sqrt
double sqrt(double);
u = errcheck(sqrt(getfval(x)), "sqrt"); break;
return (realnode(sqrt(exprreal(na==0 ? field0 : getlist(&np)))));
sqrt(((smean - mean*mean) * nreceived) / (nreceived-1));
arg2 = sqrt(arg1);
struct blk *sqrt(struct blk *);
| SQRT box { sqrt($2); }
vv = 1 + sqrt(nn);
vv = 1 + sqrt(nn);
double modf(), sqrt();
vv = 1. + sqrt(nn);
extern double sqrt();
stddev = (uint_t)sqrt(sum / (double)nz) * 10;
u = sqrt(getfval(x));
sd = java.lang.Math.sqrt(sd);
info->ri_stddev = sqrt(info->ri_stddev);
return sqrt(dx*dx + dy*dy) + 0.5;
r = sqrt((float) dx1 * dx1 + (float) dy1 * dy1) + 0.5;
radius = sqrt((float)(sqr(x0 - x) + sqr(y0 - y)));
Ys = Yc = sqrt((float)(sqr(xs) + sqr(ys)));
inline float sqrt(float __X) { return __sqrtf(__X); }
inline long double sqrt(long double __X) { return __sqrtl(__X); }
extern double sqrt(double);
using std::sqrt;
return sqrt(rho_squared);
*result = sqrt(*result);
s = sqrt(z);
s = sqrt(z);
return (log(2.0 * x - one / (x + sqrt(t - one))));
return (log1p(t + sqrt(2.0 * t + t * t)));
s = sqrt(t);
w = log(2.0 * t + one / (sqrt(x * x + one) + t));
w = log1p(fabs(x) + t / (one + sqrt(one + t)));
ax += ay / (ax + sqrt(ax * ax + ay));
w = sqrt(ax * ax + ay * ay);
ax = sqrt(xh * xh + ay);
ax = sqrt(xh * yh + ay);
if (x > 1.0e40) z = (invsqrtpi*cc)/sqrt(x);
z = invsqrtpi*(u*cc-v*ss)/sqrt(x);
z = (invsqrtpi*ss)/sqrt(x);
z = invsqrtpi*(pzero(x)*ss+qzero(x)*cc)/sqrt(x);
d = (invsqrtpi*cc)/sqrt(x);
d = invsqrtpi*(pone(x)*cc-qone(x)*ss)/sqrt(x);
d = (invsqrtpi*ss)/sqrt(x);
d = invsqrtpi*(pone(x)*ss+qone(x)*cc)/sqrt(x);
b = invsqrtpi*temp/sqrt(x);
b = invsqrtpi*temp/sqrt(x);
return (sqrt(x)); /* y is 0.5 and x > 0 */
c = sqrt((x[0] + x[1]) + x[2]);
t = sqrt(t);
t = sqrt(t);
return (isqrtpi * (p0 * cc - q0 * ss) / sqrt(x));
return (isqrtpi * (p0 * ss + q0 * cc) / sqrt(x));
t = isqrtpi * (p1 * cc - q1 * ss) / sqrt(x);
return (isqrtpi * (p1 * ss + q1 * cc) / sqrt(x));
w = (float) sqrt(dx * dx + dy * dy);
ax += ay / (ax + sqrt(ax * ax + ay));
w = sqrt(ax * ax + ay * ay);
ax = sqrt(xh * xh + ay);
ax = sqrt(xh * yh + ay);
D_IM(ans) = log(x + sqrt((x - one) * (x +
D_IM(ans) = log1p(xm1 + sqrt(xm1 * (x + one)));
D_IM(ans) = y / sqrt((one + x) * (one - x));
t = sqrt((x - one) * (x + one));
t = sqrt(y);
A = sqrt(one + y * y);
R = sqrt(xp1 * xp1 + y2);
S = sqrt(xm1 * xm1 + y2);
D_RE(ans) = atan(sqrt(half * Apx * (y2 / (R +
D_RE(ans) = atan((y * sqrt(half * (Apx / (R +
D_IM(ans) = log1p(Am1 + sqrt(Am1 * (A + one)));
D_IM(ans) = log(A + sqrt(A * A - one));
D_IM(ans) = log(x + sqrt((x - one) * (x +
D_IM(ans) = log1p(xm1 + sqrt(xm1 * (x + one)));
D_IM(ans) = y / sqrt((one + x) * (one - x));
D_IM(ans) = log(x + sqrt((x - one) * (x +
D_IM(ans) = log1p((x - one) + sqrt((x - one) *
t = sqrt(y);
A = sqrt(one + y * y);
R = sqrt(xp1 * xp1 + y2);
S = sqrt(xm1 * xm1 + y2);
D_RE(ans) = atan(x / sqrt(half * Apx * (y2 /
D_RE(ans) = atan(x / (y * sqrt(half * (Apx /
D_IM(ans) = log1p(Am1 + sqrt(Am1 * (A + one)));
D_IM(ans) = log(A + sqrt(A * A - one));
D_RE(ans) = sqrt(ax);
D_IM(ans) = sqrt(ax);
t = sqrt(ax);
t = two300 * sqrt(ax + sqrt(ax * ax + y * y));
t = twom300 * sqrt(ax + sqrt(ax * ax + y * y));
t = sqrt(half * (ax + sqrt(ax * ax + ay * ay)));
t = sqrt(half * ay);
t = sqrt(half * ay + half * ax);
t = half * sqrt(two * (ay + ax));
t = sqrt(half * (ay + ax));
t = two300 * sqrt(ax + sqrt(ax * ax + y * y));
t = twom300 * sqrt(ax + sqrt(ax * ax + y * y));
t = sqrt(half * (ax + sqrt(ax * ax + ay * ay)));
dt = sqrt(0.5 * (sqrt(dx * dx + dy * dy) + dx));
info->res.val.d = sqrt(info->op1.val.d);
res = sqrt(res);
res = sqrt(res);
res = sqrt(res);
res = sqrt(res);
res = sqrt(res);
res = sqrt(res);
res0 = sqrt(res0);
extern double sqrt(double);
z0 = sqrt(x0 * (double)x0 + y0 * (double)y0);
z1 = sqrt(x1 * (double)x1 + y1 * (double)y1);
z2 = sqrt(x2 * (double)x2 + y2 * (double)y2);
z1 = sqrt(x1 * (double)x1 + y1 * (double)y1);
z0 = sqrt(x0 * (double)x0 + y0 * (double)y0);
extern double sqrt(double);
res0 = sqrt (res0); \
res0 = sqrt (res0);
res1 = sqrt (res1);
res2 = sqrt (res2);
res0 = sqrt (res0);
res1 = sqrt (res1);
extern double sqrt(double);
RETURN(sqrt(res))
*py = sqrt(res);
extern double sqrt(double);
extern double sqrt(double);
*y = sqrt(*x);
sqrt((p->sum2 - p->sum*p->sum/rCnt)/(rCnt-1.0)));