fabs
if (fabs(Player.p_level - Other.p_level) > 20.0)
&& (dtemp = fabs(Player.p_x)) == fabs(Player.p_y)
if (fabs(Player.p_x) > D_EXPER || fabs(Player.p_y) > D_EXPER)
if (Beyond && fabs(xnew) < D_BEYOND && fabs(ynew) < D_BEYOND)
if (fabs(xnew) > fabs(ynew))
xnew = SGN(Player.p_x) * MAX(fabs(Player.p_x), D_BEYOND);
ynew = SGN(Player.p_y) * MAX(fabs(Player.p_y), D_BEYOND);
else if (MAX(fabs(Player.p_x), fabs(Player.p_y)) >= D_BEYOND)
if (MAX(fabs(playerp->p_x), fabs(playerp->p_y)) > D_BEYOND)
size = sqrt(fabs(Player.p_x / 100)) + 1;
bigger = fabs(dx);
dist = fabs(dy);
bigger = fabs(dx);
x = fabs(dy);
double fabs(double);
#define fabs(x) __tg_impl_full(x, x, x, fabs, fabsf, fabsl, \
__strong_alias(fabsl, fabs);
__strong_alias(fabsl, fabs);
__strong_alias(fabsl, fabs);
__strong_alias(fabsl, fabs);
__strong_alias(fabsl, fabs);
__strong_alias(fabsl, fabs);
__strong_alias(fabsl, fabs);
w = one-fabs(x);
else z=atan(fabs(y/x)); /* safe to do y/x */
t = expm1(fabs(x));
t = exp(fabs(x));
if (ix < 0x40862E42) return half*exp(fabs(x));
w = exp(half*fabs(x));
x = fabs(x);
y = fabs(x);
tmp = tmp*log(fabs(v*tmp));
x = fabs(x);
nadj = log(pi/fabs(t*x));
ax = fabs(x);
t = fabs(x);
x = fabs(x);
p = fabs(p);
t = expm1(fabs(x));
if (ix < 0x40862E42) return h*exp(fabs(x));
w = exp(0.5*fabs(x));
return one / fabs(x);
w = log(fabs(x))+ln2;
t = fabs(x);
w =log1p(fabs(x)+t/(one+sqrt(one+t)));
x = fabs(x);
if (fabs(x) > 1.0) {
if (fabs(x) <= 0.5) {
if (fabs(x) <= 0.5) {
if ((fabs(x) > 4.0) || (fabs(y) > 4.0)) {
r = scale * fabs((0.5 * y) / t);
t = scale * fabs( (0.5 * y) / r );
r = fabs (x);
r = fabs (y);
while (fabs(t/d) > MACHEP)
if (fabs(d) < 0.25)
x = fabs (2.0 * creal (z));
y = fabs (2.0 * cimag(z));
s = fabs(x)-one;
x = fabs(x);
s = fabs(x)-one;
x = fabs(x);
if((ix|lx)==0) return -1.0/fabs(x);
y = fabs(y);
t = expm1(two*fabs(x));
t = expm1(-two*fabs(x));
if (fabs (err) > ((OKERROR + test1[i].thresh) * MACHEP))
if (fabs (err) > ((OKERROR + test1[i].thresh) * MACHEP))
double fabs (double);
{"fabs", fabs, &ONE, &ONE, 0},
{"fabs", fabs, &MONE, &ONE, 0},
{"fabs", fabs, &ZERO, &ZERO, 0},
{"fabs", fabs, &MZERO, &ZERO, 0},
{"fabs", fabs, &INF, &INF, 0},
{"fabs", fabs, &MINF, &INF, 0},
double fabs (double);
q->err2 = fabs(t);
q->err1 = fabs(t);
assert(fabs(lgamma(3.0) - M_LN2) < DBL_EPSILON && signgam == 1);
ATF_CHECK(fabs(sinf(f_pi_odd[i])) < FLT_EPSILON);
ATF_CHECK(fabs(tan(f_pi_odd[i])) < FLT_EPSILON);
ATF_CHECK(fabs(sinf(-f_pi_odd[i])) < FLT_EPSILON);
ATF_CHECK(fabs(tanf(-f_pi_odd[i])) < FLT_EPSILON);
ATF_CHECK(fabs(sinf(f_pi_odd[i] * 2)) < FLT_EPSILON);
ATF_CHECK(fabs(tanf(f_pi_odd[i] * 2)) < FLT_EPSILON);
ATF_CHECK(fabs(sinf(-f_pi_odd[i] * 2)) < FLT_EPSILON);
ATF_CHECK(fabs(tanf(-f_pi_odd[i] * 2)) < FLT_EPSILON);
ATF_CHECK(fabs(sin(d_pi_odd[i])) < 2 * DBL_EPSILON);
ATF_CHECK(fabs(tan(d_pi_odd[i])) < 2 * DBL_EPSILON);
ATF_CHECK(fabs(sin(-d_pi_odd[i])) < 2 * DBL_EPSILON);
ATF_CHECK(fabs(tan(-d_pi_odd[i])) < 2 * DBL_EPSILON);
ATF_CHECK(fabs(sin(d_pi_odd[i] * 2)) < 2 * DBL_EPSILON);
ATF_CHECK(fabs(tan(d_pi_odd[i] * 2)) < 2 * DBL_EPSILON);
ATF_CHECK(fabs(sin(-d_pi_odd[i] * 2)) < 2 * DBL_EPSILON);
ATF_CHECK(fabs(tan(-d_pi_odd[i] * 2)) < 2 * DBL_EPSILON);
if (fabs(x) > DBL_EPSILON)
error = fabs(target / (estimate - target));
error = fabs(1 / (estimate - target));
if (fabs(aa1 - aa2) < epsilon)
if (fabs(aa1 - aa2) >= epsilon)
result = fabs(mleft - mright) < 1e-9;
result = fabs(mleft - mright) > 1e-9;
diff = fabs(val - gettime_from_timeval(&tv));