/* @(#)fdlibm.h 5.1 93/09/24 */ /* * ==================================================== * Copyright (C) 1993 by Sun Microsystems, Inc. All rights reserved. * * Developed at SunPro, a Sun Microsystems, Inc. business. * Permission to use, copy, modify, and distribute this * software is freely granted, provided that this notice * is preserved. * ==================================================== */ /* REDHAT LOCAL: Include files. */ #include #include #include #include "math_config.h" /* Most routines need to check whether a float is finite, infinite, or not a number, and many need to know whether the result of an operation will overflow. These conditions depend on whether the largest exponent is used for NaNs & infinities, or whether it's used for finite numbers. The macros below wrap up that kind of information: FLT_UWORD_IS_FINITE(X) True if a positive float with bitmask X is finite. FLT_UWORD_IS_NAN(X) True if a positive float with bitmask X is not a number. FLT_UWORD_IS_INFINITE(X) True if a positive float with bitmask X is +infinity. FLT_UWORD_MAX The bitmask of FLT_MAX. FLT_UWORD_HALF_MAX The bitmask of FLT_MAX/2. FLT_UWORD_EXP_MAX The bitmask of the largest finite exponent (129 if the largest exponent is used for finite numbers, 128 otherwise). FLT_UWORD_LOG_MAX The bitmask of log(FLT_MAX), rounded down. This value is the largest input that can be passed to exp() without producing overflow. FLT_UWORD_LOG_2MAX The bitmask of log(2*FLT_MAX), rounded down. This value is the largest input than can be passed to cosh() without producing overflow. FLT_LARGEST_EXP The largest biased exponent that can be used for finite numbers (255 if the largest exponent is used for finite numbers, 254 otherwise) */ #ifdef _FLT_LARGEST_EXPONENT_IS_NORMAL #define FLT_UWORD_IS_FINITE(x) 1 #define FLT_UWORD_IS_NAN(x) 0 #define FLT_UWORD_IS_INFINITE(x) 0 #define FLT_UWORD_MAX 0x7fffffff #define FLT_UWORD_EXP_MAX 0x43010000 #define FLT_UWORD_LOG_MAX 0x42b2d4fc #define FLT_UWORD_LOG_2MAX 0x42b437e0 #define HUGE ((float)0X1.FFFFFEP128) #else #define FLT_UWORD_IS_FINITE(x) ((x)<0x7f800000L) #define FLT_UWORD_IS_NAN(x) ((x)>0x7f800000L) #define FLT_UWORD_IS_INFINITE(x) ((x)==0x7f800000L) #define FLT_UWORD_MAX 0x7f7fffffL #define FLT_UWORD_EXP_MAX 0x43000000 #define FLT_UWORD_LOG_MAX 0x42b17217 #define FLT_UWORD_LOG_2MAX 0x42b2d4fc #define HUGE ((float)3.40282346638528860e+38) #endif #define FLT_UWORD_HALF_MAX (FLT_UWORD_MAX-(1L<<23)) #define FLT_LARGEST_EXP (FLT_UWORD_MAX>>23) /* Many routines check for zero and subnormal numbers. Such things depend on whether the target supports denormals or not: FLT_UWORD_IS_ZERO(X) True if a positive float with bitmask X is +0. Without denormals, any float with a zero exponent is a +0 representation. With denormals, the only +0 representation is a 0 bitmask. FLT_UWORD_IS_SUBNORMAL(X) True if a non-zero positive float with bitmask X is subnormal. (Routines should check for zeros first.) FLT_UWORD_MIN The bitmask of the smallest float above +0. Call this number REAL_FLT_MIN... FLT_UWORD_EXP_MIN The bitmask of the float representation of REAL_FLT_MIN's exponent. FLT_UWORD_LOG_MIN The bitmask of |log(REAL_FLT_MIN)|, rounding down. FLT_SMALLEST_EXP REAL_FLT_MIN's exponent - EXP_BIAS (1 if denormals are not supported, -22 if they are). */ #ifdef _FLT_NO_DENORMALS #define FLT_UWORD_IS_ZERO(x) ((x)<0x00800000L) #define FLT_UWORD_IS_SUBNORMAL(x) 0 #define FLT_UWORD_MIN 0x00800000 #define FLT_UWORD_EXP_MIN 0x42fc0000 #define FLT_UWORD_LOG_MIN 0x42aeac50 #define FLT_SMALLEST_EXP 1 #else #define FLT_UWORD_IS_ZERO(x) ((x)==0) #define FLT_UWORD_IS_SUBNORMAL(x) ((x)<0x00800000L) #define FLT_UWORD_MIN 0x00000001 #define FLT_UWORD_EXP_MIN 0x43160000 #define FLT_UWORD_LOG_MIN 0x42cff1b5 #define FLT_SMALLEST_EXP -22 #endif #ifdef __STDC__ #undef __P #define __P(p) p #else #define __P(p) () #endif /* * set X_TLOSS = pi*2**52, which is possibly defined in * (one may replace the following line by "#include ") */ #define X_TLOSS 1.41484755040568800000e+16 /* Functions that are not documented, and are not in . */ #ifdef _SCALB_INT extern double scalb __P((double, int)); #else extern double scalb __P((double, double)); #endif extern double significand __P((double)); extern long double __ieee754_hypotl __P((long double, long double)); /* ieee style elementary functions */ extern double __ieee754_sqrt __P((double)); extern double __ieee754_acos __P((double)); extern double __ieee754_acosh __P((double)); extern double __ieee754_log __P((double)); extern double __ieee754_atanh __P((double)); extern double __ieee754_asin __P((double)); extern double __ieee754_atan2 __P((double,double)); extern double __ieee754_exp __P((double)); extern double __ieee754_cosh __P((double)); extern double __ieee754_fmod __P((double,double)); extern double __ieee754_pow __P((double,double)); extern double __ieee754_lgamma_r __P((double,int *)); extern double __ieee754_gamma_r __P((double,int *)); extern double __ieee754_tgamma __P((double)); extern double __ieee754_log10 __P((double)); extern double __ieee754_sinh __P((double)); extern double __ieee754_hypot __P((double,double)); extern double __ieee754_j0 __P((double)); extern double __ieee754_j1 __P((double)); extern double __ieee754_y0 __P((double)); extern double __ieee754_y1 __P((double)); extern double __ieee754_jn __P((int,double)); extern double __ieee754_yn __P((int,double)); extern double __ieee754_remainder __P((double,double)); extern __int32_t __ieee754_rem_pio2 __P((double,double*)); #ifdef _SCALB_INT extern double __ieee754_scalb __P((double,int)); #else extern double __ieee754_scalb __P((double,double)); #endif /* fdlibm kernel function */ extern double __kernel_standard __P((double,double,int)); extern double __kernel_sin __P((double,double,int)); extern double __kernel_cos __P((double,double)); extern double __kernel_tan __P((double,double,int)); extern int __kernel_rem_pio2 __P((double*,double*,int,int,int,const __int32_t*)); /* Undocumented float functions. */ #ifdef _SCALB_INT extern float scalbf __P((float, int)); #else extern float scalbf __P((float, float)); #endif extern float significandf __P((float)); /* ieee style elementary float functions */ extern float __ieee754_sqrtf __P((float)); extern float __ieee754_acosf __P((float)); extern float __ieee754_acoshf __P((float)); extern float __ieee754_logf __P((float)); extern float __ieee754_atanhf __P((float)); extern float __ieee754_asinf __P((float)); extern float __ieee754_atan2f __P((float,float)); extern float __ieee754_expf __P((float)); extern float __ieee754_coshf __P((float)); extern float __ieee754_fmodf __P((float,float)); extern float __ieee754_powf __P((float,float)); extern float __ieee754_lgammaf_r __P((float,int *)); extern float __ieee754_gammaf_r __P((float,int *)); extern float __ieee754_tgammaf __P((float)); extern float __ieee754_log10f __P((float)); extern float __ieee754_sinhf __P((float)); extern float __ieee754_hypotf __P((float,float)); extern float __ieee754_j0f __P((float)); extern float __ieee754_j1f __P((float)); extern float __ieee754_y0f __P((float)); extern float __ieee754_y1f __P((float)); extern float __ieee754_jnf __P((int,float)); extern float __ieee754_ynf __P((int,float)); extern float __ieee754_remainderf __P((float,float)); extern __int32_t __ieee754_rem_pio2f __P((float,float*)); #ifdef _SCALB_INT extern float __ieee754_scalbf __P((float,int)); #else extern float __ieee754_scalbf __P((float,float)); #endif #if !__OBSOLETE_MATH /* The new math code does not provide separate wrapper function for error handling, so the extern symbol is called directly. This is valid as long as there are no namespace issues (the extern symbol is reserved whenever the caller is reserved) and there are no observable error handling side effects. */ # define __ieee754_exp(x) exp(x) # define __ieee754_log(x) log(x) # define __ieee754_pow(x,y) pow(x,y) # define __ieee754_expf(x) expf(x) # define __ieee754_logf(x) logf(x) # define __ieee754_powf(x,y) powf(x,y) #endif /* float versions of fdlibm kernel functions */ extern float __kernel_sinf __P((float,float,int)); extern float __kernel_cosf __P((float,float)); extern float __kernel_tanf __P((float,float,int)); extern int __kernel_rem_pio2f __P((float*,float*,int,int,int,const __int32_t*)); /* The original code used statements like n0 = ((*(int*)&one)>>29)^1; * index of high word * ix0 = *(n0+(int*)&x); * high word of x * ix1 = *((1-n0)+(int*)&x); * low word of x * to dig two 32 bit words out of the 64 bit IEEE floating point value. That is non-ANSI, and, moreover, the gcc instruction scheduler gets it wrong. We instead use the following macros. Unlike the original code, we determine the endianness at compile time, not at run time; I don't see much benefit to selecting endianness at run time. */ #ifndef __IEEE_BIG_ENDIAN #ifndef __IEEE_LITTLE_ENDIAN #error Must define endianness #endif #endif /* A union which permits us to convert between a double and two 32 bit ints. */ #ifdef __IEEE_BIG_ENDIAN typedef union { double value; struct { __uint32_t msw; __uint32_t lsw; } parts; } ieee_double_shape_type; #endif #ifdef __IEEE_LITTLE_ENDIAN typedef union { double value; struct { __uint32_t lsw; __uint32_t msw; } parts; } ieee_double_shape_type; #endif /* Get two 32 bit ints from a double. */ #define EXTRACT_WORDS(ix0,ix1,d) \ do { \ ieee_double_shape_type ew_u; \ ew_u.value = (d); \ (ix0) = ew_u.parts.msw; \ (ix1) = ew_u.parts.lsw; \ } while (0) /* Get the more significant 32 bit int from a double. */ #define GET_HIGH_WORD(i,d) \ do { \ ieee_double_shape_type gh_u; \ gh_u.value = (d); \ (i) = gh_u.parts.msw; \ } while (0) /* Get the less significant 32 bit int from a double. */ #define GET_LOW_WORD(i,d) \ do { \ ieee_double_shape_type gl_u; \ gl_u.value = (d); \ (i) = gl_u.parts.lsw; \ } while (0) /* Set a double from two 32 bit ints. */ #define INSERT_WORDS(d,ix0,ix1) \ do { \ ieee_double_shape_type iw_u; \ iw_u.parts.msw = (ix0); \ iw_u.parts.lsw = (ix1); \ (d) = iw_u.value; \ } while (0) /* Set the more significant 32 bits of a double from an int. */ #define SET_HIGH_WORD(d,v) \ do { \ ieee_double_shape_type sh_u; \ sh_u.value = (d); \ sh_u.parts.msw = (v); \ (d) = sh_u.value; \ } while (0) /* Set the less significant 32 bits of a double from an int. */ #define SET_LOW_WORD(d,v) \ do { \ ieee_double_shape_type sl_u; \ sl_u.value = (d); \ sl_u.parts.lsw = (v); \ (d) = sl_u.value; \ } while (0) /* A union which permits us to convert between a float and a 32 bit int. */ typedef union { float value; __uint32_t word; } ieee_float_shape_type; /* Get a 32 bit int from a float. */ #define GET_FLOAT_WORD(i,d) \ do { \ ieee_float_shape_type gf_u; \ gf_u.value = (d); \ (i) = gf_u.word; \ } while (0) /* Set a float from a 32 bit int. */ #define SET_FLOAT_WORD(d,i) \ do { \ ieee_float_shape_type sf_u; \ sf_u.word = (i); \ (d) = sf_u.value; \ } while (0) /* Macros to avoid undefined behaviour that can arise if the amount of a shift is exactly equal to the size of the shifted operand. */ #define SAFE_LEFT_SHIFT(op,amt) \ (((amt) < 8 * sizeof(op)) ? ((op) << (amt)) : 0) #define SAFE_RIGHT_SHIFT(op,amt) \ (((amt) < 8 * sizeof(op)) ? ((op) >> (amt)) : 0) #ifdef _COMPLEX_H /* * Quoting from ISO/IEC 9899:TC2: * * 6.2.5.13 Types * Each complex type has the same representation and alignment requirements as * an array type containing exactly two elements of the corresponding real type; * the first element is equal to the real part, and the second element to the * imaginary part, of the complex number. */ typedef union { float complex z; float parts[2]; } float_complex; typedef union { double complex z; double parts[2]; } double_complex; typedef union { long double complex z; long double parts[2]; } long_double_complex; #define REAL_PART(z) ((z).parts[0]) #define IMAG_PART(z) ((z).parts[1]) #endif /* _COMPLEX_H */