elk/configure.ac

484 lines
15 KiB
Plaintext

# $Id$
AC_INIT(src/main.c)
AC_PREREQ(2.50)
AC_CONFIG_AUX_DIR(autotools)
AC_CANONICAL_SYSTEM
AM_INIT_AUTOMAKE(elk, 3.99.1)
AM_CONFIG_HEADER(config.h)
AC_PROG_CC
AM_PROG_CC_C_O
AC_PROG_CXX
AC_PROG_LIBTOOL
AC_STDC_HEADERS
AC_C_CONST
AC_C_INLINE
AC_TYPE_SIZE_T
AC_CHECK_HEADERS(stdint.h inttypes.h sys/_inttypes.h)
if test "${ac_cv_header_stdint_h}" = "yes"; then
STDINT_HEADER="stdint.h"
elif test "${ac_cv_header_inttypes_h}" = "yes"; then
STDINT_HEADER="inttypes.h"
elif test "${ac_cv_header_sys__inttypes_h}" = "yes"; then
STDINT_HEADER="sys/_inttypes.h"
else
AC_MSG_ERROR([cannot find C99 integer headers])
fi
AC_SUBST(STDINT_HEADER)
# $system should contain the name of this file. It may be used by some
# of the build scripts to do things that are specific to one single
# type of system.
AC_DEFINE(SYSTEMTYPE, "${target_os}", Our operating system)
# Does the system support the vprintf library function? If not,
# availability of the (non-portable) _doprnt function is assumed.
AC_CHECK_FUNCS(vprintf)
# Does the directory(3) library follow the POSIX conventions (i.e.
# requires the <dirent.h> include file and uses "struct dirent")?
# If not, the (obsolete) BSD-style interface with <sys/dir.h> and
# "struct direct" is assumed.
AC_CHECK_FUNCS(dirent)
# Does the system have the random/srandom library functions? If not,
# rand/srand will be used instead.
AC_CHECK_FUNCS(random)
# Does the system have the index library function? If not, strchr
# will be used.
dnl FIXME
# Does the system have the bcopy, bzero, and bcmp library functions?
# If not, memcpy/memset/memcmp will be used.
dnl FIXME
# Does using the access system call require <unistd.h> to be included?
# (Look into the manual page for access if in doubt.)
AC_CHECK_HEADERS(unistd.h)
# If the FIONREAD ioctl command is defined, which file must be included?
AC_MSG_CHECKING(for FIONREAD in termios.h)
AC_EGREP_HEADER(FIONREAD, termios.h, [
AC_MSG_RESULT(yes) AC_DEFINE(FIONREAD_IN_TERMIOS_H, 1, Define if <termios.h> defines FIONREAD)
],[
AC_MSG_RESULT(no)
AC_MSG_CHECKING(for FIONREAD in sys/ioctl.h)
AC_EGREP_HEADER(FIONREAD, sys/ioctl.h, [
AC_MSG_RESULT(yes) AC_DEFINE(FIONREAD_IN_SYS_IOCTL_H, 1, Define if <sys/ioctl.h> defines FIONREAD)
],[
AC_MSG_RESULT(no)
AC_MSG_CHECKING(for FIONREAD in sys/filio.h)
AC_EGREP_HEADER(FIONREAD, sys/filio.h, [
AC_MSG_RESULT(yes) AC_DEFINE(FIONREAD_IN_SYS_FILIO_H, 1, Define if <sys/filio.h> defines FIONREAD)
],[
AC_MSG_RESULT(no)
])
])
])
# If getdtablesize() is available to determine the maximum number of open
# files per process, set getdtablesize=yes.
# Alternatively, if POSIX-style sysconf() can be called with _SC_OPEN_MAX,
# set sysconf_open_max=yes.
# If neither is set to "yes", an educated guess will be made.
AC_CHECK_FUNCS(getdtablesize)
AC_MSG_CHECKING(for _SC_OPEN_MAX in unistd.h)
AC_EGREP_HEADER(_SC_OPEN_MAX, unistd.h, [
AC_MSG_RESULT(yes) AC_DEFINE(SC_OPEN_MAX_IN_UNISTD_H, 1, Define if <unistd.h> defines _SC_OPEN_MAX)
],[
AC_MSG_RESULT(no)
])
# If POSIX-style pathconf() can be invoked with _PC_PATH_MAX to determine
# the maximum pathname length, set pathconf_path_max=yes.
AC_MSG_CHECKING(for _PC_PATH_MAX in unistd.h)
AC_EGREP_HEADER(_PC_PATH_MAX, unistd.h, [
AC_MSG_RESULT(yes) AC_DEFINE(PC_PATH_MAX_IN_UNISTD_H, 1, Define if <unistd.h> defines _PC_PATH_MAX)
],[
AC_MSG_RESULT(no)
])
# If the system page size can be determined by calling getpagesize()
# set getpagesize=yes.
# Alternatively, if sysconf() can be invoked with _SC_PAGESIZE, set
# sysconf_pagesize=yes.
# These two variables are only required if the generational garbage
# collector is used.
AC_CHECK_FUNCS(getpagesize)
AC_MSG_CHECKING(for _SC_PAGESIZE in unistd.h)
AC_EGREP_HEADER(_SC_PAGESIZE, unistd.h, [
AC_MSG_RESULT(yes) AC_DEFINE(SC_PAGESIZE_IN_UNISTD_H, 1, Define if <unistd.h> defines _SC_PAGESIZE)
],[
AC_MSG_RESULT(no)
])
# Set reliable_signals=bsd if your system supports BSD-style reliable
# signals (has sigblock and related functions); set reliable_signals=posix
# for POSIX-style signals (sigprocmask, sigsets); otherwise old V7/SysV
# signal semantics are assumed.
if false; then
AC_DEFINE(BSD_SIGNALS, 1, [FIXME HARD])
fi
AC_DEFINE(POSIX_SIGNALS, 1, [FIXME HARD])
# To support dynamic loading of object files and "dump", the system's
# a.out format has to be known. Choose one of the following:
#
# coff ecoff xcoff elf macho hp9k convex
#
# Other values of "aout_format" are interpreted as BSD-style a.out format.
if false; then
AC_DEFINE(COFF, 1, [FIXME HARD])
fi
if false; then
AC_DEFINE(ECOFF, 1, [FIXME HARD])
fi
if false; then
AC_DEFINE(XCOFF, 1, [FIXME HARD])
fi
AC_CHECK_LIB(elf, elf_begin, ac_cv_my_have_elf=yes, ac_cv_my_have_elf=no)
AM_CONDITIONAL(HAVE_LIBELF, test "${ac_cv_my_have_elf}" = "yes")
if false; then
AC_DEFINE(MACH_O, 1, [FIXME HARD])
fi
if false; then
AC_DEFINE(CONVEX_AOUT, 1, [FIXME HARD])
fi
if false; then
AC_DEFINE(HP9K, 1, [FIXME HARD])
fi
if test "${ac_cv_my_have_elf}" = "yes"; then
AC_DEFINE(HAVE_LIBELF, 1, Define if you have libelf.)
ELK_LIBS="${ELK_LIBS} -lelf"
ac_cv_my_can_dump=yes
else
ac_cv_my_can_dump=no
dnl AC_MSG_ERROR([could not handle the native object format, if you are running Linux please install the libelf development headers])
fi
# Which mechanism should be used to dynamically load object files?
ac_cv_my_can_load_lib=no
AC_CHECK_HEADERS(dlfcn.h, ac_cv_my_can_load_lib=yes)
AC_CHECK_HEADERS(a.out.h, ac_cv_my_can_load_lib=yes)
if test "${ac_cv_my_can_load_lib}" = "yes"; then
AC_DEFINE(CAN_LOAD_LIB, 1, [FIXME HARD])
fi
# Systems with "aout_format=ecoff" may require a call to the cacheflush
# system call after an object file has been loaded. Which include file
# has to be included in this case?
AC_DEFINE(CACHECTL_H, <sys/cachectl.h>, [FIXME HARD])
# Is the ANSI-C atexit function supported to register an exit handler?
# If not, the exit library function will be redefined and will end in
# a call to _exit.
AC_CHECK_FUNCS(atexit)
# Do the names of external functions in the symbol table always begin
# with a special character (such as underline)? If so, syms_begin_with
# should hold this character, otherwise leave it empty.
if false; then
AC_DEFINE(SYMS_BEGIN_WITH, ['_'], [FIXME HARD])
fi
# The symbol prefixes of extension initialization and finalization
# functions (without the initial $syms_begin_with). Do not change
# these unless the compiler or linker restricts the length of symbols!
AC_DEFINE(INIT_PREFIX, "elk_init_", [FIXME HARD])
AC_DEFINE(FINIT_PREFIX, "elk_finit_", [FIXME HARD])
# Is the "dump" function supported?
if test "${ac_cv_my_can_dump}" = "yes"; then
AC_DEFINE(CAN_DUMP, 1, [FIXME HARD])
fi
# Is the fchmod system call broken or unavailable?
if false; then
AC_DEFINE(FCHMOD_BROKEN, 1, [FIXME HARD])
fi
# These four variables are only relevant if the system has the BSD-style
# a.out format.
# segment_size is the segment size of the system's memory management
# unit, i.e. the number to a multiple of which the size of an a.out
# segment (e.g. .text) is rounded up.
# file_text_start is the file offset at which the text segment starts
# in an a.out file.
# mem_text_start is the starting address of the text segment in memory.
# text_length_adj must be set to "sizeof (struct exec)" if the length of
# the text segment stored in the a.out header includes the a.out header
# itself.
AC_DEFINE(SEG_SIZ, 1024, [FIXME HARD])
AC_DEFINE(FILE_TEXT_START, N_TXTOFF(hdr), [FIXME HARD])
AC_DEFINE(MEM_TEXT_START, 0, [FIXME HARD])
AC_DEFINE(TEXT_LENGTH_ADJ, 0, [FIXME HARD])
# Only relevant if "aout_format=coff": the system's pagesize.
AC_DEFINE(COFF_PAGESIZE, 4096, [FIXME HARD])
# Only relevant if "aout_format=hp9k" and "load_obj=shl"
AC_DEFINE(HPSHLIB, 1, [FIXME HARD])
# Print debug messages when dumping
AC_DEFINE(DEBUG_DUMP, 1, [FIXME HARD])
# Is the "termio" terminal interface supported by the system? If not,
# BSD-style tty handling will be used.
AC_DEFINE(TERMIO, 1, [FIXME HARD])
# flush_stdio and flush_tty indicate how clear-input/output-port can
# flush (purge) a FILE pointer and a TTY file descriptor.
# Possible values of flush_stdio:
# bsd assume old BSD-style FILE* (with _cnt, _ptr, _base)
# fpurge use 4.4BSD-style fpurge stdio library function
# Possible values of flush_tty:
# tiocflush use TIOCFLUSH ioctl from <sys/ioctl.h>
# tcflsh use TCFLSH ioctl from <termio.h>
# Leave the variable(s) empty if flushing is not supported.
if false; then
AC_DEFINE(FLUSH_BSD, 1, [FIXME HARD])
fi
if false; then
AC_DEFINE(FLUSH_FPURGE, 1, [FIXME HARD])
fi
if false; then
AC_DEFINE(FLUSH_TIOCFLUSH, 1, [FIXME HARD])
fi
AC_DEFINE(FLUSH_TCFLSH, 1, [FIXME HARD])
# The interpreter uses the getrlimit function to determine the maximum
# stack size of the running program. If this function is not supported,
# set max_stack_size to a (fixed) maximum stack size (in bytes).
if false; then
AC_DEFINE(MAX_STACK_SIZE, 1, [FIXME HARD])
fi
# Is the mprotect system call supported? The generational garbage collector
# requires mprotect to implement incremental GC. $mprotect is ignored if
# generational_gc is set to "no" in the site file. Set mprotect=mmap if
# mprotect is supported, but only for mmap()ed memory.
AC_CHECK_FUNCS(mprotect)
if false; then
AC_DEFINE(MPROTECT_SIG, 1, [FIXME HARD])
fi
if false; then
AC_DEFINE(MPROTECT_MMAP, 1, [FIXME HARD])
fi
# How can a SIGSEGV or SIGBUS signal handler find out the address of
# the faulting memory reference? This variable is only used if
# $mprotect is "yes" or "mmap". Possible values are:
#
# siginfo handler is called with siginfo_t structure (enabled
# by a call to sigaction)
# sigcontext address is in the sigcontext structure (3rd arg, sc_badvaddr)
# arg4 address is delivered to handler as argument #4
# aix use an AIX-specific hack to get hold of the bad address
# hpux use a HP-UX-specific hack
if false; then
AC_DEFINE(SIGSEGV_SIGINFO, 1, [FIXME HARD])
fi
if false; then
AC_DEFINE(SIGSEGV_SIGCONTEXT, 1, [FIXME HARD])
fi
if false; then
AC_DEFINE(SIGSEGV_ARG4, 1, [FIXME HARD])
fi
if false; then
AC_DEFINE(SIGSEGV_AIX, 1, [FIXME HARD])
fi
if false; then
AC_DEFINE(SIGSEGV_HPUX, 1, [FIXME HARD])
fi
# Does the system support the alloca library function, and does this
# function actually extend the stack? If in doubt, extract alloca.o
# from the C library and check if it contains the symbols malloc and free.
# If this is the case, forget it.
AC_DEFINE(USE_ALLOCA, 1, [FIXME HARD])
# Must <alloca.h> be included to use alloca? Is "#pragma alloca" required?
AC_CHECK_HEADERS(alloca.h)
if false; then
AC_DEFINE(PRAGMA_ALLOCA, 1, [FIXME HARD])
fi
# Does the system (or compiler) require certain objects (e.g. doubles)
# to be aligned at 8-byte boundaries? If not, 4-byte alignment will
# be assumed.
if false; then
AC_DEFINE(ALIGN_8BYTE, 1, [FIXME HARD])
fi
# The name of the linker. This is usually just "ld", or /usr/ccs/bin/ld
# in SVR4-based systems.
AC_DEFINE(LD_NAME, "ld", [FIXME HARD])
# Does your C preprocessor support the ANSI-C ## operator, although
# __STDC__ is not defined?
AC_DEFINE(ANSI_CPP, 1, [FIXME HARD])
# The UNIX extension likes to know which of the following system calls,
# library functions, and include files are supported by the system.
AC_CHECK_HEADERS(utime.h)
AC_CHECK_FUNCS(waitpid wait3 wait4 vfork uname gethostname gettimeofday ftime)
AC_CHECK_FUNCS(mktemp tmpnam tempnam getcwd getwd rename regcomp)
# Element type of the gidset argument of getgroups(); typically int
# or gid_t. Only needed by the UNIX extension.
AC_DEFINE(GETGROUPS_TYPE, gid_t, [FIXME HARD])
# Do you want to use the generational garbage collector? If not, the
# stop-and-copy garbage collector will be used.
AC_DEFINE(GENERATIONAL_GC, 1, [FIXME HARD])
# The default heap size of the Scheme interpreter in KBytes (if the
# stop-and-copy garbage collector is used).
AC_DEFINE(HEAP_SIZE, 1024, [FIXME HARD])
# The directory where all files are installed by running "make install".
# The subdirectories bin, lib, include, and runtime (with various
# subdirectories) are created automatically, but $install_dir isn't.
# Make sure $install_dir doesn't point to the top of the source tree
# (i.e. choose a subdirectory or a directory outside the source tree).
AC_DEFINE(SCM_DIR, "/usr/share/elk", [FIXME HARD])
AC_DEFINE(OBJ_DIR, "/usr/lib/elk", [FIXME HARD])
#define FIND_AOUT defined(USE_LD) || defined(CAN_DUMP) || defined(INIT_OBJECTS)
AC_DEFINE(FIND_AOUT, 1, [FIXME HARD])
dnl
dnl Check for available compiler features
dnl
CFLAGS_save="${CFLAGS}"
LDFLAGS_save="${LDFLAGS}"
if test -n "${CXX}"; then
ac_cv_my_have_cxx=yes
else
ac_cv_my_have_cxx=no
fi
AM_CONDITIONAL(HAVE_CXX, test "${ac_cv_my_have_cxx}" = "yes")
AC_CACHE_CHECK([if \$CC accepts -Wall],
[ac_cv_c_Wall],
[CFLAGS="-Wall ${CFLAGS_save}"
AC_TRY_COMPILE([],,ac_cv_c_Wall=yes, ac_cv_c_Wall=no)])
if test "x${ac_cv_c_Wall}" != "xno"; then
CFLAGS_save="-Wall ${CFLAGS_save}"
fi
AC_CACHE_CHECK([if \$CC accepts -Wsign-compare],
[ac_cv_c_Wsign_compare],
[CFLAGS="-Wsign-compare ${CFLAGS_save}"
AC_TRY_COMPILE([],,ac_cv_c_Wsign_compare=yes, ac_cv_c_Wsign_compare=no)])
if test "x${ac_cv_c_Wsign_compare}" != "xno"; then
CFLAGS_save="-Wsign-compare ${CFLAGS_save}"
fi
dnl
dnl Check for available headers and libraries
dnl
CFLAGS="${CFLAGS_save}"
LDFLAGS="${LDFLAGS_save}"
AC_CHECK_LIB(gdbm, gdbm_open, ac_cv_my_have_gdbm=yes, ac_cv_my_have_gdbm=no)
AM_CONDITIONAL(HAVE_GDBM, test "${ac_cv_my_have_gdbm}" = "yes")
AC_PATH_X
AC_CHECK_LIB(X11, XOpenDisplay, [
ac_cv_my_have_x11=yes
X_CFLAGS="-I${x_includes}"
X_LIBS="-lX11 -L${x_libraries}"
], [ac_cv_my_have_x11=no],
[[-lXt -L${x_libraries}]])
AM_CONDITIONAL(HAVE_X11, test "${ac_cv_my_have_x11}" = "yes")
AC_SUBST(X_CFLAGS)
AC_SUBST(X_LIBS)
AC_CHECK_LIB(Xaw, XawTextSearch, [
ac_cv_my_have_xaw=yes
XAW_CFLAGS="-I${x_includes}"
XAW_LIBS="-L${x_libraries} -lXaw -lXmu -lXt -lSM -lICE -lXext -lX11"
], [ac_cv_my_have_xaw=no],
[[-lXmu -lXt -lSM -lICE -lXext -lX11 -L${x_libraries}]])
AM_CONDITIONAL(HAVE_XAW, test "${ac_cv_my_have_xaw}" = "yes")
AC_SUBST(XAW_CFLAGS)
AC_SUBST(XAW_LIBS)
AC_CHECK_LIB(Xm, XmStringConcat, [
ac_cv_my_have_motif=yes
MOTIF_CFLAGS="-I${x_includes} -I/usr/include/Xm"
MOTIF_LIBS="-L${x_libraries} -lXm -lXmu -lXt -lSM -lICE -lXext -lX11"
], [ac_cv_my_have_motif=no],
[[-lXmu -lXt -lSM -lICE -lXext -lX11 -L${x_libraries}]])
AM_CONDITIONAL(HAVE_MOTIF, test "${ac_cv_my_have_motif}" = "yes")
AC_SUBST(MOTIF_CFLAGS)
AC_SUBST(MOTIF_LIBS)
dnl Export variables
INCLUDES="${INCLUDES} -I\$(top_srcdir)/include"
ELK_LIBS="${ELK_LIBS} -lm -ldl"
AC_SUBST(INCLUDES)
AC_SUBST(ELK_LIBS)
AC_OUTPUT([
Makefile
autotools/Makefile
debian/Makefile
doc/Makefile
doc/bitstring/Makefile
doc/cprog/Makefile
doc/kernel/Makefile
doc/man/Makefile
doc/oops/Makefile
doc/record/Makefile
doc/regexp/Makefile
doc/unix/Makefile
doc/usenix/Makefile
doc/util/Makefile
doc/xlib/Makefile
doc/xt/Makefile
examples/Makefile
include/Makefile
lib/Makefile
lib/misc/Makefile
lib/unix/Makefile
lib/xlib/Makefile
lib/xwidgets/Makefile
lib/xwidgets/xaw/Makefile
lib/xwidgets/motif/Makefile
scm/Makefile
src/Makefile
scm/slib.scm
include/site.h
])
cat << EOF
Elk configuration summary
-------------------------
build C++ plugins: ${ac_cv_my_have_cxx}
libgdbm support: ${ac_cv_my_have_gdbm}
X11 support: ${ac_cv_my_have_x11}
Xaw support: ${ac_cv_my_have_xaw}
Motif support: ${ac_cv_my_have_motif}
EOF