mirror of
https://gitee.com/he3db/he3pg.git
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657 lines
24 KiB
Plaintext
657 lines
24 KiB
Plaintext
# Macros to detect C compiler features
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# config/c-compiler.m4
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# PGAC_PRINTF_ARCHETYPE
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# ---------------------
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# Select the format archetype to be used by gcc to check printf-type functions.
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# We prefer "gnu_printf", as that most closely matches the features supported
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# by src/port/snprintf.c (particularly the %m conversion spec). However,
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# on some NetBSD versions, that doesn't work while "__syslog__" does.
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# If all else fails, use "printf".
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AC_DEFUN([PGAC_PRINTF_ARCHETYPE],
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[AC_CACHE_CHECK([for printf format archetype], pgac_cv_printf_archetype,
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[pgac_cv_printf_archetype=gnu_printf
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PGAC_TEST_PRINTF_ARCHETYPE
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if [[ "$ac_archetype_ok" = no ]]; then
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pgac_cv_printf_archetype=__syslog__
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PGAC_TEST_PRINTF_ARCHETYPE
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if [[ "$ac_archetype_ok" = no ]]; then
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pgac_cv_printf_archetype=printf
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fi
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fi])
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AC_DEFINE_UNQUOTED([PG_PRINTF_ATTRIBUTE], [$pgac_cv_printf_archetype],
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[Define to best printf format archetype, usually gnu_printf if available.])
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])# PGAC_PRINTF_ARCHETYPE
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# Subroutine: test $pgac_cv_printf_archetype, set $ac_archetype_ok to yes or no
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AC_DEFUN([PGAC_TEST_PRINTF_ARCHETYPE],
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[ac_save_c_werror_flag=$ac_c_werror_flag
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ac_c_werror_flag=yes
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AC_COMPILE_IFELSE([AC_LANG_PROGRAM(
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[extern void pgac_write(int ignore, const char *fmt,...)
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__attribute__((format($pgac_cv_printf_archetype, 2, 3)));],
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[pgac_write(0, "error %s: %m", "foo");])],
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[ac_archetype_ok=yes],
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[ac_archetype_ok=no])
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ac_c_werror_flag=$ac_save_c_werror_flag
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])# PGAC_TEST_PRINTF_ARCHETYPE
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# PGAC_TYPE_64BIT_INT(TYPE)
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# -------------------------
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# Check if TYPE is a working 64 bit integer type. Set HAVE_TYPE_64 to
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# yes or no respectively, and define HAVE_TYPE_64 if yes.
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AC_DEFUN([PGAC_TYPE_64BIT_INT],
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[define([Ac_define], [translit([have_$1_64], [a-z *], [A-Z_P])])dnl
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define([Ac_cachevar], [translit([pgac_cv_type_$1_64], [ *], [_p])])dnl
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AC_CACHE_CHECK([whether $1 is 64 bits], [Ac_cachevar],
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[AC_RUN_IFELSE([AC_LANG_SOURCE(
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[typedef $1 ac_int64;
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/*
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* These are globals to discourage the compiler from folding all the
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* arithmetic tests down to compile-time constants.
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*/
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ac_int64 a = 20000001;
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ac_int64 b = 40000005;
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int does_int64_work()
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{
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ac_int64 c,d;
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if (sizeof(ac_int64) != 8)
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return 0; /* definitely not the right size */
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/* Do perfunctory checks to see if 64-bit arithmetic seems to work */
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c = a * b;
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d = (c + b) / b;
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if (d != a+1)
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return 0;
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return 1;
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}
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int
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main() {
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return (! does_int64_work());
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}])],
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[Ac_cachevar=yes],
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[Ac_cachevar=no],
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[# If cross-compiling, check the size reported by the compiler and
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# trust that the arithmetic works.
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AC_COMPILE_IFELSE([AC_LANG_BOOL_COMPILE_TRY([], [sizeof($1) == 8])],
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Ac_cachevar=yes,
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Ac_cachevar=no)])])
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Ac_define=$Ac_cachevar
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if test x"$Ac_cachevar" = xyes ; then
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AC_DEFINE(Ac_define, 1, [Define to 1 if `]$1[' works and is 64 bits.])
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fi
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undefine([Ac_define])dnl
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undefine([Ac_cachevar])dnl
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])# PGAC_TYPE_64BIT_INT
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# PGAC_TYPE_128BIT_INT
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# --------------------
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# Check if __int128 is a working 128 bit integer type, and if so
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# define PG_INT128_TYPE to that typename, and define ALIGNOF_PG_INT128_TYPE
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# as its alignment requirement.
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#
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# This currently only detects a GCC/clang extension, but support for other
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# environments may be added in the future.
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#
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# For the moment we only test for support for 128bit math; support for
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# 128bit literals and snprintf is not required.
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AC_DEFUN([PGAC_TYPE_128BIT_INT],
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[AC_CACHE_CHECK([for __int128], [pgac_cv__128bit_int],
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[AC_LINK_IFELSE([AC_LANG_PROGRAM([
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/*
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* We don't actually run this test, just link it to verify that any support
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* functions needed for __int128 are present.
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*
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* These are globals to discourage the compiler from folding all the
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* arithmetic tests down to compile-time constants. We do not have
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* convenient support for 128bit literals at this point...
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*/
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__int128 a = 48828125;
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__int128 b = 97656250;
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],[
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__int128 c,d;
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a = (a << 12) + 1; /* 200000000001 */
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b = (b << 12) + 5; /* 400000000005 */
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/* try the most relevant arithmetic ops */
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c = a * b;
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d = (c + b) / b;
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/* must use the results, else compiler may optimize arithmetic away */
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if (d != a+1)
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return 1;
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])],
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[pgac_cv__128bit_int=yes],
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[pgac_cv__128bit_int=no])])
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if test x"$pgac_cv__128bit_int" = xyes ; then
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# Use of non-default alignment with __int128 tickles bugs in some compilers.
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# If not cross-compiling, we can test for bugs and disable use of __int128
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# with buggy compilers. If cross-compiling, hope for the best.
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# https://gcc.gnu.org/bugzilla/show_bug.cgi?id=83925
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AC_CACHE_CHECK([for __int128 alignment bug], [pgac_cv__128bit_int_bug],
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[AC_RUN_IFELSE([AC_LANG_PROGRAM([
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/* This must match the corresponding code in c.h: */
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#if defined(__GNUC__) || defined(__SUNPRO_C) || defined(__IBMC__)
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#define pg_attribute_aligned(a) __attribute__((aligned(a)))
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#endif
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typedef __int128 int128a
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#if defined(pg_attribute_aligned)
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pg_attribute_aligned(8)
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#endif
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;
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int128a holder;
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void pass_by_val(void *buffer, int128a par) { holder = par; }
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],[
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long int i64 = 97656225L << 12;
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int128a q;
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pass_by_val(main, (int128a) i64);
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q = (int128a) i64;
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if (q != holder)
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return 1;
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])],
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[pgac_cv__128bit_int_bug=ok],
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[pgac_cv__128bit_int_bug=broken],
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[pgac_cv__128bit_int_bug="assuming ok"])])
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if test x"$pgac_cv__128bit_int_bug" != xbroken ; then
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AC_DEFINE(PG_INT128_TYPE, __int128, [Define to the name of a signed 128-bit integer type.])
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AC_CHECK_ALIGNOF(PG_INT128_TYPE)
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fi
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fi])# PGAC_TYPE_128BIT_INT
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# PGAC_C_FUNCNAME_SUPPORT
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# -----------------------
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# Check if the C compiler understands __func__ (C99) or __FUNCTION__ (gcc).
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# Define HAVE_FUNCNAME__FUNC or HAVE_FUNCNAME__FUNCTION accordingly.
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AC_DEFUN([PGAC_C_FUNCNAME_SUPPORT],
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[AC_CACHE_CHECK(for __func__, pgac_cv_funcname_func_support,
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[AC_COMPILE_IFELSE([AC_LANG_PROGRAM([#include <stdio.h>],
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[printf("%s\n", __func__);])],
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[pgac_cv_funcname_func_support=yes],
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[pgac_cv_funcname_func_support=no])])
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if test x"$pgac_cv_funcname_func_support" = xyes ; then
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AC_DEFINE(HAVE_FUNCNAME__FUNC, 1,
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[Define to 1 if your compiler understands __func__.])
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else
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AC_CACHE_CHECK(for __FUNCTION__, pgac_cv_funcname_function_support,
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[AC_COMPILE_IFELSE([AC_LANG_PROGRAM([#include <stdio.h>],
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[printf("%s\n", __FUNCTION__);])],
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[pgac_cv_funcname_function_support=yes],
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[pgac_cv_funcname_function_support=no])])
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if test x"$pgac_cv_funcname_function_support" = xyes ; then
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AC_DEFINE(HAVE_FUNCNAME__FUNCTION, 1,
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[Define to 1 if your compiler understands __FUNCTION__.])
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fi
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fi])# PGAC_C_FUNCNAME_SUPPORT
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# PGAC_C_STATIC_ASSERT
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# --------------------
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# Check if the C compiler understands _Static_assert(),
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# and define HAVE__STATIC_ASSERT if so.
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#
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# We actually check the syntax ({ _Static_assert(...) }), because we need
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# gcc-style compound expressions to be able to wrap the thing into macros.
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AC_DEFUN([PGAC_C_STATIC_ASSERT],
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[AC_CACHE_CHECK(for _Static_assert, pgac_cv__static_assert,
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[AC_LINK_IFELSE([AC_LANG_PROGRAM([],
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[({ _Static_assert(1, "foo"); })])],
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[pgac_cv__static_assert=yes],
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[pgac_cv__static_assert=no])])
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if test x"$pgac_cv__static_assert" = xyes ; then
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AC_DEFINE(HAVE__STATIC_ASSERT, 1,
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[Define to 1 if your compiler understands _Static_assert.])
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fi])# PGAC_C_STATIC_ASSERT
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# PGAC_C_TYPEOF
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# -------------
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# Check if the C compiler understands typeof or a variant. Define
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# HAVE_TYPEOF if so, and define 'typeof' to the actual key word.
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#
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AC_DEFUN([PGAC_C_TYPEOF],
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[AC_CACHE_CHECK(for typeof, pgac_cv_c_typeof,
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[pgac_cv_c_typeof=no
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for pgac_kw in typeof __typeof__ decltype; do
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AC_COMPILE_IFELSE([AC_LANG_PROGRAM([],
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[int x = 0;
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$pgac_kw(x) y;
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y = x;
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return y;])],
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[pgac_cv_c_typeof=$pgac_kw])
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test "$pgac_cv_c_typeof" != no && break
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done])
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if test "$pgac_cv_c_typeof" != no; then
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AC_DEFINE(HAVE_TYPEOF, 1,
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[Define to 1 if your compiler understands `typeof' or something similar.])
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if test "$pgac_cv_c_typeof" != typeof; then
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AC_DEFINE_UNQUOTED(typeof, $pgac_cv_c_typeof, [Define to how the compiler spells `typeof'.])
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fi
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fi])# PGAC_C_TYPEOF
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# PGAC_C_TYPES_COMPATIBLE
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# -----------------------
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# Check if the C compiler understands __builtin_types_compatible_p,
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# and define HAVE__BUILTIN_TYPES_COMPATIBLE_P if so.
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#
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# We check usage with __typeof__, though it's unlikely any compiler would
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# have the former and not the latter.
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AC_DEFUN([PGAC_C_TYPES_COMPATIBLE],
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[AC_CACHE_CHECK(for __builtin_types_compatible_p, pgac_cv__types_compatible,
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[AC_COMPILE_IFELSE([AC_LANG_PROGRAM([],
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[[ int x; static int y[__builtin_types_compatible_p(__typeof__(x), int)]; ]])],
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[pgac_cv__types_compatible=yes],
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[pgac_cv__types_compatible=no])])
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if test x"$pgac_cv__types_compatible" = xyes ; then
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AC_DEFINE(HAVE__BUILTIN_TYPES_COMPATIBLE_P, 1,
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[Define to 1 if your compiler understands __builtin_types_compatible_p.])
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fi])# PGAC_C_TYPES_COMPATIBLE
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# PGAC_C_BUILTIN_CONSTANT_P
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# -------------------------
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# Check if the C compiler understands __builtin_constant_p(),
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# and define HAVE__BUILTIN_CONSTANT_P if so.
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# We need __builtin_constant_p("string literal") to be true, but some older
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# compilers don't think that, so test for that case explicitly.
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AC_DEFUN([PGAC_C_BUILTIN_CONSTANT_P],
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[AC_CACHE_CHECK(for __builtin_constant_p, pgac_cv__builtin_constant_p,
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[AC_COMPILE_IFELSE([AC_LANG_SOURCE(
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[[static int x;
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static int y[__builtin_constant_p(x) ? x : 1];
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static int z[__builtin_constant_p("string literal") ? 1 : x];
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]]
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)],
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[pgac_cv__builtin_constant_p=yes],
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[pgac_cv__builtin_constant_p=no])])
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if test x"$pgac_cv__builtin_constant_p" = xyes ; then
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AC_DEFINE(HAVE__BUILTIN_CONSTANT_P, 1,
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[Define to 1 if your compiler understands __builtin_constant_p.])
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fi])# PGAC_C_BUILTIN_CONSTANT_P
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# PGAC_C_BUILTIN_OP_OVERFLOW
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# --------------------------
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# Check if the C compiler understands __builtin_$op_overflow(),
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# and define HAVE__BUILTIN_OP_OVERFLOW if so.
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#
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# Check for the most complicated case, 64 bit multiplication, as a
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# proxy for all of the operations. To detect the case where the compiler
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# knows the function but library support is missing, we must link not just
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# compile, and store the results in global variables so the compiler doesn't
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# optimize away the call.
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AC_DEFUN([PGAC_C_BUILTIN_OP_OVERFLOW],
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[AC_CACHE_CHECK(for __builtin_mul_overflow, pgac_cv__builtin_op_overflow,
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[AC_LINK_IFELSE([AC_LANG_PROGRAM([
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PG_INT64_TYPE a = 1;
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PG_INT64_TYPE b = 1;
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PG_INT64_TYPE result;
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int oflo;
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],
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[oflo = __builtin_mul_overflow(a, b, &result);])],
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[pgac_cv__builtin_op_overflow=yes],
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[pgac_cv__builtin_op_overflow=no])])
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if test x"$pgac_cv__builtin_op_overflow" = xyes ; then
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AC_DEFINE(HAVE__BUILTIN_OP_OVERFLOW, 1,
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[Define to 1 if your compiler understands __builtin_$op_overflow.])
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fi])# PGAC_C_BUILTIN_OP_OVERFLOW
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# PGAC_C_BUILTIN_UNREACHABLE
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# --------------------------
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# Check if the C compiler understands __builtin_unreachable(),
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# and define HAVE__BUILTIN_UNREACHABLE if so.
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#
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# NB: Don't get the idea of putting a for(;;); or such before the
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# __builtin_unreachable() call. Some compilers would remove it before linking
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# and only a warning instead of an error would be produced.
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AC_DEFUN([PGAC_C_BUILTIN_UNREACHABLE],
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[AC_CACHE_CHECK(for __builtin_unreachable, pgac_cv__builtin_unreachable,
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[AC_LINK_IFELSE([AC_LANG_PROGRAM([],
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[__builtin_unreachable();])],
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[pgac_cv__builtin_unreachable=yes],
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[pgac_cv__builtin_unreachable=no])])
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if test x"$pgac_cv__builtin_unreachable" = xyes ; then
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AC_DEFINE(HAVE__BUILTIN_UNREACHABLE, 1,
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[Define to 1 if your compiler understands __builtin_unreachable.])
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fi])# PGAC_C_BUILTIN_UNREACHABLE
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# PGAC_C_COMPUTED_GOTO
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# --------------------
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# Check if the C compiler knows computed gotos (gcc extension, also
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# available in at least clang). If so, define HAVE_COMPUTED_GOTO.
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#
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# Checking whether computed gotos are supported syntax-wise ought to
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# be enough, as the syntax is otherwise illegal.
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AC_DEFUN([PGAC_C_COMPUTED_GOTO],
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[AC_CACHE_CHECK(for computed goto support, pgac_cv_computed_goto,
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[AC_COMPILE_IFELSE([AC_LANG_PROGRAM([],
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[[void *labeladdrs[] = {&&my_label};
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goto *labeladdrs[0];
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my_label:
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return 1;
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]])],
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[pgac_cv_computed_goto=yes],
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[pgac_cv_computed_goto=no])])
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if test x"$pgac_cv_computed_goto" = xyes ; then
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AC_DEFINE(HAVE_COMPUTED_GOTO, 1,
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[Define to 1 if your compiler handles computed gotos.])
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fi])# PGAC_C_COMPUTED_GOTO
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# PGAC_CHECK_BUILTIN_FUNC
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# -----------------------
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# This is similar to AC_CHECK_FUNCS(), except that it will work for compiler
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# builtin functions, as that usually fails to.
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# The first argument is the function name, eg [__builtin_clzl], and the
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# second is its argument list, eg [unsigned long x]. The current coding
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# works only for a single argument named x; we might generalize that later.
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# It's assumed that the function's result type is coercible to int.
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# On success, we define "HAVEfuncname" (there's usually more than enough
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# underscores already, so we don't add another one).
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AC_DEFUN([PGAC_CHECK_BUILTIN_FUNC],
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[AC_CACHE_CHECK(for $1, pgac_cv$1,
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[AC_LINK_IFELSE([AC_LANG_PROGRAM([
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int
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call$1($2)
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{
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return $1(x);
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}], [])],
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[pgac_cv$1=yes],
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[pgac_cv$1=no])])
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if test x"${pgac_cv$1}" = xyes ; then
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AC_DEFINE_UNQUOTED(AS_TR_CPP([HAVE$1]), 1,
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[Define to 1 if your compiler understands $1.])
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fi])# PGAC_CHECK_BUILTIN_FUNC
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# PGAC_PROG_VARCC_VARFLAGS_OPT
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# ----------------------------
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# Given a compiler, variable name and a string, check if the compiler
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# supports the string as a command-line option. If it does, add the
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# string to the given variable.
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AC_DEFUN([PGAC_PROG_VARCC_VARFLAGS_OPT],
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[define([Ac_cachevar], [AS_TR_SH([pgac_cv_prog_$1_cflags_$3])])dnl
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AC_CACHE_CHECK([whether ${$1} supports $3, for $2], [Ac_cachevar],
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[pgac_save_CFLAGS=$CFLAGS
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pgac_save_CC=$CC
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CC=${$1}
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CFLAGS="${$2} $3"
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ac_save_c_werror_flag=$ac_c_werror_flag
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ac_c_werror_flag=yes
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_AC_COMPILE_IFELSE([AC_LANG_PROGRAM()],
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[Ac_cachevar=yes],
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[Ac_cachevar=no])
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ac_c_werror_flag=$ac_save_c_werror_flag
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CFLAGS="$pgac_save_CFLAGS"
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CC="$pgac_save_CC"])
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if test x"$Ac_cachevar" = x"yes"; then
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$2="${$2} $3"
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fi
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undefine([Ac_cachevar])dnl
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])# PGAC_PROG_VARCC_VARFLAGS_OPT
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# PGAC_PROG_CC_CFLAGS_OPT
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# -----------------------
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# Given a string, check if the compiler supports the string as a
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# command-line option. If it does, add the string to CFLAGS.
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AC_DEFUN([PGAC_PROG_CC_CFLAGS_OPT], [
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PGAC_PROG_VARCC_VARFLAGS_OPT(CC, CFLAGS, $1)
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])# PGAC_PROG_CC_CFLAGS_OPT
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# PGAC_PROG_CC_VAR_OPT
|
|
# --------------------
|
|
# Given a variable name and a string, check if the compiler supports
|
|
# the string as a command-line option. If it does, add the string to
|
|
# the given variable.
|
|
AC_DEFUN([PGAC_PROG_CC_VAR_OPT],
|
|
[PGAC_PROG_VARCC_VARFLAGS_OPT(CC, $1, $2)
|
|
])# PGAC_PROG_CC_VAR_OPT
|
|
|
|
|
|
|
|
# PGAC_PROG_VARCXX_VARFLAGS_OPT
|
|
# -----------------------------
|
|
# Given a compiler, variable name and a string, check if the compiler
|
|
# supports the string as a command-line option. If it does, add the
|
|
# string to the given variable.
|
|
AC_DEFUN([PGAC_PROG_VARCXX_VARFLAGS_OPT],
|
|
[define([Ac_cachevar], [AS_TR_SH([pgac_cv_prog_$1_cxxflags_$3])])dnl
|
|
AC_CACHE_CHECK([whether ${$1} supports $3, for $2], [Ac_cachevar],
|
|
[pgac_save_CXXFLAGS=$CXXFLAGS
|
|
pgac_save_CXX=$CXX
|
|
CXX=${$1}
|
|
CXXFLAGS="${$2} $3"
|
|
ac_save_cxx_werror_flag=$ac_cxx_werror_flag
|
|
ac_cxx_werror_flag=yes
|
|
AC_LANG_PUSH(C++)
|
|
_AC_COMPILE_IFELSE([AC_LANG_PROGRAM()],
|
|
[Ac_cachevar=yes],
|
|
[Ac_cachevar=no])
|
|
AC_LANG_POP([])
|
|
ac_cxx_werror_flag=$ac_save_cxx_werror_flag
|
|
CXXFLAGS="$pgac_save_CXXFLAGS"
|
|
CXX="$pgac_save_CXX"])
|
|
if test x"$Ac_cachevar" = x"yes"; then
|
|
$2="${$2} $3"
|
|
fi
|
|
undefine([Ac_cachevar])dnl
|
|
])# PGAC_PROG_VARCXX_VARFLAGS_OPT
|
|
|
|
|
|
|
|
# PGAC_PROG_CXX_CFLAGS_OPT
|
|
# ------------------------
|
|
# Given a string, check if the compiler supports the string as a
|
|
# command-line option. If it does, add the string to CXXFLAGS.
|
|
AC_DEFUN([PGAC_PROG_CXX_CFLAGS_OPT],
|
|
[PGAC_PROG_VARCXX_VARFLAGS_OPT(CXX, CXXFLAGS, $1)
|
|
])# PGAC_PROG_CXX_CFLAGS_OPT
|
|
|
|
|
|
|
|
# PGAC_PROG_CC_LDFLAGS_OPT
|
|
# ------------------------
|
|
# Given a string, check if the compiler supports the string as a
|
|
# command-line option. If it does, add the string to LDFLAGS.
|
|
# For reasons you'd really rather not know about, this checks whether
|
|
# you can link to a particular function, not just whether you can link.
|
|
# In fact, we must actually check that the resulting program runs :-(
|
|
AC_DEFUN([PGAC_PROG_CC_LDFLAGS_OPT],
|
|
[define([Ac_cachevar], [AS_TR_SH([pgac_cv_prog_cc_ldflags_$1])])dnl
|
|
AC_CACHE_CHECK([whether $CC supports $1], [Ac_cachevar],
|
|
[pgac_save_LDFLAGS=$LDFLAGS
|
|
LDFLAGS="$pgac_save_LDFLAGS $1"
|
|
AC_RUN_IFELSE([AC_LANG_PROGRAM([extern void $2 (); void (*fptr) () = $2;],[])],
|
|
[Ac_cachevar=yes],
|
|
[Ac_cachevar=no],
|
|
[Ac_cachevar="assuming no"])
|
|
LDFLAGS="$pgac_save_LDFLAGS"])
|
|
if test x"$Ac_cachevar" = x"yes"; then
|
|
LDFLAGS="$LDFLAGS $1"
|
|
fi
|
|
undefine([Ac_cachevar])dnl
|
|
])# PGAC_PROG_CC_LDFLAGS_OPT
|
|
|
|
# PGAC_HAVE_GCC__SYNC_CHAR_TAS
|
|
# ----------------------------
|
|
# Check if the C compiler understands __sync_lock_test_and_set(char),
|
|
# and define HAVE_GCC__SYNC_CHAR_TAS
|
|
#
|
|
# NB: There are platforms where test_and_set is available but compare_and_swap
|
|
# is not, so test this separately.
|
|
# NB: Some platforms only do 32bit tas, others only do 8bit tas. Test both.
|
|
AC_DEFUN([PGAC_HAVE_GCC__SYNC_CHAR_TAS],
|
|
[AC_CACHE_CHECK(for builtin __sync char locking functions, pgac_cv_gcc_sync_char_tas,
|
|
[AC_LINK_IFELSE([AC_LANG_PROGRAM([],
|
|
[char lock = 0;
|
|
__sync_lock_test_and_set(&lock, 1);
|
|
__sync_lock_release(&lock);])],
|
|
[pgac_cv_gcc_sync_char_tas="yes"],
|
|
[pgac_cv_gcc_sync_char_tas="no"])])
|
|
if test x"$pgac_cv_gcc_sync_char_tas" = x"yes"; then
|
|
AC_DEFINE(HAVE_GCC__SYNC_CHAR_TAS, 1, [Define to 1 if you have __sync_lock_test_and_set(char *) and friends.])
|
|
fi])# PGAC_HAVE_GCC__SYNC_CHAR_TAS
|
|
|
|
# PGAC_HAVE_GCC__SYNC_INT32_TAS
|
|
# -----------------------------
|
|
# Check if the C compiler understands __sync_lock_test_and_set(),
|
|
# and define HAVE_GCC__SYNC_INT32_TAS
|
|
AC_DEFUN([PGAC_HAVE_GCC__SYNC_INT32_TAS],
|
|
[AC_CACHE_CHECK(for builtin __sync int32 locking functions, pgac_cv_gcc_sync_int32_tas,
|
|
[AC_LINK_IFELSE([AC_LANG_PROGRAM([],
|
|
[int lock = 0;
|
|
__sync_lock_test_and_set(&lock, 1);
|
|
__sync_lock_release(&lock);])],
|
|
[pgac_cv_gcc_sync_int32_tas="yes"],
|
|
[pgac_cv_gcc_sync_int32_tas="no"])])
|
|
if test x"$pgac_cv_gcc_sync_int32_tas" = x"yes"; then
|
|
AC_DEFINE(HAVE_GCC__SYNC_INT32_TAS, 1, [Define to 1 if you have __sync_lock_test_and_set(int *) and friends.])
|
|
fi])# PGAC_HAVE_GCC__SYNC_INT32_TAS
|
|
|
|
# PGAC_HAVE_GCC__SYNC_INT32_CAS
|
|
# -----------------------------
|
|
# Check if the C compiler understands __sync_compare_and_swap() for 32bit
|
|
# types, and define HAVE_GCC__SYNC_INT32_CAS if so.
|
|
AC_DEFUN([PGAC_HAVE_GCC__SYNC_INT32_CAS],
|
|
[AC_CACHE_CHECK(for builtin __sync int32 atomic operations, pgac_cv_gcc_sync_int32_cas,
|
|
[AC_LINK_IFELSE([AC_LANG_PROGRAM([],
|
|
[int val = 0;
|
|
__sync_val_compare_and_swap(&val, 0, 37);])],
|
|
[pgac_cv_gcc_sync_int32_cas="yes"],
|
|
[pgac_cv_gcc_sync_int32_cas="no"])])
|
|
if test x"$pgac_cv_gcc_sync_int32_cas" = x"yes"; then
|
|
AC_DEFINE(HAVE_GCC__SYNC_INT32_CAS, 1, [Define to 1 if you have __sync_val_compare_and_swap(int *, int, int).])
|
|
fi])# PGAC_HAVE_GCC__SYNC_INT32_CAS
|
|
|
|
# PGAC_HAVE_GCC__SYNC_INT64_CAS
|
|
# -----------------------------
|
|
# Check if the C compiler understands __sync_compare_and_swap() for 64bit
|
|
# types, and define HAVE_GCC__SYNC_INT64_CAS if so.
|
|
AC_DEFUN([PGAC_HAVE_GCC__SYNC_INT64_CAS],
|
|
[AC_CACHE_CHECK(for builtin __sync int64 atomic operations, pgac_cv_gcc_sync_int64_cas,
|
|
[AC_LINK_IFELSE([AC_LANG_PROGRAM([],
|
|
[PG_INT64_TYPE lock = 0;
|
|
__sync_val_compare_and_swap(&lock, 0, (PG_INT64_TYPE) 37);])],
|
|
[pgac_cv_gcc_sync_int64_cas="yes"],
|
|
[pgac_cv_gcc_sync_int64_cas="no"])])
|
|
if test x"$pgac_cv_gcc_sync_int64_cas" = x"yes"; then
|
|
AC_DEFINE(HAVE_GCC__SYNC_INT64_CAS, 1, [Define to 1 if you have __sync_val_compare_and_swap(int64 *, int64, int64).])
|
|
fi])# PGAC_HAVE_GCC__SYNC_INT64_CAS
|
|
|
|
# PGAC_HAVE_GCC__ATOMIC_INT32_CAS
|
|
# -------------------------------
|
|
# Check if the C compiler understands __atomic_compare_exchange_n() for 32bit
|
|
# types, and define HAVE_GCC__ATOMIC_INT32_CAS if so.
|
|
AC_DEFUN([PGAC_HAVE_GCC__ATOMIC_INT32_CAS],
|
|
[AC_CACHE_CHECK(for builtin __atomic int32 atomic operations, pgac_cv_gcc_atomic_int32_cas,
|
|
[AC_LINK_IFELSE([AC_LANG_PROGRAM([],
|
|
[int val = 0;
|
|
int expect = 0;
|
|
__atomic_compare_exchange_n(&val, &expect, 37, 0, __ATOMIC_SEQ_CST, __ATOMIC_RELAXED);])],
|
|
[pgac_cv_gcc_atomic_int32_cas="yes"],
|
|
[pgac_cv_gcc_atomic_int32_cas="no"])])
|
|
if test x"$pgac_cv_gcc_atomic_int32_cas" = x"yes"; then
|
|
AC_DEFINE(HAVE_GCC__ATOMIC_INT32_CAS, 1, [Define to 1 if you have __atomic_compare_exchange_n(int *, int *, int).])
|
|
fi])# PGAC_HAVE_GCC__ATOMIC_INT32_CAS
|
|
|
|
# PGAC_HAVE_GCC__ATOMIC_INT64_CAS
|
|
# -------------------------------
|
|
# Check if the C compiler understands __atomic_compare_exchange_n() for 64bit
|
|
# types, and define HAVE_GCC__ATOMIC_INT64_CAS if so.
|
|
AC_DEFUN([PGAC_HAVE_GCC__ATOMIC_INT64_CAS],
|
|
[AC_CACHE_CHECK(for builtin __atomic int64 atomic operations, pgac_cv_gcc_atomic_int64_cas,
|
|
[AC_LINK_IFELSE([AC_LANG_PROGRAM([],
|
|
[PG_INT64_TYPE val = 0;
|
|
PG_INT64_TYPE expect = 0;
|
|
__atomic_compare_exchange_n(&val, &expect, 37, 0, __ATOMIC_SEQ_CST, __ATOMIC_RELAXED);])],
|
|
[pgac_cv_gcc_atomic_int64_cas="yes"],
|
|
[pgac_cv_gcc_atomic_int64_cas="no"])])
|
|
if test x"$pgac_cv_gcc_atomic_int64_cas" = x"yes"; then
|
|
AC_DEFINE(HAVE_GCC__ATOMIC_INT64_CAS, 1, [Define to 1 if you have __atomic_compare_exchange_n(int64 *, int64 *, int64).])
|
|
fi])# PGAC_HAVE_GCC__ATOMIC_INT64_CAS
|
|
|
|
# PGAC_SSE42_CRC32_INTRINSICS
|
|
# ---------------------------
|
|
# Check if the compiler supports the x86 CRC instructions added in SSE 4.2,
|
|
# using the _mm_crc32_u8 and _mm_crc32_u32 intrinsic functions. (We don't
|
|
# test the 8-byte variant, _mm_crc32_u64, but it is assumed to be present if
|
|
# the other ones are, on x86-64 platforms)
|
|
#
|
|
# An optional compiler flag can be passed as argument (e.g. -msse4.2). If the
|
|
# intrinsics are supported, sets pgac_sse42_crc32_intrinsics, and CFLAGS_SSE42.
|
|
AC_DEFUN([PGAC_SSE42_CRC32_INTRINSICS],
|
|
[define([Ac_cachevar], [AS_TR_SH([pgac_cv_sse42_crc32_intrinsics_$1])])dnl
|
|
AC_CACHE_CHECK([for _mm_crc32_u8 and _mm_crc32_u32 with CFLAGS=$1], [Ac_cachevar],
|
|
[pgac_save_CFLAGS=$CFLAGS
|
|
CFLAGS="$pgac_save_CFLAGS $1"
|
|
AC_LINK_IFELSE([AC_LANG_PROGRAM([#include <nmmintrin.h>],
|
|
[unsigned int crc = 0;
|
|
crc = _mm_crc32_u8(crc, 0);
|
|
crc = _mm_crc32_u32(crc, 0);
|
|
/* return computed value, to prevent the above being optimized away */
|
|
return crc == 0;])],
|
|
[Ac_cachevar=yes],
|
|
[Ac_cachevar=no])
|
|
CFLAGS="$pgac_save_CFLAGS"])
|
|
if test x"$Ac_cachevar" = x"yes"; then
|
|
CFLAGS_SSE42="$1"
|
|
pgac_sse42_crc32_intrinsics=yes
|
|
fi
|
|
undefine([Ac_cachevar])dnl
|
|
])# PGAC_SSE42_CRC32_INTRINSICS
|
|
|
|
|
|
# PGAC_ARMV8_CRC32C_INTRINSICS
|
|
# ----------------------------
|
|
# Check if the compiler supports the CRC32C instructions using the __crc32cb,
|
|
# __crc32ch, __crc32cw, and __crc32cd intrinsic functions. These instructions
|
|
# were first introduced in ARMv8 in the optional CRC Extension, and became
|
|
# mandatory in ARMv8.1.
|
|
#
|
|
# An optional compiler flag can be passed as argument (e.g.
|
|
# -march=armv8-a+crc). If the intrinsics are supported, sets
|
|
# pgac_armv8_crc32c_intrinsics, and CFLAGS_ARMV8_CRC32C.
|
|
AC_DEFUN([PGAC_ARMV8_CRC32C_INTRINSICS],
|
|
[define([Ac_cachevar], [AS_TR_SH([pgac_cv_armv8_crc32c_intrinsics_$1])])dnl
|
|
AC_CACHE_CHECK([for __crc32cb, __crc32ch, __crc32cw, and __crc32cd with CFLAGS=$1], [Ac_cachevar],
|
|
[pgac_save_CFLAGS=$CFLAGS
|
|
CFLAGS="$pgac_save_CFLAGS $1"
|
|
AC_LINK_IFELSE([AC_LANG_PROGRAM([#include <arm_acle.h>],
|
|
[unsigned int crc = 0;
|
|
crc = __crc32cb(crc, 0);
|
|
crc = __crc32ch(crc, 0);
|
|
crc = __crc32cw(crc, 0);
|
|
crc = __crc32cd(crc, 0);
|
|
/* return computed value, to prevent the above being optimized away */
|
|
return crc == 0;])],
|
|
[Ac_cachevar=yes],
|
|
[Ac_cachevar=no])
|
|
CFLAGS="$pgac_save_CFLAGS"])
|
|
if test x"$Ac_cachevar" = x"yes"; then
|
|
CFLAGS_ARMV8_CRC32C="$1"
|
|
pgac_armv8_crc32c_intrinsics=yes
|
|
fi
|
|
undefine([Ac_cachevar])dnl
|
|
])# PGAC_ARMV8_CRC32C_INTRINSICS
|