mirror of https://git.musl-libc.org/git/musl
271 lines
8.4 KiB
C
271 lines
8.4 KiB
C
#ifndef _TGMATH_H
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#define _TGMATH_H
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/*
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the return types are only correct with gcc (__GNUC__)
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otherwise they are long double or long double complex
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the long double version of a function is never chosen when
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sizeof(double) == sizeof(long double)
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(but the return type is set correctly with gcc)
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*/
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#include <math.h>
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#include <complex.h>
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#define __IS_FP(x) (sizeof((x)+1ULL) == sizeof((x)+1.0f))
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#define __IS_CX(x) (__IS_FP(x) && sizeof(x) == sizeof((x)+I))
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#define __IS_REAL(x) (__IS_FP(x) && 2*sizeof(x) == sizeof((x)+I))
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#define __FLT(x) (__IS_REAL(x) && sizeof(x) == sizeof(float))
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#define __LDBL(x) (__IS_REAL(x) && sizeof(x) == sizeof(long double) && sizeof(long double) != sizeof(double))
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#define __FLTCX(x) (__IS_CX(x) && sizeof(x) == sizeof(float complex))
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#define __DBLCX(x) (__IS_CX(x) && sizeof(x) == sizeof(double complex))
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#define __LDBLCX(x) (__IS_CX(x) && sizeof(x) == sizeof(long double complex) && sizeof(long double) != sizeof(double))
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/* return type */
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#ifdef __GNUC__
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/*
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the result must be casted to the right type
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(otherwise the result type is determined by the conversion
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rules applied to all the function return types so it is long
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double or long double complex except for integral functions)
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this cannot be done in c99, so the typeof gcc extension is
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used and that the type of ?: depends on wether an operand is
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a null pointer constant or not
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(in c11 _Generic can be used)
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the c arguments below must be integer constant expressions
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so they can be in null pointer constants
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(__IS_FP above was carefully chosen this way)
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*/
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/* if c then t else void */
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#define __type1(c,t) __typeof__(*(0?(t*)0:(void*)!(c)))
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/* if c then t1 else t2 */
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#define __type2(c,t1,t2) __typeof__(*(0?(__type1(c,t1)*)0:(__type1(!(c),t2)*)0))
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/* cast to double when x is integral, otherwise use typeof(x) */
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#define __RETCAST(x) ( \
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__type2(__IS_FP(x), __typeof__(x), double))
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/* 2 args case, should work for complex types (cpow) */
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#define __RETCAST_2(x, y) ( \
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__type2(__IS_FP(x) && __IS_FP(y), \
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__typeof__((x)+(y)), \
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__typeof__((x)+(y)+1.0)))
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/* 3 args case (fma only) */
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#define __RETCAST_3(x, y, z) ( \
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__type2(__IS_FP(x) && __IS_FP(y) && __IS_FP(z), \
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__typeof__((x)+(y)+(z)), \
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__typeof__((x)+(y)+(z)+1.0)))
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/* drop complex from the type of x */
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/* TODO: wrong when sizeof(long double)==sizeof(double) */
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#define __RETCAST_REAL(x) ( \
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__type2(__IS_FP(x) && sizeof((x)+I) == sizeof(float complex), float, \
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__type2(sizeof((x)+1.0+I) == sizeof(double complex), double, \
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long double)))
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/* add complex to the type of x */
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#define __RETCAST_CX(x) (__typeof__(__RETCAST(x)0+I))
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#else
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#define __RETCAST(x)
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#define __RETCAST_2(x, y)
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#define __RETCAST_3(x, y, z)
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#define __RETCAST_REAL(x)
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#define __RETCAST_CX(x)
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#endif
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/* function selection */
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#define __tg_real_nocast(fun, x) ( \
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__FLT(x) ? fun ## f (x) : \
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__LDBL(x) ? fun ## l (x) : \
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fun(x) )
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#define __tg_real(fun, x) (__RETCAST(x)__tg_real_nocast(fun, x))
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#define __tg_real_2_1(fun, x, y) (__RETCAST(x)( \
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__FLT(x) ? fun ## f (x, y) : \
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__LDBL(x) ? fun ## l (x, y) : \
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fun(x, y) ))
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#define __tg_real_2(fun, x, y) (__RETCAST_2(x, y)( \
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__FLT(x) && __FLT(y) ? fun ## f (x, y) : \
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__LDBL((x)+(y)) ? fun ## l (x, y) : \
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fun(x, y) ))
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#define __tg_complex(fun, x) (__RETCAST_CX(x)( \
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__FLTCX((x)+I) && __IS_FP(x) ? fun ## f (x) : \
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__LDBLCX((x)+I) ? fun ## l (x) : \
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fun(x) ))
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#define __tg_complex_retreal(fun, x) (__RETCAST_REAL(x)( \
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__FLTCX((x)+I) && __IS_FP(x) ? fun ## f (x) : \
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__LDBLCX((x)+I) ? fun ## l (x) : \
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fun(x) ))
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#define __tg_real_complex(fun, x) (__RETCAST(x)( \
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__FLTCX(x) ? c ## fun ## f (x) : \
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__DBLCX(x) ? c ## fun (x) : \
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__LDBLCX(x) ? c ## fun ## l (x) : \
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__FLT(x) ? fun ## f (x) : \
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__LDBL(x) ? fun ## l (x) : \
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fun(x) ))
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/* special cases */
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#define __tg_real_remquo(x, y, z) (__RETCAST_2(x, y)( \
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__FLT(x) && __FLT(y) ? remquof(x, y, z) : \
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__LDBL((x)+(y)) ? remquol(x, y, z) : \
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remquo(x, y, z) ))
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#define __tg_real_fma(x, y, z) (__RETCAST_3(x, y, z)( \
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__FLT(x) && __FLT(y) && __FLT(z) ? fmaf(x, y, z) : \
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__LDBL((x)+(y)+(z)) ? fmal(x, y, z) : \
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fma(x, y, z) ))
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#define __tg_real_complex_pow(x, y) (__RETCAST_2(x, y)( \
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__FLTCX((x)+(y)) && __IS_FP(x) && __IS_FP(y) ? cpowf(x, y) : \
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__FLTCX((x)+(y)) ? cpow(x, y) : \
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__DBLCX((x)+(y)) ? cpow(x, y) : \
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__LDBLCX((x)+(y)) ? cpowl(x, y) : \
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__FLT(x) && __FLT(y) ? powf(x, y) : \
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__LDBL((x)+(y)) ? powl(x, y) : \
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pow(x, y) ))
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#define __tg_real_complex_fabs(x) (__RETCAST_REAL(x)( \
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__FLTCX(x) ? cabsf(x) : \
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__DBLCX(x) ? cabs(x) : \
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__LDBLCX(x) ? cabsl(x) : \
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__FLT(x) ? fabsf(x) : \
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__LDBL(x) ? fabsl(x) : \
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fabs(x) ))
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/* suppress any macros in math.h or complex.h */
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#undef acos
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#undef acosh
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#undef asin
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#undef asinh
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#undef atan
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#undef atan2
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#undef atanh
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#undef carg
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#undef cbrt
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#undef ceil
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#undef cimag
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#undef conj
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#undef copysign
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#undef cos
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#undef cosh
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#undef cproj
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#undef creal
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#undef erf
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#undef erfc
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#undef exp
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#undef exp2
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#undef expm1
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#undef fabs
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#undef fdim
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#undef floor
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#undef fma
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#undef fmax
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#undef fmin
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#undef fmod
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#undef frexp
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#undef hypot
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#undef ilogb
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#undef ldexp
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#undef lgamma
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#undef llrint
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#undef llround
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#undef log
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#undef log10
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#undef log1p
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#undef log2
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#undef logb
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#undef lrint
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#undef lround
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#undef nearbyint
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#undef nextafter
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#undef nexttoward
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#undef pow
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#undef remainder
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#undef remquo
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#undef rint
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#undef round
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#undef scalbln
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#undef scalbn
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#undef sin
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#undef sinh
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#undef sqrt
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#undef tan
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#undef tanh
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#undef tgamma
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#undef trunc
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/* tg functions */
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#define acos(x) __tg_real_complex(acos, (x))
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#define acosh(x) __tg_real_complex(acosh, (x))
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#define asin(x) __tg_real_complex(asin, (x))
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#define asinh(x) __tg_real_complex(asinh, (x))
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#define atan(x) __tg_real_complex(atan, (x))
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#define atan2(x,y) __tg_real_2(atan2, (x), (y))
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#define atanh(x) __tg_real_complex(atanh, (x))
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#define carg(x) __tg_complex_retreal(carg, (x))
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#define cbrt(x) __tg_real(cbrt, (x))
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#define ceil(x) __tg_real(ceil, (x))
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#define cimag(x) __tg_complex_retreal(cimag, (x))
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#define conj(x) __tg_complex(conj, (x))
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#define copysign(x,y) __tg_real_2(copysign, (x), (y))
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#define cos(x) __tg_real_complex(cos, (x))
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#define cosh(x) __tg_real_complex(cosh, (x))
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#define cproj(x) __tg_complex(cproj, (x))
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#define creal(x) __tg_complex_retreal(creal, (x))
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#define erf(x) __tg_real(erf, (x))
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#define erfc(x) __tg_real(erfc, (x))
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#define exp(x) __tg_real_complex(exp, (x))
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#define exp2(x) __tg_real(exp2, (x))
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#define expm1(x) __tg_real(expm1, (x))
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#define fabs(x) __tg_real_complex_fabs(x)
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#define fdim(x,y) __tg_real_2(fdim, (x), (y))
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#define floor(x) __tg_real(floor, (x))
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#define fma(x,y,z) __tg_real_fma((x), (y), (z))
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#define fmax(x,y) __tg_real_2(fmax, (x), (y))
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#define fmin(x,y) __tg_real_2(fmin, (x), (y))
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#define fmod(x,y) __tg_real_2(fmod, (x), (y))
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#define frexp(x,y) __tg_real_2_1(frexp, (x), (y))
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#define hypot(x,y) __tg_real_2(hypot, (x), (y))
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#define ilogb(x) __tg_real_nocast(ilogb, (x))
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#define ldexp(x,y) __tg_real_2_1(ldexp, (x), (y))
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#define lgamma(x) __tg_real(lgamma, (x))
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#define llrint(x) __tg_real_nocast(llrint, (x))
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#define llround(x) __tg_real_nocast(llround, (x))
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#define log(x) __tg_real_complex(log, (x))
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#define log10(x) __tg_real(log10, (x))
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#define log1p(x) __tg_real(log1p, (x))
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#define log2(x) __tg_real(log2, (x))
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#define logb(x) __tg_real(logb, (x))
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#define lrint(x) __tg_real_nocast(lrint, (x))
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#define lround(x) __tg_real_nocast(lround, (x))
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#define nearbyint(x) __tg_real(nearbyint, (x))
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#define nextafter(x,y) __tg_real_2(nextafter, (x), (y))
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#define nexttoward(x,y) __tg_real_2(nexttoward, (x), (y))
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#define pow(x,y) __tg_real_complex_pow((x), (y))
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#define remainder(x,y) __tg_real_2(remainder, (x), (y))
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#define remquo(x,y,z) __tg_real_remquo((x), (y), (z))
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#define rint(x) __tg_real(rint, (x))
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#define round(x) __tg_real(round, (x))
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#define scalbln(x,y) __tg_real_2_1(scalbln, (x), (y))
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#define scalbn(x,y) __tg_real_2_1(scalbn, (x), (y))
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#define sin(x) __tg_real_complex(sin, (x))
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#define sinh(x) __tg_real_complex(sinh, (x))
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#define sqrt(x) __tg_real_complex(sqrt, (x))
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#define tan(x) __tg_real_complex(tan, (x))
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#define tanh(x) __tg_real_complex(tanh, (x))
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#define tgamma(x) __tg_real(tgamma, (x))
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#define trunc(x) __tg_real(trunc, (x))
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#endif
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