kc3-lang/gnulib/m4/fmaf.m4

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• Hash : 0569df14
  Author :
  Date : 2012-03-08T12:33:36
  

  fma, fmaf, fmal: Override undeclared system functions on IRIX 6.5.
  
  * m4/fma.m4 (gl_FUNC_FMA): If fma() exists but is not declared,
  arrange to set REPLACE_FMA=1, not HAVE_FMA=0.
  * m4/fmaf.m4 (gl_FUNC_FMAF): If fmaf() exists but is not declared,
  arrange to set REPLACE_FMAF=1, not HAVE_FMAF=0.
  * m4/fmal.m4 (gl_FUNC_FMAL): If fmal() exists but is not declared,
  arrange to set REPLACE_FMAL=1, not HAVE_FMAL=0.
  

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• m4/fmaf.m4

• # fmaf.m4 serial 3
  dnl Copyright (C) 2011-2012 Free Software Foundation, Inc.
  dnl This file is free software; the Free Software Foundation
  dnl gives unlimited permission to copy and/or distribute it,
  dnl with or without modifications, as long as this notice is preserved.
  
  AC_DEFUN([gl_FUNC_FMAF],
  [
    AC_REQUIRE([gl_MATH_H_DEFAULTS])
  
    dnl Persuade glibc <math.h> to declare fmaf().
    AC_REQUIRE([gl_USE_SYSTEM_EXTENSIONS])
  
    dnl Determine FMAF_LIBM.
    gl_MATHFUNC([fmaf], [float], [(float, float, float)],
      [extern
       #ifdef __cplusplus
       "C"
       #endif
       float fmaf (float, float, float);
      ])
    if test $gl_cv_func_fmaf_no_libm = yes \
       || test $gl_cv_func_fmaf_in_libm = yes; then
      dnl Also check whether it's declared.
      dnl IRIX 6.5 has fmaf() in libm but doesn't declare it in <math.h>,
      dnl and the function is likely buggy.
      AC_CHECK_DECL([fmaf], , [REPLACE_FMAF=1], [[#include <math.h>]])
      if test $REPLACE_FMAF = 0; then
        gl_FUNC_FMAF_WORKS
        case "$gl_cv_func_fmaf_works" in
          *no) REPLACE_FMAF=1 ;;
        esac
      fi
    else
      HAVE_FMAF=0
    fi
    if test $HAVE_FMAF = 0 || test $REPLACE_FMAF = 1; then
      dnl Find libraries needed to link lib/fmaf.c.
      AC_REQUIRE([gl_FUNC_FREXPF])
      AC_REQUIRE([gl_FUNC_LDEXPF])
      AC_REQUIRE([gl_FUNC_FEGETROUND])
      FMAF_LIBM=
      dnl Append $FREXPF_LIBM to FMAF_LIBM, avoiding gratuitous duplicates.
      case " $FMAF_LIBM " in
        *" $FREXPF_LIBM "*) ;;
        *) FMAF_LIBM="$FMAF_LIBM $FREXPF_LIBM" ;;
      esac
      dnl Append $LDEXPF_LIBM to FMAF_LIBM, avoiding gratuitous duplicates.
      case " $FMAF_LIBM " in
        *" $LDEXPF_LIBM "*) ;;
        *) FMAF_LIBM="$FMAF_LIBM $LDEXPF_LIBM" ;;
      esac
      dnl Append $FEGETROUND_LIBM to FMAF_LIBM, avoiding gratuitous duplicates.
      case " $FMAF_LIBM " in
        *" $FEGETROUND_LIBM "*) ;;
        *) FMAF_LIBM="$FMAF_LIBM $FEGETROUND_LIBM" ;;
      esac
    fi
    AC_SUBST([FMAF_LIBM])
  ])
  
  dnl Test whether fmaf() has any of the 7 known bugs of glibc 2.11.3 on x86_64.
  AC_DEFUN([gl_FUNC_FMAF_WORKS],
  [
    AC_REQUIRE([AC_PROG_CC])
    AC_REQUIRE([AC_CANONICAL_HOST]) dnl for cross-compiles
    AC_REQUIRE([gl_FUNC_LDEXPF])
    save_LIBS="$LIBS"
    LIBS="$LIBS $FMAF_LIBM $LDEXPF_LIBM"
    AC_CACHE_CHECK([whether fmaf works], [gl_cv_func_fmaf_works],
      [
        AC_RUN_IFELSE(
          [AC_LANG_SOURCE([[
  #include <float.h>
  #include <math.h>
  float p0 = 0.0f;
  int main()
  {
    int failed_tests = 0;
    /* These tests fail with glibc 2.11.3 on x86_64.  */
    {
      volatile float x = 1.5f; /* 3 * 2^-1 */
      volatile float y = x;
      volatile float z = ldexpf (1.0f, FLT_MANT_DIG + 1); /* 2^25 */
      /* x * y + z with infinite precision: 2^25 + 9 * 2^-2.
         Lies between (2^23 + 0) * 2^2 and (2^23 + 1) * 2^2
         and is closer to (2^23 + 1) * 2^2, therefore the rounding
         must round up and produce (2^23 + 1) * 2^2.  */
      volatile float expected = z + 4.0f;
      volatile float result = fmaf (x, y, z);
      if (result != expected)
        failed_tests |= 1;
    }
    {
      volatile float x = 1.25f; /* 2^0 + 2^-2 */
      volatile float y = - x;
      volatile float z = ldexpf (1.0f, FLT_MANT_DIG + 1); /* 2^25 */
      /* x * y + z with infinite precision: 2^25 - 2^0 - 2^-1 - 2^-4.
         Lies between (2^24 - 1) * 2^1 and 2^24 * 2^1
         and is closer to (2^24 - 1) * 2^1, therefore the rounding
         must round down and produce (2^24 - 1) * 2^1.  */
      volatile float expected = (ldexpf (1.0f, FLT_MANT_DIG) - 1.0f) * 2.0f;
      volatile float result = fmaf (x, y, z);
      if (result != expected)
        failed_tests |= 2;
    }
    {
      volatile float x = 1.0f + ldexpf (1.0f, 1 - FLT_MANT_DIG); /* 2^0 + 2^-23 */
      volatile float y = x;
      volatile float z = 4.0f; /* 2^2 */
      /* x * y + z with infinite precision: 2^2 + 2^0 + 2^-22 + 2^-46.
         Lies between (2^23 + 2^21) * 2^-21 and (2^23 + 2^21 + 1) * 2^-21
         and is closer to (2^23 + 2^21 + 1) * 2^-21, therefore the rounding
         must round up and produce (2^23 + 2^21 + 1) * 2^-21.  */
      volatile float expected = 4.0f + 1.0f + ldexpf (1.0f, 3 - FLT_MANT_DIG);
      volatile float result = fmaf (x, y, z);
      if (result != expected)
        failed_tests |= 4;
    }
    {
      volatile float x = 1.0f + ldexpf (1.0f, 1 - FLT_MANT_DIG); /* 2^0 + 2^-23 */
      volatile float y = - x;
      volatile float z = 8.0f; /* 2^3 */
      /* x * y + z with infinite precision: 2^2 + 2^1 + 2^0 - 2^-22 - 2^-46.
         Lies between (2^23 + 2^22 + 2^21 - 1) * 2^-21 and
         (2^23 + 2^22 + 2^21) * 2^-21 and is closer to
         (2^23 + 2^22 + 2^21 - 1) * 2^-21, therefore the rounding
         must round down and produce (2^23 + 2^22 + 2^21 - 1) * 2^-21.  */
      volatile float expected = 7.0f - ldexpf (1.0f, 3 - FLT_MANT_DIG);
      volatile float result = fmaf (x, y, z);
      if (result != expected)
        failed_tests |= 8;
    }
    {
      volatile float x = 1.25f; /* 2^0 + 2^-2 */
      volatile float y = - 0.75f; /* - 2^0 + 2^-2 */
      volatile float z = ldexpf (1.0f, FLT_MANT_DIG); /* 2^24 */
      /* x * y + z with infinite precision: 2^24 - 2^0 + 2^-4.
         Lies between (2^24 - 2^0) and 2^24 and is closer to (2^24 - 2^0),
         therefore the rounding must round down and produce (2^24 - 2^0).  */
      volatile float expected = ldexpf (1.0f, FLT_MANT_DIG) - 1.0f;
      volatile float result = fmaf (x, y, z);
      if (result != expected)
        failed_tests |= 16;
    }
    if ((FLT_MANT_DIG % 2) == 0)
      {
        volatile float x = 1.0f + ldexpf (1.0f, - FLT_MANT_DIG / 2); /* 2^0 + 2^-12 */
        volatile float y = x;
        volatile float z = ldexpf (1.0f, FLT_MIN_EXP - FLT_MANT_DIG); /* 2^-149 */
        /* x * y + z with infinite precision: 2^0 + 2^-11 + 2^-24 + 2^-149.
           Lies between (2^23 + 2^12 + 0) * 2^-23 and (2^23 + 2^12 + 1) * 2^-23
           and is closer to (2^23 + 2^12 + 1) * 2^-23, therefore the rounding
           must round up and produce (2^23 + 2^12 + 1) * 2^-23.  */
        volatile float expected =
          1.0f + ldexpf (1.0f, 1 - FLT_MANT_DIG / 2) + ldexpf (1.0f, 1 - FLT_MANT_DIG);
        volatile float result = fmaf (x, y, z);
        if (result != expected)
          failed_tests |= 32;
      }
    {
      float minus_inf = -1.0f / p0;
      volatile float x = ldexpf (1.0f, FLT_MAX_EXP - 1);
      volatile float y = ldexpf (1.0f, FLT_MAX_EXP - 1);
      volatile float z = minus_inf;
      volatile float result = fmaf (x, y, z);
      if (!(result == minus_inf))
        failed_tests |= 64;
    }
    return failed_tests;
  }]])],
          [gl_cv_func_fmaf_works=yes],
          [gl_cv_func_fmaf_works=no],
          [dnl Guess no, even on glibc systems.
           gl_cv_func_fmaf_works="guessing no"
          ])
      ])
    LIBS="$save_LIBS"
  ])
  
  # Prerequisites of lib/fmaf.c.
  AC_DEFUN([gl_PREREQ_FMAF], [:])
  

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