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Thu Mar 14 15:20:45 1996 Andreas Schwab <schwab@issan.informatik.uni-dortmund.de>

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* sysdeps/m68k/fpu/__math.h: Rewritten for fdlibm.
This commit is contained in:
Roland McGrath 1996-03-16 21:30:15 +00:00
parent 61e73b405a
commit 8849f1d244
1 changed files with 277 additions and 81 deletions
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358
sysdeps/m68k/fpu/__math.h
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@ -19,8 +19,6 @@ Cambridge, MA 02139, USA. */
#ifdef __GNUC__
#include <sys/cdefs.h>
#define __need_Emath
#include <errno.h>
#ifdef __NO_MATH_INLINES
/* This is used when defining the functions themselves. Define them with
@ -34,59 +32,87 @@ Cambridge, MA 02139, USA. */
#define __MATH_INLINES 1
#endif
#define __inline_mathop2(func, op) \
__m81_inline double \
__m81_u(func)(double __mathop_x) __attribute__((__const__)); \
__m81_inline double \
__m81_u(func)(double __mathop_x) \
/* Define a const math function. */
#define __m81_defun(rettype, func, args) \
__m81_inline rettype \
__m81_u(func) args __attribute__((__const__)); \
__m81_inline rettype \
__m81_u(func) args
#define __inline_mathop(func, op) \
__m81_defun (double, func, (double __mathop_x)) \
{ \
double __result; \
__asm("f" __STRING(op) "%.x %1, %0" : "=f" (__result) : "f" (__mathop_x));\
return __result; \
}
#define __inline_mathop(op) __inline_mathop2(op, op)
__inline_mathop(acos)
__inline_mathop(asin)
__inline_mathop(atan)
__inline_mathop(cos)
__inline_mathop(sin)
__inline_mathop(tan)
__inline_mathop(cosh)
__inline_mathop(sinh)
__inline_mathop(tanh)
__inline_mathop2(exp, etox)
__inline_mathop2(fabs, abs)
__inline_mathop(log10)
__inline_mathop2(log, logn)
__inline_mathop(sqrt)
#define __inline_mathopf(func, op) \
__m81_defun (float, func, (float __mathop_x)) \
{ \
float __result; \
__asm("f" __STRING(op) "%.x %1, %0" : "=f" (__result) : "f" (__mathop_x));\
return __result; \
}
/* ieee style elementary functions */
__inline_mathop(__ieee754_acos, acos)
__inline_mathop(__ieee754_asin, asin)
__inline_mathop(__ieee754_cosh, cosh)
__inline_mathop(__ieee754_sinh, sinh)
__inline_mathop(__ieee754_exp, etox)
__inline_mathop(__ieee754_log10, log10)
__inline_mathop(__ieee754_log, logn)
__inline_mathop(__ieee754_sqrt, sqrt)
__inline_mathop(__ieee754_atanh, atanh)
__inline_mathop2(__rint, int)
__inline_mathop2(__expm1, etoxm1)
/* ieee style elementary float functions */
__inline_mathopf(__ieee754_acosf, acos)
__inline_mathopf(__ieee754_asinf, asin)
__inline_mathopf(__ieee754_coshf, cosh)
__inline_mathopf(__ieee754_sinhf, sinh)
__inline_mathopf(__ieee754_expf, etox)
__inline_mathopf(__ieee754_log10f, log10)
__inline_mathopf(__ieee754_logf, logn)
__inline_mathopf(__ieee754_sqrtf, sqrt)
__inline_mathopf(__ieee754_atanhf, atan)
#ifdef __USE_MISC
#ifndef __NO_MATH_INLINES
__inline_mathop2(rint, int)
__inline_mathop2(expm1, etoxm1)
#endif
__inline_mathop2(log1p, lognp1)
__inline_mathop(atanh)
#endif
__inline_mathop(__atan, atan)
__inline_mathop(__cos, cos)
__inline_mathop(__sin, sin)
__inline_mathop(__tan, tan)
__inline_mathop(__tanh, tanh)
__inline_mathop(__fabs, abs)
__inline_mathop(__sqrt, sqrt)
__m81_inline double
__m81_u(__drem)(double __x, double __y) __attribute__ ((__const__));
__m81_inline double
__m81_u(__drem)(double __x, double __y)
__inline_mathop(__rint, int)
__inline_mathop(__expm1, etoxm1)
__inline_mathop(__log1p, lognp1)
__inline_mathop(__logb, log2)
__inline_mathop(__significand, getman)
__inline_mathopf(__atanf, atan)
__inline_mathopf(__cosf, cos)
__inline_mathopf(__sinf, sin)
__inline_mathopf(__tanf, tan)
__inline_mathopf(__tanhf, tanh)
__inline_mathopf(__fabsf, abs)
__inline_mathopf(__sqrtf, sqrt)
__inline_mathopf(__rintf, int)
__inline_mathopf(__expm1f, etoxm1)
__inline_mathopf(__log1pf, lognp1)
__inline_mathopf(__logbf, log2)
__inline_mathopf(__significandf, getman)
__m81_defun (double, __ieee754_remainder, (double __x, double __y))
{
double __result;
__asm("frem%.x %1, %0" : "=f" (__result) : "f" (__y), "0" (__x));
return __result;
}
__m81_inline double
__m81_u(ldexp)(double __x, int __e) __attribute__ ((__const__));
__m81_inline double
__m81_u(ldexp)(double __x, int __e)
__m81_defun (double, __ldexp, (double __x, int __e))
{
double __result;
double __double_e = (double) __e;
@ -94,10 +120,7 @@ __m81_u(ldexp)(double __x, int __e)
return __result;
}
__m81_inline double
__m81_u(fmod)(double __x, double __y) __attribute__ ((__const__));
__m81_inline double
__m81_u(fmod)(double __x, double __y)
__m81_defun (double, __ieee754_fmod, (double __x, double __y))
{
double __result;
__asm("fmod%.x %1, %0" : "=f" (__result) : "f" (__y), "0" (__x));
@ -105,7 +128,7 @@ __m81_u(fmod)(double __x, double __y)
}
__m81_inline double
__m81_u(frexp)(double __value, int *__expptr)
__m81_u(__frexp)(double __value, int *__expptr)
{
double __mantissa, __exponent;
__asm("fgetexp%.x %1, %0" : "=f" (__exponent) : "f" (__value));
@ -114,10 +137,7 @@ __m81_u(frexp)(double __value, int *__expptr)
return __mantissa;
}
__m81_inline double
__m81_u(floor)(double __x) __attribute__ ((__const__));
__m81_inline double
__m81_u(floor)(double __x)
__m81_defun (double, __floor, (double __x))
{
double __result;
unsigned long int __ctrl_reg;
@ -133,16 +153,13 @@ __m81_u(floor)(double __x)
return __result;
}
__m81_inline double
__m81_u(pow)(double __x, double __y) __attribute__ ((__const__));
__m81_inline double
__m81_u(pow)(double __x, double __y)
__m81_defun (double, __ieee754_pow, (double __x, double __y))
{
double __result;
if (__x == 0.0)
{
if (__y <= 0.0)
__result = __infnan (EDOM);
__result = 0.0 / 0.0;
else
__result = 0.0;
}
@ -162,22 +179,19 @@ __m81_u(pow)(double __x, double __y)
if (__y == __temp)
{
int i = (int) __y;
__result = __m81_u (exp) (__y * __m81_u (log) (-__x));
__result = __m81_u(__ieee754_exp)(__y * __m81_u(__ieee754_log)(-__x));
if (i & 1)
__result = -__result;
}
else
__result = __infnan (EDOM);
__result = 0.0 / 0.0;
}
else
__result = __m81_u(exp)(__y * __m81_u(log)(__x));
__result = __m81_u(__ieee754_exp)(__y * __m81_u(__ieee754_log)(__x));
return __result;
}
__m81_inline double
__m81_u(ceil)(double __x) __attribute__ ((__const__));
__m81_inline double
__m81_u(ceil)(double __x)
__m81_defun (double, __ceil, (double __x))
{
double __result;
unsigned long int __ctrl_reg;
@ -194,30 +208,25 @@ __m81_u(ceil)(double __x)
}
__m81_inline double
__m81_u(modf)(double __value, double *__iptr)
__m81_u(__modf)(double __value, double *__iptr)
{
double __modf_int = __m81_u(floor)(__value);
double __modf_int;
__asm ("fintrz%.x %1, %0" : "=f" (__modf_int) : "f" (__value));
*__iptr = __modf_int;
return __value - __modf_int;
}
__m81_inline int
__m81_u(__isinf)(double __value) __attribute__ ((__const__));
__m81_inline int
__m81_u(__isinf)(double __value)
__m81_defun (int, __isinf, (double __value))
{
/* There is no branch-condition for infinity,
so we must extract and examine the condition codes manually. */
unsigned long int __fpsr;
__asm("ftst%.x %1\n"
"fmove%.l %/fpsr, %0" : "=dm" (__fpsr) : "f" (__value));
return (__fpsr & (2 << (3 * 8))) ? (__value < 0 ? -1 : 1) : 0;
return (__fpsr & (2 << 24)) ? (__fpsr & (8 << 24) ? -1 : 1) : 0;
}
__m81_inline int
__m81_u(__isnan)(double __value) __attribute__ ((__const__));
__m81_inline int
__m81_u(__isnan)(double __value)
__m81_defun (int, __isnan, (double __value))
{
char __result;
__asm("ftst%.x %1\n"
@ -225,23 +234,210 @@ __m81_u(__isnan)(double __value)
return __result;
}
__m81_inline int
__m81_u(__isinfl)(long double __value) __attribute__ ((__const__));
__m81_inline int
__m81_u(__isinfl)(long double __value)
__m81_defun (int, __finite, (double __value))
{
/* There is no branch-condition for infinity, so we must extract and
examine the condition codes manually. */
unsigned long int __fpsr;
__asm ("ftst%.x %1\n"
"fmove%.l %/fpsr, %0" : "=dm" (__fpsr) : "f" (__value));
return (__fpsr & (3 << 24)) == 0;
}
__m81_defun (int, __ilogb, (double __x))
{
double __result;
__asm("fgetexp%.x %1, %0" : "=f" (__result) : "f" (__x));
return (int) __result;
}
__m81_defun (double, __ieee754_scalb, (double __x, double __n))
{
double __result;
__asm ("fscale%.x %1, %0" : "=f" (__result) : "f" (__n), "0" (__x));
return __result;
}
__m81_defun (double, __scalbn, (double __x, int __n))
{
double __result;
double __double_n = (double) __n;
__asm ("fscale%.x %1, %0" : "=f" (__result) : "f" (__double_n), "0" (__x));
return __result;
}
__m81_defun (float, __ieee754_remainderf, (float __x, float __y))
{
float __result;
__asm("frem%.x %1, %0" : "=f" (__result) : "f" (__y), "0" (__x));
return __result;
}
__m81_defun (float, __ldexpf, (float __x, int __e))
{
float __result;
float __float_e = (float) __e;
__asm("fscale%.x %1, %0" : "=f" (__result) : "f" (__float_e), "0" (__x));
return __result;
}
__m81_defun (float, __ieee754_fmodf, (float __x, float __y))
{
float __result;
__asm("fmod%.x %1, %0" : "=f" (__result) : "f" (__y), "0" (__x));
return __result;
}
__m81_inline float
__m81_u(__frexpf)(float __value, int *__expptr)
{
float __mantissa, __exponent;
__asm("fgetexp%.x %1, %0" : "=f" (__exponent) : "f" (__value));
__asm("fgetman%.x %1, %0" : "=f" (__mantissa) : "f" (__value));
*__expptr = (int) __exponent;
return __mantissa;
}
__m81_defun (float, __floorf, (float __x))
{
float __result;
unsigned long int __ctrl_reg;
__asm __volatile__ ("fmove%.l %!, %0" : "=dm" (__ctrl_reg));
/* Set rounding towards negative infinity. */
__asm __volatile__ ("fmove%.l %0, %!" : /* No outputs. */
: "dmi" ((__ctrl_reg & ~0x10) | 0x20));
/* Convert X to an integer, using -Inf rounding. */
__asm __volatile__ ("fint%.x %1, %0" : "=f" (__result) : "f" (__x));
/* Restore the previous rounding mode. */
__asm __volatile__ ("fmove%.l %0, %!" : /* No outputs. */
: "dmi" (__ctrl_reg));
return __result;
}
__m81_defun (float, __ieee754_powf, (float __x, float __y))
{
float __result;
if (__x == 0.0f)
{
if (__y <= 0.0f)
__result = 0.0f / 0.0f;
else
__result = 0.0f;
}
else if (__y == 0.0f || __x == 1.0f)
__result = 1.0;
else if (__y == 1.0f)
__result = __x;
else if (__y == 2.0f)
__result = __x * __x;
else if (__x == 10.0f)
__asm("ftentox%.x %1, %0" : "=f" (__result) : "f" (__y));
else if (__x == 2.0f)
__asm("ftwotox%.x %1, %0" : "=f" (__result) : "f" (__y));
else if (__x < 0.0f)
{
float __temp = __m81_u(__rintf)(__y);
if (__y == __temp)
{
int i = (int) __y;
__result = __m81_u(__ieee754_expf)(__y * __m81_u(__ieee754_logf)(-__x));
if (i & 1)
__result = -__result;
}
else
__result = 0.0f / 0.0f;
}
else
__result = __m81_u(__ieee754_expf)(__y * __m81_u(__ieee754_logf)(__x));
return __result;
}
__m81_defun (float, __ceilf, (float __x))
{
float __result;
unsigned long int __ctrl_reg;
__asm __volatile__ ("fmove%.l %!, %0" : "=dm" (__ctrl_reg));
/* Set rounding towards positive infinity. */
__asm __volatile__ ("fmove%.l %0, %!" : /* No outputs. */
: "dmi" (__ctrl_reg | 0x30));
/* Convert X to an integer, using +Inf rounding. */
__asm __volatile__ ("fint%.x %1, %0" : "=f" (__result) : "f" (__x));
/* Restore the previous rounding mode. */
__asm __volatile__ ("fmove%.l %0, %!" : /* No outputs. */
: "dmi" (__ctrl_reg));
return __result;
}
__m81_inline float
__m81_u(__modff)(float __value, float *__iptr)
{
float __modf_int;
__asm ("fintrz%.x %1, %0" : "=f" (__modf_int) : "f" (__value));
*__iptr = __modf_int;
return __value - __modf_int;
}
__m81_defun (int, __isinff, (float __value))
{
/* There is no branch-condition for infinity,
so we must extract and examine the condition codes manually. */
unsigned long int __fpsr;
__asm("ftst%.x %1\n"
"fmove%.l %/fpsr, %0" : "=dm" (__fpsr) : "f" (__value));
return (__fpsr & (2 << (3 * 8))) ? (__value < 0 ? -1 : 1) : 0;
return (__fpsr & (2 << 24)) ? (__fpsr & (8 << 24) ? -1 : 1) : 0;
}
__m81_inline int
__m81_u(__isnanl)(long double __value) __attribute__ ((__const__));
__m81_inline int
__m81_u(__isnanl)(long double __value)
__m81_defun (int, __isnanf, (float __value))
{
char __result;
__asm("ftst%.x %1\n"
"fsun %0" : "=dm" (__result) : "f" (__value));
return __result;
}
__m81_defun (int, __finitef, (float __value))
{
/* There is no branch-condition for infinity, so we must extract and
examine the condition codes manually. */
unsigned long int __fpsr;
__asm ("ftst%.x %1\n"
"fmove%.l %/fpsr, %0" : "=dm" (__fpsr) : "f" (__value));
return (__fpsr & (3 << 24)) == 0;
}
__m81_defun (int, __ilogbf, (float __x))
{
float __result;
__asm("fgetexp%.x %1, %0" : "=f" (__result) : "f" (__x));
return (int) __result;
}
__m81_defun (float, __ieee754_scalbf, (float __x, float __n))
{
float __result;
__asm ("fscale%.x %1, %0" : "=f" (__result) : "f" (__n), "0" (__x));
return __result;
}
__m81_defun (float, __scalbnf, (float __x, int __n))
{
float __result;
float __float_n = (float) __n;
__asm ("fscale%.x %1, %0" : "=f" (__result) : "f" (__float_n), "0" (__x));
return __result;
}
__m81_defun (int, __isinfl, (long double __value))
{
/* There is no branch-condition for infinity,
so we must extract and examine the condition codes manually. */
unsigned long int __fpsr;
__asm("ftst%.x %1\n"
"fmove%.l %/fpsr, %0" : "=dm" (__fpsr) : "f" (__value));
return (__fpsr & (2 << 24)) ? (__fpsr & (8 << 24) ? -1 : 1) : 0;
}
__m81_defun (int, __isnanl, (long double __value))
{
char __result;
__asm("ftst%.x %1\n"