# This file is part of Autoconf. -*- Autoconf -*- # Programming languages support. # Copyright 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. m4_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. m4_define([_AC_LANG_DISPATCH], [m4_ifdef([$1($2)], [m4_indir([$1($2)], m4_shiftn(2, $@))], [AC_FATAL([$1: unknown language: $2])])]) # _AC_LANG_SET(OLD, NEW) # ---------------------- # Output the shell code needed to switch from OLD language to NEW language. # Do not try to optimize like this: # # m4_defun([_AC_LANG_SET], # [m4_if([$1], [$2], [], # [_AC_LANG_DISPATCH([AC_LANG], [$2])])]) # # as it can introduce differences between the sh-current language and the # m4-current-language when m4_require is used. Something more subtle # might be possible, but at least for the time being, play it safe. m4_defun([_AC_LANG_SET], [_AC_LANG_DISPATCH([AC_LANG], [$2])]) # AC_LANG(LANG) # ------------- # Set the current language to LANG. m4_defun([AC_LANG], [_AC_LANG_SET(m4_ifdef([_AC_LANG], [m4_defn([_AC_LANG])]), [$1])dnl m4_define([_AC_LANG], [$1])]) # AC_LANG_PUSH(LANG) # ------------------ # Save the current language, and use LANG. m4_defun([AC_LANG_PUSH], [_AC_LANG_SET(m4_ifdef([_AC_LANG], [m4_defn([_AC_LANG])]), [$1])dnl m4_pushdef([_AC_LANG], [$1])]) # AC_LANG_POP([LANG]) # ------------------- # If given, check that the current language is LANG, and restore the # previous language. m4_defun([AC_LANG_POP], [m4_ifval([$1], [m4_if([$1], m4_defn([_AC_LANG]), [], [m4_fatal([$0($1): unexpected current language: ]m4_defn([_AC_LANG]))])])dnl m4_pushdef([$0 OLD], m4_defn([_AC_LANG]))dnl m4_popdef([_AC_LANG])dnl _AC_LANG_SET(m4_defn([$0 OLD]), m4_defn([_AC_LANG]))dnl m4_popdef([$0 OLD])dnl ]) # AC_LANG_SAVE # ------------ # Save the current language, but don't change language. AU_DEFUN([AC_LANG_SAVE], [AC_DIAGNOSE([obsolete], [instead of using `AC_LANG', `AC_LANG_SAVE', and `AC_LANG_RESTORE', you should use `AC_LANG_PUSH' and `AC_LANG_POP'.]) m4_pushdef([_AC_LANG], _AC_LANG)]) # AC_LANG_RESTORE # --------------- # Restore the current language from the stack. AU_DEFUN([AC_LANG_RESTORE], [AC_LANG_POP($@)]) # _AC_LANG_ABBREV # --------------- # Return a short signature of _AC_LANG which can be used in shell # variable names, or in M4 macro names. m4_defun([_AC_LANG_ABBREV], [_AC_LANG_DISPATCH([$0], _AC_LANG, $@)]) # AC_LANG_ASSERT(LANG) # -------------------- # Current language must be LANG. m4_defun([AC_LANG_ASSERT], [m4_if(_AC_LANG, $1, [], [m4_fatal([$0: current language is not $1: ] _AC_LANG)])]) # -------------------- # # 1b. The C language. # # -------------------- # # AC_LANG(C) # ---------- # CFLAGS is not in ac_cpp because -g, -O, etc. are not valid cpp options. m4_define([AC_LANG(C)], [ac_ext=c ac_cpp='$CPP $CPPFLAGS' ac_compile='$CC -c $CFLAGS $CPPFLAGS conftest.$ac_ext >&AS_MESSAGE_LOG_FD' ac_link='$CC -o conftest$ac_exeext $CFLAGS $CPPFLAGS $LDFLAGS conftest.$ac_ext $LIBS >&AS_MESSAGE_LOG_FD' ac_compiler_gnu=$ac_cv_c_compiler_gnu ]) # AC_LANG_C # --------- AU_DEFUN([AC_LANG_C], [AC_LANG(C)]) # _AC_LANG_ABBREV(C) # ------------------ m4_define([_AC_LANG_ABBREV(C)], [c]) # ---------------------- # # 1c. The C++ language. # # ---------------------- # # AC_LANG(C++) # ------------ # CXXFLAGS is not in ac_cpp because -g, -O, etc. are not valid cpp options. m4_define([AC_LANG(C++)], [ac_ext=cc ac_cpp='$CXXCPP $CPPFLAGS' ac_compile='$CXX -c $CXXFLAGS $CPPFLAGS conftest.$ac_ext >&AS_MESSAGE_LOG_FD' ac_link='$CXX -o conftest$ac_exeext $CXXFLAGS $CPPFLAGS $LDFLAGS conftest.$ac_ext $LIBS >&AS_MESSAGE_LOG_FD' ac_compiler_gnu=$ac_cv_cxx_compiler_gnu ]) # AC_LANG_CPLUSPLUS # ----------------- AU_DEFUN([AC_LANG_CPLUSPLUS], [AC_LANG(C++)]) # _AC_LANG_ABBREV(C++) # -------------------- m4_define([_AC_LANG_ABBREV(C++)], [cxx]) # ----------------------------- # # 1d. The Fortran 77 language. # # ----------------------------- # # AC_LANG(Fortran 77) # ------------------- m4_define([AC_LANG(Fortran 77)], [ac_ext=f ac_compile='$F77 -c $FFLAGS conftest.$ac_ext >&AS_MESSAGE_LOG_FD' ac_link='$F77 -o conftest$ac_exeext $FFLAGS $LDFLAGS conftest.$ac_ext $LIBS >&AS_MESSAGE_LOG_FD' ac_compiler_gnu=$ac_cv_f77_compiler_gnu ]) # AC_LANG_FORTRAN77 # ----------------- AU_DEFUN([AC_LANG_FORTRAN77], [AC_LANG(Fortran 77)]) # _AC_LANG_ABBREV(Fortran 77) # --------------------------- m4_define([_AC_LANG_ABBREV(Fortran 77)], [f77]) ## ---------------------- ## ## 2.Producing programs. ## ## ---------------------- ## # ---------------------- # # 2a. Generic routines. # # ---------------------- # # AC_LANG_CONFTEST(BODY) # ---------------------- # Save the BODY in `conftest.$ac_ext'. Add a trailing new line. m4_define([AC_LANG_CONFTEST], [cat >conftest.$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 `conftest.val'. 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]" m4_define([AC_LANG_SOURCE(C)], [#line __oline__ "configure" #include "confdefs.h" $1]) # AC_LANG_PROGRAM(C)([PROLOGUE], [BODY]) # -------------------------------------- m4_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. m4_define([AC_LANG_CALL(C)], [AC_LANG_PROGRAM([$1 m4_if([$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 because on OSF/1 3.0 it includes # which includes which contains a # prototype for select. Similarly for bzero. m4_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 /* 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) # ------------------------------------------------- m4_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'. m4_define([AC_LANG_INT_SAVE(C)], [AC_LANG_PROGRAM([m4_default([$1], [@%:@include ])], [FILE *f = fopen ("conftest.val", "w"); if (!f) exit (1); fprintf (f, "%d", ($2)); fclose (f);])]) # ----------------- # # 2c. C++ sources. # # ----------------- # # AC_LANG_SOURCE(C++)(BODY) # ------------------------- m4_copy([AC_LANG_SOURCE(C)], [AC_LANG_SOURCE(C++)]) # AC_LANG_PROGRAM(C++)([PROLOGUE], [BODY]) # ---------------------------------------- m4_copy([AC_LANG_PROGRAM(C)], [AC_LANG_PROGRAM(C++)]) # AC_LANG_CALL(C++)(PROLOGUE, FUNCTION) # ------------------------------------- m4_copy([AC_LANG_CALL(C)], [AC_LANG_CALL(C++)]) # AC_LANG_FUNC_LINK_TRY(C++)(FUNCTION) # ------------------------------------ m4_copy([AC_LANG_FUNC_LINK_TRY(C)], [AC_LANG_FUNC_LINK_TRY(C++)]) # AC_LANG_BOOL_COMPILE_TRY(C++)(PROLOGUE, EXPRESSION) # --------------------------------------------------- m4_copy([AC_LANG_BOOL_COMPILE_TRY(C)], [AC_LANG_BOOL_COMPILE_TRY(C++)]) # AC_LANG_INT_SAVE(C++)(PROLOGUE, EXPRESSION) # ------------------------------------------- m4_copy([AC_LANG_INT_SAVE(C)], [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? m4_define([AC_LANG_SOURCE(Fortran 77)], [$1]) # AC_LANG_PROGRAM(Fortran 77)([PROLOGUE], [BODY]) # ----------------------------------------------- # Yes, we discard the PROLOGUE. m4_define([AC_LANG_PROGRAM(Fortran 77)], [m4_ifval([$1], [m4_warn([syntax], [$0: ignoring PROLOGUE: $1])])dnl program main $2 end]) # AC_LANG_CALL(Fortran 77)(PROLOGUE, FUNCTION) # -------------------------------------------- # FIXME: This is a guess, help! m4_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_LANG_COMPILER # ---------------- # Find a compiler for the current LANG. Be sure to be run before # AC_LANG_PREPROC. # # Note that because we might AC_REQUIRE `AC_LANG_COMPILER(C)' for # instance, the latter must be AC_DEFUN'd, not just define'd. m4_define([AC_LANG_COMPILER], [AC_BEFORE([AC_LANG_COMPILER(]_AC_LANG[)], [AC_LANG_PREPROC(]_AC_LANG[)])dnl _AC_LANG_DISPATCH([$0], _AC_LANG, $@)]) # AC_LANG_COMPILER_REQUIRE # ------------------------ # Ensure we have a compiler for the current LANG. AC_DEFUN([AC_LANG_COMPILER_REQUIRE], [m4_require([AC_LANG_COMPILER(]_AC_LANG[)], [AC_LANG_COMPILER])]) # _AC_LANG_COMPILER_GNU # --------------------- # Check whether the compiler for the current language is GNU. # # It doesn't seem necessary right now to have a different source # according to the current language, since this works fine. Some day # it might be needed. Nevertheless, pay attention to the fact that # the position of `choke me' on the seventh column is meant: otherwise # some Fortran compilers (e.g., SGI) might consider it's a # continuation line, and warn instead of reporting an error. m4_define([_AC_LANG_COMPILER_GNU], [AC_CACHE_CHECK([whether we are using the GNU _AC_LANG compiler], [ac_cv_[]_AC_LANG_ABBREV[]_compiler_gnu], [_AC_COMPILE_IFELSE([AC_LANG_PROGRAM([], [[#ifndef __GNUC__ choke me #endif ]])], [ac_compiler_gnu=yes], [ac_compiler_gnu=no]) ac_cv_[]_AC_LANG_ABBREV[]_compiler_gnu=$ac_compiler_gnu ])])# _AC_LANG_COMPILER_GNU # AC_LANG_PREPROC # --------------- # Find a preprocessor for the current language. Note that because we # might AC_REQUIRE `AC_LANG_PREPROC(C)' for instance, the latter must # be AC_DEFUN'd, not just define'd. Since the preprocessor depends # upon the compiler, look for the compiler. m4_define([AC_LANG_PREPROC], [AC_LANG_COMPILER_REQUIRE()dnl _AC_LANG_DISPATCH([$0], _AC_LANG, $@)]) # AC_LANG_PREPROC_REQUIRE # ----------------------- # Ensure we have a preprocessor for the current language. AC_DEFUN([AC_LANG_PREPROC_REQUIRE], [m4_require([AC_LANG_PREPROC(]_AC_LANG[)], [AC_LANG_PREPROC])]) # AC_REQUIRE_CPP # -------------- # Require the preprocessor for the current language. # FIXME: AU_ALIAS once AC_LANG is officially documented (2.51?). AC_DEFUN([AC_REQUIRE_CPP], [AC_LANG_PREPROC_REQUIRE]) # AC_NO_EXECUTABLES # ----------------- # FIXME: The GCC team has specific needs which the current Autoconf # framework cannot solve elegantly. This macro implements a dirty # hack until Autoconf is abble to provide the services its users # needs. # # Several of the support libraries that are often built with GCC can't # assume the tool-chain is already capable of linking a program: the # compiler often expects to be able to link with some of such # libraries. # # In several of these libraries, work-arounds have been introduced to # avoid the AC_PROG_CC_WORKS test, that would just abort their # configuration. The introduction of AC_EXEEXT, enabled either by # libtool or by CVS autoconf, have just made matters worse. AC_DEFUN_ONCE([AC_NO_EXECUTABLES], [m4_divert_push([KILL]) AC_BEFORE([$0], [_AC_LANG_COMPILER_WORKS]) AC_BEFORE([$0], [_AC_COMPILER_EXEEXT]) m4_define([_AC_LANG_COMPILER_WORKS], [cross_compiling=maybe]) m4_define([_AC_COMPILER_EXEEXT], [EXEEXT=]) m4_define([AC_LINK_IFELSE], [AC_FATAL([All the tests involving linking were disabled by $0])]) m4_divert_pop()dnl ])# AC_NO_EXECUTABLES # ----------------------------- # # Computing EXEEXT and OBJEXT. # # ----------------------------- # # Files to ignore # --------------- # Ignore .d files produced by CFLAGS=-MD. # # On UWIN (which uses a cc wrapper for MSVC), the compiler also generates # a .pdb file # # When the w32 free Borland C++ command line compiler links a program # (conftest.exe), it also produces a file named `conftest.tds' in # addition to `conftest.obj' # We must not AU define them, because autoupdate would then remove # them, which is right, but Automake 1.4 would remove the support for # $(EXEEXT) etc. # FIXME: Remove this once Automake fixed. AC_DEFUN([AC_EXEEXT], []) AC_DEFUN([AC_OBJEXT], []) # _AC_COMPILER_EXEEXT_DEFAULT # --------------------------- # Check for the extension used for the default name for executables. # Beware of `expr' that may return `0' or `'. Since this macro is # the first one in touch with the compiler, it should also check that # it compiles properly. m4_define([_AC_COMPILER_EXEEXT_DEFAULT], [# Try to create an executable without -o first, disregard a.out. # It will help us diagnose broken compiler, and finding out an intuition # of exeext. AC_MSG_CHECKING([for _AC_LANG compiler default output]) ac_link_default=`echo "$ac_link" | sed ['s/ -o *conftest[^ ]*//']` AS_IF([AC_TRY_EVAL(ac_link_default)], [for ac_file in `ls a.exe conftest.exe a.* conftest conftest.* 2>/dev/null`; do case $ac_file in *.$ac_ext | *.o | *.obj | *.xcoff | *.tds | *.d | *.pdb ) ;; a.out ) # We found the default executable, but exeext='' is most # certainly right. break;; *.* ) ac_cv_exeext=`expr "$ac_file" : ['[^.]*\(\..*\)']` export ac_cv_exeext break;; * ) break;; esac done], [echo "$as_me: failed program was:" >&AS_MESSAGE_LOG_FD cat conftest.$ac_ext >&AS_MESSAGE_LOG_FD AC_MSG_ERROR([_AC_LANG compiler cannot create executables], 77)]) ac_exeext=$ac_cv_exeext AC_MSG_RESULT([$ac_file]) ])# _AC_COMPILER_EXEEXT_DEFAULT # _AC_COMPILER_EXEEXT_WORKS # ------------------------- m4_define([_AC_COMPILER_EXEEXT_WORKS], [# Check the compiler produces executables we can run. If not, either # the compiler is broken, or we cross compile. AC_MSG_CHECKING([whether the _AC_LANG compiler works]) # 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 "$cross_compiling" != yes; then if AC_TRY_COMMAND([./$ac_file]); then cross_compiling=no else if test "$cross_compiling" = maybe; then cross_compiling=yes else AC_MSG_ERROR([cannot run _AC_LANG compiled programs. If you meant to cross compile, use `--host'.]) fi fi fi AC_MSG_RESULT([yes]) ])# _AC_COMPILER_EXEEXT_WORKS # _AC_COMPILER_EXEEXT_CROSS # ------------------------- m4_define([_AC_COMPILER_EXEEXT_CROSS], [# Check the compiler produces executables we can run. If not, either # the compiler is broken, or we cross compile. AC_MSG_CHECKING([whether we are cross compiling]) AC_MSG_RESULT([$cross_compiling]) ])# _AC_COMPILER_EXEEXT_CROSS # _AC_COMPILER_EXEEXT_O # --------------------- # Check for the extension used when `-o foo'. Try to see if ac_cv_exeext, # as computed by _AC_COMPILER_EXEEXT_DEFAULT is OK. m4_define([_AC_COMPILER_EXEEXT_O], [AC_MSG_CHECKING([for executable suffix]) AS_IF([AC_TRY_EVAL(ac_link)], [# If both `conftest.exe' and `conftest' are `present' (well, observable) # catch `conftest.exe'. For instance with Cygwin, `ls conftest' will # work properly (i.e., refer to `conftest.exe'), while it won't with # `rm'. for ac_file in `(ls conftest.exe; ls conftest; ls conftest.*) 2>/dev/null`; do case $ac_file in *.$ac_ext | *.o | *.obj | *.xcoff | *.tds | *.d | *.pdb ) ;; *.* ) ac_cv_exeext=`expr "$ac_file" : ['[^.]*\(\..*\)']` export ac_cv_exeext break;; * ) break;; esac done], [AC_MSG_ERROR([cannot compute EXEEXT: cannot compile and link])]) rm -f conftest$ac_cv_exeext AC_MSG_RESULT([$ac_cv_exeext]) ])# _AC_COMPILER_EXEEXT_O # _AC_COMPILER_EXEEXT # ------------------- # Check for the extension used for executables. It compiles a test # executable. If this is called, the executable extensions will be # automatically used by link commands run by the configure script. # # Note that some compilers (cross or not), strictly obey to `-o foo' while # the host requires `foo.exe', so we should not depend upon `-o' to # test EXEEXT. But then, be sure no to destroy user files. # # Must be run before _AC_COMPILER_OBJEXT because _AC_COMPILER_EXEEXT_DEFAULT # checks whether the compiler works. m4_define([_AC_COMPILER_EXEEXT], [AC_LANG_CONFTEST([AC_LANG_PROGRAM()]) ac_clean_files_save=$ac_clean_files ac_clean_files="$ac_clean_files a.out a.exe" _AC_COMPILER_EXEEXT_DEFAULT _AC_COMPILER_EXEEXT_WORKS rm -f a.out a.exe conftest$ac_cv_exeext ac_clean_files=$ac_clean_files_save _AC_COMPILER_EXEEXT_CROSS _AC_COMPILER_EXEEXT_O rm -f conftest.$ac_ext AC_SUBST([EXEEXT], [$ac_cv_exeext])dnl ac_exeext=$EXEEXT ])# _AC_COMPILER_EXEEXT # _AC_COMPILER_OBJEXT # ------------------- # Check the object extension used by the compiler: typically `.o' or # `.obj'. If this is called, some other behaviour will change, # determined by ac_objext. # # This macro is called by AC_LANG_COMPILER, the latter being required # by the AC_COMPILE_IFELSE macros, so use _AC_COMPILE_IFELSE. And in fact, # don't, since _AC_COMPILE_IFELSE needs to know ac_objext for the `test -s' # it includes. 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AC_DEFUN([AC_LANG_PREPROC(C)], [AC_REQUIRE([AC_PROG_CPP])]) # _AC_PROG_PREPROC_WORKS # ---------------------- # Check if $ac_cpp is a working preprocessor that can flag absent # includes either by the exit status or by warnings # Set ac_cpp_err to a non-empty value if the preprocessor failed # This macro is for all languages, not only C AC_DEFUN([_AC_PROG_PREPROC_WORKS], [# Use a header file that comes with gcc, so configuring glibc # with a fresh cross-compiler works. # On the NeXT, cc -E runs the code through the compiler's parser, # not just through cpp. "Syntax error" is here to catch this case. ac_[]_AC_LANG_ABBREV[]_preproc_warn_flag=maybe _AC_PREPROC_IFELSE([AC_LANG_SOURCE([[@%:@include Syntax error]])], [# Now check whether non-existent headers can be detected and how # Skip if ac_cpp_err is not empty - ac_cpp is broken if test -z "$ac_cpp_err"; then _AC_PREPROC_IFELSE([AC_LANG_SOURCE([[@%:@include ]])], [# cannot detect missing includes at all ac_cpp_err=yes], [if test "x$ac_cpp_err" = xmaybe; then ac_[]_AC_LANG_ABBREV[]_preproc_warn_flag=yes else ac_[]_AC_LANG_ABBREV[]_preproc_warn_flag= fi ac_cpp_err=]) fi])])# _AC_PROG_PREPROC_WORKS # AC_PROG_CPP # ----------- # Find a working C preprocessor. # We shouldn't have to require AC_PROG_CC, but this is due to the concurrency # between the AC_LANG_COMPILER_REQUIRE family and that of AC_PROG_CC. 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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 static $ac_kw int static_foo () {return 0; } $ac_kw int foo () {return 0; } #endif ])], [ac_cv_c_inline=$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_CACHE_CHECK([for preprocessor stringizing operator], [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 $ac_cv_c_stringize = yes; then AC_DEFINE(HAVE_STRINGIZE, 1, [Define if cpp supports the ANSI @%:@ stringizing operator.]) fi ])# AC_C_STRINGIZE # AC_C_PROTOTYPES # --------------- # Check if the C compiler supports prototypes, included if it needs # options. AC_DEFUN([AC_C_PROTOTYPES], [AC_REQUIRE([AC_PROG_CC_STDC])dnl AC_MSG_CHECKING([for function prototypes]) if test "$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 $ac_f77_v_output. This # output is processed in the way expected by AC_F77_LIBRARY_LDFLAGS, # so that any link flags that are echoed by the compiler appear as # space-separated items. AC_DEFUN([_AC_PROG_F77_V_OUTPUT], [AC_REQUIRE([AC_PROG_F77])dnl AC_LANG_PUSH(Fortran 77)dnl AC_LANG_CONFTEST([AC_LANG_PROGRAM([])]) # Compile and link our simple test program by passing a flag (argument # 1 to this macro) to the Fortran 77 compiler in order to get # "verbose" output that we can then parse for the Fortran 77 linker # flags. ac_save_FFLAGS=$FFLAGS FFLAGS="$FFLAGS m4_default([$1], [$ac_cv_prog_f77_v])" (eval echo $as_me:__oline__: \"$ac_link\") >&AS_MESSAGE_LOG_FD ac_f77_v_output=`eval $ac_link AS_MESSAGE_LOG_FD>&1 2>&1 | grep -v 'Driving:'` echo "$ac_f77_v_output" >&AS_MESSAGE_LOG_FD FFLAGS=$ac_save_FFLAGS rm -f conftest.* AC_LANG_POP(Fortran 77)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_CACHE_CHECK([how to get verbose linking output from $F77], [ac_cv_prog_f77_v], [AC_LANG_ASSERT(Fortran 77) AC_COMPILE_IFELSE([AC_LANG_PROGRAM()], [ac_cv_prog_f77_v= # Try some options frequently used verbose output for ac_verb in -v -verbose --verbose -V; do _AC_PROG_F77_V_OUTPUT($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 $F77]) fi], [AC_MSG_WARN([compilation failed])]) ])])# _AC_PROG_F77_V # AC_F77_LIBRARY_LDFLAGS # ---------------------- # # Determine the linker flags (e.g. "-L" and "-l") for the Fortran 77 # intrinsic and run-time libraries that are required to successfully # link a Fortran 77 program or shared library. The output variable # FLIBS is set to these flags. # # This macro is intended to be used in those situations when it is # necessary to mix, e.g. C++ and Fortran 77, source code into a single # program or shared library. # # For example, if object files from a C++ and Fortran 77 compiler must # be linked together, then the C++ compiler/linker must be used for # linking (since special C++-ish things need to happen at link time # like calling global constructors, instantiating templates, enabling # exception support, etc.). # # However, the Fortran 77 intrinsic and run-time libraries must be # linked in as well, but the C++ compiler/linker doesn't know how to # add these Fortran 77 libraries. Hence, the macro # "AC_F77_LIBRARY_LDFLAGS" was created to determine these Fortran 77 # libraries. # # This macro was packaged in its current form by Matthew D. Langston. # However, nearly all of this macro came from the "OCTAVE_FLIBS" macro # in "octave-2.0.13/aclocal.m4", and full credit should go to John # W. Eaton for writing this extremely useful macro. Thank you John. AC_DEFUN([AC_F77_LIBRARY_LDFLAGS], [AC_LANG_PUSH(Fortran 77)dnl _AC_PROG_F77_V AC_CACHE_CHECK([for Fortran 77 libraries], ac_cv_flibs, [if test "x$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="$ac_cv_flibs" AC_SUBST(FLIBS) AC_LANG_POP(Fortran 77)dnl ])# AC_F77_LIBRARY_LDFLAGS # _AC_F77_NAME_MANGLING # --------------------- # Test for the name mangling scheme used by the Fortran 77 compiler. # # Sets ac_cv_f77_mangling. The value contains three fields, separated # by commas: # # lower case / upper case: # case translation of the Fortan 77 symbols # underscore / no underscore: # whether the compiler appends "_" to symbol names # extra underscore / no extra underscore: # whether the compiler appends an extra "_" to symbol names already # containing at least one underscore # AC_DEFUN([_AC_F77_NAME_MANGLING], [AC_REQUIRE([AC_F77_LIBRARY_LDFLAGS])dnl AC_CACHE_CHECK([for Fortran 77 name-mangling scheme], ac_cv_f77_mangling, [AC_LANG_PUSH(Fortran 77)dnl AC_COMPILE_IFELSE( [ subroutine foobar() return end subroutine foo_bar() return end], [mv conftest.$ac_objext cf77_test.$ac_objext AC_LANG_PUSH(C)dnl ac_save_LIBS=$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(C)dnl rm -f cf77_test* conftest*]) AC_LANG_POP(Fortran 77)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="m4_toupper([$1])" ;; lower*) ac_val="m4_tolower([$1])" ;; *) ac_val="unknown" ;; esac case $ac_cv_f77_mangling in *," underscore"*) ac_val="$ac_val"_ ;; esac m4_if(m4_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