG compiler works])
AC_LINK_IFELSE([AC_LANG_PROGRAM()],
[# FIXME: these cross compiler hacks should be removed for autoconf 3.0
# If not cross compiling, check that we can run a simple program.
if test "$cross_compiling" != yes; then
if AC_TRY_COMMAND(./conftest); then
cross_compiling=no
else
if test "$cross_compiling" = maybe; then
cross_compiling=yes
else
AC_MSG_ERROR([cannot run _AC_LANG compiled programs.
To enable cross compilation, use `--host'.])
fi
fi
fi
AC_MSG_RESULT(yes)],
[AC_MSG_RESULT(no)
AC_MSG_ERROR([_AC_LANG compiler cannot create executables], 77)])[]dnl
AC_MSG_CHECKING([whether we are cross compiling])
AC_MSG_RESULT($cross_compiling)
])# AC_LANG_COMPILER_WORKS
# -------------------- #
# 3b. The C compiler. #
# -------------------- #
# AC_PROG_CPP
# -----------
AC_DEFUN([AC_PROG_CPP],
[AC_MSG_CHECKING(how to run the C preprocessor)
# On Suns, sometimes $CPP names a directory.
if test -n "$CPP" && test -d "$CPP"; then
CPP=
fi
if test -z "$CPP"; then
AC_CACHE_VAL(ac_cv_prog_CPP,
[ # This must be in double quotes, not single quotes, because CPP may get
# substituted into the Makefile and "${CC-cc}" will confuse make.
CPP="${CC-cc} -E"
# On the NeXT, cc -E runs the code through the compiler's parser,
# not just through cpp.
# Use a header file that comes with gcc, so configuring glibc
# with a fresh cross-compiler works.
AC_TRY_CPP([#include <assert.h>
Syntax Error], ,
CPP="${CC-cc} -E -traditional-cpp"
AC_TRY_CPP([#include <assert.h>
Syntax Error], ,
CPP="${CC-cc} -nologo -E"
AC_TRY_CPP([#include <assert.h>
Syntax Error], , CPP=/lib/cpp)))
ac_cv_prog_CPP=$CPP])dnl
CPP=$ac_cv_prog_CPP
else
ac_cv_prog_CPP=$CPP
fi
AC_MSG_RESULT($CPP)
AC_SUBST(CPP)dnl
])# AC_PROG_CPP
# AC_PROG_CC([COMPILER ...])
# --------------------------
# COMPILER ... is a space separated list of C compilers to search for.
# This just gives the user an opportunity to specify an alternative
# search list for the C compiler.
AC_DEFUN([AC_PROG_CC],
[AC_BEFORE([$0], [AC_PROG_CPP])dnl
AC_LANG_PUSH(C)
AC_ARG_VAR([CC], [C compiler command])
AC_ARG_VAR([CFLAGS], [C compiler flags])
ifval([$1],
[AC_CHECK_TOOLS(CC, [$1])],
[AC_CHECK_TOOL(CC, gcc)
if test -z "$CC"; then
AC_CHECK_TOOL(CC, cc)
fi
if test -z "$CC"; then
AC_CHECK_PROG(CC, cc, cc, , , /usr/ucb/cc)
fi
if test -z "$CC"; then
AC_CHECK_TOOLS(CC, cl)
fi
])
test -z "$CC" && AC_MSG_ERROR([no acceptable cc found in \$PATH])
_AC_LANG_COMPILER_WORKS
_AC_PROG_CC_GNU
_AC_PROG_CC_G
AC_EXPAND_ONCE([_AC_EXEEXT])
AC_EXPAND_ONCE([_AC_OBJEXT])
AC_LANG_POP
])# AC_PROG_CC
# _AC_PROG_CC_GNU
# ---------------
define([_AC_PROG_CC_GNU],
[AC_CACHE_CHECK(whether we are using GNU C, ac_cv_prog_gcc,
[# The semicolon is to pacify NeXT's syntax-checking cpp.
cat >conftest.$ac_ext <<_ACEOF
#ifdef __GNUC__
yes;
#endif
_ACEOF
if AC_TRY_COMMAND(${CC-cc} -E conftest.$ac_ext) | grep yes >/dev/null; then
ac_cv_prog_gcc=yes
else
ac_cv_prog_gcc=no
fi])
ac_gnu_compiler=$ac_cv_prog_gcc
if test $ac_gnu_compiler = yes; then
GCC=yes
else
GCC=
fi[]dnl
])# _AC_PROG_CC_GNU
# _AC_PROG_CC_G
# -------------
# Check whether -g works, even if CFLAGS is set, in case the package
# plays around with CFLAGS (such as to build both debugging and normal
# versions of a library), tasteless as that idea is.
define([_AC_PROG_CC_G],
[ac_test_CFLAGS=${CFLAGS+set}
ac_save_CFLAGS=$CFLAGS
CFLAGS=
AC_CACHE_CHECK(whether ${CC-cc} accepts -g, ac_cv_prog_cc_g,
[AC_LANG_CONFTEST([AC_LANG_PROGRAM([])])
if ${CC-cc} -g -c conftest.$ac_ext 2>&1 | grep . >/dev/null; then
ac_cv_prog_cc_g=no
else
ac_cv_prog_cc_g=yes
fi
rm -f conftest*
])
if test "$ac_test_CFLAGS" = set; then
CFLAGS=$ac_save_CFLAGS
elif test $ac_cv_prog_cc_g = yes; then
if test "$GCC" = yes; then
CFLAGS="-g -O2"
else
CFLAGS="-g"
fi
else
if test "$GCC" = yes; then
CFLAGS="-O2"
else
CFLAGS=
fi
fi[]dnl
])# _AC_PROG_CC_G
# AC_PROG_GCC_TRADITIONAL
# -----------------------
AC_DEFUN([AC_PROG_GCC_TRADITIONAL],
[AC_REQUIRE([AC_PROG_CC])dnl
AC_REQUIRE([AC_PROG_CPP])dnl
if test $ac_cv_prog_gcc = yes; then
AC_CACHE_CHECK(whether ${CC-cc} needs -traditional,
ac_cv_prog_gcc_traditional,
[ ac_pattern="Autoconf.*'x'"
AC_EGREP_CPP($ac_pattern, [#include <sgtty.h>
Autoconf TIOCGETP],
ac_cv_prog_gcc_traditional=yes, ac_cv_prog_gcc_traditional=no)
if test $ac_cv_prog_gcc_traditional = no; then
AC_EGREP_CPP($ac_pattern, [#include <termio.h>
Autoconf TCGETA],
ac_cv_prog_gcc_traditional=yes)
fi])
if test $ac_cv_prog_gcc_traditional = yes; then
CC="$CC -traditional"
fi
fi
])# AC_PROG_GCC_TRADITIONAL
# AC_PROG_CC_C_O
# --------------
AC_DEFUN([AC_PROG_CC_C_O],
[AC_REQUIRE([AC_PROG_CC])dnl
if test "x$CC" != xcc; then
AC_MSG_CHECKING(whether $CC and cc understand -c and -o together)
else
AC_MSG_CHECKING(whether cc understands -c and -o together)
fi
set dummy $CC; ac_cc=`echo $[2] |
sed 's/[[^a-zA-Z0-9_]]/_/g;s/^[[0-9]]/_/'`
AC_CACHE_VAL(ac_cv_prog_cc_${ac_cc}_c_o,
[AC_LANG_CONFTEST([AC_LANG_PROGRAM([])])
# Make sure it works both with $CC and with simple cc.
# We do the test twice because some compilers refuse to overwrite an
# existing .o file with -o, though they will create one.
ac_try='${CC-cc} -c conftest.$ac_ext -o conftest.$objext >&AC_FD_LOG'
if AC_TRY_EVAL(ac_try) &&
test -f conftest.$objext && AC_TRY_EVAL(ac_try);
then
eval ac_cv_prog_cc_${ac_cc}_c_o=yes
if test "x$CC" != xcc; then
# Test first that cc exists at all.
if AC_TRY_COMMAND(cc -c conftest.$ac_ext >&AC_FD_LOG); then
ac_try='cc -c conftest.$ac_ext -o conftest.$ac_objext >&AC_FD_LOG'
if AC_TRY_EVAL(ac_try) &&
test -f conftest.$objext && AC_TRY_EVAL(ac_try);
then
# cc works too.
:
else
# cc exists but doesn't like -o.
eval ac_cv_prog_cc_${ac_cc}_c_o=no
fi
fi
fi
else
eval ac_cv_prog_cc_${ac_cc}_c_o=no
fi
rm -f conftest*
])dnl
if eval "test \"`echo '$ac_cv_prog_cc_'${ac_cc}_c_o`\" = yes"; then
AC_MSG_RESULT(yes)
else
AC_MSG_RESULT(no)
AC_DEFINE(NO_MINUS_C_MINUS_O, 1,
[Define if your C compiler doesn't accept -c and -o together.])
fi
])# AC_PROG_CC_C_O
# ---------------------- #
# 3c. The C++ compiler. #
# ---------------------- #
# AC_PROG_CXXCPP
# --------------
AC_DEFUN([AC_PROG_CXXCPP],
[AC_MSG_CHECKING(how to run the C++ preprocessor)
if test -z "$CXXCPP"; then
AC_CACHE_VAL(ac_cv_prog_CXXCPP,
[AC_LANG_PUSH(C++)
CXXCPP="${CXX-g++} -E"
AC_TRY_CPP([#include <stdlib.h>], , CXXCPP=/lib/cpp)
ac_cv_prog_CXXCPP=$CXXCPP
AC_LANG_POP()dnl
])dnl
CXXCPP=$ac_cv_prog_CXXCPP
fi
AC_MSG_RESULT($CXXCPP)
AC_SUBST(CXXCPP)dnl
])
# AC_PROG_CXXCPP
# AC_PROG_CXX([LIST-OF-COMPILERS])
# --------------------------------
# LIST-OF-COMPILERS is a space separated list of C++ compilers to search
# for (if not specified, a default list is used). This just gives the
# user an opportunity to specify an alternative search list for the C++
# compiler.
# aCC HP-UX C++ compiler much better than `CC', so test before.
# KCC KAI C++ compiler
# RCC Rational C++
# xlC_r AIX C Set++ (with support for reentrant code)
# xlC AIX C Set++
AC_DEFUN([AC_PROG_CXX],
[AC_BEFORE([$0], [AC_PROG_CXXCPP])dnl
AC_LANG_PUSH(C++)
AC_ARG_VAR([CXX], [C++ compiler command])
AC_ARG_VAR([CXXFLAGS], [C++ compiler flags])
AC_CHECK_TOOLS(CXX,
[$CCC m4_default([$1],
[g++ c++ gpp aCC CC cxx cc++ cl KCC RCC xlC_r xlC])],
g++)
_AC_LANG_COMPILER_WORKS
_AC_PROG_CXX_GNU
_AC_PROG_CXX_G
AC_EXPAND_ONCE([_AC_EXEEXT])
AC_EXPAND_ONCE([_AC_OBJEXT])
AC_LANG_POP
])# AC_PROG_CXX
# _AC_PROG_CXX_GNU
# ----------------
define([_AC_PROG_CXX_GNU],
[AC_CACHE_CHECK(whether we are using GNU C++, ac_cv_prog_gxx,
[# The semicolon is to pacify NeXT's syntax-checking cpp.
cat >conftest.$ac_ext <<_ACEOF
#ifdef __GNUC__
yes;
#endif
_ACEOF
if AC_TRY_COMMAND(${CXX-g++} -E conftest.$ac_ext) | grep yes >/dev/null; then
ac_cv_prog_gxx=yes
else
ac_cv_prog_gxx=no
fi])
ac_gnu_compiler=$ac_cv_prog_gxx
if test $ac_gnu_compiler = yes; then
GXX=yes
else
GXX=
fi[]dnl
])# _AC_PROG_CXX_GNU
# _AC_PROG_CXX_G
# --------------
# Check whether -g works, even if CXXFLAGS is set, in case the package
# plays around with CXXFLAGS (such as to build both debugging and
# normal versions of a library), tasteless as that idea is.
define([_AC_PROG_CXX_G],
[ac_test_CXXFLAGS=${CXXFLAGS+set}
ac_save_CXXFLAGS=$CXXFLAGS
CXXFLAGS=
AC_CACHE_CHECK(whether ${CXX-g++} accepts -g, ac_cv_prog_cxx_g,
[AC_LANG_CONFTEST([AC_LANG_PROGRAM([])])
if ${CXX-g++} -g -c conftest.$ac_ext 2>&1 | grep . >/dev/null; then
ac_cv_prog_cxx_g=no
else
ac_cv_prog_cxx_g=yes
fi
rm -f conftest*
])
if test "$ac_test_CXXFLAGS" = set; then
CXXFLAGS=$ac_save_CXXFLAGS
elif test $ac_cv_prog_cxx_g = yes; then
if test "$GXX" = yes; then
CXXFLAGS="-g -O2"
else
CXXFLAGS="-g"
fi
else
if test "$GXX" = yes; then
CXXFLAGS="-O2"
else
CXXFLAGS=
fi
fi[]dnl
])# _AC_PROG_CXX_G
# ----------------------------- #
# 3d. The Fortran 77 compiler. #
# ----------------------------- #
# AC_PROG_F77([COMPILERS...])
# ---------------------------
# COMPILERS is a space separated list of Fortran 77 compilers to search
# for.
# Fortran 95 isn't strictly backwards-compatiable with Fortran 77, but
# `f95' is worth trying.
#
# Compilers are ordered by
# 1. F77, F90, F95
# 2. Good native compilers, bad native compilers, wrappers around f2c.
#
# `fort77' and `fc' are wrappers around `f2c', `fort77' being better.
# It is believed that under HP-UX `fort77' is the name of the native
# compiler. NAG f95 is preferred over `fc', so put `fc' last.
# pgf77 is the Portland Group f77 compiler.
# lf95 is the Lahey-Fujitsu compiler.
AC_DEFUN([AC_PROG_F77],
[AC_LANG_PUSH(Fortran 77)
AC_ARG_VAR([F77], [Fortran 77 compiler command])
AC_ARG_VAR([FFLAGS], [Fortran 77 compiler flags])
AC_CHECK_TOOLS(F77,
[m4_default([$1],
[g77 f77 xlf cf77 pgf77 fl32 fort77 f90 xlf90 f95 lf95 fc])])
_AC_LANG_COMPILER_WORKS
_AC_PROG_F77_GNU
_AC_PROG_F77_G
AC_EXPAND_ONCE([_AC_EXEEXT])
AC_EXPAND_ONCE([_AC_OBJEXT])
AC_LANG_POP
])# AC_PROG_F77
# _AC_PROG_F77_GNU
# ----------------
# Test whether for Fortran 77 compiler is `g77' (the GNU Fortran 77
# Compiler). This test depends on whether the Fortran 77 compiler can
# do CPP pre-processing.
define([_AC_PROG_F77_GNU],
[AC_CACHE_CHECK(whether we are using GNU Fortran 77, ac_cv_prog_g77,
[cat >conftest.$ac_ext <<_ACEOF
#ifdef __GNUC__
yes
#endif
_ACEOF
if AC_TRY_COMMAND($F77 -E conftest.$ac_ext) | grep yes >/dev/null; then
ac_cv_prog_g77=yes
else
ac_cv_prog_g77=no
fi])
ac_gnu_compiler=$ac_cv_prog_g77
if test $ac_gnu_compiler = yes; then
G77=yes
else
G77=
fi[]dnl
])# _AC_PROG_F77_GNU
# _AC_PROG_F77_G
# --------------
# Check whether -g works, even if FFLAGS is set, in case the package
# plays around with FFLAGS (such as to build both debugging and normal
# versions of a library), tasteless as that idea is.
define([_AC_PROG_F77_G],
[ac_test_FFLAGS=${FFLAGS+set}
ac_save_FFLAGS=$FFLAGS
FFLAGS=
AC_CACHE_CHECK(whether $F77 accepts -g, ac_cv_prog_f77_g,
[FFLAGS=-g
AC_COMPILE_IFELSE([AC_LANG_PROGRAM()],
[ac_cv_prog_f77_g=yes],
[ac_cv_prog_f77_g=no])
])
if test "$ac_test_FFLAGS" = set; then
FFLAGS=$ac_save_FFLAGS
elif test $ac_cv_prog_f77_g = yes; then
if test "$G77" = yes; then
FFLAGS="-g -O2"
else
FFLAGS="-g"
fi
else
if test "$G77" = yes; then
FFLAGS="-O2"
else
FFLAGS=
fi
fi[]dnl
])# _AC_PROG_F77_G
# AC_PROG_F77_C_O
# ---------------
# Test if the Fortran 77 compiler accepts the options `-c' and `-o'
# simultaneously, and define `F77_NO_MINUS_C_MINUS_O' if it does not.
#
# The usefulness of this macro is questionable, as I can't really see
# why anyone would use it. The only reason I include it is for
# completeness, since a similar test exists for the C compiler.
AC_DEFUN([AC_PROG_F77_C_O],
[AC_REQUIRE([AC_PROG_F77])dnl
AC_CACHE_CHECK([whether $F77 understand -c and -o together],
[ac_cv_prog_f77_c_o],
[AC_LANG_CONFTEST([AC_LANG_PROGRAM([])])
# We do the `AC_TRY_EVAL' test twice because some compilers refuse to
# overwrite an existing `.o' file with `-o', although they will create
# one.
ac_try='$F77 $FFLAGS -c conftest.$ac_ext -o conftest.$objext >&AC_FD_LOG'
if AC_TRY_EVAL(ac_try) && test -f conftest.$objext && AC_TRY_EVAL(ac_try); then
ac_cv_prog_f77_c_o=yes
else
ac_cv_prog_f77_c_o=no
fi
rm -f conftest*])
if test $ac_cv_prog_f77_c_o = yes; then
AC_DEFINE(F77_NO_MINUS_C_MINUS_O, 1,
[Define if your Fortran 77 compiler doesn't accept -c and -o together.])
fi
])# AC_PROG_F77_C_O
## ------------------------------- ##
## 4. Compilers' characteristics. ##
## ------------------------------- ##
# -------------------------------- #
# 4b. C compiler characteristics. #
# -------------------------------- #
# AC_PROG_CC_STDC
# ---------------
# If the C compiler in not in ANSI C mode by default, try to add an
# option to output variable @code{CC} to make it so. This macro tries
# various options that select ANSI C on some system or another. It
# considers the compiler to be in ANSI C mode if it handles function
# prototypes correctly.
AC_DEFUN([AC_PROG_CC_STDC],
[AC_REQUIRE([AC_PROG_CC])dnl
AC_BEFORE([$0], [AC_C_INLINE])dnl
AC_BEFORE([$0], [AC_C_CONST])dnl
dnl Force this before AC_PROG_CPP. Some cpp's, eg on HPUX, require
dnl a magic option to avoid problems with ANSI preprocessor commands
dnl like #elif.
dnl FIXME: can't do this because then AC_AIX won't work due to a
dnl circular dependency.
dnl AC_BEFORE([$0], [AC_PROG_CPP])
AC_MSG_CHECKING(for ${CC-cc} option to accept ANSI C)
AC_CACHE_VAL(ac_cv_prog_cc_stdc,
[ac_cv_prog_cc_stdc=no
ac_save_CC=$CC
# Don't try gcc -ansi; that turns off useful extensions and
# breaks some systems' header files.
# AIX -qlanglvl=ansi
# Ultrix and OSF/1 -std1
# HP-UX 10.20 and later -Ae
# HP-UX older versions -Aa -D_HPUX_SOURCE
# SVR4 -Xc -D__EXTENSIONS__
for ac_arg in "" -qlanglvl=ansi -std1 -Ae "-Aa -D_HPUX_SOURCE" "-Xc -D__EXTENSIONS__"
do
CC="$ac_save_CC $ac_arg"
AC_COMPILE_IFELSE(
[AC_LANG_PROGRAM(
[[#include <stdarg.h>
#include <stdio.h>
#include <sys/types.h>
#include <sys/stat.h>
/* Most of the following tests are stolen from RCS 5.7's src/conf.sh. */
struct buf { int x; };
FILE * (*rcsopen) (struct buf *, struct stat *, int);
static char *e (p, i)
char **p;
int i;
{
return p[i];
}
static char *f (char * (*g) (char **, int), char **p, ...)
{
char *s;
va_list v;
va_start (v,p);
s = g (p, va_arg (v,int));
va_end (v);
return s;
}
int test (int i, double x);
struct s1 {int (*f) (int a);};
struct s2 {int (*f) (double a);};
int pairnames (int, char **, FILE *(*)(struct buf *, struct stat *, int), int, int);
int argc;
char **argv;]],
[[return f (e, argv, 0) != argv[0] || f (e, argv, 1) != argv[1];]])],
[ac_cv_prog_cc_stdc=$ac_arg; break])
done
CC=$ac_save_CC
])
case "x$ac_cv_prog_cc_stdc" in
x|xno)
AC_MSG_RESULT([none needed]) ;;
*)
AC_MSG_RESULT($ac_cv_prog_cc_stdc)
CC="$CC $ac_cv_prog_cc_stdc" ;;
esac
])# AC_PROG_CC_STDC
AC_DEFUN([AC_C_CROSS],
[AC_OBSOLETE([$0], [; it has been merged into AC_PROG_CC])])
# AC_C_CHAR_UNSIGNED
# ------------------
AC_DEFUN([AC_C_CHAR_UNSIGNED],
[AH_VERBATIM([__CHAR_UNSIGNED__],
[/* Define if type `char' is unsigned and you are not using gcc. */
#ifndef __CHAR_UNSIGNED__
# undef __CHAR_UNSIGNED__
#endif])dnl
AC_CACHE_CHECK(whether char is unsigned, ac_cv_c_char_unsigned,
[AC_COMPILE_IFELSE([AC_LANG_BOOL_COMPILE_TRY([AC_INCLUDES_DEFAULT([])],
[((char) -1) < 0])],
ac_cv_c_char_unsigned=no, ac_cv_c_char_unsigned=yes)])
if test $ac_cv_c_char_unsigned = yes && test "$GCC" != yes; then
AC_DEFINE(__CHAR_UNSIGNED__)
fi
])# AC_C_CHAR_UNSIGNED
# AC_C_LONG_DOUBLE
# ----------------
AC_DEFUN([AC_C_LONG_DOUBLE],
[AC_CACHE_CHECK(for long double, ac_cv_c_long_double,
[if test "$GCC" = yes; then
ac_cv_c_long_double=yes
else
AC_TRY_RUN(
[int
main ()
{
/* The Stardent Vistra knows sizeof(long double), but does not
support it. */
long double foo = 0.0;
/* On Ultrix 4.3 cc, long double is 4 and double is 8. */
exit (sizeof (long double) < sizeof (double));
}],
ac_cv_c_long_double=yes, ac_cv_c_long_double=no)
fi])
if test $ac_cv_c_long_double = yes; then
AC_DEFINE(HAVE_LONG_DOUBLE, 1,
[Define if the `long double' type works.])
fi
])# AC_C_LONG_DOUBLE
# AC_C_BIGENDIAN
# --------------
AC_DEFUN([AC_C_BIGENDIAN],
[AC_CACHE_CHECK(whether byte ordering is bigendian, ac_cv_c_bigendian,
[ac_cv_c_bigendian=unknown
# See if sys/param.h defines the BYTE_ORDER macro.
AC_COMPILE_IFELSE([AC_LANG_PROGRAM([#include <sys/types.h>
#include <sys/param.h>
],
[#if !BYTE_ORDER || !BIG_ENDIAN || !LITTLE_ENDIAN
bogus endian macros
#endif
])],
[# It does; now see whether it defined to BIG_ENDIAN or not.
AC_COMPILE_IFELSE([AC_LANG_PROGRAM([#include <sys/types.h>
#include <sys/param.h>
], [#if BYTE_ORDER != BIG_ENDIAN
not big endian
#endif
])], [ac_cv_c_bigendian=yes],
[ac_cv_c_bigendian=no])])
if test $ac_cv_c_bigendian = unknown; then
AC_TRY_RUN(
[int
main ()
{
/* Are we little or big endian? From Harbison&Steele. */
union
{
long l;
char c[sizeof (long)];
} u;
u.l = 1;
exit (u.c[sizeof (long) - 1] == 1);
}], ac_cv_c_bigendian=no, ac_cv_c_bigendian=yes)
fi])
if test $ac_cv_c_bigendian = yes; then
AC_DEFINE(WORDS_BIGENDIAN, 1,
[Define if your processor stores words with the most significant
byte first (like Motorola and SPARC, unlike Intel and VAX).])
fi
])# AC_C_BIGENDIAN
# AC_C_INLINE
# -----------
# Do nothing if the compiler accepts the inline keyword.
# Otherwise define inline to __inline__ or __inline if one of those work,
# otherwise define inline to be empty.
AC_DEFUN([AC_C_INLINE],
[AC_REQUIRE([AC_PROG_CC_STDC])dnl
AC_CACHE_CHECK([for inline], ac_cv_c_inline,
[ac_cv_c_inline=no
for ac_kw in inline __inline__ __inline; do
AC_COMPILE_IFELSE([AC_LANG_SOURCE(
[#ifndef __cplusplus
$ac_kw int foo () {return 0; }
#endif
])],
[ac_cv_c_inline=$ac_kw; break])
done
])
case $ac_cv_c_inline in
inline | yes) ;;
no) AC_DEFINE(inline,,
[Define as `__inline' if that's what the C compiler calls it,
or to nothing if it is not supported.]) ;;
*) AC_DEFINE_UNQUOTED(inline, $ac_cv_c_inline) ;;
esac
])# AC_C_INLINE
# AC_C_CONST
# ----------
AC_DEFUN([AC_C_CONST],
[AC_REQUIRE([AC_PROG_CC_STDC])dnl
AC_CACHE_CHECK([for an ANSI C-conforming const], ac_cv_c_const,
[AC_COMPILE_IFELSE([AC_LANG_PROGRAM([],
[[/* FIXME: Include the comments suggested by Paul. */
#ifndef __cplusplus
/* Ultrix mips cc rejects this. */
typedef int charset[2];
const charset x;
/* SunOS 4.1.1 cc rejects this. */
char const *const *ccp;
char **p;
/* NEC SVR4.0.2 mips cc rejects this. */
struct point {int x, y;};
static struct point const zero = {0,0};
/* AIX XL C 1.02.0.0 rejects this.
It does not let you subtract one const X* pointer from another in
an arm of an if-expression whose if-part is not a constant
expression */
const char *g = "string";
ccp = &g + (g ? g-g : 0);
/* HPUX 7.0 cc rejects these. */
++ccp;
p = (char**) ccp;
ccp = (char const *const *) p;
{ /* SCO 3.2v4 cc rejects this. */
char *t;
char const *s = 0 ? (char *) 0 : (char const *) 0;
*t++ = 0;
}
{ /* Someone thinks the Sun supposedly-ANSI compiler will reject this. */
int x[] = {25, 17};
const int *foo = &x[0];
++foo;
}
{ /* Sun SC1.0 ANSI compiler rejects this -- but not the above. */
typedef const int *iptr;
iptr p = 0;
++p;
}
{ /* AIX XL C 1.02.0.0 rejects this saying
"k.c", line 2.27: 1506-025 (S) Operand must be a modifiable lvalue. */
struct s { int j; const int *ap[3]; };
struct s *b; b->j = 5;
}
{ /* ULTRIX-32 V3.1 (Rev 9) vcc rejects this */
const int foo = 10;
}
#endif
]])],
[ac_cv_c_const=yes],
[ac_cv_c_const=no])])
if test $ac_cv_c_const = no; then
AC_DEFINE(const,,
[Define to empty if `const' does not conform to ANSI C.])
fi
])# AC_C_CONST
# AC_C_VOLATILE
# -------------
# Note that, unlike const, #defining volatile to be the empty string can
# actually turn a correct program into an incorrect one, since removing
# uses of volatile actually grants the compiler permission to perform
# optimizations that could break the user's code. So, do not #define
# volatile away unless it is really necessary to allow the user's code
# to compile cleanly. Benign compiler failures should be tolerated.
AC_DEFUN([AC_C_VOLATILE],
[AC_REQUIRE([AC_PROG_CC_STDC])dnl
AC_CACHE_CHECK([for working volatile], ac_cv_c_volatile,
[AC_COMPILE_IFELSE([AC_LANG_PROGRAM([], [
volatile int x;
int * volatile y;])],
[ac_cv_c_volatile=yes],
[ac_cv_c_volatile=no])])
if test $ac_cv_c_volatile = no; then
AC_DEFINE(volatile,,
[Define to empty if the keyword `volatile' does not work.
Warning: valid code using `volatile' can become incorrect
without. Disable with care.])
fi
])# AC_C_VOLATILE
# AC_C_STRINGIZE
# --------------
# Checks if `#' can be used to glue strings together at the CPP level.
# Defines HAVE_STRINGIZE if positive.
AC_DEFUN([AC_C_STRINGIZE],
[AC_REQUIRE([AC_PROG_CPP])dnl
AC_MSG_CHECKING([for preprocessor stringizing operator])
AC_CACHE_VAL(ac_cv_c_stringize,
AC_EGREP_CPP([#teststring],[
#define x(y) #y
char *s = x(teststring);
], ac_cv_c_stringize=no, ac_cv_c_stringize=yes))
if test "${ac_cv_c_stringize}" = yes; then
AC_DEFINE(HAVE_STRINGIZE, 1,
[Define if cpp supports the ANSI # stringizing operator.])
fi
AC_MSG_RESULT([${ac_cv_c_stringize}])
])# AC_C_STRINGIZE
# AC_C_PROTOTYPES
# ---------------
# Check if the C compiler supports prototypes, included if it needs
# options.
AC_DEFUN([AC_C_PROTOTYPES],
[AC_REQUIRE([AC_PROG_CC_STDC])dnl
AC_REQUIRE([AC_PROG_CPP])dnl
AC_MSG_CHECKING([for function prototypes])
if test "$ac_cv_prog_cc_stdc" != no; then
AC_MSG_RESULT(yes)
AC_DEFINE(PROTOTYPES, 1,
[Define if the C compiler supports function prototypes.])
else
AC_MSG_RESULT(no)
fi
])# AC_C_PROTOTYPES
# ---------------------------------------- #
# 4d. Fortan 77 compiler characteristics. #
# ---------------------------------------- #
# _AC_PROG_F77_V_OUTPUT([FLAG = $ac_cv_prog_f77_v])
# -------------------------------------------------
# Link a trivial Fortran program, compiling with a verbose output FLAG
# (which default value, $ac_cv_prog_f77_v, is computed by
# _AC_PROG_F77_V), and return the output in $ac_f77_v_output. This
# output is processed in the way expected by AC_F77_LIBRARY_LDFLAGS,
# so that any link flags that are echoed by the compiler appear as
# space-separated items.
AC_DEFUN([_AC_PROG_F77_V_OUTPUT],
[AC_REQUIRE([AC_PROG_F77])dnl
AC_LANG_PUSH(Fortran 77)
AC_LANG_CONFTEST([AC_LANG_PROGRAM([])])
# Compile and link our simple test program by passing a flag
# (argument 1 to this macro) to the Fortran 77 compiler in
# order to get "verbose" output that we can then parse for the
# Fortran 77 linker flags.
ac_save_FFLAGS=$FFLAGS
FFLAGS="$FFLAGS m4_default([$1], [$ac_cv_prog_f77_v])"
(eval echo configure:__oline__: \"$ac_link\") >&AC_FD_LOG
ac_f77_v_output=`eval $ac_link AC_FD_LOG>&1 2>&1 | grep -v 'Driving:'`
echo "$ac_f77_v_output" >&AC_FD_LOG
FFLAGS=$ac_save_FFLAGS
rm -f conftest.*
AC_LANG_POP()dnl
# If we are using xlf then replace all the commas with spaces.
if echo $ac_f77_v_output | grep xlfentry >/dev/null 2>&1; then
ac_f77_v_output=`echo $ac_f77_v_output | sed 's/,/ /g'`
fi
# If we are using Cray Fortran then delete quotes.
# Use "\"" instead of '"' for font-lock-mode.
# FIXME: a more general fix for quoted arguments with spaces?
if echo $ac_f77_v_output | grep cft90 >/dev/null 2>&1; then
ac_f77_v_output=`echo $ac_f77_v_output | sed "s/\"//g"`
fi[]dnl
])# _AC_PROG_F77_V_OUTPUT
# _AC_PROG_F77_V
# ---------------
#
# Determine the flag that causes the Fortran 77 compiler to print
# information of library and object files (normally -v)
# Needed for AC_F77_LIBRARY_FLAGS
# Some compilers don't accept -v (Lahey: -verbose, xlf: -V)
AC_DEFUN([_AC_PROG_F77_V],
[AC_REQUIRE([AC_PROG_F77])dnl
AC_CACHE_CHECK([how to get verbose linking output from $F77],
[ac_cv_prog_f77_v],
[AC_LANG_PUSH(Fortran 77)
AC_COMPILE_IFELSE([AC_LANG_PROGRAM()],
[ac_cv_prog_f77_v=
# Try some options frequently used verbose output
for ac_verb in -v -verbose --verbose -V; do
_AC_PROG_F77_V_OUTPUT($ac_verb)
# look for -l* and *.a constructs in the output
for ac_arg in $ac_f77_v_output; do
case $ac_arg in
[[\\/]]*.a | ?:[[\\/]]*.a | -[[lLRu]]*)
ac_cv_prog_f77_v=$ac_verb
break 2 ;;
esac
done
done
if test -z "$ac_cv_prog_f77_v"; then
AC_MSG_WARN([cannot determine how to obtain linking information from $F77])
fi],
[AC_MSG_WARN([compilation failed])])
AC_LANG_POP()dnl
])]) # _AC_PROG_F77_V
# AC_F77_LIBRARY_LDFLAGS
# ----------------------
#
# Determine the linker flags (e.g. "-L" and "-l") for the Fortran 77
# intrinsic and run-time libraries that are required to successfully
# link a Fortran 77 program or shared library. The output variable
# FLIBS is set to these flags.
#
# This macro is intended to be used in those situations when it is
# necessary to mix, e.g. C++ and Fortran 77, source code into a single
# program or shared library.
#
# For example, if object files from a C++ and Fortran 77 compiler must
# be linked together, then the C++ compiler/linker must be used for
# linking (since special C++-ish things need to happen at link time
# like calling global constructors, instantiating templates, enabling
# exception support, etc.).
#
# However, the Fortran 77 intrinsic and run-time libraries must be
# linked in as well, but the C++ compiler/linker doesn't know how to
# add these Fortran 77 libraries. Hence, the macro
# "AC_F77_LIBRARY_LDFLAGS" was created to determine these Fortran 77
# libraries.
#
# This macro was packaged in its current form by Matthew D. Langston.
# However, nearly all of this macro came from the "OCTAVE_FLIBS" macro
# in "octave-2.0.13/aclocal.m4", and full credit should go to John
# W. Eaton for writing this extremely useful macro. Thank you John.
AC_DEFUN([AC_F77_LIBRARY_LDFLAGS],
[AC_REQUIRE([AC_PROG_F77])dnl
_AC_PROG_F77_V
AC_CACHE_CHECK([for Fortran 77 libraries], ac_cv_flibs,
[if test "x$FLIBS" != "x"; then
ac_cv_flibs="$FLIBS" # Let the user override the test.
else
_AC_PROG_F77_V_OUTPUT
ac_cv_flibs=
# Save positional arguments (if any)
ac_save_positional="$[@]"
set X $ac_f77_v_output
while test $[@%:@] != 1; do
shift
ac_arg=$[1]
case $ac_arg in
[[\\/]]*.a | ?:[[\\/]]*.a)
AC_LIST_MEMBER_OF($ac_arg, $ac_cv_flibs, ,
ac_cv_flibs="$ac_cv_flibs $ac_arg")
;;
-bI:*)
AC_LIST_MEMBER_OF($ac_arg, $ac_cv_flibs, ,
[AC_LINKER_OPTION([$ac_arg], ac_cv_flibs)])
;;
# Ignore these flags.
-lang* | -lcrt0.o | -lc | -lgcc | -LANG:=*)
;;
-lkernel32)
test x"$CYGWIN" != xyes && ac_cv_flibs="$ac_cv_flibs $ac_arg"
;;
-[[LRuY]])
# These flags, when seen by themselves, take an argument.
# We remove the space between option and argument and re-iterate
# unless we find an empty arg or a new option (starting with -)
case $[2] in
"" | -*);;
*)
ac_arg="$ac_arg$[2]"
shift; shift
set X $ac_arg "$[@]"
;;
esac
;;
-YP,*)
for ac_j in `echo $ac_arg | sed -e 's/-YP,/-L/;s/:/ -L/g'`; do
AC_LIST_MEMBER_OF($ac_j, $ac_cv_flibs, ,
[ac_arg="$ac_arg $ac_j"
ac_cv_flibs="$ac_cv_flibs $ac_j"])
done
;;
-[[lLR]]*)
AC_LIST_MEMBER_OF($ac_arg, $ac_cv_flibs, ,
ac_cv_flibs="$ac_cv_flibs $ac_arg")
;;
# Ignore everything else.
esac
done
# restore positional arguments
set X $ac_save_positional; shift
# We only consider "LD_RUN_PATH" on Solaris systems. If this is seen,
# then we insist that the "run path" must be an absolute path (i.e. it
# must begin with a "/").
case `(uname -sr) 2>/dev/null` in
"SunOS 5"*)
ac_ld_run_path=`echo $ac_f77_v_output |
sed -n 's,^.*LD_RUN_PATH *= *\(/[[^ ]]*\).*$,-R\1,p'`
test "x$ac_ld_run_path" != x &&
AC_LINKER_OPTION([$ac_ld_run_path], ac_cv_flibs)
;;
esac
fi # test "x$FLIBS" = "x"
])
FLIBS="$ac_cv_flibs"
AC_SUBST(FLIBS)
])# AC_F77_LIBRARY_LDFLAGS
# _AC_F77_NAME_MANGLING
# --------------------
# Test for the name mangling scheme used by the Fortran 77 compiler.
#
# Sets ac_cv_f77_mangling. The value contains three fields, separated by commas:
#
# lower case / upper case:
# case translation of the Fortan 77 symbols
# underscore / no underscore:
# whether the compiler appends "_" to symbol names
# extra underscore / no extra underscore:
# whether the compiler appends an extra "_" to symbol names already
# containing at least one underscore
#
AC_DEFUN([_AC_F77_NAME_MANGLING],
[AC_REQUIRE([AC_PROG_CC])dnl
AC_REQUIRE([AC_PROG_F77])dnl
AC_REQUIRE([AC_F77_LIBRARY_LDFLAGS])dnl
AC_CACHE_CHECK([for Fortran 77 name-mangling scheme],
ac_cv_f77_mangling,
[AC_LANG_PUSH(Fortran 77)
AC_COMPILE_IFELSE(
[ subroutine foobar()
return
end
subroutine foo_bar()
return
end],
[mv conftest.${ac_objext} cf77_test.${ac_objext}
AC_LANG_PUSH(C)
ac_save_LIBS=$LIBS
LIBS="cf77_test.${ac_objext} $FLIBS $LIBS"
ac_success=no
for ac_foobar in foobar FOOBAR; do
for ac_underscore in "" "_"; do
ac_func="$ac_foobar$ac_underscore"
AC_TRY_LINK_FUNC($ac_func,
[ac_success=yes; break 2])
done
done
if test "$ac_success" = "yes"; then
case $ac_foobar in
foobar)
ac_case=lower
ac_foo_bar=foo_bar
;;
FOOBAR)
ac_case=upper
ac_foo_bar=FOO_BAR
;;
esac
ac_success_extra=no
for ac_extra in "" "_"; do
ac_func="$ac_foo_bar$ac_underscore$ac_extra"
AC_TRY_LINK_FUNC($ac_func,
[ac_success_extra=yes; break])
done
if test "$ac_success_extra" = "yes"; then
ac_cv_f77_mangling="$ac_case case"
if test -z "$ac_underscore"; then
ac_cv_f77_mangling="$ac_cv_f77_mangling, no underscore"
else
ac_cv_f77_mangling="$ac_cv_f77_mangling, underscore"
fi
if test -z "$ac_extra"; then
ac_cv_f77_mangling="$ac_cv_f77_mangling, no extra underscore"
else
ac_cv_f77_mangling="$ac_cv_f77_mangling, extra underscore"
fi
else
ac_cv_f77_mangling="unknown"
fi
else
ac_cv_f77_mangling="unknown"
fi
LIBS=$ac_save_LIBS
AC_LANG_POP()dnl
rm -f cf77_test*])
AC_LANG_POP()dnl
])
])# _AC_F77_NAME_MANGLING
# The replacement is empty.
AU_DEFUN([AC_F77_NAME_MANGLING], [])
# AC_F77_WRAPPERS
# ---------------
# Defines C macros F77_FUNC(name,NAME) and F77_FUNC_(name,NAME) to
# properly mangle the names of C identifiers, and C identifiers with
# underscores, respectively, so that they match the name mangling
# scheme used by the Fortran 77 compiler.
AC_DEFUN([AC_F77_WRAPPERS],
[AC_REQUIRE([_AC_F77_NAME_MANGLING])dnl
AH_TEMPLATE([F77_FUNC],
[Define to a macro mangling the given C identifier (in lower and upper
case), which must not contain underscores, for linking with Fortran.])dnl
AH_TEMPLATE([F77_FUNC_],
[As F77_FUNC, but for C identifiers containing underscores.])dnl
case $ac_cv_f77_mangling in
"lower case, no underscore, no extra underscore")
AC_DEFINE([F77_FUNC(name,NAME)], [name])
AC_DEFINE([F77_FUNC_(name,NAME)], [name]) ;;
"lower case, no underscore, extra underscore")
AC_DEFINE([F77_FUNC(name,NAME)], [name])
AC_DEFINE([F77_FUNC_(name,NAME)], [name ## _]) ;;
"lower case, underscore, no extra underscore")
AC_DEFINE([F77_FUNC(name,NAME)], [name ## _])
AC_DEFINE([F77_FUNC_(name,NAME)], [name ## _]) ;;
"lower case, underscore, extra underscore")
AC_DEFINE([F77_FUNC(name,NAME)], [name ## _])
AC_DEFINE([F77_FUNC_(name,NAME)], [name ## __]) ;;
"upper case, no underscore, no extra underscore")
AC_DEFINE([F77_FUNC(name,NAME)], [NAME])
AC_DEFINE([F77_FUNC_(name,NAME)], [NAME]) ;;
"upper case, no underscore, extra underscore")
AC_DEFINE([F77_FUNC(name,NAME)], [NAME])
AC_DEFINE([F77_FUNC_(name,NAME)], [NAME ## _]) ;;
"upper case, underscore, no extra underscore")
AC_DEFINE([F77_FUNC(name,NAME)], [NAME ## _])
AC_DEFINE([F77_FUNC_(name,NAME)], [NAME ## _]) ;;
"upper case, underscore, extra underscore")
AC_DEFINE([F77_FUNC(name,NAME)], [NAME ## _])
AC_DEFINE([F77_FUNC_(name,NAME)], [NAME ## __]) ;;
*)
AC_MSG_WARN(unknown Fortran 77 name-mangling scheme)
;;
esac
])# AC_F77_WRAPPERS
# AC_F77_FUNC(NAME, [SHELLVAR = NAME])
# ------------------------------------
# For a Fortran subroutine of given NAME, define a shell variable
# $SHELLVAR to the Fortran-77 mangled name. If the SHELLVAR
# argument is not supplied, it defaults to NAME.
AC_DEFUN([AC_F77_FUNC],
[AC_REQUIRE([_AC_F77_NAME_MANGLING])dnl
case $ac_cv_f77_mangling in
upper*) ac_val="translit([$1],[a-z],[A-Z])" ;;
lower*) ac_val="translit([$1],[A-Z],[a-z])" ;;
*) ac_val="unknown" ;;
esac
case $ac_cv_f77_mangling in *," underscore"*) ac_val="$ac_val"_ ;; esac
ifelse(index([$1],[_]),-1,[],
[case $ac_cv_f77_mangling in *," extra underscore"*) ac_val="$ac_val"_ ;; esac
])
m4_default([$2],[$1])="$ac_val"
]) # AC_F77_FUNC