/* * Copyright 2008-2013 NVIDIA Corporation * Copyright 2013 Filipe RNC Maia * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ /*- * Copyright (c) 2012 Stephen Montgomery-Smith * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ /* * Adapted from FreeBSD by Filipe Maia : * freebsd/lib/msun/src/catrig.c */ #pragma once #include #if defined(_CCCL_IMPLICIT_SYSTEM_HEADER_GCC) # pragma GCC system_header #elif defined(_CCCL_IMPLICIT_SYSTEM_HEADER_CLANG) # pragma clang system_header #elif defined(_CCCL_IMPLICIT_SYSTEM_HEADER_MSVC) # pragma system_header #endif // no system header #include #include #include #include THRUST_NAMESPACE_BEGIN namespace detail{ namespace complex{ using thrust::complex; __host__ __device__ inline void raise_inexact(){ const volatile float tiny = 7.888609052210118054117286e-31; /* 0x1p-100; */ // needs the volatile to prevent compiler from ignoring it volatile float junk = 1 + tiny; (void)junk; } __host__ __device__ inline complex clog_for_large_values(complex z); /* * Testing indicates that all these functions are accurate up to 4 ULP. * The functions casin(h) and cacos(h) are about 2.5 times slower than asinh. * The functions catan(h) are a little under 2 times slower than atanh. * * The code for casinh, casin, cacos, and cacosh comes first. The code is * rather complicated, and the four functions are highly interdependent. * * The code for catanh and catan comes at the end. It is much simpler than * the other functions, and the code for these can be disconnected from the * rest of the code. */ /* * ================================ * | casinh, casin, cacos, cacosh | * ================================ */ /* * The algorithm is very close to that in "Implementing the complex arcsine * and arccosine functions using exception handling" by T. E. Hull, Thomas F. * Fairgrieve, and Ping Tak Peter Tang, published in ACM Transactions on * Mathematical Software, Volume 23 Issue 3, 1997, Pages 299-335, * http://dl.acm.org/citation.cfm?id=275324. * * Throughout we use the convention z = x + I*y. * * casinh(z) = sign(x)*log(A+sqrt(A*A-1)) + I*asin(B) * where * A = (|z+I| + |z-I|) / 2 * B = (|z+I| - |z-I|) / 2 = y/A * * These formulas become numerically unstable: * (a) for Re(casinh(z)) when z is close to the line segment [-I, I] (that * is, Re(casinh(z)) is close to 0); * (b) for Im(casinh(z)) when z is close to either of the intervals * [I, I*infinity) or (-I*infinity, -I] (that is, |Im(casinh(z))| is * close to PI/2). * * These numerical problems are overcome by defining * f(a, b) = (hypot(a, b) - b) / 2 = a*a / (hypot(a, b) + b) / 2 * Then if A < A_crossover, we use * log(A + sqrt(A*A-1)) = log1p((A-1) + sqrt((A-1)*(A+1))) * A-1 = f(x, 1+y) + f(x, 1-y) * and if B > B_crossover, we use * asin(B) = atan2(y, sqrt(A*A - y*y)) = atan2(y, sqrt((A+y)*(A-y))) * A-y = f(x, y+1) + f(x, y-1) * where without loss of generality we have assumed that x and y are * non-negative. * * Much of the difficulty comes because the intermediate computations may * produce overflows or underflows. This is dealt with in the paper by Hull * et al by using exception handling. We do this by detecting when * computations risk underflow or overflow. The hardest part is handling the * underflows when computing f(a, b). * * Note that the function f(a, b) does not appear explicitly in the paper by * Hull et al, but the idea may be found on pages 308 and 309. Introducing the * function f(a, b) allows us to concentrate many of the clever tricks in this * paper into one function. */ /* * Function f(a, b, hypot_a_b) = (hypot(a, b) - b) / 2. * Pass hypot(a, b) as the third argument. */ __host__ __device__ inline double f(double a, double b, double hypot_a_b) { if (b < 0) return ((hypot_a_b - b) / 2); if (b == 0) return (a / 2); return (a * a / (hypot_a_b + b) / 2); } /* * All the hard work is contained in this function. * x and y are assumed positive or zero, and less than RECIP_EPSILON. * Upon return: * rx = Re(casinh(z)) = -Im(cacos(y + I*x)). * B_is_usable is set to 1 if the value of B is usable. * If B_is_usable is set to 0, sqrt_A2my2 = sqrt(A*A - y*y), and new_y = y. * If returning sqrt_A2my2 has potential to result in an underflow, it is * rescaled, and new_y is similarly rescaled. */ __host__ __device__ inline void do_hard_work(double x, double y, double *rx, int *B_is_usable, double *B, double *sqrt_A2my2, double *new_y) { double R, S, A; /* A, B, R, and S are as in Hull et al. */ double Am1, Amy; /* A-1, A-y. */ const double A_crossover = 10; /* Hull et al suggest 1.5, but 10 works better */ const double FOUR_SQRT_MIN = 5.966672584960165394632772e-154; /* =0x1p-509; >= 4 * sqrt(DBL_MIN) */ const double B_crossover = 0.6417; /* suggested by Hull et al */ R = hypot(x, y + 1); /* |z+I| */ S = hypot(x, y - 1); /* |z-I| */ /* A = (|z+I| + |z-I|) / 2 */ A = (R + S) / 2; /* * Mathematically A >= 1. There is a small chance that this will not * be so because of rounding errors. So we will make certain it is * so. */ if (A < 1) A = 1; if (A < A_crossover) { /* * Am1 = fp + fm, where fp = f(x, 1+y), and fm = f(x, 1-y). * rx = log1p(Am1 + sqrt(Am1*(A+1))) */ if (y == 1 && x < DBL_EPSILON * DBL_EPSILON / 128) { /* * fp is of order x^2, and fm = x/2. * A = 1 (inexactly). */ *rx = sqrt(x); } else if (x >= DBL_EPSILON * fabs(y - 1)) { /* * Underflow will not occur because * x >= DBL_EPSILON^2/128 >= FOUR_SQRT_MIN */ Am1 = f(x, 1 + y, R) + f(x, 1 - y, S); *rx = log1p(Am1 + sqrt(Am1 * (A + 1))); } else if (y < 1) { /* * fp = x*x/(1+y)/4, fm = x*x/(1-y)/4, and * A = 1 (inexactly). */ *rx = x / sqrt((1 - y) * (1 + y)); } else { /* if (y > 1) */ /* * A-1 = y-1 (inexactly). */ *rx = log1p((y - 1) + sqrt((y - 1) * (y + 1))); } } else { *rx = log(A + sqrt(A * A - 1)); } *new_y = y; if (y < FOUR_SQRT_MIN) { /* * Avoid a possible underflow caused by y/A. For casinh this * would be legitimate, but will be picked up by invoking atan2 * later on. For cacos this would not be legitimate. */ *B_is_usable = 0; *sqrt_A2my2 = A * (2 / DBL_EPSILON); *new_y = y * (2 / DBL_EPSILON); return; } /* B = (|z+I| - |z-I|) / 2 = y/A */ *B = y / A; *B_is_usable = 1; if (*B > B_crossover) { *B_is_usable = 0; /* * Amy = fp + fm, where fp = f(x, y+1), and fm = f(x, y-1). * sqrt_A2my2 = sqrt(Amy*(A+y)) */ if (y == 1 && x < DBL_EPSILON / 128) { /* * fp is of order x^2, and fm = x/2. * A = 1 (inexactly). */ *sqrt_A2my2 = sqrt(x) * sqrt((A + y) / 2); } else if (x >= DBL_EPSILON * fabs(y - 1)) { /* * Underflow will not occur because * x >= DBL_EPSILON/128 >= FOUR_SQRT_MIN * and * x >= DBL_EPSILON^2 >= FOUR_SQRT_MIN */ Amy = f(x, y + 1, R) + f(x, y - 1, S); *sqrt_A2my2 = sqrt(Amy * (A + y)); } else if (y > 1) { /* * fp = x*x/(y+1)/4, fm = x*x/(y-1)/4, and * A = y (inexactly). * * y < RECIP_EPSILON. So the following * scaling should avoid any underflow problems. */ *sqrt_A2my2 = x * (4 / DBL_EPSILON / DBL_EPSILON) * y / sqrt((y + 1) * (y - 1)); *new_y = y * (4 / DBL_EPSILON / DBL_EPSILON); } else { /* if (y < 1) */ /* * fm = 1-y >= DBL_EPSILON, fp is of order x^2, and * A = 1 (inexactly). */ *sqrt_A2my2 = sqrt((1 - y) * (1 + y)); } } } /* * casinh(z) = z + O(z^3) as z -> 0 * * casinh(z) = sign(x)*clog(sign(x)*z) + O(1/z^2) as z -> infinity * The above formula works for the imaginary part as well, because * Im(casinh(z)) = sign(x)*atan2(sign(x)*y, fabs(x)) + O(y/z^3) * as z -> infinity, uniformly in y */ __host__ __device__ inline complex casinh(complex z) { double x, y, ax, ay, rx, ry, B, sqrt_A2my2, new_y; int B_is_usable; complex w; const double RECIP_EPSILON = 1.0 / DBL_EPSILON; const double m_ln2 = 6.9314718055994531e-1; /* 0x162e42fefa39ef.0p-53 */ x = z.real(); y = z.imag(); ax = fabs(x); ay = fabs(y); if (isnan(x) || isnan(y)) { /* casinh(+-Inf + I*NaN) = +-Inf + I*NaN */ if (isinf(x)) return (complex(x, y + y)); /* casinh(NaN + I*+-Inf) = opt(+-)Inf + I*NaN */ if (isinf(y)) return (complex(y, x + x)); /* casinh(NaN + I*0) = NaN + I*0 */ if (y == 0) return (complex(x + x, y)); /* * All other cases involving NaN return NaN + I*NaN. * C99 leaves it optional whether to raise invalid if one of * the arguments is not NaN, so we opt not to raise it. */ return (complex(x + 0.0 + (y + 0.0), x + 0.0 + (y + 0.0))); } if (ax > RECIP_EPSILON || ay > RECIP_EPSILON) { /* clog...() will raise inexact unless x or y is infinite. */ if (signbit(x) == 0) w = clog_for_large_values(z) + m_ln2; else w = clog_for_large_values(-z) + m_ln2; return (complex(copysign(w.real(), x), copysign(w.imag(), y))); } /* Avoid spuriously raising inexact for z = 0. */ if (x == 0 && y == 0) return (z); /* All remaining cases are inexact. */ raise_inexact(); const double SQRT_6_EPSILON = 3.6500241499888571e-8; /* 0x13988e1409212e.0p-77 */ if (ax < SQRT_6_EPSILON / 4 && ay < SQRT_6_EPSILON / 4) return (z); do_hard_work(ax, ay, &rx, &B_is_usable, &B, &sqrt_A2my2, &new_y); if (B_is_usable) ry = asin(B); else ry = atan2(new_y, sqrt_A2my2); return (complex(copysign(rx, x), copysign(ry, y))); } /* * casin(z) = reverse(casinh(reverse(z))) * where reverse(x + I*y) = y + I*x = I*conj(z). */ __host__ __device__ inline complex casin(complex z) { complex w = casinh(complex(z.imag(), z.real())); return (complex(w.imag(), w.real())); } /* * cacos(z) = PI/2 - casin(z) * but do the computation carefully so cacos(z) is accurate when z is * close to 1. * * cacos(z) = PI/2 - z + O(z^3) as z -> 0 * * cacos(z) = -sign(y)*I*clog(z) + O(1/z^2) as z -> infinity * The above formula works for the real part as well, because * Re(cacos(z)) = atan2(fabs(y), x) + O(y/z^3) * as z -> infinity, uniformly in y */ __host__ __device__ inline complex cacos(complex z) { double x, y, ax, ay, rx, ry, B, sqrt_A2mx2, new_x; int sx, sy; int B_is_usable; complex w; const double pio2_hi = 1.5707963267948966e0; /* 0x1921fb54442d18.0p-52 */ const volatile double pio2_lo = 6.1232339957367659e-17; /* 0x11a62633145c07.0p-106 */ const double m_ln2 = 6.9314718055994531e-1; /* 0x162e42fefa39ef.0p-53 */ x = z.real(); y = z.imag(); sx = signbit(x); sy = signbit(y); ax = fabs(x); ay = fabs(y); if (isnan(x) || isnan(y)) { /* cacos(+-Inf + I*NaN) = NaN + I*opt(-)Inf */ if (isinf(x)) return (complex(y + y, -infinity())); /* cacos(NaN + I*+-Inf) = NaN + I*-+Inf */ if (isinf(y)) return (complex(x + x, -y)); /* cacos(0 + I*NaN) = PI/2 + I*NaN with inexact */ if (x == 0) return (complex(pio2_hi + pio2_lo, y + y)); /* * All other cases involving NaN return NaN + I*NaN. * C99 leaves it optional whether to raise invalid if one of * the arguments is not NaN, so we opt not to raise it. */ return (complex(x + 0.0 + (y + 0), x + 0.0 + (y + 0))); } const double RECIP_EPSILON = 1.0 / DBL_EPSILON; if (ax > RECIP_EPSILON || ay > RECIP_EPSILON) { /* clog...() will raise inexact unless x or y is infinite. */ w = clog_for_large_values(z); rx = fabs(w.imag()); ry = w.real() + m_ln2; if (sy == 0) ry = -ry; return (complex(rx, ry)); } /* Avoid spuriously raising inexact for z = 1. */ if (x == 1.0 && y == 0.0) return (complex(0, -y)); /* All remaining cases are inexact. */ raise_inexact(); const double SQRT_6_EPSILON = 3.6500241499888571e-8; /* 0x13988e1409212e.0p-77 */ if (ax < SQRT_6_EPSILON / 4 && ay < SQRT_6_EPSILON / 4) return (complex(pio2_hi - (x - pio2_lo), -y)); do_hard_work(ay, ax, &ry, &B_is_usable, &B, &sqrt_A2mx2, &new_x); if (B_is_usable) { if (sx == 0) rx = acos(B); else rx = acos(-B); } else { if (sx == 0) rx = atan2(sqrt_A2mx2, new_x); else rx = atan2(sqrt_A2mx2, -new_x); } if (sy == 0) ry = -ry; return (complex(rx, ry)); } /* * cacosh(z) = I*cacos(z) or -I*cacos(z) * where the sign is chosen so Re(cacosh(z)) >= 0. */ __host__ __device__ inline complex cacosh(complex z) { complex w; double rx, ry; w = cacos(z); rx = w.real(); ry = w.imag(); /* cacosh(NaN + I*NaN) = NaN + I*NaN */ if (isnan(rx) && isnan(ry)) return (complex(ry, rx)); /* cacosh(NaN + I*+-Inf) = +Inf + I*NaN */ /* cacosh(+-Inf + I*NaN) = +Inf + I*NaN */ if (isnan(rx)) return (complex(fabs(ry), rx)); /* cacosh(0 + I*NaN) = NaN + I*NaN */ if (isnan(ry)) return (complex(ry, ry)); return (complex(fabs(ry), copysign(rx, z.imag()))); } /* * Optimized version of clog() for |z| finite and larger than ~RECIP_EPSILON. */ __host__ __device__ inline complex clog_for_large_values(complex z) { double x, y; double ax, ay, t; const double m_e = 2.7182818284590452e0; /* 0x15bf0a8b145769.0p-51 */ x = z.real(); y = z.imag(); ax = fabs(x); ay = fabs(y); if (ax < ay) { t = ax; ax = ay; ay = t; } /* * Avoid overflow in hypot() when x and y are both very large. * Divide x and y by E, and then add 1 to the logarithm. This depends * on E being larger than sqrt(2). * Dividing by E causes an insignificant loss of accuracy; however * this method is still poor since it is uneccessarily slow. */ if (ax > DBL_MAX / 2) return (complex(log(hypot(x / m_e, y / m_e)) + 1, atan2(y, x))); /* * Avoid overflow when x or y is large. Avoid underflow when x or * y is small. */ const double QUARTER_SQRT_MAX = 5.966672584960165394632772e-154; /* = 0x1p509; <= sqrt(DBL_MAX) / 4 */ const double SQRT_MIN = 1.491668146240041348658193e-154; /* = 0x1p-511; >= sqrt(DBL_MIN) */ if (ax > QUARTER_SQRT_MAX || ay < SQRT_MIN) return (complex(log(hypot(x, y)), atan2(y, x))); return (complex(log(ax * ax + ay * ay) / 2, atan2(y, x))); } /* * ================= * | catanh, catan | * ================= */ /* * sum_squares(x,y) = x*x + y*y (or just x*x if y*y would underflow). * Assumes x*x and y*y will not overflow. * Assumes x and y are finite. * Assumes y is non-negative. * Assumes fabs(x) >= DBL_EPSILON. */ __host__ __device__ inline double sum_squares(double x, double y) { const double SQRT_MIN = 1.491668146240041348658193e-154; /* = 0x1p-511; >= sqrt(DBL_MIN) */ /* Avoid underflow when y is small. */ if (y < SQRT_MIN) return (x * x); return (x * x + y * y); } /* * real_part_reciprocal(x, y) = Re(1/(x+I*y)) = x/(x*x + y*y). * Assumes x and y are not NaN, and one of x and y is larger than * RECIP_EPSILON. We avoid unwarranted underflow. It is important to not use * the code creal(1/z), because the imaginary part may produce an unwanted * underflow. * This is only called in a context where inexact is always raised before * the call, so no effort is made to avoid or force inexact. */ __host__ __device__ inline double real_part_reciprocal(double x, double y) { double scale; uint32_t hx, hy; int32_t ix, iy; /* * This code is inspired by the C99 document n1124.pdf, Section G.5.1, * example 2. */ get_high_word(hx, x); ix = hx & 0x7ff00000; get_high_word(hy, y); iy = hy & 0x7ff00000; //#define BIAS (DBL_MAX_EXP - 1) const int BIAS = DBL_MAX_EXP - 1; /* XXX more guard digits are useful iff there is extra precision. */ //#define CUTOFF (DBL_MANT_DIG / 2 + 1) /* just half or 1 guard digit */ const int CUTOFF = (DBL_MANT_DIG / 2 + 1); if (ix - iy >= CUTOFF << 20 || isinf(x)) return (1 / x); /* +-Inf -> +-0 is special */ if (iy - ix >= CUTOFF << 20) return (x / y / y); /* should avoid double div, but hard */ if (ix <= (BIAS + DBL_MAX_EXP / 2 - CUTOFF) << 20) return (x / (x * x + y * y)); scale = 1; set_high_word(scale, 0x7ff00000 - ix); /* 2**(1-ilogb(x)) */ x *= scale; y *= scale; return (x / (x * x + y * y) * scale); } /* * catanh(z) = log((1+z)/(1-z)) / 2 * = log1p(4*x / |z-1|^2) / 4 * + I * atan2(2*y, (1-x)*(1+x)-y*y) / 2 * * catanh(z) = z + O(z^3) as z -> 0 * * catanh(z) = 1/z + sign(y)*I*PI/2 + O(1/z^3) as z -> infinity * The above formula works for the real part as well, because * Re(catanh(z)) = x/|z|^2 + O(x/z^4) * as z -> infinity, uniformly in x */ #if THRUST_CPP_DIALECT >= 2011 || THRUST_HOST_COMPILER != THRUST_HOST_COMPILER_MSVC __host__ __device__ inline complex catanh(complex z) { double x, y, ax, ay, rx, ry; const volatile double pio2_lo = 6.1232339957367659e-17; /* 0x11a62633145c07.0p-106 */ const double pio2_hi = 1.5707963267948966e0;/* 0x1921fb54442d18.0p-52 */ x = z.real(); y = z.imag(); ax = fabs(x); ay = fabs(y); /* This helps handle many cases. */ if (y == 0 && ax <= 1) return (complex(atanh(x), y)); /* To ensure the same accuracy as atan(), and to filter out z = 0. */ if (x == 0) return (complex(x, atan(y))); if (isnan(x) || isnan(y)) { /* catanh(+-Inf + I*NaN) = +-0 + I*NaN */ if (isinf(x)) return (complex(copysign(0.0, x), y + y)); /* catanh(NaN + I*+-Inf) = sign(NaN)0 + I*+-PI/2 */ if (isinf(y)) return (complex(copysign(0.0, x), copysign(pio2_hi + pio2_lo, y))); /* * All other cases involving NaN return NaN + I*NaN. * C99 leaves it optional whether to raise invalid if one of * the arguments is not NaN, so we opt not to raise it. */ return (complex(x + 0.0 + (y + 0), x + 0.0 + (y + 0))); } const double RECIP_EPSILON = 1.0 / DBL_EPSILON; if (ax > RECIP_EPSILON || ay > RECIP_EPSILON) return (complex(real_part_reciprocal(x, y), copysign(pio2_hi + pio2_lo, y))); const double SQRT_3_EPSILON = 2.5809568279517849e-8; /* 0x1bb67ae8584caa.0p-78 */ if (ax < SQRT_3_EPSILON / 2 && ay < SQRT_3_EPSILON / 2) { /* * z = 0 was filtered out above. All other cases must raise * inexact, but this is the only only that needs to do it * explicitly. */ raise_inexact(); return (z); } const double m_ln2 = 6.9314718055994531e-1; /* 0x162e42fefa39ef.0p-53 */ if (ax == 1 && ay < DBL_EPSILON) rx = (m_ln2 - log(ay)) / 2; else rx = log1p(4 * ax / sum_squares(ax - 1, ay)) / 4; if (ax == 1) ry = atan2(2.0, -ay) / 2; else if (ay < DBL_EPSILON) ry = atan2(2 * ay, (1 - ax) * (1 + ax)) / 2; else ry = atan2(2 * ay, (1 - ax) * (1 + ax) - ay * ay) / 2; return (complex(copysign(rx, x), copysign(ry, y))); } /* * catan(z) = reverse(catanh(reverse(z))) * where reverse(x + I*y) = y + I*x = I*conj(z). */ __host__ __device__ inline complexcatan(complex z) { complex w = catanh(complex(z.imag(), z.real())); return (complex(w.imag(), w.real())); } #endif } // namespace complex } // namespace detail template __host__ __device__ inline complex acos(const complex& z){ const complex ret = thrust::asin(z); const ValueType pi = ValueType(3.14159265358979323846); return complex(pi/2 - ret.real(),-ret.imag()); } template __host__ __device__ inline complex asin(const complex& z){ const complex i(0,1); return -i*asinh(i*z); } template __host__ __device__ inline complex atan(const complex& z){ const complex i(0,1); return -i*thrust::atanh(i*z); } template __host__ __device__ inline complex acosh(const complex& z){ thrust::complex ret((z.real() - z.imag()) * (z.real() + z.imag()) - ValueType(1.0), ValueType(2.0) * z.real() * z.imag()); ret = thrust::sqrt(ret); if (z.real() < ValueType(0.0)){ ret = -ret; } ret += z; ret = thrust::log(ret); if (ret.real() < ValueType(0.0)){ ret = -ret; } return ret; } template __host__ __device__ inline complex asinh(const complex& z){ return thrust::log(thrust::sqrt(z*z+ValueType(1))+z); } template __host__ __device__ inline complex atanh(const complex& z){ ValueType imag2 = z.imag() * z.imag(); ValueType n = ValueType(1.0) + z.real(); n = imag2 + n * n; ValueType d = ValueType(1.0) - z.real(); d = imag2 + d * d; complex ret(ValueType(0.25) * (std::log(n) - std::log(d)),0); d = ValueType(1.0) - z.real() * z.real() - imag2; ret.imag(ValueType(0.5) * std::atan2(ValueType(2.0) * z.imag(), d)); return ret; } template <> __host__ __device__ inline complex acos(const complex& z){ return detail::complex::cacos(z); } template <> __host__ __device__ inline complex asin(const complex& z){ return detail::complex::casin(z); } #if THRUST_CPP_DIALECT >= 2011 || THRUST_HOST_COMPILER != THRUST_HOST_COMPILER_MSVC template <> __host__ __device__ inline complex atan(const complex& z){ return detail::complex::catan(z); } #endif template <> __host__ __device__ inline complex acosh(const complex& z){ return detail::complex::cacosh(z); } template <> __host__ __device__ inline complex asinh(const complex& z){ return detail::complex::casinh(z); } #if THRUST_CPP_DIALECT >= 2011 || THRUST_HOST_COMPILER != THRUST_HOST_COMPILER_MSVC template <> __host__ __device__ inline complex atanh(const complex& z){ return detail::complex::catanh(z); } #endif THRUST_NAMESPACE_END