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glibc/math/test-tgmath.c
Paul Eggert 5a82c74822 Prefer https to http for gnu.org and fsf.org URLs 
Also, change sources.redhat.com to sourceware.org.
This patch was automatically generated by running the following shell
script, which uses GNU sed, and which avoids modifying files imported
from upstream:

sed -ri '
  s,(http|ftp)(://(.*\.)?(gnu|fsf|sourceware)\.org($|[^.]|\.[^a-z])),https\2,g
  s,(http|ftp)(://(.*\.)?)sources\.redhat\.com($|[^.]|\.[^a-z]),https\2sourceware.org\4,g
' \
  $(find $(git ls-files) -prune -type f \
      ! -name '*.po' \
      ! -name 'ChangeLog*' \
      ! -path COPYING ! -path COPYING.LIB \
      ! -path manual/fdl-1.3.texi ! -path manual/lgpl-2.1.texi \
      ! -path manual/texinfo.tex ! -path scripts/config.guess \
      ! -path scripts/config.sub ! -path scripts/install-sh \
      ! -path scripts/mkinstalldirs ! -path scripts/move-if-change \
      ! -path INSTALL ! -path  locale/programs/charmap-kw.h \
      ! -path po/libc.pot ! -path sysdeps/gnu/errlist.c \
      ! '(' -name configure \
            -execdir test -f configure.ac -o -f configure.in ';' ')' \
      ! '(' -name preconfigure \
            -execdir test -f preconfigure.ac ';' ')' \
      -print)

and then by running 'make dist-prepare' to regenerate files built
from the altered files, and then executing the following to cleanup:

  chmod a+x sysdeps/unix/sysv/linux/riscv/configure
  # Omit irrelevant whitespace and comment-only changes,
  # perhaps from a slightly-different Autoconf version.
  git checkout -f \
    sysdeps/csky/configure \
    sysdeps/hppa/configure \
    sysdeps/riscv/configure \
    sysdeps/unix/sysv/linux/csky/configure
  # Omit changes that caused a pre-commit check to fail like this:
  # remote: *** error: sysdeps/powerpc/powerpc64/ppc-mcount.S: trailing lines
  git checkout -f \
    sysdeps/powerpc/powerpc64/ppc-mcount.S \
    sysdeps/unix/sysv/linux/s390/s390-64/syscall.S
  # Omit change that caused a pre-commit check to fail like this:
  # remote: *** error: sysdeps/sparc/sparc64/multiarch/memcpy-ultra3.S: last line does not end in newline
  git checkout -f sysdeps/sparc/sparc64/multiarch/memcpy-ultra3.S
2019-09-07 02:43:31 -07:00

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/* Test compilation of tgmath macros.
Copyright (C) 2001-2019 Free Software Foundation, Inc.
This file is part of the GNU C Library.
Contributed by Jakub Jelinek <jakub@redhat.com> and
Ulrich Drepper <drepper@redhat.com>, 2001.
The GNU C 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 GNU C 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 GNU C Library; if not, see
<https://www.gnu.org/licenses/>. */
#ifndef HAVE_MAIN
#undef __NO_MATH_INLINES
#define __NO_MATH_INLINES 1
#include <float.h>
#include <math.h>
#include <stdint.h>
#include <stdio.h>
#include <tgmath.h>
//#define DEBUG
static void compile_test (void);
static void compile_testf (void);
#if LDBL_MANT_DIG > DBL_MANT_DIG
static void compile_testl (void);
#endif
float fx;
double dx;
long double lx;
const float fy = 1.25;
const double dy = 1.25;
const long double ly = 1.25;
complex float fz;
complex double dz;
complex long double lz;
volatile int count_double;
volatile int count_float;
volatile int count_ldouble;
volatile int count_cdouble;
volatile int count_cfloat;
volatile int count_cldouble;
#define NCALLS 132
#define NCALLS_INT 4
#define NCCALLS 47
static int
do_test (void)
{
int result = 0;
count_float = count_double = count_ldouble = 0;
count_cfloat = count_cdouble = count_cldouble = 0;
compile_test ();
if (count_float != 0 || count_cfloat != 0)
{
puts ("float function called for double test");
result = 1;
}
if (count_ldouble != 0 || count_cldouble != 0)
{
puts ("long double function called for double test");
result = 1;
}
if (count_double < NCALLS + NCALLS_INT)
{
printf ("double functions not called often enough (%d)\n",
count_double);
result = 1;
}
else if (count_double > NCALLS + NCALLS_INT)
{
printf ("double functions called too often (%d)\n",
count_double);
result = 1;
}
if (count_cdouble < NCCALLS)
{
printf ("double complex functions not called often enough (%d)\n",
count_cdouble);
result = 1;
}
else if (count_cdouble > NCCALLS)
{
printf ("double complex functions called too often (%d)\n",
count_cdouble);
result = 1;
}
count_float = count_double = count_ldouble = 0;
count_cfloat = count_cdouble = count_cldouble = 0;
compile_testf ();
if (count_double != 0 || count_cdouble != 0)
{
puts ("double function called for float test");
result = 1;
}
if (count_ldouble != 0 || count_cldouble != 0)
{
puts ("long double function called for float test");
result = 1;
}
if (count_float < NCALLS)
{
printf ("float functions not called often enough (%d)\n", count_float);
result = 1;
}
else if (count_float > NCALLS)
{
printf ("float functions called too often (%d)\n",
count_double);
result = 1;
}
if (count_cfloat < NCCALLS)
{
printf ("float complex functions not called often enough (%d)\n",
count_cfloat);
result = 1;
}
else if (count_cfloat > NCCALLS)
{
printf ("float complex functions called too often (%d)\n",
count_cfloat);
result = 1;
}
#if LDBL_MANT_DIG > DBL_MANT_DIG
count_float = count_double = count_ldouble = 0;
count_cfloat = count_cdouble = count_cldouble = 0;
compile_testl ();
if (count_float != 0 || count_cfloat != 0)
{
puts ("float function called for long double test");
result = 1;
}
if (count_double != 0 || count_cdouble != 0)
{
puts ("double function called for long double test");
result = 1;
}
if (count_ldouble < NCALLS)
{
printf ("long double functions not called often enough (%d)\n",
count_ldouble);
result = 1;
}
else if (count_ldouble > NCALLS)
{
printf ("long double functions called too often (%d)\n",
count_double);
result = 1;
}
if (count_cldouble < NCCALLS)
{
printf ("long double complex functions not called often enough (%d)\n",
count_cldouble);
result = 1;
}
else if (count_cldouble > NCCALLS)
{
printf ("long double complex functions called too often (%d)\n",
count_cldouble);
result = 1;
}
#endif
return result;
}
/* Now generate the three functions. */
#define HAVE_MAIN
#define F(name) name
#define TYPE double
#define TEST_INT 1
#define x dx
#define y dy
#define z dz
#define count count_double
#define ccount count_cdouble
#include "test-tgmath.c"
#define F(name) name##f
#define TYPE float
#define x fx
#define y fy
#define z fz
#define count count_float
#define ccount count_cfloat
#include "test-tgmath.c"
#if LDBL_MANT_DIG > DBL_MANT_DIG
#define F(name) name##l
#define TYPE long double
#define x lx
#define y ly
#define z lz
#define count count_ldouble
#define ccount count_cldouble
#include "test-tgmath.c"
#endif
#define TEST_FUNCTION do_test ()
#include "../test-skeleton.c"
#else
#ifdef DEBUG
#define P() puts (__FUNCTION__)
#else
#define P()
#endif
static void
F(compile_test) (void)
{
TYPE a, b, c = 1.0;
complex TYPE d;
int i = 2;
int saved_count;
long int j;
long long int k;
intmax_t m;
uintmax_t um;
a = cos (cos (x));
b = acos (acos (a));
a = sin (sin (x));
b = asin (asin (a));
a = tan (tan (x));
b = atan (atan (a));
c = atan2 (atan2 (a, c), atan2 (b, x));
a = cosh (cosh (x));
b = acosh (acosh (a));
a = sinh (sinh (x));
b = asinh (asinh (a));
a = tanh (tanh (x));
b = atanh (atanh (a));
a = exp (exp (x));
b = log (log (a));
a = log10 (log10 (x));
b = ldexp (ldexp (a, 1), 5);
a = frexp (frexp (x, &i), &i);
b = expm1 (expm1 (a));
a = log1p (log1p (x));
b = logb (logb (a));
a = exp2 (exp2 (x));
b = log2 (log2 (a));
a = pow (pow (x, a), pow (c, b));
b = sqrt (sqrt (a));
a = hypot (hypot (x, b), hypot (c, a));
b = cbrt (cbrt (a));
a = ceil (ceil (x));
b = fabs (fabs (a));
a = floor (floor (x));
b = fmod (fmod (a, b), fmod (c, x));
a = nearbyint (nearbyint (x));
b = round (round (a));
c = roundeven (roundeven (a));
a = trunc (trunc (x));
b = remquo (remquo (a, b, &i), remquo (c, x, &i), &i);
j = lrint (x) + lround (a);
k = llrint (b) + llround (c);
m = fromfp (a, FP_INT_UPWARD, 2) + fromfpx (b, FP_INT_DOWNWARD, 3);
um = ufromfp (c, FP_INT_TONEAREST, 4) + ufromfpx (a, FP_INT_TOWARDZERO, 5);
a = erf (erf (x));
b = erfc (erfc (a));
a = tgamma (tgamma (x));
b = lgamma (lgamma (a));
a = rint (rint (x));
b = nextafter (nextafter (a, b), nextafter (c, x));
a = nextdown (nextdown (a));
b = nexttoward (nexttoward (x, a), c);
a = nextup (nextup (a));
b = remainder (remainder (a, b), remainder (c, x));
a = scalb (scalb (x, a), (TYPE) (6));
k = scalbn (a, 7) + scalbln (c, 10l);
i = ilogb (x);
j = llogb (x);
a = fdim (fdim (x, a), fdim (c, b));
b = fmax (fmax (a, x), fmax (c, b));
a = fmin (fmin (x, a), fmin (c, b));
b = fmaxmag (fmaxmag (a, x), fmaxmag (c, b));
a = fminmag (fminmag (x, a), fminmag (c, b));
b = fma (sin (a), sin (x), sin (c));
#ifdef TEST_INT
a = atan2 (i, b);
b = remquo (i, a, &i);
c = fma (i, b, i);
a = pow (i, c);
#endif
x = a + b + c + i + j + k + m + um;
saved_count = count;
if (ccount != 0)
ccount = -10000;
d = cos (cos (z));
z = acos (acos (d));
d = sin (sin (z));
z = asin (asin (d));
d = tan (tan (z));
z = atan (atan (d));
d = cosh (cosh (z));
z = acosh (acosh (d));
d = sinh (sinh (z));
z = asinh (asinh (d));
d = tanh (tanh (z));
z = atanh (atanh (d));
d = exp (exp (z));
z = log (log (d));
d = sqrt (sqrt (z));
z = conj (conj (d));
d = fabs (conj (a));
z = pow (pow (a, d), pow (b, z));
d = cproj (cproj (z));
z += fabs (cproj (a));
a = carg (carg (z));
b = creal (creal (d));
c = cimag (cimag (z));
x += a + b + c + i + j + k;
z += d;
if (saved_count != count)
count = -10000;
if (0)
{
a = cos (y);
a = acos (y);
a = sin (y);
a = asin (y);
a = tan (y);
a = atan (y);
a = atan2 (y, y);
a = cosh (y);
a = acosh (y);
a = sinh (y);
a = asinh (y);
a = tanh (y);
a = atanh (y);
a = exp (y);
a = log (y);
a = log10 (y);
a = ldexp (y, 5);
a = frexp (y, &i);
a = expm1 (y);
a = log1p (y);
a = logb (y);
a = exp2 (y);
a = log2 (y);
a = pow (y, y);
a = sqrt (y);
a = hypot (y, y);
a = cbrt (y);
a = ceil (y);
a = fabs (y);
a = floor (y);
a = fmod (y, y);
a = nearbyint (y);
a = round (y);
a = roundeven (y);
a = trunc (y);
a = remquo (y, y, &i);
j = lrint (y) + lround (y);
k = llrint (y) + llround (y);
m = fromfp (y, FP_INT_UPWARD, 6) + fromfpx (y, FP_INT_DOWNWARD, 7);
um = (ufromfp (y, FP_INT_TONEAREST, 8)
+ ufromfpx (y, FP_INT_TOWARDZERO, 9));
a = erf (y);
a = erfc (y);
a = tgamma (y);
a = lgamma (y);
a = rint (y);
a = nextafter (y, y);
a = nexttoward (y, y);
a = remainder (y, y);
a = scalb (y, (const TYPE) (6));
k = scalbn (y, 7) + scalbln (y, 10l);
i = ilogb (y);
j = llogb (y);
a = fdim (y, y);
a = fmax (y, y);
a = fmin (y, y);
a = fmaxmag (y, y);
a = fminmag (y, y);
a = fma (y, y, y);
#ifdef TEST_INT
a = atan2 (i, y);
a = remquo (i, y, &i);
a = fma (i, y, i);
a = pow (i, y);
#endif
d = cos ((const complex TYPE) z);
d = acos ((const complex TYPE) z);
d = sin ((const complex TYPE) z);
d = asin ((const complex TYPE) z);
d = tan ((const complex TYPE) z);
d = atan ((const complex TYPE) z);
d = cosh ((const complex TYPE) z);
d = acosh ((const complex TYPE) z);
d = sinh ((const complex TYPE) z);
d = asinh ((const complex TYPE) z);
d = tanh ((const complex TYPE) z);
d = atanh ((const complex TYPE) z);
d = exp ((const complex TYPE) z);
d = log ((const complex TYPE) z);
d = sqrt ((const complex TYPE) z);
d = pow ((const complex TYPE) z, (const complex TYPE) z);
d = fabs ((const complex TYPE) z);
d = carg ((const complex TYPE) z);
d = creal ((const complex TYPE) z);
d = cimag ((const complex TYPE) z);
d = conj ((const complex TYPE) z);
d = cproj ((const complex TYPE) z);
}
}
#undef x
#undef y
#undef z
TYPE
(F(cos)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(acos)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(sin)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(asin)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(tan)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(atan)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(atan2)) (TYPE x, TYPE y)
{
++count;
P ();
return x + y;
}
TYPE
(F(cosh)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(acosh)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(sinh)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(asinh)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(tanh)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(atanh)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(exp)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(log)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(log10)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(ldexp)) (TYPE x, int y)
{
++count;
P ();
return x + y;
}
TYPE
(F(frexp)) (TYPE x, int *y)
{
++count;
P ();
return x + *y;
}
TYPE
(F(expm1)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(log1p)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(logb)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(exp2)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(log2)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(pow)) (TYPE x, TYPE y)
{
++count;
P ();
return x + y;
}
TYPE
(F(sqrt)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(hypot)) (TYPE x, TYPE y)
{
++count;
P ();
return x + y;
}
TYPE
(F(cbrt)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(ceil)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(fabs)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(floor)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(fmod)) (TYPE x, TYPE y)
{
++count;
P ();
return x + y;
}
TYPE
(F(nearbyint)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(round)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(roundeven)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(trunc)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(remquo)) (TYPE x, TYPE y, int *i)
{
++count;
P ();
return x + y + *i;
}
long int
(F(lrint)) (TYPE x)
{
++count;
P ();
return x;
}
long int
(F(lround)) (TYPE x)
{
++count;
P ();
return x;
}
long long int
(F(llrint)) (TYPE x)
{
++count;
P ();
return x;
}
long long int
(F(llround)) (TYPE x)
{
++count;
P ();
return x;
}
intmax_t
(F(fromfp)) (TYPE x, int round, unsigned int width)
{
++count;
P ();
return x;
}
intmax_t
(F(fromfpx)) (TYPE x, int round, unsigned int width)
{
++count;
P ();
return x;
}
uintmax_t
(F(ufromfp)) (TYPE x, int round, unsigned int width)
{
++count;
P ();
return x;
}
uintmax_t
(F(ufromfpx)) (TYPE x, int round, unsigned int width)
{
++count;
P ();
return x;
}
TYPE
(F(erf)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(erfc)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(tgamma)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(lgamma)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(rint)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(nextafter)) (TYPE x, TYPE y)
{
++count;
P ();
return x + y;
}
TYPE
(F(nextdown)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(nexttoward)) (TYPE x, long double y)
{
++count;
P ();
return x + y;
}
TYPE
(F(nextup)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(remainder)) (TYPE x, TYPE y)
{
++count;
P ();
return x + y;
}
TYPE
(F(scalb)) (TYPE x, TYPE y)
{
++count;
P ();
return x + y;
}
TYPE
(F(scalbn)) (TYPE x, int y)
{
++count;
P ();
return x + y;
}
TYPE
(F(scalbln)) (TYPE x, long int y)
{
++count;
P ();
return x + y;
}
int
(F(ilogb)) (TYPE x)
{
++count;
P ();
return x;
}
long int
(F(llogb)) (TYPE x)
{
++count;
P ();
return x;
}
TYPE
(F(fdim)) (TYPE x, TYPE y)
{
++count;
P ();
return x + y;
}
TYPE
(F(fmin)) (TYPE x, TYPE y)
{
++count;
P ();
return x + y;
}
TYPE
(F(fmax)) (TYPE x, TYPE y)
{
++count;
P ();
return x + y;
}
TYPE
(F(fminmag)) (TYPE x, TYPE y)
{
++count;
P ();
return x + y;
}
TYPE
(F(fmaxmag)) (TYPE x, TYPE y)
{
++count;
P ();
return x + y;
}
TYPE
(F(fma)) (TYPE x, TYPE y, TYPE z)
{
++count;
P ();
return x + y + z;
}
complex TYPE
(F(cacos)) (complex TYPE x)
{
++ccount;
P ();
return x;
}
complex TYPE
(F(casin)) (complex TYPE x)
{
++ccount;
P ();
return x;
}
complex TYPE
(F(catan)) (complex TYPE x)
{
++ccount;
P ();
return x;
}
complex TYPE
(F(ccos)) (complex TYPE x)
{
++ccount;
P ();
return x;
}
complex TYPE
(F(csin)) (complex TYPE x)
{
++ccount;
P ();
return x;
}
complex TYPE
(F(ctan)) (complex TYPE x)
{
++ccount;
P ();
return x;
}
complex TYPE
(F(cacosh)) (complex TYPE x)
{
++ccount;
P ();
return x;
}
complex TYPE
(F(casinh)) (complex TYPE x)
{
++ccount;
P ();
return x;
}
complex TYPE
(F(catanh)) (complex TYPE x)
{
++ccount;
P ();
return x;
}
complex TYPE
(F(ccosh)) (complex TYPE x)
{
++ccount;
P ();
return x;
}
complex TYPE
(F(csinh)) (complex TYPE x)
{
++ccount;
P ();
return x;
}
complex TYPE
(F(ctanh)) (complex TYPE x)
{
++ccount;
P ();
return x;
}
complex TYPE
(F(cexp)) (complex TYPE x)
{
++ccount;
P ();
return x;
}
complex TYPE
(F(clog)) (complex TYPE x)
{
++ccount;
P ();
return x;
}
complex TYPE
(F(csqrt)) (complex TYPE x)
{
++ccount;
P ();
return x;
}
complex TYPE
(F(cpow)) (complex TYPE x, complex TYPE y)
{
++ccount;
P ();
return x + y;
}
TYPE
(F(cabs)) (complex TYPE x)
{
++ccount;
P ();
return x;
}
TYPE
(F(carg)) (complex TYPE x)
{
++ccount;
P ();
return x;
}
TYPE
(F(creal)) (complex TYPE x)
{
++ccount;
P ();
return __real__ x;
}
TYPE
(F(cimag)) (complex TYPE x)
{
++ccount;
P ();
return __imag__ x;
}
complex TYPE
(F(conj)) (complex TYPE x)
{
++ccount;
P ();
return x;
}
complex TYPE
(F(cproj)) (complex TYPE x)
{
++ccount;
P ();
return x;
}
#undef F
#undef TYPE
#undef count
#undef ccount
#undef TEST_INT
#endif
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