/* clang-format off */ /*===-- divtc3.c - Implement __divtc3 -------------------------------------=== * * The LLVM Compiler Infrastructure * * This file is dual licensed under the MIT and the University of Illinois Open * Source Licenses. See LICENSE.TXT for details. * * ===----------------------------------------------------------------------=== * * This file implements __divtc3 for the compiler_rt library. * *===----------------------------------------------------------------------=== */ STATIC_YOINK("huge_compiler_rt_license"); #define QUAD_PRECISION #include "third_party/compiler_rt/fp_lib.inc" #include "third_party/compiler_rt/int_lib.h" #include "third_party/compiler_rt/int_math.h" /* Returns: the quotient of (a + ib) / (c + id) */ COMPILER_RT_ABI Lcomplex __divtc3(long double __a, long double __b, long double __c, long double __d) { int __ilogbw = 0; long double __logbw = __compiler_rt_logbl(crt_fmaxl(crt_fabsl(__c), crt_fabsl(__d))); if (crt_isfinite(__logbw)) { __ilogbw = (int)__logbw; __c = crt_scalbnl(__c, -__ilogbw); __d = crt_scalbnl(__d, -__ilogbw); } long double __denom = __c * __c + __d * __d; Lcomplex z; COMPLEX_REAL(z) = crt_scalbnl((__a * __c + __b * __d) / __denom, -__ilogbw); COMPLEX_IMAGINARY(z) = crt_scalbnl((__b * __c - __a * __d) / __denom, -__ilogbw); if (crt_isnan(COMPLEX_REAL(z)) && crt_isnan(COMPLEX_IMAGINARY(z))) { if ((__denom == 0.0) && (!crt_isnan(__a) || !crt_isnan(__b))) { COMPLEX_REAL(z) = crt_copysignl(CRT_INFINITY, __c) * __a; COMPLEX_IMAGINARY(z) = crt_copysignl(CRT_INFINITY, __c) * __b; } else if ((crt_isinf(__a) || crt_isinf(__b)) && crt_isfinite(__c) && crt_isfinite(__d)) { __a = crt_copysignl(crt_isinf(__a) ? 1.0 : 0.0, __a); __b = crt_copysignl(crt_isinf(__b) ? 1.0 : 0.0, __b); COMPLEX_REAL(z) = CRT_INFINITY * (__a * __c + __b * __d); COMPLEX_IMAGINARY(z) = CRT_INFINITY * (__b * __c - __a * __d); } else if (crt_isinf(__logbw) && __logbw > 0.0 && crt_isfinite(__a) && crt_isfinite(__b)) { __c = crt_copysignl(crt_isinf(__c) ? 1.0 : 0.0, __c); __d = crt_copysignl(crt_isinf(__d) ? 1.0 : 0.0, __d); COMPLEX_REAL(z) = 0.0 * (__a * __c + __b * __d); COMPLEX_IMAGINARY(z) = 0.0 * (__b * __c - __a * __d); } } return z; }