dnl Process this file with autoconf to produce a configure script. define(GMP_COPYRIGHT,[[ Copyright 1996, 1997, 1998, 1999, 2000, 2001, 2002, 2003, 2004, 2005, 2006 Free Software Foundation, Inc. Copyright 2008 William Hart. This file is part of the MPIR Library. The MPIR Library is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. The MPIR Library 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 Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with the MPIR Library; see the file COPYING.LIB. If not, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. ]]) AC_COPYRIGHT(GMP_COPYRIGHT) AH_TOP(/*GMP_COPYRIGHT*/) AC_REVISION($Revision: 1.11 $) AC_PREREQ(2.59) AC_INIT(MPIR, MPIR_VERSION, http://groups.google.co.uk/group/mpir-devel/, mpir) AC_CONFIG_SRCDIR(gmp-impl.h) m4_pattern_forbid([^[ \t]*GMP_]) m4_pattern_allow(GMP_LDFLAGS) m4_pattern_allow(GMP_LIMB_BITS) m4_pattern_allow(GMP_MPARAM_H_SUGGEST) m4_pattern_allow(GMP_NAIL_BITS) m4_pattern_allow(GMP_NUMB_BITS) # If --target is not used then $target_alias is empty, but if say # "./configure athlon-pc-freebsd3.5" is used, then all three of # $build_alias, $host_alias and $target_alias are set to # "athlon-pc-freebsd3.5". # if test -n "$target_alias" && test "$target_alias" != "$host_alias"; then AC_MSG_ERROR([--target is not appropriate for GMP Use --build=CPU-VENDOR-OS if you need to specify your CPU and/or system explicitly. Use --host if cross-compiling (see "Installing GMP" in the manual for more on this).]) fi GMP_INIT(config.m4) AC_CANONICAL_HOST dnl Automake "no-dependencies" is used because include file dependencies dnl are not useful to us. Pretty much everything depends just on mpir.h, dnl gmp-impl.h and longlong.h, and yet only rarely does everything need to dnl be rebuilt for changes to those files. dnl dnl "no-dependencies" also helps with the way we're setup to run dnl AC_PROG_CXX only conditionally. If dependencies are used then recent dnl automake (eg 1.7.2) appends an AM_CONDITIONAL to AC_PROG_CXX, and then dnl gets upset if it's not actually executed. dnl dnl Note that there's a copy of these options in the top-level Makefile.am, dnl so update there too if changing anything. dnl AM_INIT_AUTOMAKE([1.8 gnu no-dependencies $(top_builddir)/ansi2knr]) AM_CONFIG_HEADER(config.h:config.in) AM_MAINTAINER_MODE AC_ARG_ENABLE(assert, AC_HELP_STRING([--enable-assert],[enable ASSERT checking [[default=no]]]), [case $enableval in yes|no) ;; *) AC_MSG_ERROR([bad value $enableval for --enable-assert, need yes or no]) ;; esac], [enable_assert=no]) if test "$enable_assert" = "yes"; then AC_DEFINE(WANT_ASSERT,1, [Define to 1 to enable ASSERT checking, per --enable-assert]) want_assert_01=1 else want_assert_01=0 fi GMP_DEFINE_RAW(["define(,$want_assert_01)"]) AC_ARG_ENABLE(alloca, AC_HELP_STRING([--enable-alloca],[how to get temp memory [[default=reentrant]]]), [case $enableval in alloca|malloc-reentrant|malloc-notreentrant) ;; yes|no|reentrant|notreentrant) ;; debug) ;; *) AC_MSG_ERROR([bad value $enableval for --enable-alloca, need one of: yes no reentrant notreentrant alloca malloc-reentrant malloc-notreentrant debug]) ;; esac], [enable_alloca=reentrant]) # IMPROVE ME: The default for C++ is disabled. The tests currently # performed below for a working C++ compiler are not particularly strong, # and in general can't be expected to get the right setup on their own. The # most significant problem is getting the ABI the same. Defaulting CXXFLAGS # to CFLAGS takes only a small step towards this. It's also probably worth # worrying whether the C and C++ runtimes from say gcc and a vendor C++ can # work together. Some rather broken C++ installations were encountered # during testing, and though such things clearly aren't GMP's problem, if # --enable-cxx=detect were to be the default then some careful checks of # which, if any, C++ compiler on the system is up to scratch would be # wanted. # AC_ARG_ENABLE(cxx, AC_HELP_STRING([--enable-cxx],[enable C++ support [[default=no]]]), [case $enableval in yes|no|detect) ;; *) AC_MSG_ERROR([bad value $enableval for --enable-cxx, need yes/no/detect]) ;; esac], [enable_cxx=no]) AC_ARG_ENABLE(fft, AC_HELP_STRING([--enable-fft],[enable FFTs for multiplication [[default=yes]]]), [case $enableval in yes|no) ;; *) AC_MSG_ERROR([bad value $enableval for --enable-fft, need yes or no]) ;; esac], [enable_fft=yes]) if test "$enable_fft" = "yes"; then AC_DEFINE(WANT_FFT,1, [Define to 1 to enable FFTs for multiplication, per --enable-fft]) fi AC_ARG_ENABLE(mpbsd, AC_HELP_STRING([--enable-mpbsd], [build Berkeley MP compatibility library [[default=no]]]), [case $enableval in yes|no) ;; *) AC_MSG_ERROR([bad value $enableval for --enable-mpbsd, need yes or no]) ;; esac], [enable_mpbsd=no]) AM_CONDITIONAL(WANT_MPBSD, test "$enable_mpbsd" = "yes") AC_ARG_ENABLE(gmplink, AC_HELP_STRING([--enable-gmplink], [create symbolic links named gmp that point to mpir [[default=no]]]), [case $enableval in yes|no) ;; *) AC_MSG_ERROR([bad value $enableval for --enable-gmplink, need yes or no]) ;; esac], [enable_gmplink=no]) AM_CONDITIONAL(WANT_GMPLINK, test "$enable_gmplink" = "yes") AC_ARG_ENABLE(nails, AC_HELP_STRING([--enable-nails],[use nails on limbs [[default=no]]]), [case $enableval in [no|[0]]) ;; *) AC_MSG_ERROR([bad value $enableval for --enable-nails, Sorry nails not available in this build]) ;; esac], [enable_nails=no]) case $enable_nails in yes) GMP_NAIL_BITS=2 ;; no) GMP_NAIL_BITS=0 ;; *) GMP_NAIL_BITS=$enable_nails ;; esac AC_SUBST(GMP_NAIL_BITS) AC_ARG_ENABLE(profiling, AC_HELP_STRING([--enable-profiling], [build with profiler support [[default=no]]]), [case $enableval in no|prof|gprof|instrument) ;; *) AC_MSG_ERROR([bad value $enableval for --enable-profiling, need no/prof/gprof/instrument]) ;; esac], [enable_profiling=no]) case $enable_profiling in prof) AC_DEFINE(WANT_PROFILING_PROF, 1, [Define to 1 if --enable-profiling=prof]) ;; gprof) AC_DEFINE(WANT_PROFILING_GPROF, 1, [Define to 1 if --enable-profiling=gprof]) ;; instrument) AC_DEFINE(WANT_PROFILING_INSTRUMENT, 1, [Define to 1 if --enable-profiling=instrument]) ;; esac GMP_DEFINE_RAW(["define(,<\`$enable_profiling'>)"]) # -fomit-frame-pointer is incompatible with -pg on some chips if test "$enable_profiling" = gprof; then fomit_frame_pointer= else fomit_frame_pointer="-fomit-frame-pointer" fi AC_ARG_WITH(readline, AC_HELP_STRING([--with-readline], [readline support in calc demo program [[default=detect]]]), [case $withval in yes|no|detect) ;; *) AC_MSG_ERROR([bad value $withval for --with-readline, need yes/no/detect]) ;; esac], [with_readline=detect]) AC_ARG_ENABLE(fat, AC_HELP_STRING([--enable-fat], [build a fat binary on systems that support it [[default=no]]]), [case $enableval in yes|no) ;; *) AC_MSG_ERROR([bad value $enableval for --enable-fat, need yes or no]) ;; esac], [enable_fat=no]) tmp_host=`echo $host_cpu | sed 's/\./_/'` AC_DEFINE_UNQUOTED(HAVE_HOST_CPU_$tmp_host) GMP_DEFINE_RAW("define_not_for_expansion(\`HAVE_HOST_CPU_$tmp_host')", POST) dnl The HAVE_HOST_CPU_ list here only needs to have entries for those which dnl are going to be tested, not everything that can possibly be selected. dnl dnl The HAVE_HOST_CPU_FAMILY_ list similarly, and note that the AC_DEFINEs dnl for these are under the cpu specific setups below. AH_VERBATIM([HAVE_HOST_CPU_1], [/* Define one of these to 1 for the host CPU family. If your CPU is not in any of these families, leave all undefined. */ #undef HAVE_HOST_CPU_FAMILY_alpha #undef HAVE_HOST_CPU_FAMILY_m68k #undef HAVE_HOST_CPU_FAMILY_power #undef HAVE_HOST_CPU_FAMILY_powerpc #undef HAVE_HOST_CPU_FAMILY_x86 #undef HAVE_HOST_CPU_FAMILY_x86_64 /* Define one of the following to 1 for the host CPU, as per the output of ./config.guess. If your CPU is not listed here, leave all undefined. */ #undef HAVE_HOST_CPU_alphaev67 #undef HAVE_HOST_CPU_alphaev68 #undef HAVE_HOST_CPU_alphaev7 #undef HAVE_HOST_CPU_m68020 #undef HAVE_HOST_CPU_m68030 #undef HAVE_HOST_CPU_m68040 #undef HAVE_HOST_CPU_m68060 #undef HAVE_HOST_CPU_m68360 #undef HAVE_HOST_CPU_powerpc604 #undef HAVE_HOST_CPU_powerpc604e #undef HAVE_HOST_CPU_powerpc750 #undef HAVE_HOST_CPU_powerpc7400 #undef HAVE_HOST_CPU_supersparc #undef HAVE_HOST_CPU_i386 #undef HAVE_HOST_CPU_i586 #undef HAVE_HOST_CPU_i686 #undef HAVE_HOST_CPU_pentium #undef HAVE_HOST_CPU_pentiummmx #undef HAVE_HOST_CPU_pentiumpro #undef HAVE_HOST_CPU_pentium2 #undef HAVE_HOST_CPU_pentium3]) # Table of compilers, options, and mpn paths. This code has various related # purposes # # - better default CC/CFLAGS selections than autoconf otherwise gives # - default CC/CFLAGS selections for extra CPU types specific to GMP # - a few tests for known bad compilers # - choice of ABIs on suitable systems # - selection of corresponding mpn search path # # After GMP specific searches and tests, the standard autoconf AC_PROG_CC is # called. User selections of CC etc are respected. # # Care is taken not to use macros like AC_TRY_COMPILE during the GMP # pre-testing, since they of course depend on AC_PROG_CC, and also some of # them cache their results, which is not wanted. # # The ABI selection mechanism is unique to GMP. All that reaches autoconf # is a different selection of CC/CFLAGS according to the best ABI the system # supports, and/or what the user selects. Naturally the mpn assembler code # selected is very dependent on the ABI. # # The closest the standard tools come to a notion of ABI is something like # "sparc64" which encodes a CPU and an ABI together. This doesn't seem to # scale well for GMP, where exact CPU types like "ultrasparc2" are wanted, # separate from the ABI used on them. # # # The variables set here are # # cclist the compiler choices # xx_cflags flags for compiler xx # xx_cflags_maybe flags for compiler xx, if they work # xx_cppflags cpp flags for compiler xx # xx_cflags_optlist list of sets of optional flags # xx_cflags_yyy set yyy of optional flags for compiler xx # xx_ldflags -Wc,-foo flags for libtool linking with compiler xx # ar_flags extra flags for $AR # nm_flags extra flags for $NM # limb limb size, can be "longlong" # path mpn search path # extra_functions extra mpn functions # fat_path fat binary mpn search path [if fat binary desired] # fat_functions fat functions # fat_thresholds fat thresholds # # Suppose xx_cflags_optlist="arch", then flags from $xx_cflags_arch are # tried, and the first flag that works will be used. An optlist like "arch # cpu optimize" can be used to get multiple independent sets of flags tried. # The first that works from each will be used. If no flag in a set works # then nothing from that set is added. # # For multiple ABIs, the scheme extends as follows. # # abilist set of ABI choices # cclist_aa compiler choices in ABI aa # xx_aa_cflags flags for xx in ABI aa # xx_aa_cflags_maybe flags for xx in ABI aa, if they work # xx_aa_cppflags cpp flags for xx in ABI aa # xx_aa_cflags_optlist list of sets of optional flags in ABI aa # xx_aa_cflags_yyy set yyy of optional flags for compiler xx in ABI aa # xx_aa_ldflags -Wc,-foo flags for libtool linking # ar_aa_flags extra flags for $AR in ABI aa # nm_aa_flags extra flags for $NM in ABI aa # limb_aa limb size in ABI aa, can be "longlong" # path_aa mpn search path in ABI aa # extra_functions_aa extra mpn functions in ABI aa # # As a convenience, the unadorned xx_cflags (etc) are used for the last ABI # in ablist, if an xx_aa_cflags for that ABI isn't given. For example if # abilist="64 32" then $cc_64_cflags will be used for the 64-bit ABI, but # for the 32-bit either $cc_32_cflags or $cc_cflags is used, whichever is # defined. This makes it easy to add some 64-bit compilers and flags to an # unadorned 32-bit set. # # limb=longlong (or limb_aa=longlong) applies to all compilers within that # ABI. It won't work to have some needing long long and some not, since a # single instantiated mpir.h will be used by both. # # SPEED_CYCLECOUNTER, cyclecounter_size and CALLING_CONVENTIONS_OBJS are # also set here, with an ABI suffix. # # # # A table-driven approach like this to mapping cpu type to good compiler # options is a bit of a maintenance burden, but there's not much uniformity # between options specifications on different compilers. Some sort of # separately updatable tool might be cute. # # The use of lots of variables like this, direct and indirect, tends to # obscure when and how various things are done, but unfortunately it's # pretty much the only way. If shell subroutines were portable then actual # code like "if this .. do that" could be written, but attempting the same # with full copies of GMP_PROG_CC_WORKS etc expanded at every point would # hugely bloat the output. AC_ARG_VAR(ABI, [desired ABI (for processors supporting more than one ABI)]) # abilist needs to be non-empty, "standard" is just a generic name here abilist="standard" # FIXME: We'd like to prefer an ANSI compiler, perhaps by preferring # c89 over cc here. But note that on HP-UX c89 provides a castrated # environment, and would want to be excluded somehow. Maybe # AC_PROG_CC_STDC already does enough to stick cc into ANSI mode and # we don't need to worry. # cclist="gcc cc" gcc_cflags="-O3" gcc_64_cflags="-O3" cc_cflags="-O" cc_64_cflags="-O" SPEED_CYCLECOUNTER_OBJ= cyclecounter_size=2 AC_SUBST(HAVE_HOST_CPU_FAMILY_power, 0) AC_SUBST(HAVE_HOST_CPU_FAMILY_powerpc,0) case $host in a29k*-*-*) path="a29k" ;; alpha*-*-*) AC_DEFINE(HAVE_HOST_CPU_FAMILY_alpha) case $host_cpu in alphaev5* | alphapca5*) path="alpha/ev5 alpha" ;; alphaev67 | alphaev68 | alphaev7*) path="alpha/ev67 alpha/ev6 alpha/ev5 alpha" ;; alphaev6* | alphaev7*) path="alpha/ev6 alpha/ev5 alpha" ;; *) path="alpha" ;; esac extra_functions="cntlz" gcc_cflags_optlist="asm cpu oldas" # need asm ahead of cpu, see below gcc_cflags_oldas="-Wa,-oldas" # see GMP_GCC_WA_OLDAS. # gcc 2.7.2.3 doesn't know any -mcpu= for alpha, apparently. # gcc 2.95 knows -mcpu= ev4, ev5, ev56, pca56, ev6. # gcc 3.0 adds nothing. # gcc 3.1 adds ev45, ev67 (but ev45 is the same as ev4). # gcc 3.2 adds nothing. # # gcc version "2.9-gnupro-99r1" under "-O2 -mcpu=ev6" strikes internal # compiler errors too easily and is rejected by GMP_PROG_CC_WORKS. Each # -mcpu=ev6 below has a fallback to -mcpu=ev56 for this reason. # case $host_cpu in alpha) gcc_cflags_cpu="-mcpu=ev4" ;; alphaev5) gcc_cflags_cpu="-mcpu=ev5" ;; alphaev56) gcc_cflags_cpu="-mcpu=ev56" ;; alphapca56 | alphapca57) gcc_cflags_cpu="-mcpu=pca56" ;; alphaev6) gcc_cflags_cpu="-mcpu=ev6 -mcpu=ev56" ;; alphaev67 | alphaev68 | alphaev7*) gcc_cflags_cpu="-mcpu=ev67 -mcpu=ev6 -mcpu=ev56" ;; esac # gcc version "2.9-gnupro-99r1" on alphaev68-dec-osf5.1 has been seen # accepting -mcpu=ev6, but not putting the assembler in the right mode # for what it produces. We need to do this for it, and need to do it # before testing the -mcpu options. # # On old versions of gcc, which don't know -mcpu=, we believe an # explicit -Wa,-mev5 etc will be necessary to put the assembler in # the right mode for our .asm files and longlong.h asm blocks. # # On newer versions of gcc, when -mcpu= is known, we must give a -Wa # which is at least as high as the code gcc will generate. gcc # establishes what it needs with a ".arch" directive, our command line # option seems to override that. # # gas prior to 2.14 doesn't accept -mev67, but -mev6 seems enough for # ctlz and cttz (in 2.10.0 at least). # # OSF `as' accepts ev68 but stupidly treats it as ev4. -arch only seems # to affect insns like ldbu which are expanded as macros when necessary. # Insns like ctlz which were never available as macros are always # accepted and always generate their plain code. # case $host_cpu in alpha) gcc_cflags_asm="-Wa,-arch,ev4 -Wa,-mev4" ;; alphaev5) gcc_cflags_asm="-Wa,-arch,ev5 -Wa,-mev5" ;; alphaev56) gcc_cflags_asm="-Wa,-arch,ev56 -Wa,-mev56" ;; alphapca56 | alphapca57) gcc_cflags_asm="-Wa,-arch,pca56 -Wa,-mpca56" ;; alphaev6) gcc_cflags_asm="-Wa,-arch,ev6 -Wa,-mev6" ;; alphaev67 | alphaev68 | alphaev7*) gcc_cflags_asm="-Wa,-arch,ev67 -Wa,-mev67 -Wa,-arch,ev6 -Wa,-mev6" ;; esac # It might be better to ask "cc" whether it's Cray C or DEC C, # instead of relying on the OS part of $host. But it's hard to # imagine either of those compilers anywhere except their native # systems. # GMP_INCLUDE_MPN(alpha/alpha-defs.m4) case $host in *-cray-unicos*) cc_cflags="-O" # no -g, it silently disables all optimizations GMP_INCLUDE_MPN(alpha/unicos.m4) # Don't perform any assembly syntax tests on this beast. gmp_asm_syntax_testing=no ;; *-*-osf*) GMP_INCLUDE_MPN(alpha/default.m4) cc_cflags="" cc_cflags_optlist="opt cpu" # not sure if -fast works on old versions, so make it optional cc_cflags_opt="-fast -O2" # DEC C V5.9-005 knows ev4, ev5, ev56, pca56, ev6. # Compaq C V6.3-029 adds ev67. # case $host_cpu in alpha) cc_cflags_cpu="-arch~ev4~-tune~ev4" ;; alphaev5) cc_cflags_cpu="-arch~ev5~-tune~ev5" ;; alphaev56) cc_cflags_cpu="-arch~ev56~-tune~ev56" ;; alphapca56 | alphapca57) cc_cflags_cpu="-arch~pca56~-tune~pca56" ;; alphaev6) cc_cflags_cpu="-arch~ev6~-tune~ev6" ;; alphaev67 | alphaev68 | alphaev7*) cc_cflags_cpu="-arch~ev67~-tune~ev67 -arch~ev6~-tune~ev6" ;; esac ;; *) GMP_INCLUDE_MPN(alpha/default.m4) ;; esac case $host in *-*-unicos*) # tune/alpha.asm assumes int==4bytes but unicos uses int==8bytes ;; *) SPEED_CYCLECOUNTER_OBJ=alpha.lo cyclecounter_size=1 ;; esac ;; # Cray vector machines. # This must come after alpha* so that we can recognize present and future # vector processors with a wildcard. *-cray-unicos*) gmp_asm_syntax_testing=no cclist="cc" # We used to have -hscalar0 here as a workaround for miscompilation of # mpz/import.c, but let's hope Cray fixes their bugs instead, since # -hscalar0 causes disastrously poor code to be generated. cc_cflags="-O3 -hnofastmd -htask0 -Wa,-B" path="cray" ;; arm*-*-*) path="arm" gcc_cflags="$gcc_cflags $fomit_frame_pointer" gcc_testlist="gcc-arm-umodsi" GMP_INCLUDE_MPN(arm/arm-defs.m4) ;; clipper*-*-*) path="clipper" ;; # Fujitsu [f30[01]-fujitsu-sysv*]) cclist="gcc vcc" # FIXME: flags for vcc? vcc_cflags="-g" path="fujitsu" ;; hppa*-*-*) # HP cc (the one sold separately) is K&R by default, but AM_C_PROTOTYPES # will add "-Ae", or "-Aa -D_HPUX_SOURCE", to put it into ansi mode, if # possible. # # gcc for hppa 2.0 can be built either for 2.0n (32-bit) or 2.0w # (64-bit), but not both, so there's no option to choose the desired # mode, we must instead detect which of the two it is. This is done by # checking sizeof(long), either 4 or 8 bytes respectively. Do this in # ABI=1.0 too, in case someone tries to build that with a 2.0w gcc. # gcc_cflags="-O2" gcc_cflags_optlist="arch" gcc_testlist="sizeof-long-4" SPEED_CYCLECOUNTER_OBJ=hppa.lo cyclecounter_size=1 # FIXME: For hppa2.0*, path should be "pa32/hppa2_0 pa32/hppa1_1 pa32". # (Can't remember why this isn't done already, have to check what .asm # files are available in each and how they run on a typical 2.0 cpu.) # case $host_cpu in hppa1.0*) path="pa32" ;; hppa7000*) path="pa32/hppa1_1 pa32" ;; hppa2.0* | hppa64) path="pa32/hppa2_0 pa32/hppa1_1/pa7100 pa32/hppa1_1 pa32" ;; *) # default to 7100 path="pa32/hppa1_1/pa7100 pa32/hppa1_1 pa32" ;; esac # gcc 2.7.2.3 knows -mpa-risc-1-0 and -mpa-risc-1-1 # gcc 2.95 adds -mpa-risc-2-0, plus synonyms -march=1.0, 1.1 and 2.0 # # We don't use -mpa-risc-2-0 in ABI=1.0 because 64-bit registers may not # be saved by the kernel on an old system. Actually gcc (as of 3.2) # only adds a few float instructions with -mpa-risc-2-0, so it would # probably be safe, but let's not take the chance. In any case, a # configuration like --host=hppa2.0 ABI=1.0 is far from optimal. # case $host_cpu in hppa1.0*) gcc_cflags_arch="-mpa-risc-1-0" ;; *) # default to 7100 gcc_cflags_arch="-mpa-risc-1-1" ;; esac case $host_cpu in hppa1.0*) cc_cflags="+O2" ;; *) # default to 7100 cc_cflags="+DA1.1 +O2" ;; esac case $host in hppa2.0*-*-* | hppa64-*-*) cclist_20n="gcc cc" abilist="2.0n 1.0" path_20n="pa64" limb_20n=longlong any_20n_testlist="sizeof-long-4" SPEED_CYCLECOUNTER_OBJ_20n=hppa2.lo cyclecounter_size_20n=2 # -mpa-risc-2-0 is only an optional flag, in case an old gcc is # used. Assembler support for 2.0 is essential though, for our asm # files. gcc_20n_cflags="-O2" gcc_20n_cflags_optlist="arch" gcc_20n_cflags_arch="-mpa-risc-2-0 -mpa-risc-1-1" gcc_20n_testlist="sizeof-long-4 hppa-level-2.0" cc_20n_cflags="+DA2.0 +e +O2 -Wl,+vnocompatwarnings" cc_20n_testlist="hpc-hppa-2-0" # ABI=2.0w is available for hppa2.0w and hppa2.0, but not for # hppa2.0n, on the assumption that that the latter indicates a # desire for ABI=2.0n. case $host in hppa2.0n-*-*) ;; *) # HPUX 10 and earlier cannot run 2.0w. Not sure about other # systems (GNU/Linux for instance), but lets assume they're ok. case $host in [*-*-hpux[1-9] | *-*-hpux[1-9].* | *-*-hpux10 | *-*-hpux10.*]) ;; *) abilist="2.0w $abilist" ;; esac cclist_20w="gcc cc" gcc_20w_cflags="-O2 -mpa-risc-2-0" cc_20w_cflags="+DD64 +O2" cc_20w_testlist="hpc-hppa-2-0" path_20w="pa64" any_20w_testlist="sizeof-long-8" SPEED_CYCLECOUNTER_OBJ_20w=hppa2w.lo cyclecounter_size_20w=2 ;; esac ;; esac ;; i960*-*-*) path="i960" ;; IA64_PATTERN) abilist="64" GMP_INCLUDE_MPN(ia64/ia64-defs.m4) SPEED_CYCLECOUNTER_OBJ=ia64.lo case $host_cpu in itanium) path="ia64/itanium ia64" ;; itanium2) path="ia64/itanium2 ia64" ;; *) path="ia64" ;; esac gcc_64_cflags_optlist="tune" gcc_32_cflags_optlist=$gcc_64_cflags_optlist # gcc pre-release 3.4 adds -mtune itanium and itanium2 case $host_cpu in itanium) gcc_cflags_tune="-mtune=itanium" ;; itanium2) gcc_cflags_tune="-mtune=itanium2" ;; esac case $host in *-*-linux*) cclist="gcc icc" icc_cflags="-no-gcc" icc_cflags_optlist="opt" # FIXME: Check if -O3 is really right. The manual warns it is for # large data sets, for which GMP uses assembly loops. icc_cflags_opt="-O3 -O2 -O1" ;; *-*-hpux*) # HP cc sometimes gets internal errors if the optimization level is # too high. GMP_PROG_CC_WORKS detects this, the "_opt" fallbacks # let us use whatever seems to work. # abilist="32 64" cclist_32="gcc cc" path_32="ia64" cc_32_cflags="" cc_32_cflags_optlist="opt" cc_32_cflags_opt="+O3 +O2 +O1" gcc_32_cflags="-milp32 -O2" limb_32=longlong SPEED_CYCLECOUNTER_OBJ_32=ia64.lo cyclecounter_size_32=2 # Must have +DD64 in CPPFLAGS to get the right __LP64__ for headers, # but also need it in CFLAGS for linking programs, since automake # only uses CFLAGS when linking, not CPPFLAGS. # FIXME: Maybe should use cc_64_ldflags for this, but that would # need GMP_LDFLAGS used consistently by all the programs. # cc_64_cflags="+DD64" cc_64_cppflags="+DD64" cc_64_cflags_optlist="opt" cc_64_cflags_opt="+O3 +O2 +O1" gcc_64_cflags="-mlp64 -O2" ;; esac ;; # Motorola 68k # M68K_PATTERN) AC_DEFINE(HAVE_HOST_CPU_FAMILY_m68k) GMP_INCLUDE_MPN(m68k/m68k-defs.m4) gcc_cflags="-O2 $fomit_frame_pointer" gcc_cflags_optlist="arch" # gcc 2.7.2 knows -m68000, -m68020, -m68030, -m68040. # gcc 2.95 adds -mcpu32, -m68060. # FIXME: Maybe "-m68020 -mnobitfield" would suit cpu32 on 2.7.2. # case $host_cpu in m68020) gcc_cflags_arch="-m68020" ;; m68030) gcc_cflags_arch="-m68030" ;; m68040) gcc_cflags_arch="-m68040" ;; m68060) gcc_cflags_arch="-m68060 -m68000" ;; m68360) gcc_cflags_arch="-mcpu32 -m68000" ;; *) gcc_cflags_arch="-m68000" ;; esac # FIXME: m68k/mc68020 looks like it's ok for cpu32, but this wants to be # tested. Will need to introduce an m68k/cpu32 if m68k/mc68020 ever uses # the bitfield instructions. case $host_cpu in [m680[234]0 | m68360]) path="m68k/mc68020 m68k" ;; *) path="m68k" ;; esac ;; # Motorola 88k m88k*-*-*) path="m88k" ;; m88110*-*-*) # FIXME: Use `-O2'? gcc_cflags="-O -m88110" path="m88k/mc88110 m88k" ;; # National Semiconductor 32k ns32k*-*-*) path="ns32k" ;; # IRIX 5 and earlier can only run 32-bit o32. # # IRIX 6 and up always has a 64-bit mips CPU can run n32 or 64. n32 is # preferred over 64, but only because that's been the default in past # versions of GMP. The two are equally efficient. # # Linux kernel 2.2.13 arch/mips/kernel/irixelf.c has a comment about not # supporting n32 or 64. # # For reference, libtool (eg. 1.5.6) recognises the n32 ABI and knows the # right options to use when linking (both cc and gcc), so no need for # anything special from us. # mips*-*-*) abilist="o32" gcc_cflags_optlist="abi" gcc_cflags_abi="-mabi=32" gcc_testlist="gcc-mips-o32" path="mips32" cc_cflags="-O2 -o32" # no -g, it disables all optimizations # this suits both mips32 and mips64 GMP_INCLUDE_MPN(mips32/mips-defs.m4) case $host in [mips64*-*-* | mips*-*-irix[6789]*]) abilist="n32 64 o32" cclist_n32="gcc cc" gcc_n32_cflags="-O2 -mabi=n32" cc_n32_cflags="-O2 -n32" # no -g, it disables all optimizations limb_n32=longlong path_n32="mips64" cclist_64="gcc cc" gcc_64_cflags="-O2 -mabi=64" gcc_64_ldflags="-Wc,-mabi=64" cc_64_cflags="-O2 -64" # no -g, it disables all optimizations cc_64_ldflags="-Wc,-64" path_64="mips64" ;; esac ;; # Darwin (powerpc-apple-darwin1.3) has it's hacked gcc installed as cc. # Our usual "gcc in disguise" detection means gcc_cflags etc here gets # used. # # The darwin pre-compiling preprocessor is disabled with -no-cpp-precomp # since it doesn't like "__attribute__ ((mode (SI)))" etc in gmp-impl.h, # and so always ends up running the plain preprocessor anyway. This could # be done in CPPFLAGS rather than CFLAGS, but there's not many places # preprocessing is done separately, and this is only a speedup, the normal # preprocessor gets run if there's any problems. # # We used to use -Wa,-mppc with gcc, but can't remember exactly why. # Presumably it was for old versions of gcc where -mpowerpc doesn't put # the assembler in the right mode. In any case -Wa,-mppc is not good, for # instance -mcpu=604 makes recent gcc use -m604 to get access to the # "fsel" instruction, but a -Wa,-mppc overrides that, making code that # comes out with fsel fail. # # (Note also that the darwin assembler doesn't accept "-mppc", so any # -Wa,-mppc was used only if it worked. The right flag on darwin would be # "-arch ppc" or some such, but that's already the default.) # [powerpc*-*-* | power[3-9]-*-*]) AC_DEFINE(HAVE_HOST_CPU_FAMILY_powerpc) HAVE_HOST_CPU_FAMILY_powerpc=1 abilist="32" cclist="gcc cc" cc_cflags="-O2" gcc_cflags="-O2 -mpowerpc" gcc_cflags_optlist="precomp subtype asm cpu" gcc_cflags_precomp="-no-cpp-precomp" gcc_cflags_subtype="-force_cpusubtype_ALL" # for vmx on darwin gcc_cflags_asm="" gcc_cflags_cpu="" # grab this object, though it's not a true cycle counter routine SPEED_CYCLECOUNTER_OBJ=powerpc.lo cyclecounter_size=0 case $host_cpu in powerpc740 | powerpc750) path="powerpc32/750 powerpc32" ;; powerpc7400) path="powerpc32/vmx powerpc32/750 powerpc32" ;; [powerpc74[45]?]) path="powerpc32/vmx powerpc32 powerpc32" ;; *) path="powerpc32" ;; esac # gcc 2.7.2 knows -mcpu=403, 601, 603, 604. # gcc 2.95 adds 401, 505, 602, 603e, ec603e, 604e, 620, 740, 750, # 801, 821, 823, 860. # gcc 3.0 adds 630, rs64a. # gcc 3.1 adds 405, 7400, 7450. # gcc 3.2 adds nothing. # gcc 3.3 adds power3, power4, 8540. power3 seems to be a synonym for 630. # gcc pre-release 3.4 adds 405fp, 440, 440fp, 970. # # FIXME: The way 603e falls back to 603 for gcc 2.7.2 should be # done for all the others too. But what would be the correct # arrangements? # case $host_cpu in powerpc401) gcc_cflags_cpu="-mcpu=401" ;; powerpc403) gcc_cflags_cpu="-mcpu=403" ;; powerpc405) gcc_cflags_cpu="-mcpu=405" ;; powerpc505) gcc_cflags_cpu="-mcpu=505" ;; powerpc601) gcc_cflags_cpu="-mcpu=601" ;; powerpc602) gcc_cflags_cpu="-mcpu=602" ;; powerpc603) gcc_cflags_cpu="-mcpu=603" ;; powerpc603e) gcc_cflags_cpu="-mcpu=603e -mcpu=603" ;; powerpc604) gcc_cflags_cpu="-mcpu=604" ;; powerpc604e) gcc_cflags_cpu="-mcpu=604e -mcpu=604" ;; powerpc620) gcc_cflags_cpu="-mcpu=620" ;; powerpc630) gcc_cflags_cpu="-mcpu=630" ;; powerpc740) gcc_cflags_cpu="-mcpu=740" ;; powerpc7400 | powerpc7410) gcc_cflags_asm="-Wa,-maltivec" gcc_cflags_cpu="-mcpu=7400 -mcpu=750" ;; powerpc74[45]?) gcc_cflags_asm="-Wa,-maltivec" gcc_cflags_cpu="-mcpu=7450" ;; powerpc750) gcc_cflags_cpu="-mcpu=750" ;; powerpc801) gcc_cflags_cpu="-mcpu=801" ;; powerpc821) gcc_cflags_cpu="-mcpu=821" ;; powerpc823) gcc_cflags_cpu="-mcpu=823" ;; powerpc860) gcc_cflags_cpu="-mcpu=860" ;; powerpc970) gcc_cflags_cpu="-mcpu=970" ;; esac case $host in *-*-aix*) cclist="gcc xlc cc" xlc_cflags="-O2 -qmaxmem=20000" xlc_cflags_optlist="arch" # xlc (what version?) knows -qarch=ppc, ppcgr, 601, 602, 603, 604, # 403, rs64a # -qarch=ppc is needed, so ensure everything falls back to that. # FIXME: Perhaps newer versions know more flavours. # case $host_cpu in powerpc403) xlc_cflags_arch="-qarch=403 -qarch=ppc" ;; powerpc601) xlc_cflags_arch="-qarch=601 -qarch=ppc" ;; powerpc602) xlc_cflags_arch="-qarch=602 -qarch=ppc" ;; powerpc603) xlc_cflags_arch="-qarch=603 -qarch=ppc" ;; powerpc603e) xlc_cflags_arch="-qarch=603 -qarch=ppc" ;; powerpc604) xlc_cflags_arch="-qarch=604 -qarch=ppc" ;; powerpc604e) xlc_cflags_arch="-qarch=604 -qarch=ppc" ;; *) xlc_cflags_arch="-qarch=ppc" ;; esac ;; esac case $host in POWERPC64_PATTERN) case $host_cpu in powerpc970) vmx_path="powerpc64/vmx" ;; *) vmx_path="" ;; esac case $host in *-*-aix*) # On AIX a true 64-bit ABI is available. # Need -Wc to pass object type flags through to the linker. abilist="aix64 $abilist" cclist_aix64="gcc xlc" gcc_aix64_cflags="-O2 -maix64 -mpowerpc64" gcc_aix64_cflags_optlist="cpu" gcc_aix64_ldflags="-Wc,-maix64" xlc_aix64_cflags="-O2 -q64 -qtune=pwr3 -qmaxmem=20000" xlc_aix64_ldflags="-Wc,-q64" # Must indicate object type to ar and nm ar_aix64_flags="-X64" nm_aix64_flags="-X64" path_aix64="powerpc64/mode64 $vmx_path powerpc64" # grab this object, though it's not a true cycle counter routine SPEED_CYCLECOUNTER_OBJ_aix64=powerpc64.lo cyclecounter_size_aix64=0 ;; *-*-darwin*) # On Darwin we can use 64-bit instructions with a longlong limb, # but the chip still in 32-bit mode. # In theory this can be used on any OS which knows how to save # 64-bit registers in a context switch. # # Note that we must use -mpowerpc64 with gcc, since the # longlong.h macros expect limb operands in a single 64-bit # register, not two 32-bit registers as would be given for a # long long without -mpowerpc64. In theory we could detect and # accomodate both styles, but the proper 64-bit registers will # be fastest and are what we really want to use. # # One would think -mpowerpc64 would set the assembler in the right # mode to handle 64-bit instructions. But for that, also # -force_cpusubtype_ALL is needed. # # Do not use -fast for Darwin, it actually adds options # incompatible with a shared library. # abilist="mode64 mode32 $abilist" gcc_cflags_opt="-O3 -O2 -O1" # will this become used? cclist_mode32="gcc" gcc_mode32_cflags="-mpowerpc64" gcc_mode32_cflags_optlist="subtype cpu opt" gcc_mode32_cflags_subtype="-force_cpusubtype_ALL" gcc_mode32_cflags_opt="-O3 -O2 -O1" path_mode32="powerpc64/mode32 $vmx_path powerpc64" limb_mode32=longlong cclist_mode64="gcc" gcc_mode64_cflags="-m64" gcc_mode64_cflags_optlist="cpu opt" gcc_mode64_cflags_opt="-O3 -O2 -O1" path_mode64="powerpc64/mode64 $vmx_path powerpc64" SPEED_CYCLECOUNTER_OBJ_mode64=powerpc64.lo cyclecounter_size_mode64=0 any_mode64_testlist="sizeof-long-8" ;; *-*-linux* | *-*-*bsd*) # On GNU/Linux, assume the processor is in 64-bit mode. Some # environments have a gcc that is always in 64-bit mode, while # others require -m64, hence the use of cflags_maybe. The # sizeof-long-8 test checks the mode is right (for the no option # case). # # -mpowerpc64 is not used, since it should be the default in # 64-bit mode. (We need its effect for the various longlong.h # asm macros to be right of course.) # # gcc64 was an early port of gcc to 64-bit mode, but should be # obsolete before too long. We prefer plain gcc when it knows # 64-bits. # abilist="mode64 mode32 $abilist" cclist_mode32="gcc" gcc_mode32_cflags="-mpowerpc64 -Wa,-mppc64" gcc_mode32_cflags_optlist="cpu opt" gcc_mode32_cflags_opt="-O3 -O2 -O1" path_mode32="powerpc64/mode32 $vmx_path powerpc64" limb_mode32=longlong cclist_mode64="gcc gcc64" gcc_mode64_cflags_maybe="-m64" gcc_mode64_cflags_optlist="cpu opt" gcc_mode64_cflags_opt="-O3 -O2 -O1" path_mode64="powerpc64/mode64 $vmx_path powerpc64" SPEED_CYCLECOUNTER_OBJ_mode64=powerpc64.lo cyclecounter_size_mode64=0 any_mode64_testlist="sizeof-long-8" ;; esac ;; esac ;; # POWER [power-*-* | power[12]-*-* | power2sc-*-*]) AC_DEFINE(HAVE_HOST_CPU_FAMILY_power) HAVE_HOST_CPU_FAMILY_power=1 cclist="gcc" extra_functions="udiv_w_sdiv" path="power" # gcc 2.7.2 knows rios1, rios2, rsc # # -mcpu=rios2 can tickle an AIX assembler bug (see GMP_PROG_CC_WORKS) so # there needs to be a fallback to just -mpower. # gcc_cflags_optlist="cpu" case $host in power-*-*) gcc_cflags_cpu="-mcpu=power -mpower" ;; power1-*-*) gcc_cflags_cpu="-mcpu=rios1 -mpower" ;; power2-*-*) gcc_cflags_cpu="-mcpu=rios2 -mpower" ;; power2sc-*-*) gcc_cflags_cpu="-mcpu=rsc -mpower" ;; esac case $host in *-*-aix*) cclist="gcc xlc" xlc_cflags="-O2 -qarch=pwr -qmaxmem=20000" ;; esac ;; pyramid-*-*) path="pyr" ;; # IBM s/370 and similar [s3[6-9]0*-*-*]) gcc_cflags="-O2 $fomit_frame_pointer" path="s390" extra_functions="udiv_w_sdiv" ;; sh-*-*) path="sh" ;; sh2-*-*) path="sh/sh2 sh" ;; *sparc*-*-*) # sizeof(long)==4 or 8 is tested, to ensure we get the right ABI. We've # had various bug reports where users have set CFLAGS for their desired # mode, but not set our ABI. For some reason it's sparc where this # keeps coming up, presumably users there are accustomed to driving the # compiler mode that way. The effect of our testlist setting is to # reject ABI=64 in favour of ABI=32 if the user has forced the flags to # 32-bit mode. # abilist="32" cclist="gcc acc cc" any_testlist="sizeof-long-4" GMP_INCLUDE_MPN(sparc32/sparc-defs.m4) case $host_cpu in sparcv8 | microsparc | turbosparc) path="sparc32/v8 sparc32" ;; supersparc) path="sparc32/v8/supersparc sparc32/v8 sparc32" ;; sparc64 | sparcv9* | ultrasparc*) path="sparc32/v9 sparc32/v8 sparc32" ;; *) path="sparc32" ;; esac # gcc 2.7.2 doesn't know about v9 and doesn't pass -xarch=v8plus to the # assembler. Add it explicitly since the solaris assembler won't accept # our sparc32/v9 asm code without it. gas accepts -xarch=v8plus too, so # it can be in the cflags unconditionally (though gas doesn't need it). # # gcc -m32 is needed to force 32-bit mode on a dual-ABI system, but past # gcc doesn't know that flag, hence cflags_maybe. Note that -m32 cannot # be done through the optlist since the plain cflags would be run first # and we don't want to require the default mode (whatever it is) works. # # Note it's gcc_32_cflags_maybe and not gcc_cflags_maybe because the # latter would be used in the 64-bit ABI on systems like "*bsd" where # abilist="64" only. # case $host_cpu in sparc64 | sparcv9* | ultrasparc*) gcc_cflags="-O2 -Wa,-xarch=v8plus" ;; *) gcc_cflags="-O2" ;; esac gcc_32_cflags_maybe="-m32" gcc_cflags_optlist="cpu" # gcc 2.7.2 knows -mcypress, -msupersparc, -mv8, -msparclite. # gcc 2.95 knows -mcpu= v7, hypersparc, sparclite86x, f930, f934, # sparclet, tsc701, v9, ultrasparc. A warning is given that the # plain -m forms will disappear. # gcc 3.0 adds nothing. # gcc 3.1 adds nothing. # gcc 3.2 adds nothing. # gcc 3.3 adds ultrasparc3. # case $host_cpu in supersparc) gcc_cflags_cpu="-mcpu=supersparc -msupersparc" ;; sparcv8 | microsparc | turbosparc) gcc_cflags_cpu="-mcpu=v8 -mv8" ;; sparc64 | sparcv9*) gcc_cflags_cpu="-mcpu=v9 -mv8" ;; ultrasparc3) gcc_cflags_cpu="-mcpu=ultrasparc3 -mcpu=ultrasparc -mv8" ;; ultrasparc*) gcc_cflags_cpu="-mcpu=ultrasparc -mv8" ;; *) gcc_cflags_cpu="-mcpu=v7 -mcypress" ;; esac # SunPRO cc and acc, and SunOS bundled cc case $host in *-*-solaris* | *-*-sunos*) # Note no -g, it disables all optimizations. cc_cflags= cc_cflags_optlist="opt arch cpu" # SunOS cc doesn't know -xO4, fallback to -O2. cc_cflags_opt="-xO4 -O2" # SunOS cc doesn't know -xarch, apparently always generating v7 # code, so make this optional case $host_cpu in sparcv8 | microsparc | supersparc | turbosparc) cc_cflags_arch="-xarch=v8" ;; sparc64 | sparcv9* | ultrasparc*) cc_cflags_arch="-xarch=v8plus" ;; *) cc_cflags_arch="-xarch=v7" ;; esac # SunOS cc doesn't know -xchip and doesn't seem to have an equivalent. # SunPRO cc 5 recognises -xchip=generic, old, super, super2, micro, # micro2, hyper, hyper2, powerup, ultra, ultra2, ultra2i. # SunPRO cc 6 adds -xchip=ultra2e, ultra3cu. # # FIXME: Which of ultra, ultra2 or ultra2i is the best fallback for # ultrasparc3? # case $host_cpu in supersparc) cc_cflags_cpu="-xchip=super" ;; microsparc) cc_cflags_cpu="-xchip=micro" ;; turbosparc) cc_cflags_cpu="-xchip=micro2" ;; ultrasparc) cc_cflags_cpu="-xchip=ultra" ;; ultrasparc2) cc_cflags_cpu="-xchip=ultra2" ;; ultrasparc2i) cc_cflags_cpu="-xchip=ultra2i" ;; ultrasparc3) cc_cflags_cpu="-xchip=ultra3 -xchip=ultra" ;; *) cc_cflags_cpu="-xchip=generic" ;; esac esac case $host_cpu in sparc64 | sparcv9* | ultrasparc*) case $host in # Solaris 6 and earlier cannot run ABI=64 since it doesn't save # registers properly, so ABI=32 is left as the only choice. # [*-*-solaris2.[0-6] | *-*-solaris2.[0-6].*]) ;; # BSD sparc64 ports are 64-bit-only systems, so ABI=64 is the only # choice. In fact they need no special compiler flags, gcc -m64 # is the default, but it doesn't hurt to add it. v9 CPUs always # use the sparc64 port, since the plain 32-bit sparc ports don't # run on a v9. # *-*-*bsd*) abilist="64" ;; # For all other systems, we try both 64 and 32. # # GNU/Linux sparc64 has only recently gained a 64-bit user mode. # In the past sparc64 meant a v9 cpu, but there were no 64-bit # operations in user mode. We assume that if "gcc -m64" works # then the system is suitable. Hopefully even if someone attempts # to put a new gcc and/or glibc on an old system it won't run. # *) abilist="64 32" ;; esac path_64="sparc64" cclist_64="gcc" any_64_testlist="sizeof-long-8" # gcc -mptr64 is probably implied by -m64, but we're not sure if # this was always so. On Solaris in the past we always used both # "-m64 -mptr64". # # gcc -Wa,-xarch=v9 is thought to be necessary in some cases on # solaris, but it would seem likely that if gcc is going to generate # 64-bit code it will have to add that option itself where needed. # An extra copy of this option should be harmless though, but leave # it until we're sure. (Might want -xarch=v9a or -xarch=v9b for the # higher cpu types instead.) # gcc_64_cflags="-O2 -m64 -mptr64" gcc_64_ldflags="-Wc,-m64" gcc_64_cflags_optlist="cpu" case $host in *-*-solaris*) # Sun cc. # # -fast enables different optimizations depending on compiler # version. Unfortunately it does things according to the native # system, which may not be optimal when cross compiling (to a # different sparc). -xchip from cc_cflags_cpu will override at # least that part of its selections. # # -fns=no and -fsimple=1 disable some transformations that # conflict with IEEE 754, which some compiler versions perform # under -fast. # # In any case -fast can result in incorrect optimisations and so # has been removed (see # http://swox.com/list-archives/gmp-bugs/2008-April/000987.html) # cclist_64="$cclist_64 cc" cc_64_cflags="-xarch=v9" cc_64_cflags_optlist="cpu" ;; esac # using the v9 %tick register SPEED_CYCLECOUNTER_OBJ_32=sparcv9.lo SPEED_CYCLECOUNTER_OBJ_64=sparcv9.lo cyclecounter_size_32=2 cyclecounter_size_64=2 ;; esac ;; # VAX vax*-*-*) # Currently gcc (version 3.0) on vax always uses a frame pointer # (config/vax/vax.h FRAME_POINTER_REQUIRED=1), so -fomit-frame-pointer # will be ignored. # gcc_cflags="-O2 $fomit_frame_pointer" path="vax" extra_functions="udiv_w_sdiv" ;; # AMD and Intel x86 configurations, including AMD64 # # Rumour has it gcc -O2 used to give worse register allocation than just # -O, but lets assume that's no longer true. # # -m32 forces 32-bit mode on a bi-arch 32/64 amd64 build of gcc. -m64 is # the default in such a build (we think), so -m32 is essential for ABI=32. # This is, of course, done for any $host_cpu, not just x86_64, so we can # get such a gcc into the right mode to cross-compile to say i486-*-*. # # -m32 is not available in gcc 2.95 and earlier, hence cflags_maybe to use # it when it works. We check sizeof(long)==4 to ensure we get the right # mode, in case -m32 has failed not because it's an old gcc, but because # it's a dual 32/64-bit gcc without a 32-bit libc, or whatever. # X86_PATTERN | X86_64_PATTERN) abilist="32" cclist="gcc icc cc" gcc_cflags="-O2 $fomit_frame_pointer" gcc_32_cflags_maybe="-m32" icc_cflags="-no-gcc" icc_cflags_optlist="opt" icc_cflags_opt="-O3 -O2 -O1" any_32_testlist="sizeof-long-4" CALLING_CONVENTIONS_OBJS='x86call.lo x86check$U.lo' # Currently yasm is only needed to build x86 assembly files on some hosts want_yasm="yes" # Availability of rdtsc is checked at run-time. SPEED_CYCLECOUNTER_OBJ=pentium.lo case $host in *-*-solaris* | *-*-sunos*) # Note no -g, it disables all optimizations. cc_cflags= cc_cflags_optlist="opt arch cpu" # SunOS cc doesn't know -xO4, fallback to -O2. cc_cflags_opt="-xO4 -O2" ;; esac # gcc 2.7.2 only knows i386 and i486, using -m386 or -m486. These # represent -mcpu= since -m486 doesn't generate 486 specific insns. # gcc 2.95 adds k6, pentium and pentiumpro, and takes -march= and -mcpu=. # gcc 3.0 adds athlon. # gcc 3.1 adds k6-2, k6-3, pentium-mmx, pentium2, pentium3, pentium4, # athlon-tbird, athlon-4, athlon-xp, athlon-mp. # gcc 3.2 adds winchip2. # gcc 3.3 adds winchip-c6. # gcc 3.3.1 from mandrake adds k8 and knows -mtune. # gcc 3.4 adds c3, c3-2, k8, and deprecates -mcpu in favour of -mtune. # # In gcc 2.95.[0123], -march=pentiumpro provoked a stack slot bug in an # old version of mpz/powm.c. Seems to be fine with the current code, so # no need for any restrictions on that option. # # -march=pentiumpro can fail if the assembler doesn't know "cmov" # (eg. solaris 2.8 native "as"), so always have -march=pentium after # that as a fallback. # # -march=pentium4 and -march=k8 enable SSE2 instructions, which may or # may not be supported by the assembler and/or the OS, and is bad in gcc # prior to 3.3. The tests will reject these if no good, so fallbacks # like "-march=pentium4 -mno-sse2" are given to try also without SSE2. # Note the relevant -march types are listed in the optflags handling # below, be sure to update there if adding new types emitting SSE2. # # -mtune is used at the start of each cpu option list to give something # gcc 3.4 will use, thereby avoiding warnings from -mcpu. -mcpu forms # are retained for use by prior gcc. For example pentium has # "-mtune=pentium -mcpu=pentium ...", the -mtune is for 3.4 and the # -mcpu for prior. If there's a brand new choice in 3.4 for a chip, # like k8 for x86_64, then it can be the -mtune at the start, no need to # duplicate anything. # gcc_cflags_optlist="cpu arch" case $host_cpu in i386*) gcc_cflags_cpu="-mtune=i386 -mcpu=i386 -m386" gcc_cflags_arch="-march=i386" ;; i486*) gcc_cflags_cpu="-mtune=i486 -mcpu=i486 -m486" gcc_cflags_arch="-march=i486" ;; i586 | pentium) gcc_cflags_cpu="-mtune=pentium -mcpu=pentium -m486" gcc_cflags_arch="-march=pentium" ;; pentiummmx) gcc_cflags_cpu="-mtune=pentium-mmx -mcpu=pentium-mmx -mcpu=pentium -m486" gcc_cflags_arch="-march=pentium-mmx -march=pentium" ;; i686 | pentiumpro) gcc_cflags_cpu="-mtune=pentiumpro -mcpu=pentiumpro -mcpu=i486 -m486" gcc_cflags_arch="-march=pentiumpro -march=pentium" ;; pentium2) gcc_cflags_cpu="-mtune=pentium2 -mcpu=pentium2 -mcpu=pentiumpro -mcpu=i486 -m486" gcc_cflags_arch="-march=pentium2 -march=pentiumpro -march=pentium" ;; pentium3) gcc_cflags_cpu="-mtune=pentium3 -mcpu=pentium3 -mcpu=pentiumpro -mcpu=i486 -m486" gcc_cflags_arch="-march=pentium3 -march=pentiumpro -march=pentium" ;; k6) gcc_cflags_cpu="-mtune=k6 -mcpu=k6 -mcpu=i486 -m486" gcc_cflags_arch="-march=k6" ;; k62) gcc_cflags_cpu="-mtune=k6-2 -mcpu=k6-2 -mcpu=k6 -mcpu=i486 -m486" gcc_cflags_arch="-march=k6-2 -march=k6" ;; k63) gcc_cflags_cpu="-mtune=k6-3 -mcpu=k6-3 -mcpu=k6 -mcpu=i486 -m486" gcc_cflags_arch="-march=k6-3 -march=k6" ;; k7 | athlon) # Athlon instruction costs are close to P6 (3 cycle load latency, # 4-6 cycle mul, 40 cycle div, pairable adc, etc) so if gcc doesn't # know athlon (eg. 2.95.2 doesn't) then fall back on pentiumpro. gcc_cflags_cpu="-mtune=athlon -mcpu=athlon -mcpu=pentiumpro -mcpu=i486 -m486" gcc_cflags_arch="-march=athlon -march=pentiumpro -march=pentium" ;; i786 | pentium4) # pentiumpro is the primary fallback when gcc doens't know pentium4. # This gets us cmov to eliminate branches. Maybe "athlon" would be # a possibility on gcc 3.0. # gcc_cflags_cpu="-mtune=pentium4 -mcpu=pentium4 -mcpu=pentiumpro -mcpu=i486 -m486" gcc_cflags_arch="-march=pentium4 -march=pentium4~-mno-sse2 -march=pentiumpro -march=pentium" ;; prescott) # prescott is defined for our purposes as 32 bit pentium4 with SSE3 gcc_cflags_cpu="-mtune=prescott -mtune=pentium4 -mcpu=pentium4 -mcpu=pentiumpro -mcpu=i486 -m486" gcc_cflags_arch="-march=prescott -march=pentium4~-mno-sse2 -march=pentiumpro -march=pentium" ;; netburst | netburstlahf) # prescott is defined for our purposes as 32 bit pentium4 with SSE3 gcc_cflags_cpu="-mtune=nocona -mtune=pentium4 -mcpu=pentium4 -mcpu=pentiumpro -mcpu=i486 -m486" gcc_cflags_arch="-march=nocona -march=pentium4~-mno-sse2 -march=pentiumpro -march=pentium" ;; viac32) # Not sure of the best fallbacks here for -mcpu. # c3-2 has sse and mmx, so pentium3 is good for -march. gcc_cflags_cpu="-mtune=c3-2 -mcpu=c3-2 -mcpu=i486 -m486" gcc_cflags_arch="-march=c3-2 -march=pentium3 -march=pentiumpro -march=pentium" ;; viac3*) # Not sure of the best fallbacks here. gcc_cflags_cpu="-mtune=c3 -mcpu=c3 -mcpu=i486 -m486" gcc_cflags_arch="-march=c3 -march=pentium-mmx -march=pentium" ;; x86_64 | k8 | k10 | atom) gcc_cflags_cpu="-mtune=k8 -mcpu=athlon -mcpu=pentiumpro -mcpu=i486 -m486" gcc_cflags_arch="-march=k8 -march=k8~-mno-sse2 -march=athlon -march=pentiumpro -march=pentium" ;; core2 | penryn | nehalem) gcc_cflags_cpu="-mtune=core2 -mtune=nocona -mtune=pentium3 -mcpu=pentiumpro -mcpu=i486 -m486" gcc_cflags_arch="-march=core2 -march=nocona -march=pentium3 -march=pentiumpro -march=pentium" ;; *) gcc_cflags_cpu="-mtune=i486 -mcpu=i486 -m486" gcc_cflags_arch="-march=i486" ;; esac case $host_cpu in i386*) path="x86" ;; i486*) path="x86/i486 x86" ;; i586 | pentium) path="x86/pentium x86" ;; pentiummmx) path="x86/pentium/mmx x86/pentium x86" ;; i686 | pentiumpro) path="x86/p6 x86" ;; pentium2) path="x86/p6/mmx x86/p6 x86" ;; pentium3) path="x86/p6/p3mmx x86/p6/mmx x86/p6 x86";; [k6[23]]) path="x86/k6/k62mmx x86/k6/mmx x86/k6 x86" ;; k6) path="x86/k6/mmx x86/k6 x86" ;; # we don't have any specific 32-bit code for opteron (x86_64), the # athlon code should be reasonable athlon | k7 | x86_64 | k8 | k10 | atom) path="x86/k7/mmx x86/k7 x86" ;; i786 | pentium4 | core2 | penryn | nehalem) path="x86/pentium4/sse2 x86/pentium4/mmx x86/pentium4 x86" ;; prescott | netburst | netburstlahf) path="x86/pentium4/sse2 x86/pentium4/mmx x86/pentium4 x86" ;; # VIA/Centaur processors, sold as CyrixIII and C3. viac32) path="x86/p6/p3mmx x86/p6/mmx x86/p6 x86";; viac3*) path="x86/pentium/mmx x86/pentium x86";; *) path="x86" ;; esac # If the user asked for a fat build, override the path set above if test $enable_fat = yes; then gcc_cflags_cpu="" gcc_cflags_arch="" extra_functions="$extra_functions fat fat_entry" path="x86/fat x86" fat_path="x86 x86/fat x86/i486 x86/k6 x86/k6/mmx x86/k6/k62mmx x86/k7 x86/k7/mmx x86/pentium x86/pentium/mmx x86/p6 x86/p6/mmx x86/p6/p3mmx x86/pentium4 x86/pentium4/mmx x86/pentium4/sse2" fat_functions="add_n addmul_1 copyd copyi dive_1 diveby3 divrem_1 gcd_1 lshift mod_1 mod_34lsub1 mode1o mul_1 mul_basecase pre_divrem_1 pre_mod_1 redc_basecase rshift sqr_basecase sub_n submul_1 sumdiff_n" fat_exclude="" fat_thresholds="MUL_KARATSUBA_THRESHOLD MUL_TOOM3_THRESHOLD SQR_KARATSUBA_THRESHOLD SQR_TOOM3_THRESHOLD" fi case $host in X86_64_PATTERN) abilist="64 32" cclist_64="gcc cc" gcc_64_cflags="-O2 -m64" gcc_64_cflags_optlist="opt arch cpu" SPEED_CYCLECOUNTER_OBJ_64=x86_64.lo CALLING_CONVENTIONS_OBJS_64='x86_64call.lo x86_64check$U.lo' cyclecounter_size_64=2 case $host in *-*-solaris* | *-*-sunos*) # Note no -g, it disables all optimizations. cc_64_cflags="-m64" cc_64_cflags_optlist="opt arch cpu" # SunOS cc doesn't know -xO4, fallback to -O2. cc_64_cflags_opt="-xO4 -O2" ;; esac case $host in x86_64-*-*) path_64="x86_64" ;; netburst-*-*) path_64="x86_64/netburst x86_64" ;; netburstlahf-*-*) path_64="x86_64/netburst/netburstlahf x86_64/netburst x86_64" ;; k8-*-*) path_64="x86_64/k8 x86_64" ;; k10-*-*) path_64="x86_64/k8/k10 x86_64/k8 x86_64" ;; core2-*-*) path_64="x86_64/core2 x86_64" ;; penryn-*-*) path_64="x86_64/core2/penryn x86_64/core2 x86_64" ;; nehalem-*-*) path_64="x86_64/nehalem x86_64" ;; atom-*-*) path_64="x86_64/atom x86_64" ;; esac # If the user asked for a fat build, override the path set above if test $enable_fat = yes; then gcc_64_cflags_cpu="" gcc_64_cflags_arch="" extra_functions_64="$extra_functions_64 fat fat_entry" path_64="x86_64/fat x86_64" fat_path_64="x86_64 x86_64/fat x86_64/netburst x86_64/netburst/netburstlahf x86_64/k8 x86_64/k8/k10 x86_64/core2 x86_64/core2/penryn x86_64/nehalem x86_64/atom" fi ;; esac ;; # FIXME: z8kx won't get through config.sub. Could make 16 versus 32 bit # limb an ABI option perhaps. z8kx*-*-*) path="z8000x" extra_functions="udiv_w_sdiv" ;; z8k*-*-*) path="z8000" extra_functions="udiv_w_sdiv" ;; # Special CPU "none" selects generic C. -DNO_ASM is used to disable gcc # asm blocks in longlong.h (since they're driven by cpp pre-defined # symbols like __alpha rather than the configured $host_cpu). # none-*-*) abilist="long longlong" cclist_long=$cclist gcc_long_cflags=$gcc_cflags gcc_long_cppflags="-DNO_ASM" cc_long_cflags=$cc_cflags cclist_longlong=$cclist gcc_longlong_cflags=$gcc_cflags gcc_longlong_cppflags="-DNO_ASM" cc_longlong_cflags=$cc_cflags limb_longlong=longlong ;; esac # mingw can be built by the cygwin gcc if -mno-cygwin is added. For # convenience add this automatically if it works. Actual mingw gcc accepts # -mno-cygwin too, but of course is the default. mingw only runs on the # x86s, but allow any CPU here so as to catch "none" too. # case $host in *-*-mingw*) gcc_cflags_optlist="$gcc_cflags_optlist nocygwin" gcc_cflags_nocygwin="-mno-cygwin" ;; esac AM_CONDITIONAL(BUILD_YASM, test "$want_yasm" = "yes") CFLAGS_or_unset=${CFLAGS-'(unset)'} CPPFLAGS_or_unset=${CPPFLAGS-'(unset)'} cat >&AC_FD_CC <&AC_FD_CC cxxflags_ac_prog_cxx=$CXXFLAGS cxxflags_list=ac_prog_cxx # If the user didn't specify $CXXFLAGS, then try $CFLAGS, with -g removed # if AC_PROG_CXX thinks that doesn't work. $CFLAGS stands a good chance # of working, eg. on a GNU system where CC=gcc and CXX=g++. # if test "$test_CXXFLAGS" != set; then cxxflags_cflags=$CFLAGS cxxflags_list="cflags $cxxflags_list" if test "$ac_prog_cxx_g" = no; then cxxflags_cflags=`echo "$cxxflags_cflags" | sed -e 's/ -g //' -e 's/^-g //' -e 's/ -g$//'` fi fi # See if the C++ compiler works. If the user specified CXXFLAGS then all # we're doing is checking whether AC_PROG_CXX succeeded, since it doesn't # give a fatal error, just leaves CXX set to a default g++. If on the # other hand the user didn't specify CXXFLAGS then we get to try here our # $cxxflags_list alternatives. # # Automake includes $CPPFLAGS in a C++ compile, so we do the same here. # for cxxflags_choice in $cxxflags_list; do eval CXXFLAGS=\"\$cxxflags_$cxxflags_choice\" GMP_PROG_CXX_WORKS($CXX $CPPFLAGS $CXXFLAGS, [want_cxx=yes break]) done # If --enable-cxx=yes but a C++ compiler can't be found, then abort. if test $want_cxx = no && test $enable_cxx = yes; then AC_MSG_ERROR([C++ compiler not available, see config.log for details]) fi fi AM_CONDITIONAL(WANT_CXX, test $want_cxx = yes) # FIXME: We're not interested in CXXCPP for ourselves, but if we don't do it # here then AC_PROG_LIBTOOL will AC_REQUIRE it (via _LT_AC_TAGCONFIG) and # hence execute it unconditionally, and that will fail if there's no C++ # compiler (and no generic /lib/cpp). # if test $want_cxx = yes; then AC_PROG_CXXCPP fi # Path setups for Cray, according to IEEE or CFP. These must come after # deciding the compiler. # GMP_CRAY_OPTIONS( [add_path="cray/ieee"], [add_path="cray/cfp"; extra_functions="mulwwc90"], [add_path="cray/cfp"; extra_functions="mulwwj90"]) if test -z "$MPN_PATH"; then path="$add_path $path" fi # For a nail build, also look in "nails" subdirectories. # if test $GMP_NAIL_BITS != 0 && test -z "$MPN_PATH"; then new_path= for i in $path; do case $i in generic) new_path="$new_path $i" ;; *) new_path="$new_path $i/nails $i" ;; esac done path=$new_path fi # Put all directories into CPUVEC_list so as to get a full set of # CPUVEC_SETUP_$tmp_suffix defines into config.h, even if some of them are # empty because mmx and/or sse2 had to be dropped. # for i in $fat_path; do GMP_FAT_SUFFIX(tmp_suffix, $i) CPUVEC_list="$CPUVEC_list CPUVEC_SETUP_$tmp_suffix" done # If there's any sse2 or mmx in the path, check whether the assembler # supports it, and remove if not. # # We only need this in ABI=32, for ABI=64 on x86_64 we can assume a new # enough assembler. # case $host in X86_PATTERN | X86_64_PATTERN) if test "$ABI" = 32; then case "$path $fat_path" in *mmx*) GMP_ASM_X86_MMX( , [GMP_STRIP_PATH(*mmx*)]) ;; esac case "$path $fat_path" in *sse2*) GMP_ASM_X86_SSE2( , [GMP_STRIP_PATH(sse2)]) ;; esac fi ;; esac cat >&AC_FD_CC < # include #else # if HAVE_SYS_TIME_H # include # else # include # endif #endif]) # On NetBSD and OpenBSD, sys/sysctl.h needs sys/param.h for various constants AC_CHECK_HEADERS(sys/sysctl.h,,, [#if HAVE_SYS_PARAM_H # include #endif]) # On OSF 4.0, must have for ulong_t AC_CHECK_HEADERS(machine/hal_sysinfo.h,,, [#if HAVE_SYS_SYSINFO_H # include #endif]) # Reasons for testing: # optarg - not declared in mingw # fgetc, fscanf, ungetc, vfprintf - not declared in SunOS 4 # sys_errlist, sys_nerr - not declared in SunOS 4 # # optarg should be in unistd.h and the rest in stdio.h, both of which are # in the autoconf default includes. # # sys_errlist and sys_nerr are supposed to be in on SunOS according # to the man page (but aren't), in glibc they're in stdio.h. # AC_CHECK_DECLS([fgetc, fscanf, optarg, ungetc, vfprintf]) AC_CHECK_DECLS([sys_errlist, sys_nerr], , , [#include #include ]) AC_TYPE_SIGNAL # Reasons for testing: # intmax_t - C99 # long double - not in the HP bundled K&R cc # long long - only in reasonably recent compilers # ptrdiff_t - seems to be everywhere, maybe don't need to check this # quad_t - BSD specific # uint_least32_t - C99 # # the default includes are sufficient for all these types # AC_CHECK_TYPES([intmax_t, long double, long long, ptrdiff_t, quad_t, uint_least32_t]) AC_C_STRINGIZE # FIXME: Really want #ifndef __cplusplus around the #define volatile # replacement autoconf gives, since volatile is always available in C++. # But we don't use it in C++ currently. AC_C_VOLATILE # AC_C_RESTRICT GMP_C_STDARG GMP_C_ATTRIBUTE_CONST GMP_C_ATTRIBUTE_MALLOC GMP_C_ATTRIBUTE_MODE GMP_C_ATTRIBUTE_NORETURN GMP_H_EXTERN_INLINE # from libtool AC_CHECK_LIBM AC_SUBST(LIBM) GMP_FUNC_ALLOCA GMP_OPTION_ALLOCA GMP_H_HAVE_FILE AC_C_BIGENDIAN( [AC_DEFINE(HAVE_LIMB_BIG_ENDIAN, 1) GMP_DEFINE_RAW("define_not_for_expansion(\`HAVE_LIMB_BIG_ENDIAN')", POST)], [AC_DEFINE(HAVE_LIMB_LITTLE_ENDIAN, 1) GMP_DEFINE_RAW("define_not_for_expansion(\`HAVE_LIMB_LITTLE_ENDIAN')", POST) ], [:]) AH_VERBATIM([HAVE_LIMB], [/* Define one of these to 1 for the endianness of `mp_limb_t'. If the endianness is not a simple big or little, or you don't know what it is, then leave both undefined. */ #undef HAVE_LIMB_BIG_ENDIAN #undef HAVE_LIMB_LITTLE_ENDIAN]) GMP_C_DOUBLE_FORMAT # Reasons for testing: # alarm - not in mingw # attr_get - IRIX specific # clock_gettime - not in glibc 2.2.4, only very recent systems # cputime - not in glibc # getsysinfo - OSF specific # getrusage - not in mingw # gettimeofday - not in mingw # mmap - not in mingw, djgpp # nl_langinfo - X/Open standard only, not in djgpp for instance # obstack_vprintf - glibc specific # processor_info - solaris specific # pstat_getprocessor - HPUX specific (10.x and up) # raise - an ANSI-ism, though probably almost universal by now # read_real_time - AIX specific # sigaction - not in mingw # sigaltstack - not in mingw, or old AIX (reputedly) # sigstack - not in mingw # strerror - not in SunOS # strnlen - glibc extension (some other systems too) # syssgi - IRIX specific # times - not in mingw # # clock_gettime is in librt on *-*-osf5.1. We could look for it # there, but that's not worth bothering with unless it has a decent # resolution (in a quick test clock_getres said only 1 millisecond). # # AC_FUNC_STRNLEN is not used because we don't want the AC_LIBOBJ # replacement setups it gives. It detects a faulty strnlen on AIX, but # missing out on that test is ok since our only use of strnlen is in # __gmp_replacement_vsnprintf which is not required on AIX since it has a # vsnprintf. # AC_CHECK_FUNCS(alarm attr_get clock clock_gettime cputime getpagesize getrusage gettimeofday getsysinfo localeconv memset mmap mprotect nl_langinfo obstack_vprintf popen processor_info pstat_getprocessor raise read_real_time sigaction sigaltstack sigstack syssgi strchr strerror strnlen strtol strtoul sysconf sysctl sysctlbyname times) GMP_FUNC_VSNPRINTF GMP_FUNC_SSCANF_WRITABLE_INPUT # Reasons for checking: # pst_processor psp_iticksperclktick - not in hpux 9 # AC_CHECK_MEMBER(struct pst_processor.psp_iticksperclktick, [AC_DEFINE(HAVE_PSP_ITICKSPERCLKTICK, 1, [Define to 1 if `struct pst_processor' exists and contains `psp_iticksperclktick'.])],, [#include ]) # C++ tests, when required # if test $enable_cxx = yes; then AC_LANG_PUSH(C++) # Reasons for testing: # - not in g++ 2.95.2 # std::locale - not in g++ 2.95.4 # AC_CHECK_HEADERS([sstream]) AC_CHECK_TYPES([std::locale],,,[#include ]) AC_LANG_POP(C++) fi # Pick the correct source files in $path and link them to mpn/. # $gmp_mpn_functions lists all functions we need. # # The rule is to find a file with the function name and a .asm, .S, # .s, or .c extension. Certain multi-function files with special names # can provide some functions too. (mpn/Makefile.am passes # -DOPERATION_ to get them to generate the right code.) # Note: The following lines defining $gmp_mpn_functions_optional # and $gmp_mpn_functions are parsed by the "macos/configure" # Perl script. So if you change the lines in a major way # make sure to run and examine the output from # # % (cd macos; perl configure) # # Note: $gmp_mpn_functions must have mod_1 before pre_mod_1 so the former # can optionally provide the latter as an extra entrypoint. Likewise # divrem_1 and pre_divrem_1. gmp_mpn_functions_optional="umul udiv copyi copyd com_n and_n andn_n nand_n ior_n iorn_n nior_n xor_n xnor_n \ gcd_finda invert_limb sqr_diagonal lshift1 rshift1 \ bgcd hgcd hgcd2 lgcd ngcd ngcd_matrix ngcd_step \ nhgcd2 rgcd sgcd \ mul_2 mul_3 mul_4 \ addmul_2 addmul_3 addmul_4 addmul_5 addmul_6 addmul_7 addmul_8 \ addlsh1_n sublsh1_n rsh1add_n rsh1sub_n sumdiff_n lshiftc \ addadd_n addsub_n subadd_n" gmp_mpn_functions="$extra_functions \ add add_1 add_n sub sub_1 sub_n mul_1 addmul_1 submul_1 lshift rshift \ dive_1 diveby3 divebyff divebyBm1of divis divrem divrem_1 divrem_2 \ divrem_euclidean_qr_1 divrem_euclidean_r_1 \ fib2_ui mod_1 mod_34lsub1 mode1o pre_divrem_1 pre_mod_1 dump \ mul mul_fft mul_n mul_basecase sqr_basecase random random2 pow_1 \ rootrem sqrtrem get_str set_str scan0 scan1 popcount hamdist cmp perfsqr \ bdivmod gcd gcd_1 gcdext tdiv_qr dc_divrem_n sb_divrem_mn jacbase get_d \ mullow_n mullow_basecase redc_basecase \ $gmp_mpn_functions_optional toom4_mul_n" define(GMP_MULFUNC_CHOICES, [# functions that can be provided by multi-function files tmp_mulfunc= case $tmp_fn in add_n|sub_n) tmp_mulfunc="aors_n" ;; addmul_1|submul_1) tmp_mulfunc="aorsmul_1" ;; popcount|hamdist) tmp_mulfunc="popham" ;; and_n|andn_n|nand_n | ior_n|iorn_n|nior_n | xor_n|xnor_n) tmp_mulfunc="logops_n" ;; lshift|rshift) tmp_mulfunc="lorrshift";; addlsh1_n|sublsh1_n) tmp_mulfunc="aorslsh1_n";; rsh1add_n|rsh1sub_n) tmp_mulfunc="rsh1aors_n";; esac ]) # the list of all object files used by mpn/Makefile.in and the # top-level Makefile.in, respectively mpn_objects= mpn_objs_in_libgmp= # links from the sources, to be removed by "make distclean" gmp_srclinks= # mpn_relative_top_srcdir is $top_srcdir, but for use from within the mpn # build directory. If $srcdir is relative then we use a relative path too, # so the two trees can be moved together. case $srcdir in [[\\/]* | ?:[\\/]*]) # absolute, as per autoconf mpn_relative_top_srcdir=$srcdir ;; *) # relative mpn_relative_top_srcdir=../$srcdir ;; esac define(MPN_SUFFIXES,[as asm S s c]) dnl Usage: GMP_FILE_TO_FUNCTION_BASE(func,file) dnl dnl Set $func to the function base name for $file, eg. dive_1 gives dnl divexact_1. dnl define(GMP_FILE_TO_FUNCTION, [case $$2 in dive_1) $1=divexact_1 ;; diveby3) $1=divexact_by3c ;; divebyff) $1=divexact_byff ;; divebyBm1of) $1=divexact_byBm1of ;; pre_divrem_1) $1=preinv_divrem_1 ;; mode1o) $1=modexact_1c_odd ;; pre_mod_1) $1=preinv_mod_1 ;; *) $1=$$2 ;; esac ]) # Fat binary setups. # # We proceed through each $fat_path directory, and look for $fat_function # routines there. Those found are incorporated in the build by generating a # little mpn/.asm or mpn/.c file in the build directory, with # suitable function renaming, and adding that to $mpn_objects (the same as a # normal mpn file). # # fat.h is generated with macros to let internal calls to each $fat_function # go directly through __gmpn_cpuvec, plus macros and declarations helping to # setup that structure, on a per-directory basis ready for # mpn//fat/fat.c. # # fat.h includes thesholds listed in $fat_thresholds, extracted from # gmp-mparam.h in each directory. An overall maximum for each threshold is # established, for use in making fixed size arrays of temporary space. # (Eg. MUL_TOOM3_THRESHOLD_LIMIT used by mpn/generic/mul.c.) # # It'd be possible to do some of this manually, but when there's more than a # few functions and a few directories it becomes very tedious, and very # prone to having some routine accidentally omitted. On that basis it seems # best to automate as much as possible, even if the code to do so is a bit # ugly. # if test -n "$fat_path"; then if test "$ABI" = 64; then fat_path="$fat_path_64" fi # Usually the mpn build directory is created with mpn/Makefile # instantiation, but we want to write to it sooner. mkdir mpn 2>/dev/null echo "/* fat.h - setups for fat binaries." >fat.h echo " Generated by configure - DO NOT EDIT. */" >>fat.h AC_DEFINE(WANT_FAT_BINARY, 1, [Define to 1 when building a fat binary.]) GMP_DEFINE(WANT_FAT_BINARY, yes) # Don't want normal copies of fat functions for tmp_fn in $fat_functions; do GMP_REMOVE_FROM_LIST(gmp_mpn_functions, $tmp_fn) GMP_REMOVE_FROM_LIST(gmp_mpn_functions_optional, $tmp_fn) done for tmp_fn in $fat_functions; do GMP_FILE_TO_FUNCTION(tmp_fbase,tmp_fn) echo " #ifndef OPERATION_$tmp_fn #undef mpn_$tmp_fbase #define mpn_$tmp_fbase (*__gmpn_cpuvec.$tmp_fbase) #endif DECL_$tmp_fbase (__MPN(${tmp_fbase}_init));" >>fat.h # encourage various macros to use fat functions AC_DEFINE_UNQUOTED(HAVE_NATIVE_$tmp_fbase) done echo "" >>fat.h echo "/* variable thresholds */" >>fat.h for tmp_tn in $fat_thresholds; do echo "#undef $tmp_tn" >>fat.h echo "#define $tmp_tn CPUVEC_THRESHOLD (`echo $tmp_tn | tr '[A-Z]' '[a-z]'`)" >>fat.h done echo " /* Copy all fields into __gmpn_cpuvec. memcpy is not used because it might operate byte-wise (depending on its implemenation), and we need the function pointer writes to be atomic. "volatile" discourages the compiler from trying to optimize this. */ #define CPUVEC_INSTALL(vec) \\ do { \\ volatile struct cpuvec_t *p = &__gmpn_cpuvec; \\" >>fat.h for tmp_fn in $fat_functions; do GMP_FILE_TO_FUNCTION(tmp_fbase,tmp_fn) echo " p->$tmp_fbase = vec.$tmp_fbase; \\" >>fat.h done for tmp_tn in $fat_thresholds; do tmp_field_name=`echo $tmp_tn | tr '[[A-Z]]' '[[a-z]]'` echo " p->$tmp_field_name = vec.$tmp_field_name; \\" >>fat.h done echo " } while (0)" >>fat.h echo " /* A helper to check all fields are filled. */ #define ASSERT_CPUVEC(vec) \\ do { \\" >>fat.h for tmp_fn in $fat_functions; do GMP_FILE_TO_FUNCTION(tmp_fbase,tmp_fn) echo " ASSERT (vec.$tmp_fbase != NULL); \\" >>fat.h done for tmp_tn in $fat_thresholds; do tmp_field_name=`echo $tmp_tn | tr '[[A-Z]]' '[[a-z]]'` echo " ASSERT (vec.$tmp_field_name != 0); \\" >>fat.h done echo " } while (0)" >>fat.h echo " /* Call ITERATE(field) for each fat threshold field. */ #define ITERATE_FAT_THRESHOLDS() \\ do { \\" >>fat.h for tmp_tn in $fat_thresholds; do tmp_field_name=`echo $tmp_tn | tr '[[A-Z]]' '[[a-z]]'` echo " ITERATE ($tmp_tn, $tmp_field_name); \\" >>fat.h done echo " } while (0)" >>fat.h for tmp_dir in $fat_path; do CPUVEC_SETUP= THRESH_ASM_SETUP= echo "" >>fat.h GMP_FAT_SUFFIX(tmp_suffix, $tmp_dir) # In order to keep names unique on a DOS 8.3 filesystem, use a prefix # (rather than a suffix) for the generated file names, and abbreviate. case $tmp_suffix in pentium) tmp_prefix=p ;; pentium_mmx) tmp_prefix=pm ;; p6_mmx) tmp_prefix=p2 ;; p6_p3mmx) tmp_prefix=p3 ;; pentium4) tmp_prefix=p4 ;; pentium4_mmx) tmp_prefix=p4m ;; pentium4_sse2) tmp_prefix=p4s ;; k6_mmx) tmp_prefix=k6m ;; k6_k62mmx) tmp_prefix=k62 ;; k7_mmx) tmp_prefix=k7m ;; *) tmp_prefix=$tmp_suffix ;; esac # Extract desired thresholds from gmp-mparam.h file in this directory, # if prsent. tmp_mparam=$srcdir/mpn/$tmp_dir/gmp-mparam.h if test -f $tmp_mparam; then for tmp_tn in $fat_thresholds; do tmp_thresh=`sed -n "s/^#define $tmp_tn[ ]*\\([0-9][0-9]*\\).*$/\\1/p" $tmp_mparam` if test -n "$tmp_thresh"; then THRESH_ASM_SETUP=["${THRESH_ASM_SETUP}define($tmp_tn,$tmp_thresh) "] CPUVEC_SETUP="$CPUVEC_SETUP decided_cpuvec.`echo $tmp_tn | tr '[[A-Z]]' '[[a-z]]'` = $tmp_thresh; \\ " eval tmp_limit=\$${tmp_tn}_LIMIT if test -z "$tmp_limit"; then tmp_limit=0 fi if test $tmp_thresh -gt $tmp_limit; then eval ${tmp_tn}_LIMIT=$tmp_thresh fi fi done fi for tmp_fn in $fat_functions; do GMP_MULFUNC_CHOICES for tmp_base in $tmp_fn $tmp_mulfunc; do for tmp_ext in MPN_SUFFIXES; do tmp_file=$srcdir/mpn/$tmp_dir/$tmp_base.$tmp_ext if test -f $tmp_file; then mpn_objects="$mpn_objects ${tmp_prefix}_$tmp_fn.lo" mpn_objs_in_libgmp="$mpn_objs_in_libgmp mpn/${tmp_prefix}_$tmp_fn.lo" GMP_FILE_TO_FUNCTION(tmp_fbase,tmp_fn) # carry-in variant, eg. divrem_1c or modexact_1c_odd case $tmp_fbase in *_1*) tmp_fbasec=`echo $tmp_fbase | sed 's/_1/_1c/'` ;; *) tmp_fbasec=${tmp_fbase}c ;; esac # Create a little file doing an include from srcdir. The # OPERATION and renamings aren't all needed all the time, but # they don't hurt if unused. # # FIXME: Should generate these via config.status commands. # Would need them all in one AC_CONFIG_COMMANDS though, since # that macro doesn't accept a set of separate commands generated # by shell code. # case $tmp_ext in as) echo ["; mpn_$tmp_fbase - from $tmp_dir directory for fat binary. ; Generated by configure - DO NOT EDIT. %define OPERATION_$tmp_fn %define suffix $tmp_suffix ; For k6 and k7 gcd_1 calling their corresponding mpn_modexact_1_odd %ifdef __gmpn_modexact_1_odd %define __gmpn_modexact_1_odd __gmpn_modexact_1_odd_${tmp_suffix} %endif %include \"$mpn_relative_top_srcdir/mpn/$tmp_dir/$tmp_base.as\" "] >mpn/${tmp_prefix}_$tmp_fn.as ;; asm) # hide the d-n-l from autoconf's error checking tmp_d_n_l=d""nl echo ["$tmp_d_n_l mpn_$tmp_fbase - from $tmp_dir directory for fat binary. $tmp_d_n_l Generated by configure - DO NOT EDIT. define(OPERATION_$tmp_fn) define(__gmpn_$tmp_fbase, __gmpn_${tmp_fbase}_$tmp_suffix) define(__gmpn_$tmp_fbasec,__gmpn_${tmp_fbasec}_${tmp_suffix}) define(__gmpn_preinv_${tmp_fbase},__gmpn_preinv_${tmp_fbase}_${tmp_suffix}) $tmp_d_n_l For k6 and k7 gcd_1 calling their corresponding mpn_modexact_1_odd ifdef(\`__gmpn_modexact_1_odd',, \`define(__gmpn_modexact_1_odd,__gmpn_modexact_1_odd_${tmp_suffix})') $THRESH_ASM_SETUP include][($mpn_relative_top_srcdir/mpn/$tmp_dir/$tmp_base.asm) "] >mpn/${tmp_prefix}_$tmp_fn.asm ;; c) echo ["/* mpn_$tmp_fbase - from $tmp_dir directory for fat binary. Generated by configure - DO NOT EDIT. */ #define OPERATION_$tmp_fn 1 #define __gmpn_$tmp_fbase __gmpn_${tmp_fbase}_$tmp_suffix #define __gmpn_$tmp_fbasec __gmpn_${tmp_fbasec}_${tmp_suffix} #define __gmpn_preinv_${tmp_fbase} __gmpn_preinv_${tmp_fbase}_${tmp_suffix} #include \"$mpn_relative_top_srcdir/mpn/$tmp_dir/$tmp_base.c\" "] >mpn/${tmp_prefix}_$tmp_fn.c ;; esac # Prototype, and append to CPUVEC_SETUP for this directory. echo "DECL_$tmp_fbase (__gmpn_${tmp_fbase}_$tmp_suffix);" >>fat.h CPUVEC_SETUP="$CPUVEC_SETUP decided_cpuvec.$tmp_fbase = __gmpn_${tmp_fbase}_${tmp_suffix}; \\ " # Ditto for any preinv variant (preinv_divrem_1, preinv_mod_1). if grep "^PROLOGUE(mpn_preinv_$tmp_fn)\|GLOBAL_FUNC mpn_preinv_$tmp_fn" $tmp_file >/dev/null; then echo "DECL_preinv_$tmp_fbase (__gmpn_preinv_${tmp_fbase}_$tmp_suffix);" >>fat.h CPUVEC_SETUP="$CPUVEC_SETUP decided_cpuvec.preinv_$tmp_fbase = __gmpn_preinv_${tmp_fbase}_${tmp_suffix}; \\ " fi fi done done done # Emit CPUVEC_SETUP for this directory echo "" >>fat.h echo "#define CPUVEC_SETUP_$tmp_suffix \\" >>fat.h echo " do { \\" >>fat.h echo "$CPUVEC_SETUP } while (0)" >>fat.h done # Emit threshold limits echo "" >>fat.h for tmp_tn in $fat_thresholds; do eval tmp_limit=\$${tmp_tn}_LIMIT echo "#define ${tmp_tn}_LIMIT $tmp_limit" >>fat.h done fi # Normal binary setups. # for tmp_ext in MPN_SUFFIXES; do eval found_$tmp_ext=no done for tmp_fn in $gmp_mpn_functions; do for tmp_ext in MPN_SUFFIXES; do test "$no_create" = yes || rm -f mpn/$tmp_fn.$tmp_ext done # mpn_preinv_divrem_1 might have been provided by divrem_1.asm, likewise # mpn_preinv_mod_1 by mod_1.asm. case $tmp_fn in pre_divrem_1) if test "$HAVE_NATIVE_mpn_preinv_divrem_1" = yes; then continue; fi ;; pre_mod_1) if test "$HAVE_NATIVE_mpn_preinv_mod_1" = yes; then continue; fi ;; esac GMP_MULFUNC_CHOICES found=no for tmp_dir in $path; do for tmp_base in $tmp_fn $tmp_mulfunc; do for tmp_ext in MPN_SUFFIXES; do tmp_file=$srcdir/mpn/$tmp_dir/$tmp_base.$tmp_ext if test -f $tmp_file; then # For a nails build, check if the file supports our nail bits. # Generic code always supports all nails. # # FIXME: When a multi-function file is selected to provide one of # the nails-neutral routines, like logops_n for and_n, the # PROLOGUE grepping will create HAVE_NATIVE_mpn_ defines for # all functions in that file, even if they haven't all been # nailified. Not sure what to do about this, it's only really a # problem for logops_n, and it's not too terrible to insist those # get nailified always. # if test $GMP_NAIL_BITS != 0 && test $tmp_dir != generic; then case $tmp_fn in and_n | ior_n | xor_n | andn_n | \ copyi | copyd | \ popcount | hamdist | \ udiv | udiv_w_sdiv | umul | \ cntlz | invert_limb) # these operations are either unaffected by nails or defined # to operate on full limbs ;; *) nails=[`sed -n 's/^[ ]*NAILS_SUPPORT(\(.*\))/\1/p' $tmp_file `] for n in $nails; do case $n in *-*) n_start=`echo "$n" | sed -n 's/\(.*\)-.*/\1/p'` n_end=`echo "$n" | sed -n 's/.*-\(.*\)/\1/p'` ;; *) n_start=$n n_end=$n ;; esac if test $GMP_NAIL_BITS -ge $n_start && test $GMP_NAIL_BITS -le $n_end; then found=yes break fi done if test $found != yes; then continue fi ;; esac fi found=yes eval found_$tmp_ext=yes if test $tmp_ext = c; then tmp_u='$U' else tmp_u= fi mpn_objects="$mpn_objects $tmp_fn$tmp_u.lo" mpn_objs_in_libgmp="$mpn_objs_in_libgmp mpn/$tmp_fn$tmp_u.lo" AC_CONFIG_LINKS(mpn/$tmp_fn.$tmp_ext:mpn/$tmp_dir/$tmp_base.$tmp_ext) gmp_srclinks="$gmp_srclinks mpn/$tmp_fn.$tmp_ext" # Duplicate AC_DEFINEs are harmless, so it doesn't matter # that multi-function files get grepped here repeatedly. # The PROLOGUE pattern excludes the optional second parameter. gmp_ep=[` sed -n 's/^[ ]*MULFUNC_PROLOGUE(\(.*\))/\1/p' $tmp_file ; sed -n 's/^[ ]*PROLOGUE(\([^,]*\).*)/\1/p' $tmp_file ; sed -n 's/[^G]*GLOBAL_FUNC[[:space:]]*\(.*\)/\1/p' $tmp_file `] for gmp_tmp in $gmp_ep; do AC_DEFINE_UNQUOTED(HAVE_NATIVE_$gmp_tmp) eval HAVE_NATIVE_$gmp_tmp=yes done case $tmp_fn in sqr_basecase) sqr_basecase_source=$tmp_file ;; esac break fi done if test $found = yes; then break ; fi done if test $found = yes; then break ; fi done if test $found = no; then for tmp_optional in $gmp_mpn_functions_optional; do if test $tmp_optional = $tmp_fn; then found=yes fi done if test $found = no; then AC_MSG_ERROR([no version of $tmp_fn found in path: $path]) fi fi done # All cycle counters are .asm files currently if test -n "$SPEED_CYCLECOUNTER_OBJ"; then found_asm=yes fi dnl The following list only needs to have templates for those defines which dnl are going to be tested by the code, there's no need to have every dnl possible mpn routine. AH_VERBATIM([HAVE_NATIVE], [/* Define to 1 each of the following for which a native (ie. CPU specific) implementation of the corresponding routine exists. */ #undef HAVE_NATIVE_mpn_add_n #undef HAVE_NATIVE_mpn_add_nc #undef HAVE_NATIVE_mpn_addadd_n #undef HAVE_NATIVE_mpn_addlsh1_n #undef HAVE_NATIVE_mpn_addmul_1c #undef HAVE_NATIVE_mpn_addmul_2 #undef HAVE_NATIVE_mpn_addmul_3 #undef HAVE_NATIVE_mpn_addmul_4 #undef HAVE_NATIVE_mpn_addmul_5 #undef HAVE_NATIVE_mpn_addmul_6 #undef HAVE_NATIVE_mpn_addmul_7 #undef HAVE_NATIVE_mpn_addmul_8 #undef HAVE_NATIVE_mpn_addsub_n #undef HAVE_NATIVE_mpn_sumdiff_n #undef HAVE_NATIVE_mpn_and_n #undef HAVE_NATIVE_mpn_andn_n #undef HAVE_NATIVE_mpn_com_n #undef HAVE_NATIVE_mpn_copyd #undef HAVE_NATIVE_mpn_copyi #undef HAVE_NATIVE_mpn_divexact_1 #undef HAVE_NATIVE_mpn_divrem_euclidean_qr_1 #undef HAVE_NATIVE_mpn_divrem_euclidean_r_1 #undef HAVE_NATIVE_mpn_divrem_1 #undef HAVE_NATIVE_mpn_divrem_1c #undef HAVE_NATIVE_mpn_divrem_2 #undef HAVE_NATIVE_mpn_gcd_1 #undef HAVE_NATIVE_mpn_gcd_finda #undef HAVE_NATIVE_mpn_invert_limb #undef HAVE_NATIVE_mpn_ior_n #undef HAVE_NATIVE_mpn_iorn_n #undef HAVE_NATIVE_mpn_lshift1 #undef HAVE_NATIVE_mpn_lshiftc #undef HAVE_NATIVE_mpn_mod_1 #undef HAVE_NATIVE_mpn_mod_1c #undef HAVE_NATIVE_mpn_modexact_1_odd #undef HAVE_NATIVE_mpn_modexact_1c_odd #undef HAVE_NATIVE_mpn_mul_1c #undef HAVE_NATIVE_mpn_mul_2 #undef HAVE_NATIVE_mpn_mul_3 #undef HAVE_NATIVE_mpn_mul_4 #undef HAVE_NATIVE_mpn_mul_basecase #undef HAVE_NATIVE_mpn_nand_n #undef HAVE_NATIVE_mpn_nior_n #undef HAVE_NATIVE_mpn_preinv_divrem_1 #undef HAVE_NATIVE_mpn_preinv_mod_1 #undef HAVE_NATIVE_mpn_redc_basecase #undef HAVE_NATIVE_mpn_rsh1add_n #undef HAVE_NATIVE_mpn_rsh1sub_n #undef HAVE_NATIVE_mpn_rshift1 #undef HAVE_NATIVE_mpn_sqr_basecase #undef HAVE_NATIVE_mpn_sqr_diagonal #undef HAVE_NATIVE_mpn_sub_n #undef HAVE_NATIVE_mpn_sub_nc #undef HAVE_NATIVE_mpn_subadd_n #undef HAVE_NATIVE_mpn_sublsh1_n #undef HAVE_NATIVE_mpn_submul_1c #undef HAVE_NATIVE_mpn_umul_ppmm #undef HAVE_NATIVE_mpn_umul_ppmm_r #undef HAVE_NATIVE_mpn_udiv_qrnnd #undef HAVE_NATIVE_mpn_udiv_qrnnd_r #undef HAVE_NATIVE_mpn_xor_n #undef HAVE_NATIVE_mpn_xnor_n]) # Don't demand an m4 unless it's actually needed. if test $found_asm = yes; then GMP_PROG_M4 GMP_M4_M4WRAP_SPURIOUS else M4=m4-not-needed fi # Only do the GMP_ASM checks if there's a .S or .asm wanting them. if test $found_asm = no && test $found_S = no; then gmp_asm_syntax_testing=no fi if test "$gmp_asm_syntax_testing" != no; then GMP_ASM_TEXT GMP_ASM_DATA GMP_ASM_LABEL_SUFFIX GMP_ASM_GLOBL GMP_ASM_GLOBL_ATTR GMP_ASM_UNDERSCORE GMP_ASM_RODATA GMP_ASM_TYPE GMP_ASM_SIZE GMP_ASM_LSYM_PREFIX GMP_ASM_W32 GMP_ASM_ALIGN_LOG case $host in hppa*-*-*) # for both pa32 and pa64 GMP_INCLUDE_MPN(pa32/pa-defs.m4) ;; IA64_PATTERN) GMP_ASM_IA64_ALIGN_OK ;; M68K_PATTERN) GMP_ASM_M68K_INSTRUCTION GMP_ASM_M68K_ADDRESSING GMP_ASM_M68K_BRANCHES ;; [powerpc*-*-* | power[3-9]-*-*]) GMP_ASM_POWERPC_PIC_ALWAYS GMP_ASM_POWERPC_R_REGISTERS GMP_INCLUDE_MPN(powerpc32/powerpc-defs.m4) case $host in *-*-aix*) case $ABI in 64 | aix64) GMP_INCLUDE_MPN(powerpc64/aix.m4) ;; *) GMP_INCLUDE_MPN(powerpc32/aix.m4) ;; esac ;; *-*-linux* | *-*-*bsd*) case $ABI in mode64) GMP_INCLUDE_MPN(powerpc64/elf.m4) ;; mode32 | 32) GMP_INCLUDE_MPN(powerpc32/elf.m4) ;; esac ;; *-*-darwin*) case $ABI in mode64) GMP_INCLUDE_MPN(powerpc64/darwin.m4) ;; mode32 | 32) GMP_INCLUDE_MPN(powerpc32/darwin.m4) ;; esac ;; *) # Assume unrecognized operating system is the powerpc eABI GMP_INCLUDE_MPN(powerpc32/eabi.m4) ;; esac ;; power*-*-aix*) GMP_INCLUDE_MPN(powerpc32/aix.m4) ;; sparcv9*-*-* | ultrasparc*-*-* | sparc64-*-*) case $ABI in 64) GMP_ASM_SPARC_REGISTER ;; esac ;; X86_PATTERN | X86_64_PATTERN) GMP_ASM_ALIGN_FILL_0x90 case $ABI in 32) GMP_INCLUDE_MPN(x86/x86-defs.m4) AC_DEFINE(HAVE_HOST_CPU_FAMILY_x86) GMP_ASM_COFF_TYPE GMP_ASM_X86_GOT_UNDERSCORE GMP_ASM_X86_SHLDL_CL case $enable_profiling in prof | gprof) GMP_ASM_X86_MCOUNT ;; esac case $host in *-*-darwin*) OBJECT_FORMAT="-f macho32" ;; *) OBJECT_FORMAT="-f elf32" ;; esac ;; 64) case $host in *-*-darwin*) OBJECT_FORMAT="-f macho64" ;; *) OBJECT_FORMAT="-f elf64" ;; esac GMP_INCLUDE_MPN(x86_64/x86_64-defs.m4) ;; esac AC_SUBST(OBJECT_FORMAT) ;; esac fi # Create link for gmp-mparam.h. gmp_mparam_source= for gmp_mparam_dir in $path; do test "$no_create" = yes || rm -f gmp-mparam.h tmp_file=$srcdir/mpn/$gmp_mparam_dir/gmp-mparam.h if test -f $tmp_file; then AC_CONFIG_LINKS(gmp-mparam.h:mpn/$gmp_mparam_dir/gmp-mparam.h) gmp_srclinks="$gmp_srclinks gmp-mparam.h" gmp_mparam_source=$tmp_file break fi done if test -z "$gmp_mparam_source"; then AC_MSG_ERROR([no version of gmp-mparam.h found in path: $path]) fi # For a helpful message from tune/tuneup.c gmp_mparam_suggest=$gmp_mparam_source if test "$gmp_mparam_dir" = generic; then for i in $path; do break; done if test "$i" != generic; then gmp_mparam_suggest="new file $srcdir/mpn/$i/gmp-mparam.h" fi fi AC_DEFINE_UNQUOTED(GMP_MPARAM_H_SUGGEST, "$gmp_mparam_source", [The gmp-mparam.h file (a string) the tune program should suggest updating.]) # Copy any SQR_KARATSUBA_THRESHOLD from gmp-mparam.h to config.m4. # Some versions of sqr_basecase.asm use this. # Fat binaries do this on a per-file basis, so skip in that case. # if test -z "$fat_path"; then tmp_gmp_karatsuba_sqr_threshold=`sed -n 's/^#define SQR_KARATSUBA_THRESHOLD[ ]*\([0-9][0-9]*\).*$/\1/p' $gmp_mparam_source` if test -n "$tmp_gmp_karatsuba_sqr_threshold"; then GMP_DEFINE_RAW(["define(,<$tmp_gmp_karatsuba_sqr_threshold>)"]) fi fi # Sizes of some types, needed at preprocessing time. # # FIXME: The assumption that BITS_PER_MP_LIMB is 8*sizeof(mp_limb_t) might # be slightly rash, but it's true everwhere we know of and ought to be true # of any sensible system. In a generic C build, grepping LONG_BIT out of # might be an alternative, for maximum portability. # AC_CHECK_SIZEOF(unsigned short) AC_CHECK_SIZEOF(unsigned) AC_CHECK_SIZEOF(unsigned long) AC_CHECK_SIZEOF(mp_limb_t, , GMP_INCLUDE_GMP_H) if test "$ac_cv_sizeof_mp_limb_t" = 0; then AC_MSG_ERROR([Oops, mp_limb_t doesn't seem to work]) fi AC_SUBST(BITS_PER_MP_LIMB, `expr 8 \* $ac_cv_sizeof_mp_limb_t`) GMP_DEFINE_RAW(["define(,<$ac_cv_sizeof_unsigned>)"]) # Check compiler limb size matches gmp-mparam.h # # FIXME: Some of the cycle counter objects in the tune directory depend on # the size of ulong, it'd be possible to check that here, though a mismatch # probably wouldn't want to be fatal, none of the libmpir assembler code # depends on ulong. # mparam_bits=[`sed -n 's/^#define BITS_PER_MP_LIMB[ ][ ]*\([0-9]*\).*$/\1/p' $gmp_mparam_source`] if test -n "$mparam_bits" && test "$mparam_bits" -ne $BITS_PER_MP_LIMB; then if test "$test_CFLAGS" = set; then AC_MSG_ERROR([Oops, mp_limb_t is $BITS_PER_MP_LIMB bits, but the assembler code in this configuration expects $mparam_bits bits. You appear to have set \$CFLAGS, perhaps you also need to tell GMP the intended ABI, see "ABI and ISA" in the manual.]) else AC_MSG_ERROR([Oops, mp_limb_t is $BITS_PER_MP_LIMB bits, but the assembler code in this configuration expects $mparam_bits bits.]) fi fi GMP_DEFINE_RAW(["define(,$BITS_PER_MP_LIMB)"]) GMP_DEFINE_RAW(["define(,$GMP_NAIL_BITS)"]) GMP_DEFINE_RAW(["define(,eval(GMP_LIMB_BITS-GMP_NAIL_BITS))"]) # Exclude the mpn random functions from mpbsd since that would drag in the # top-level rand things, all of which are unnecessary for libmp. There's # other unnecessary objects too actually, if we could be bothered figuring # out exactly which they are. # mpn_objs_in_libmp= for i in $mpn_objs_in_libgmp; do case $i in *random*) ;; *) mpn_objs_in_libmp="$mpn_objs_in_libmp $i" ;; esac done AC_SUBST(mpn_objs_in_libmp) AC_SUBST(mpn_objects) AC_SUBST(mpn_objs_in_libgmp) AC_SUBST(gmp_srclinks) # A recompiled sqr_basecase for use in the tune program, if necessary. TUNE_SQR_OBJ= test -d tune || mkdir tune case $sqr_basecase_source in *.asm | *.as) sqr_max=[`sed -n 's/^def...(SQR_KARATSUBA_THRESHOLD_MAX, *\([0-9]*\))/\1/p' $sqr_basecase_source`] if test -n "$sqr_max"; then TUNE_SQR_OBJ=sqr_asm.o AC_DEFINE_UNQUOTED(TUNE_SQR_KARATSUBA_MAX,$sqr_max, [Maximum size the tune program can test for SQR_KARATSUBA_THRESHOLD]) fi cat >tune/sqr_basecase.c <tune/sqr_basecase.c <]) AC_SUBST(HAVE_STACK_T_01) # Configs for demos/calc directory # # AC_SUBST+AC_CONFIG_FILES is used for calc-config.h, rather than AC_DEFINE+ # AC_CONFIG_HEADERS, since with the latter automake (1.8) will then put the # directory (ie. demos/calc) into $(DEFAULT_INCLUDES) for every Makefile.in, # which would look very strange. # # -lcurses is required by libreadline. On a typical SVR4 style system this # normally doesn't have to be given explicitly, since libreadline.so will # have a NEEDED record for it. But if someone for some reason is using only # a static libreadline.a then we must give -lcurses. Readline (as of # version 4.3) doesn't use libtool, so we can't rely on a .la to cover # necessary dependencies. # # On a couple of systems we've seen libreadline available, but the headers # not in the default include path, so check for readline/readline.h. We've # also seen readline/history.h missing, not sure if that's just a broken # install or a very old version, but check that too. # AC_CONFIG_FILES(demos/calc/calc-config.h:demos/calc/calc-config-h.in) LIBCURSES= if test $with_readline != no; then AC_CHECK_LIB(ncurses, tputs, [LIBCURSES=-lncurses], [AC_CHECK_LIB(curses, tputs, [LIBCURSES=-lcurses])]) fi AC_SUBST(LIBCURSES) use_readline=$with_readline if test $with_readline = detect; then use_readline=no AC_CHECK_LIB(readline, readline, [AC_CHECK_HEADER(readline/readline.h, [AC_CHECK_HEADER(readline/history.h, use_readline=yes)])], , $LIBCURSES) AC_MSG_CHECKING(readline detected) AC_MSG_RESULT($use_readline) fi if test $use_readline = yes; then AC_SUBST(WITH_READLINE_01, 1) AC_SUBST(LIBREADLINE, -lreadline) else WITH_READLINE_01=0 fi AC_PROG_YACC AM_PROG_LEX # Configs for demos/expr directory # # Libtool already runs an AC_CHECK_TOOL for ranlib, but we give # AC_PROG_RANLIB anyway since automake is supposed to complain if it's not # called. (Automake 1.8.4 doesn't, at least not when the only library is in # an EXTRA_LIBRARIES.) # AC_PROG_RANLIB # Create config.m4. GMP_FINISH # Create Makefiles # FIXME: Upcoming version of autoconf/automake don't like broken lines. # Right now automake isn't accepting the new AC_CONFIG_FILES scheme. # allways configure all subdirectorys , even if there are not going to be built , AC_CONFIG_SUBDIRS([yasm]) if test $enable_fat = yes; then YASM_MAC_INC=yasm_mac.inc.fat else YASM_MAC_INC=yasm_mac.inc.nofat fi AC_CONFIG_LINKS(yasm_mac.inc:$YASM_MAC_INC) AC_OUTPUT(Makefile mpbsd/Makefile mpf/Makefile mpn/Makefile mpq/Makefile mpz/Makefile printf/Makefile scanf/Makefile cxx/Makefile tests/Makefile tests/devel/Makefile tests/mpbsd/Makefile tests/mpf/Makefile tests/mpn/Makefile tests/mpq/Makefile tests/mpz/Makefile tests/rand/Makefile tests/misc/Makefile tests/cxx/Makefile doc/Makefile tune/Makefile bench/Makefile demos/Makefile demos/calc/Makefile demos/expr/Makefile mpir.h:gmp-h.in mp.h:mp-h.in)