AlkantarClanX12
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Current File : //proc/self/root/usr/include/tgmath.h |
/* Copyright (C) 1997-2018 Free Software Foundation, Inc. This file is part of the GNU C Library. The GNU C Library is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. The GNU C Library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with the GNU C Library; if not, see <http://www.gnu.org/licenses/>. */ /* * ISO C99 Standard: 7.22 Type-generic math <tgmath.h> */ #ifndef _TGMATH_H #define _TGMATH_H 1 #define __GLIBC_INTERNAL_STARTING_HEADER_IMPLEMENTATION #include <bits/libc-header-start.h> /* Include the needed headers. */ #include <bits/floatn.h> #include <math.h> #include <complex.h> /* There are two variant implementations of type-generic macros in this file: one for GCC 8 and later, using __builtin_tgmath and where each macro expands each of its arguments only once, and one for older GCC, using other compiler extensions but with macros expanding their arguments many times (so resulting in exponential blowup of the size of expansions when calls to such macros are nested inside arguments to such macros). */ #define __HAVE_BUILTIN_TGMATH __GNUC_PREREQ (8, 0) #if __GNUC_PREREQ (2, 7) # if __HAVE_BUILTIN_TGMATH # if __HAVE_FLOAT16 && __GLIBC_USE (IEC_60559_TYPES_EXT) # define __TG_F16_ARG(X) X ## f16, # else # define __TG_F16_ARG(X) # endif # if __HAVE_FLOAT32 && __GLIBC_USE (IEC_60559_TYPES_EXT) # define __TG_F32_ARG(X) X ## f32, # else # define __TG_F32_ARG(X) # endif # if __HAVE_FLOAT64 && __GLIBC_USE (IEC_60559_TYPES_EXT) # define __TG_F64_ARG(X) X ## f64, # else # define __TG_F64_ARG(X) # endif # if __HAVE_FLOAT128 && __GLIBC_USE (IEC_60559_TYPES_EXT) # define __TG_F128_ARG(X) X ## f128, # else # define __TG_F128_ARG(X) # endif # if __HAVE_FLOAT32X && __GLIBC_USE (IEC_60559_TYPES_EXT) # define __TG_F32X_ARG(X) X ## f32x, # else # define __TG_F32X_ARG(X) # endif # if __HAVE_FLOAT64X && __GLIBC_USE (IEC_60559_TYPES_EXT) # define __TG_F64X_ARG(X) X ## f64x, # else # define __TG_F64X_ARG(X) # endif # if __HAVE_FLOAT128X && __GLIBC_USE (IEC_60559_TYPES_EXT) # define __TG_F128X_ARG(X) X ## f128x, # else # define __TG_F128X_ARG(X) # endif # define __TGMATH_FUNCS(X) X ## f, X, X ## l, \ __TG_F16_ARG (X) __TG_F32_ARG (X) __TG_F64_ARG (X) __TG_F128_ARG (X) \ __TG_F32X_ARG (X) __TG_F64X_ARG (X) __TG_F128X_ARG (X) # define __TGMATH_RCFUNCS(F, C) __TGMATH_FUNCS (F) __TGMATH_FUNCS (C) # define __TGMATH_1(F, X) __builtin_tgmath (__TGMATH_FUNCS (F) (X)) # define __TGMATH_2(F, X, Y) __builtin_tgmath (__TGMATH_FUNCS (F) (X), (Y)) # define __TGMATH_2STD(F, X, Y) __builtin_tgmath (F ## f, F, F ## l, (X), (Y)) # define __TGMATH_3(F, X, Y, Z) __builtin_tgmath (__TGMATH_FUNCS (F) \ (X), (Y), (Z)) # define __TGMATH_1C(F, C, X) __builtin_tgmath (__TGMATH_RCFUNCS (F, C) (X)) # define __TGMATH_2C(F, C, X, Y) __builtin_tgmath (__TGMATH_RCFUNCS (F, C) \ (X), (Y)) # else /* !__HAVE_BUILTIN_TGMATH. */ # ifdef __NO_LONG_DOUBLE_MATH # define __tgml(fct) fct # else # define __tgml(fct) fct ## l # endif /* __floating_type expands to 1 if TYPE is a floating type (including complex floating types), 0 if TYPE is an integer type (including complex integer types). __real_integer_type expands to 1 if TYPE is a real integer type. __complex_integer_type expands to 1 if TYPE is a complex integer type. All these macros expand to integer constant expressions. All these macros can assume their argument has an arithmetic type (not vector, decimal floating-point or fixed-point), valid to pass to tgmath.h macros. */ # if __GNUC_PREREQ (3, 1) /* __builtin_classify_type expands to an integer constant expression in GCC 3.1 and later. Default conversions applied to the argument of __builtin_classify_type mean it always returns 1 for real integer types rather than ever returning different values for character, boolean or enumerated types. */ # define __floating_type(type) \ (__builtin_classify_type (__real__ ((type) 0)) == 8) # define __real_integer_type(type) \ (__builtin_classify_type ((type) 0) == 1) # define __complex_integer_type(type) \ (__builtin_classify_type ((type) 0) == 9 \ && __builtin_classify_type (__real__ ((type) 0)) == 1) # else /* GCC versions predating __builtin_classify_type are also looser on what counts as an integer constant expression. */ # define __floating_type(type) (((type) 1.25) != 1) # define __real_integer_type(type) (((type) (1.25 + _Complex_I)) == 1) # define __complex_integer_type(type) \ (((type) (1.25 + _Complex_I)) == (1 + _Complex_I)) # endif /* Whether an expression (of arithmetic type) has a real type. */ # define __expr_is_real(E) (__builtin_classify_type (E) != 9) /* The tgmath real type for T, where E is 0 if T is an integer type and 1 for a floating type. If T has a complex type, it is unspecified whether the return type is real or complex (but it has the correct corresponding real type). */ # define __tgmath_real_type_sub(T, E) \ __typeof__ (*(0 ? (__typeof__ (0 ? (double *) 0 : (void *) (E))) 0 \ : (__typeof__ (0 ? (T *) 0 : (void *) (!(E)))) 0)) /* The tgmath real type of EXPR. */ # define __tgmath_real_type(expr) \ __tgmath_real_type_sub (__typeof__ ((__typeof__ (+(expr))) 0), \ __floating_type (__typeof__ (+(expr)))) /* The tgmath complex type for T, where E1 is 1 if T has a floating type and 0 otherwise, E2 is 1 if T has a real integer type and 0 otherwise, and E3 is 1 if T has a complex type and 0 otherwise. */ # define __tgmath_complex_type_sub(T, E1, E2, E3) \ __typeof__ (*(0 \ ? (__typeof__ (0 ? (T *) 0 : (void *) (!(E1)))) 0 \ : (__typeof__ (0 \ ? (__typeof__ (0 \ ? (double *) 0 \ : (void *) (!(E2)))) 0 \ : (__typeof__ (0 \ ? (_Complex double *) 0 \ : (void *) (!(E3)))) 0)) 0)) /* The tgmath complex type of EXPR. */ # define __tgmath_complex_type(expr) \ __tgmath_complex_type_sub (__typeof__ ((__typeof__ (+(expr))) 0), \ __floating_type (__typeof__ (+(expr))), \ __real_integer_type (__typeof__ (+(expr))), \ __complex_integer_type (__typeof__ (+(expr)))) # if (__HAVE_DISTINCT_FLOAT16 \ || __HAVE_DISTINCT_FLOAT32 \ || __HAVE_DISTINCT_FLOAT64 \ || __HAVE_DISTINCT_FLOAT32X \ || __HAVE_DISTINCT_FLOAT64X \ || __HAVE_DISTINCT_FLOAT128X) # error "Unsupported _FloatN or _FloatNx types for <tgmath.h>." # endif /* Expand to text that checks if ARG_COMB has type _Float128, and if so calls the appropriately suffixed FCT (which may include a cast), or FCT and CFCT for complex functions, with arguments ARG_CALL. */ # if __HAVE_DISTINCT_FLOAT128 && __GLIBC_USE (IEC_60559_TYPES_EXT) # if (!__HAVE_FLOAT64X \ || __HAVE_FLOAT64X_LONG_DOUBLE \ || !__HAVE_FLOATN_NOT_TYPEDEF) # define __TGMATH_F128(arg_comb, fct, arg_call) \ __builtin_types_compatible_p (__typeof (+(arg_comb)), _Float128) \ ? fct ## f128 arg_call : # define __TGMATH_CF128(arg_comb, fct, cfct, arg_call) \ __builtin_types_compatible_p (__typeof (+__real__ (arg_comb)), _Float128) \ ? (__expr_is_real (arg_comb) \ ? fct ## f128 arg_call \ : cfct ## f128 arg_call) : # else /* _Float64x is a distinct type at the C language level, which must be handled like _Float128. */ # define __TGMATH_F128(arg_comb, fct, arg_call) \ (__builtin_types_compatible_p (__typeof (+(arg_comb)), _Float128) \ || __builtin_types_compatible_p (__typeof (+(arg_comb)), _Float64x)) \ ? fct ## f128 arg_call : # define __TGMATH_CF128(arg_comb, fct, cfct, arg_call) \ (__builtin_types_compatible_p (__typeof (+__real__ (arg_comb)), _Float128) \ || __builtin_types_compatible_p (__typeof (+__real__ (arg_comb)), \ _Float64x)) \ ? (__expr_is_real (arg_comb) \ ? fct ## f128 arg_call \ : cfct ## f128 arg_call) : # endif # else # define __TGMATH_F128(arg_comb, fct, arg_call) /* Nothing. */ # define __TGMATH_CF128(arg_comb, fct, cfct, arg_call) /* Nothing. */ # endif # endif /* !__HAVE_BUILTIN_TGMATH. */ /* We have two kinds of generic macros: to support functions which are only defined on real valued parameters and those which are defined for complex functions as well. */ # if __HAVE_BUILTIN_TGMATH # define __TGMATH_UNARY_REAL_ONLY(Val, Fct) __TGMATH_1 (Fct, (Val)) # define __TGMATH_UNARY_REAL_RET_ONLY(Val, Fct) __TGMATH_1 (Fct, (Val)) # define __TGMATH_BINARY_FIRST_REAL_ONLY(Val1, Val2, Fct) \ __TGMATH_2 (Fct, (Val1), (Val2)) # define __TGMATH_BINARY_FIRST_REAL_STD_ONLY(Val1, Val2, Fct) \ __TGMATH_2STD (Fct, (Val1), (Val2)) # define __TGMATH_BINARY_REAL_ONLY(Val1, Val2, Fct) \ __TGMATH_2 (Fct, (Val1), (Val2)) # define __TGMATH_BINARY_REAL_STD_ONLY(Val1, Val2, Fct) \ __TGMATH_2STD (Fct, (Val1), (Val2)) # define __TGMATH_BINARY_REAL_RET_ONLY(Val1, Val2, Fct) \ __TGMATH_2 (Fct, (Val1), (Val2)) # define __TGMATH_TERNARY_FIRST_SECOND_REAL_ONLY(Val1, Val2, Val3, Fct) \ __TGMATH_3 (Fct, (Val1), (Val2), (Val3)) # define __TGMATH_TERNARY_REAL_ONLY(Val1, Val2, Val3, Fct) \ __TGMATH_3 (Fct, (Val1), (Val2), (Val3)) # define __TGMATH_TERNARY_FIRST_REAL_RET_ONLY(Val1, Val2, Val3, Fct) \ __TGMATH_3 (Fct, (Val1), (Val2), (Val3)) # define __TGMATH_UNARY_REAL_IMAG(Val, Fct, Cfct) \ __TGMATH_1C (Fct, Cfct, (Val)) # define __TGMATH_UNARY_IMAG(Val, Cfct) __TGMATH_1 (Cfct, (Val)) # define __TGMATH_UNARY_REAL_IMAG_RET_REAL(Val, Fct, Cfct) \ __TGMATH_1C (Fct, Cfct, (Val)) # define __TGMATH_UNARY_REAL_IMAG_RET_REAL_SAME(Val, Cfct) \ __TGMATH_1 (Cfct, (Val)) # define __TGMATH_BINARY_REAL_IMAG(Val1, Val2, Fct, Cfct) \ __TGMATH_2C (Fct, Cfct, (Val1), (Val2)) # else /* !__HAVE_BUILTIN_TGMATH. */ # define __TGMATH_UNARY_REAL_ONLY(Val, Fct) \ (__extension__ ((sizeof (+(Val)) == sizeof (double) \ || __builtin_classify_type (Val) != 8) \ ? (__tgmath_real_type (Val)) Fct (Val) \ : (sizeof (+(Val)) == sizeof (float)) \ ? (__tgmath_real_type (Val)) Fct##f (Val) \ : __TGMATH_F128 ((Val), (__tgmath_real_type (Val)) Fct, \ (Val)) \ (__tgmath_real_type (Val)) __tgml(Fct) (Val))) # define __TGMATH_UNARY_REAL_RET_ONLY(Val, Fct) \ (__extension__ ((sizeof (+(Val)) == sizeof (double) \ || __builtin_classify_type (Val) != 8) \ ? Fct (Val) \ : (sizeof (+(Val)) == sizeof (float)) \ ? Fct##f (Val) \ : __TGMATH_F128 ((Val), Fct, (Val)) \ __tgml(Fct) (Val))) # define __TGMATH_BINARY_FIRST_REAL_ONLY(Val1, Val2, Fct) \ (__extension__ ((sizeof (+(Val1)) == sizeof (double) \ || __builtin_classify_type (Val1) != 8) \ ? (__tgmath_real_type (Val1)) Fct (Val1, Val2) \ : (sizeof (+(Val1)) == sizeof (float)) \ ? (__tgmath_real_type (Val1)) Fct##f (Val1, Val2) \ : __TGMATH_F128 ((Val1), (__tgmath_real_type (Val1)) Fct, \ (Val1, Val2)) \ (__tgmath_real_type (Val1)) __tgml(Fct) (Val1, Val2))) # define __TGMATH_BINARY_FIRST_REAL_STD_ONLY(Val1, Val2, Fct) \ (__extension__ ((sizeof (+(Val1)) == sizeof (double) \ || __builtin_classify_type (Val1) != 8) \ ? (__tgmath_real_type (Val1)) Fct (Val1, Val2) \ : (sizeof (+(Val1)) == sizeof (float)) \ ? (__tgmath_real_type (Val1)) Fct##f (Val1, Val2) \ : (__tgmath_real_type (Val1)) __tgml(Fct) (Val1, Val2))) # define __TGMATH_BINARY_REAL_ONLY(Val1, Val2, Fct) \ (__extension__ ((sizeof ((Val1) + (Val2)) > sizeof (double) \ && __builtin_classify_type ((Val1) + (Val2)) == 8) \ ? __TGMATH_F128 ((Val1) + (Val2), \ (__typeof \ ((__tgmath_real_type (Val1)) 0 \ + (__tgmath_real_type (Val2)) 0)) Fct, \ (Val1, Val2)) \ (__typeof ((__tgmath_real_type (Val1)) 0 \ + (__tgmath_real_type (Val2)) 0)) \ __tgml(Fct) (Val1, Val2) \ : (sizeof (+(Val1)) == sizeof (double) \ || sizeof (+(Val2)) == sizeof (double) \ || __builtin_classify_type (Val1) != 8 \ || __builtin_classify_type (Val2) != 8) \ ? (__typeof ((__tgmath_real_type (Val1)) 0 \ + (__tgmath_real_type (Val2)) 0)) \ Fct (Val1, Val2) \ : (__typeof ((__tgmath_real_type (Val1)) 0 \ + (__tgmath_real_type (Val2)) 0)) \ Fct##f (Val1, Val2))) # define __TGMATH_BINARY_REAL_STD_ONLY(Val1, Val2, Fct) \ (__extension__ ((sizeof ((Val1) + (Val2)) > sizeof (double) \ && __builtin_classify_type ((Val1) + (Val2)) == 8) \ ? (__typeof ((__tgmath_real_type (Val1)) 0 \ + (__tgmath_real_type (Val2)) 0)) \ __tgml(Fct) (Val1, Val2) \ : (sizeof (+(Val1)) == sizeof (double) \ || sizeof (+(Val2)) == sizeof (double) \ || __builtin_classify_type (Val1) != 8 \ || __builtin_classify_type (Val2) != 8) \ ? (__typeof ((__tgmath_real_type (Val1)) 0 \ + (__tgmath_real_type (Val2)) 0)) \ Fct (Val1, Val2) \ : (__typeof ((__tgmath_real_type (Val1)) 0 \ + (__tgmath_real_type (Val2)) 0)) \ Fct##f (Val1, Val2))) # define __TGMATH_BINARY_REAL_RET_ONLY(Val1, Val2, Fct) \ (__extension__ ((sizeof ((Val1) + (Val2)) > sizeof (double) \ && __builtin_classify_type ((Val1) + (Val2)) == 8) \ ? __TGMATH_F128 ((Val1) + (Val2), Fct, (Val1, Val2)) \ __tgml(Fct) (Val1, Val2) \ : (sizeof (+(Val1)) == sizeof (double) \ || sizeof (+(Val2)) == sizeof (double) \ || __builtin_classify_type (Val1) != 8 \ || __builtin_classify_type (Val2) != 8) \ ? Fct (Val1, Val2) \ : Fct##f (Val1, Val2))) # define __TGMATH_TERNARY_FIRST_SECOND_REAL_ONLY(Val1, Val2, Val3, Fct) \ (__extension__ ((sizeof ((Val1) + (Val2)) > sizeof (double) \ && __builtin_classify_type ((Val1) + (Val2)) == 8) \ ? __TGMATH_F128 ((Val1) + (Val2), \ (__typeof \ ((__tgmath_real_type (Val1)) 0 \ + (__tgmath_real_type (Val2)) 0)) Fct, \ (Val1, Val2, Val3)) \ (__typeof ((__tgmath_real_type (Val1)) 0 \ + (__tgmath_real_type (Val2)) 0)) \ __tgml(Fct) (Val1, Val2, Val3) \ : (sizeof (+(Val1)) == sizeof (double) \ || sizeof (+(Val2)) == sizeof (double) \ || __builtin_classify_type (Val1) != 8 \ || __builtin_classify_type (Val2) != 8) \ ? (__typeof ((__tgmath_real_type (Val1)) 0 \ + (__tgmath_real_type (Val2)) 0)) \ Fct (Val1, Val2, Val3) \ : (__typeof ((__tgmath_real_type (Val1)) 0 \ + (__tgmath_real_type (Val2)) 0)) \ Fct##f (Val1, Val2, Val3))) # define __TGMATH_TERNARY_REAL_ONLY(Val1, Val2, Val3, Fct) \ (__extension__ ((sizeof ((Val1) + (Val2) + (Val3)) > sizeof (double) \ && __builtin_classify_type ((Val1) + (Val2) + (Val3)) \ == 8) \ ? __TGMATH_F128 ((Val1) + (Val2) + (Val3), \ (__typeof \ ((__tgmath_real_type (Val1)) 0 \ + (__tgmath_real_type (Val2)) 0 \ + (__tgmath_real_type (Val3)) 0)) Fct, \ (Val1, Val2, Val3)) \ (__typeof ((__tgmath_real_type (Val1)) 0 \ + (__tgmath_real_type (Val2)) 0 \ + (__tgmath_real_type (Val3)) 0)) \ __tgml(Fct) (Val1, Val2, Val3) \ : (sizeof (+(Val1)) == sizeof (double) \ || sizeof (+(Val2)) == sizeof (double) \ || sizeof (+(Val3)) == sizeof (double) \ || __builtin_classify_type (Val1) != 8 \ || __builtin_classify_type (Val2) != 8 \ || __builtin_classify_type (Val3) != 8) \ ? (__typeof ((__tgmath_real_type (Val1)) 0 \ + (__tgmath_real_type (Val2)) 0 \ + (__tgmath_real_type (Val3)) 0)) \ Fct (Val1, Val2, Val3) \ : (__typeof ((__tgmath_real_type (Val1)) 0 \ + (__tgmath_real_type (Val2)) 0 \ + (__tgmath_real_type (Val3)) 0)) \ Fct##f (Val1, Val2, Val3))) # define __TGMATH_TERNARY_FIRST_REAL_RET_ONLY(Val1, Val2, Val3, Fct) \ (__extension__ ((sizeof (+(Val1)) == sizeof (double) \ || __builtin_classify_type (Val1) != 8) \ ? Fct (Val1, Val2, Val3) \ : (sizeof (+(Val1)) == sizeof (float)) \ ? Fct##f (Val1, Val2, Val3) \ : __TGMATH_F128 ((Val1), Fct, (Val1, Val2, Val3)) \ __tgml(Fct) (Val1, Val2, Val3))) /* XXX This definition has to be changed as soon as the compiler understands the imaginary keyword. */ # define __TGMATH_UNARY_REAL_IMAG(Val, Fct, Cfct) \ (__extension__ ((sizeof (+__real__ (Val)) == sizeof (double) \ || __builtin_classify_type (__real__ (Val)) != 8) \ ? (__expr_is_real (Val) \ ? (__tgmath_complex_type (Val)) Fct (Val) \ : (__tgmath_complex_type (Val)) Cfct (Val)) \ : (sizeof (+__real__ (Val)) == sizeof (float)) \ ? (__expr_is_real (Val) \ ? (__tgmath_complex_type (Val)) Fct##f (Val) \ : (__tgmath_complex_type (Val)) Cfct##f (Val)) \ : __TGMATH_CF128 ((Val), \ (__tgmath_complex_type (Val)) Fct, \ (__tgmath_complex_type (Val)) Cfct, \ (Val)) \ (__expr_is_real (Val) \ ? (__tgmath_complex_type (Val)) __tgml(Fct) (Val) \ : (__tgmath_complex_type (Val)) __tgml(Cfct) (Val)))) # define __TGMATH_UNARY_IMAG(Val, Cfct) \ (__extension__ ((sizeof (+__real__ (Val)) == sizeof (double) \ || __builtin_classify_type (__real__ (Val)) != 8) \ ? (__typeof__ ((__tgmath_real_type (Val)) 0 \ + _Complex_I)) Cfct (Val) \ : (sizeof (+__real__ (Val)) == sizeof (float)) \ ? (__typeof__ ((__tgmath_real_type (Val)) 0 \ + _Complex_I)) Cfct##f (Val) \ : __TGMATH_F128 (__real__ (Val), \ (__typeof__ \ ((__tgmath_real_type (Val)) 0 \ + _Complex_I)) Cfct, (Val)) \ (__typeof__ ((__tgmath_real_type (Val)) 0 \ + _Complex_I)) __tgml(Cfct) (Val))) /* XXX This definition has to be changed as soon as the compiler understands the imaginary keyword. */ # define __TGMATH_UNARY_REAL_IMAG_RET_REAL(Val, Fct, Cfct) \ (__extension__ ((sizeof (+__real__ (Val)) == sizeof (double) \ || __builtin_classify_type (__real__ (Val)) != 8) \ ? (__expr_is_real (Val) \ ? (__typeof__ (__real__ (__tgmath_real_type (Val)) 0))\ Fct (Val) \ : (__typeof__ (__real__ (__tgmath_real_type (Val)) 0))\ Cfct (Val)) \ : (sizeof (+__real__ (Val)) == sizeof (float)) \ ? (__expr_is_real (Val) \ ? (__typeof__ (__real__ (__tgmath_real_type (Val)) 0))\ Fct##f (Val) \ : (__typeof__ (__real__ (__tgmath_real_type (Val)) 0))\ Cfct##f (Val)) \ : __TGMATH_CF128 ((Val), \ (__typeof__ \ (__real__ \ (__tgmath_real_type (Val)) 0)) Fct, \ (__typeof__ \ (__real__ \ (__tgmath_real_type (Val)) 0)) Cfct, \ (Val)) \ (__expr_is_real (Val) \ ? (__typeof__ (__real__ (__tgmath_real_type (Val)) 0)) \ __tgml(Fct) (Val) \ : (__typeof__ (__real__ (__tgmath_real_type (Val)) 0)) \ __tgml(Cfct) (Val)))) # define __TGMATH_UNARY_REAL_IMAG_RET_REAL_SAME(Val, Cfct) \ __TGMATH_UNARY_REAL_IMAG_RET_REAL ((Val), Cfct, Cfct) /* XXX This definition has to be changed as soon as the compiler understands the imaginary keyword. */ # define __TGMATH_BINARY_REAL_IMAG(Val1, Val2, Fct, Cfct) \ (__extension__ ((sizeof (__real__ (Val1) \ + __real__ (Val2)) > sizeof (double) \ && __builtin_classify_type (__real__ (Val1) \ + __real__ (Val2)) == 8) \ ? __TGMATH_CF128 ((Val1) + (Val2), \ (__typeof \ ((__tgmath_complex_type (Val1)) 0 \ + (__tgmath_complex_type (Val2)) 0)) \ Fct, \ (__typeof \ ((__tgmath_complex_type (Val1)) 0 \ + (__tgmath_complex_type (Val2)) 0)) \ Cfct, \ (Val1, Val2)) \ (__expr_is_real ((Val1) + (Val2)) \ ? (__typeof ((__tgmath_complex_type (Val1)) 0 \ + (__tgmath_complex_type (Val2)) 0)) \ __tgml(Fct) (Val1, Val2) \ : (__typeof ((__tgmath_complex_type (Val1)) 0 \ + (__tgmath_complex_type (Val2)) 0)) \ __tgml(Cfct) (Val1, Val2)) \ : (sizeof (+__real__ (Val1)) == sizeof (double) \ || sizeof (+__real__ (Val2)) == sizeof (double) \ || __builtin_classify_type (__real__ (Val1)) != 8 \ || __builtin_classify_type (__real__ (Val2)) != 8) \ ? (__expr_is_real ((Val1) + (Val2)) \ ? (__typeof ((__tgmath_complex_type (Val1)) 0 \ + (__tgmath_complex_type (Val2)) 0)) \ Fct (Val1, Val2) \ : (__typeof ((__tgmath_complex_type (Val1)) 0 \ + (__tgmath_complex_type (Val2)) 0)) \ Cfct (Val1, Val2)) \ : (__expr_is_real ((Val1) + (Val2)) \ ? (__typeof ((__tgmath_complex_type (Val1)) 0 \ + (__tgmath_complex_type (Val2)) 0)) \ Fct##f (Val1, Val2) \ : (__typeof ((__tgmath_complex_type (Val1)) 0 \ + (__tgmath_complex_type (Val2)) 0)) \ Cfct##f (Val1, Val2)))) # endif /* !__HAVE_BUILTIN_TGMATH. */ #else # error "Unsupported compiler; you cannot use <tgmath.h>" #endif /* Unary functions defined for real and complex values. */ /* Trigonometric functions. */ /* Arc cosine of X. */ #define acos(Val) __TGMATH_UNARY_REAL_IMAG (Val, acos, cacos) /* Arc sine of X. */ #define asin(Val) __TGMATH_UNARY_REAL_IMAG (Val, asin, casin) /* Arc tangent of X. */ #define atan(Val) __TGMATH_UNARY_REAL_IMAG (Val, atan, catan) /* Arc tangent of Y/X. */ #define atan2(Val1, Val2) __TGMATH_BINARY_REAL_ONLY (Val1, Val2, atan2) /* Cosine of X. */ #define cos(Val) __TGMATH_UNARY_REAL_IMAG (Val, cos, ccos) /* Sine of X. */ #define sin(Val) __TGMATH_UNARY_REAL_IMAG (Val, sin, csin) /* Tangent of X. */ #define tan(Val) __TGMATH_UNARY_REAL_IMAG (Val, tan, ctan) /* Hyperbolic functions. */ /* Hyperbolic arc cosine of X. */ #define acosh(Val) __TGMATH_UNARY_REAL_IMAG (Val, acosh, cacosh) /* Hyperbolic arc sine of X. */ #define asinh(Val) __TGMATH_UNARY_REAL_IMAG (Val, asinh, casinh) /* Hyperbolic arc tangent of X. */ #define atanh(Val) __TGMATH_UNARY_REAL_IMAG (Val, atanh, catanh) /* Hyperbolic cosine of X. */ #define cosh(Val) __TGMATH_UNARY_REAL_IMAG (Val, cosh, ccosh) /* Hyperbolic sine of X. */ #define sinh(Val) __TGMATH_UNARY_REAL_IMAG (Val, sinh, csinh) /* Hyperbolic tangent of X. */ #define tanh(Val) __TGMATH_UNARY_REAL_IMAG (Val, tanh, ctanh) /* Exponential and logarithmic functions. */ /* Exponential function of X. */ #define exp(Val) __TGMATH_UNARY_REAL_IMAG (Val, exp, cexp) /* Break VALUE into a normalized fraction and an integral power of 2. */ #define frexp(Val1, Val2) __TGMATH_BINARY_FIRST_REAL_ONLY (Val1, Val2, frexp) /* X times (two to the EXP power). */ #define ldexp(Val1, Val2) __TGMATH_BINARY_FIRST_REAL_ONLY (Val1, Val2, ldexp) /* Natural logarithm of X. */ #define log(Val) __TGMATH_UNARY_REAL_IMAG (Val, log, clog) /* Base-ten logarithm of X. */ #ifdef __USE_GNU # define log10(Val) __TGMATH_UNARY_REAL_IMAG (Val, log10, clog10) #else # define log10(Val) __TGMATH_UNARY_REAL_ONLY (Val, log10) #endif /* Return exp(X) - 1. */ #define expm1(Val) __TGMATH_UNARY_REAL_ONLY (Val, expm1) /* Return log(1 + X). */ #define log1p(Val) __TGMATH_UNARY_REAL_ONLY (Val, log1p) /* Return the base 2 signed integral exponent of X. */ #define logb(Val) __TGMATH_UNARY_REAL_ONLY (Val, logb) /* Compute base-2 exponential of X. */ #define exp2(Val) __TGMATH_UNARY_REAL_ONLY (Val, exp2) /* Compute base-2 logarithm of X. */ #define log2(Val) __TGMATH_UNARY_REAL_ONLY (Val, log2) /* Power functions. */ /* Return X to the Y power. */ #define pow(Val1, Val2) __TGMATH_BINARY_REAL_IMAG (Val1, Val2, pow, cpow) /* Return the square root of X. */ #define sqrt(Val) __TGMATH_UNARY_REAL_IMAG (Val, sqrt, csqrt) /* Return `sqrt(X*X + Y*Y)'. */ #define hypot(Val1, Val2) __TGMATH_BINARY_REAL_ONLY (Val1, Val2, hypot) /* Return the cube root of X. */ #define cbrt(Val) __TGMATH_UNARY_REAL_ONLY (Val, cbrt) /* Nearest integer, absolute value, and remainder functions. */ /* Smallest integral value not less than X. */ #define ceil(Val) __TGMATH_UNARY_REAL_ONLY (Val, ceil) /* Absolute value of X. */ #define fabs(Val) __TGMATH_UNARY_REAL_IMAG_RET_REAL (Val, fabs, cabs) /* Largest integer not greater than X. */ #define floor(Val) __TGMATH_UNARY_REAL_ONLY (Val, floor) /* Floating-point modulo remainder of X/Y. */ #define fmod(Val1, Val2) __TGMATH_BINARY_REAL_ONLY (Val1, Val2, fmod) /* Round X to integral valuein floating-point format using current rounding direction, but do not raise inexact exception. */ #define nearbyint(Val) __TGMATH_UNARY_REAL_ONLY (Val, nearbyint) /* Round X to nearest integral value, rounding halfway cases away from zero. */ #define round(Val) __TGMATH_UNARY_REAL_ONLY (Val, round) /* Round X to the integral value in floating-point format nearest but not larger in magnitude. */ #define trunc(Val) __TGMATH_UNARY_REAL_ONLY (Val, trunc) /* Compute remainder of X and Y and put in *QUO a value with sign of x/y and magnitude congruent `mod 2^n' to the magnitude of the integral quotient x/y, with n >= 3. */ #define remquo(Val1, Val2, Val3) \ __TGMATH_TERNARY_FIRST_SECOND_REAL_ONLY (Val1, Val2, Val3, remquo) /* Round X to nearest integral value according to current rounding direction. */ #define lrint(Val) __TGMATH_UNARY_REAL_RET_ONLY (Val, lrint) #define llrint(Val) __TGMATH_UNARY_REAL_RET_ONLY (Val, llrint) /* Round X to nearest integral value, rounding halfway cases away from zero. */ #define lround(Val) __TGMATH_UNARY_REAL_RET_ONLY (Val, lround) #define llround(Val) __TGMATH_UNARY_REAL_RET_ONLY (Val, llround) /* Return X with its signed changed to Y's. */ #define copysign(Val1, Val2) __TGMATH_BINARY_REAL_ONLY (Val1, Val2, copysign) /* Error and gamma functions. */ #define erf(Val) __TGMATH_UNARY_REAL_ONLY (Val, erf) #define erfc(Val) __TGMATH_UNARY_REAL_ONLY (Val, erfc) #define tgamma(Val) __TGMATH_UNARY_REAL_ONLY (Val, tgamma) #define lgamma(Val) __TGMATH_UNARY_REAL_ONLY (Val, lgamma) /* Return the integer nearest X in the direction of the prevailing rounding mode. */ #define rint(Val) __TGMATH_UNARY_REAL_ONLY (Val, rint) #if __GLIBC_USE (IEC_60559_BFP_EXT) /* Return X - epsilon. */ # define nextdown(Val) __TGMATH_UNARY_REAL_ONLY (Val, nextdown) /* Return X + epsilon. */ # define nextup(Val) __TGMATH_UNARY_REAL_ONLY (Val, nextup) #endif /* Return X + epsilon if X < Y, X - epsilon if X > Y. */ #define nextafter(Val1, Val2) __TGMATH_BINARY_REAL_ONLY (Val1, Val2, nextafter) #define nexttoward(Val1, Val2) \ __TGMATH_BINARY_FIRST_REAL_STD_ONLY (Val1, Val2, nexttoward) /* Return the remainder of integer divison X / Y with infinite precision. */ #define remainder(Val1, Val2) __TGMATH_BINARY_REAL_ONLY (Val1, Val2, remainder) /* Return X times (2 to the Nth power). */ #ifdef __USE_MISC # define scalb(Val1, Val2) __TGMATH_BINARY_REAL_STD_ONLY (Val1, Val2, scalb) #endif /* Return X times (2 to the Nth power). */ #define scalbn(Val1, Val2) __TGMATH_BINARY_FIRST_REAL_ONLY (Val1, Val2, scalbn) /* Return X times (2 to the Nth power). */ #define scalbln(Val1, Val2) \ __TGMATH_BINARY_FIRST_REAL_ONLY (Val1, Val2, scalbln) /* Return the binary exponent of X, which must be nonzero. */ #define ilogb(Val) __TGMATH_UNARY_REAL_RET_ONLY (Val, ilogb) /* Return positive difference between X and Y. */ #define fdim(Val1, Val2) __TGMATH_BINARY_REAL_ONLY (Val1, Val2, fdim) /* Return maximum numeric value from X and Y. */ #define fmax(Val1, Val2) __TGMATH_BINARY_REAL_ONLY (Val1, Val2, fmax) /* Return minimum numeric value from X and Y. */ #define fmin(Val1, Val2) __TGMATH_BINARY_REAL_ONLY (Val1, Val2, fmin) /* Multiply-add function computed as a ternary operation. */ #define fma(Val1, Val2, Val3) \ __TGMATH_TERNARY_REAL_ONLY (Val1, Val2, Val3, fma) #if __GLIBC_USE (IEC_60559_BFP_EXT) /* Round X to nearest integer value, rounding halfway cases to even. */ # define roundeven(Val) __TGMATH_UNARY_REAL_ONLY (Val, roundeven) # define fromfp(Val1, Val2, Val3) \ __TGMATH_TERNARY_FIRST_REAL_RET_ONLY (Val1, Val2, Val3, fromfp) # define ufromfp(Val1, Val2, Val3) \ __TGMATH_TERNARY_FIRST_REAL_RET_ONLY (Val1, Val2, Val3, ufromfp) # define fromfpx(Val1, Val2, Val3) \ __TGMATH_TERNARY_FIRST_REAL_RET_ONLY (Val1, Val2, Val3, fromfpx) # define ufromfpx(Val1, Val2, Val3) \ __TGMATH_TERNARY_FIRST_REAL_RET_ONLY (Val1, Val2, Val3, ufromfpx) /* Like ilogb, but returning long int. */ # define llogb(Val) __TGMATH_UNARY_REAL_RET_ONLY (Val, llogb) /* Return value with maximum magnitude. */ # define fmaxmag(Val1, Val2) __TGMATH_BINARY_REAL_ONLY (Val1, Val2, fmaxmag) /* Return value with minimum magnitude. */ # define fminmag(Val1, Val2) __TGMATH_BINARY_REAL_ONLY (Val1, Val2, fminmag) /* Total order operation. */ # define totalorder(Val1, Val2) \ __TGMATH_BINARY_REAL_RET_ONLY (Val1, Val2, totalorder) /* Total order operation on absolute values. */ # define totalordermag(Val1, Val2) \ __TGMATH_BINARY_REAL_RET_ONLY (Val1, Val2, totalordermag) #endif /* Absolute value, conjugates, and projection. */ /* Argument value of Z. */ #define carg(Val) __TGMATH_UNARY_REAL_IMAG_RET_REAL_SAME (Val, carg) /* Complex conjugate of Z. */ #define conj(Val) __TGMATH_UNARY_IMAG (Val, conj) /* Projection of Z onto the Riemann sphere. */ #define cproj(Val) __TGMATH_UNARY_IMAG (Val, cproj) /* Decomposing complex values. */ /* Imaginary part of Z. */ #define cimag(Val) __TGMATH_UNARY_REAL_IMAG_RET_REAL_SAME (Val, cimag) /* Real part of Z. */ #define creal(Val) __TGMATH_UNARY_REAL_IMAG_RET_REAL_SAME (Val, creal) #endif /* tgmath.h */