1 /* origin: FreeBSD /usr/src/lib/msun/src/s_ctanh.c */
3 * Copyright (c) 2011 David Schultz
6 * Redistribution and use in source and binary forms, with or without
7 * modification, are permitted provided that the following conditions
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28 * Hyperbolic tangent of a complex argument z = x + i y.
30 * The algorithm is from:
32 * W. Kahan. Branch Cuts for Complex Elementary Functions or Much
33 * Ado About Nothing's Sign Bit. In The State of the Art in
34 * Numerical Analysis, pp. 165 ff. Iserles and Powell, eds., 1987.
45 * tanh(z) = sinh(z) / cosh(z)
47 * sinh(x) cos(y) + i cosh(x) sin(y)
48 * = ---------------------------------
49 * cosh(x) cos(y) + i sinh(x) sin(y)
51 * cosh(x) sinh(x) / cos^2(y) + i tan(y)
52 * = -------------------------------------
53 * 1 + sinh^2(x) / cos^2(y)
61 * I omitted the original algorithm's handling of overflow in tan(x) after
62 * verifying with nearpi.c that this can't happen in IEEE single or double
63 * precision. I also handle large x differently.
68 double complex ctanh(double complex z)
71 double t, beta, s, rho, denom;
77 EXTRACT_WORDS(hx, lx, x);
81 * ctanh(NaN + i 0) = NaN + i 0
83 * ctanh(NaN + i y) = NaN + i NaN for y != 0
85 * The imaginary part has the sign of x*sin(2*y), but there's no
86 * special effort to get this right.
88 * ctanh(+-Inf +- i Inf) = +-1 +- 0
90 * ctanh(+-Inf + i y) = +-1 + 0 sin(2y) for y finite
92 * The imaginary part of the sign is unspecified. This special
93 * case is only needed to avoid a spurious invalid exception when
96 if (ix >= 0x7ff00000) {
97 if ((ix & 0xfffff) | lx) /* x is NaN */
98 return CMPLX(x, (y == 0 ? y : x * y));
99 SET_HIGH_WORD(x, hx - 0x40000000); /* x = copysign(1, x) */
100 return CMPLX(x, copysign(0, isinf(y) ? y : sin(y) * cos(y)));
104 * ctanh(x + i NAN) = NaN + i NaN
105 * ctanh(x +- i Inf) = NaN + i NaN
108 return CMPLX(y - y, y - y);
111 * ctanh(+-huge + i +-y) ~= +-1 +- i 2sin(2y)/exp(2x), using the
112 * approximation sinh^2(huge) ~= exp(2*huge) / 4.
113 * We use a modified formula to avoid spurious overflow.
115 if (ix >= 0x40360000) { /* x >= 22 */
116 double exp_mx = exp(-fabs(x));
117 return CMPLX(copysign(1, x), 4 * sin(y) * cos(y) * exp_mx * exp_mx);
120 /* Kahan's algorithm */
122 beta = 1.0 + t * t; /* = 1 / cos^2(y) */
124 rho = sqrt(1 + s * s); /* = cosh(x) */
125 denom = 1 + beta * s * s;
126 return CMPLX((beta * rho * s) / denom, t / denom);
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