third_party/musl/src/internal/libm.h - cobalt - Git at Google

 #ifndef _LIBM_H
 #define _LIBM_H

 #include <stdint.h>
 #include <float.h>
 #include <math.h>
 #include <endian.h>
 #include "fp_arch.h"

 #if LDBL_MANT_DIG == 53 && LDBL_MAX_EXP == 1024
 #elif LDBL_MANT_DIG == 64 && LDBL_MAX_EXP == 16384 && __BYTE_ORDER == __LITTLE_ENDIAN
 union ldshape {
 	long double f;
 	struct {
 		uint64_t m;
 		uint16_t se;
 	} i;
 };
 #elif LDBL_MANT_DIG == 64 && LDBL_MAX_EXP == 16384 && __BYTE_ORDER == __BIG_ENDIAN
 /* This is the m68k variant of 80-bit long double, and this definition only works
  * on archs where the alignment requirement of uint64_t is <= 4. */
 union ldshape {
 	long double f;
 	struct {
 		uint16_t se;
 		uint16_t pad;
 		uint64_t m;
 	} i;
 };
 #elif LDBL_MANT_DIG == 113 && LDBL_MAX_EXP == 16384 && __BYTE_ORDER == __LITTLE_ENDIAN
 union ldshape {
 	long double f;
 	struct {
 		uint64_t lo;
 		uint32_t mid;
 		uint16_t top;
 		uint16_t se;
 	} i;
 	struct {
 		uint64_t lo;
 		uint64_t hi;
 	} i2;
 };
 #elif LDBL_MANT_DIG == 113 && LDBL_MAX_EXP == 16384 && __BYTE_ORDER == __BIG_ENDIAN
 union ldshape {
 	long double f;
 	struct {
 		uint16_t se;
 		uint16_t top;
 		uint32_t mid;
 		uint64_t lo;
 	} i;
 	struct {
 		uint64_t hi;
 		uint64_t lo;
 	} i2;
 };
 #else
 #error Unsupported long double representation
 #endif

 /* Support non-nearest rounding mode.  */
 #define WANT_ROUNDING 1
 /* Support signaling NaNs.  */
 #define WANT_SNAN 0

 #if WANT_SNAN
 #error SNaN is unsupported
 #else
 #define issignalingf_inline(x) 0
 #define issignaling_inline(x) 0
 #endif

 #ifndef TOINT_INTRINSICS
 #define TOINT_INTRINSICS 0
 #endif

 #if TOINT_INTRINSICS
 /* Round x to nearest int in all rounding modes, ties have to be rounded
    consistently with converttoint so the results match.  If the result
    would be outside of [-2^31, 2^31-1] then the semantics is unspecified.  */
 static double_t roundtoint(double_t);

 /* Convert x to nearest int in all rounding modes, ties have to be rounded
    consistently with roundtoint.  If the result is not representible in an
    int32_t then the semantics is unspecified.  */
 static int32_t converttoint(double_t);
 #endif

 /* Helps static branch prediction so hot path can be better optimized.  */
 #ifdef __GNUC__
 #define predict_true(x) __builtin_expect(!!(x), 1)
 #define predict_false(x) __builtin_expect(x, 0)
 #else
 #define predict_true(x) (x)
 #define predict_false(x) (x)
 #endif

 /* Evaluate an expression as the specified type. With standard excess
    precision handling a type cast or assignment is enough (with
    -ffloat-store an assignment is required, in old compilers argument
    passing and return statement may not drop excess precision).  */

 static inline float eval_as_float(float x)
 {
 	float y = x;
 	return y;
 }

 static inline double eval_as_double(double x)
 {
 	double y = x;
 	return y;
 }

 /* fp_barrier returns its input, but limits code transformations
    as if it had a side-effect (e.g. observable io) and returned
    an arbitrary value.  */

 #ifndef fp_barrierf
 #define fp_barrierf fp_barrierf
 static inline float fp_barrierf(float x)
 {
 	volatile float y = x;
 	return y;
 }
 #endif

 #ifndef fp_barrier
 #define fp_barrier fp_barrier
 static inline double fp_barrier(double x)
 {
 	volatile double y = x;
 	return y;
 }
 #endif

 #ifndef fp_barrierl
 #define fp_barrierl fp_barrierl
 static inline long double fp_barrierl(long double x)
 {
 	volatile long double y = x;
 	return y;
 }
 #endif

 /* fp_force_eval ensures that the input value is computed when that's
    otherwise unused.  To prevent the constant folding of the input
    expression, an additional fp_barrier may be needed or a compilation
    mode that does so (e.g. -frounding-math in gcc). Then it can be
    used to evaluate an expression for its fenv side-effects only.   */

 #ifndef fp_force_evalf
 #define fp_force_evalf fp_force_evalf
 static inline void fp_force_evalf(float x)
 {
 	volatile float y;
 	y = x;
 }
 #endif

 #ifndef fp_force_eval
 #define fp_force_eval fp_force_eval
 static inline void fp_force_eval(double x)
 {
 	volatile double y;
 	y = x;
 }
 #endif

 #ifndef fp_force_evall
 #define fp_force_evall fp_force_evall
 static inline void fp_force_evall(long double x)
 {
 	volatile long double y;
 	y = x;
 }
 #endif

 #define FORCE_EVAL(x) do {                        \
 	if (sizeof(x) == sizeof(float)) {         \
 		fp_force_evalf(x);                \
 	} else if (sizeof(x) == sizeof(double)) { \
 		fp_force_eval(x);                 \
 	} else {                                  \
 		fp_force_evall(x);                \
 	}                                         \
 } while(0)

 #define asuint(f) ((union{float _f; uint32_t _i;}){f})._i
 #define asfloat(i) ((union{uint32_t _i; float _f;}){i})._f
 #define asuint64(f) ((union{double _f; uint64_t _i;}){f})._i
 #define asdouble(i) ((union{uint64_t _i; double _f;}){i})._f

 #define EXTRACT_WORDS(hi,lo,d)                    \
 do {                                              \
   uint64_t __u = asuint64(d);                     \
   (hi) = __u >> 32;                               \
   (lo) = (uint32_t)__u;                           \
 } while (0)

 #define GET_HIGH_WORD(hi,d)                       \
 do {                                              \
   (hi) = asuint64(d) >> 32;                       \
 } while (0)

 #define GET_LOW_WORD(lo,d)                        \
 do {                                              \
   (lo) = (uint32_t)asuint64(d);                   \
 } while (0)

 #define INSERT_WORDS(d,hi,lo)                     \
 do {                                              \
   (d) = asdouble(((uint64_t)(hi)<<32) | (uint32_t)(lo)); \
 } while (0)

 #define SET_HIGH_WORD(d,hi)                       \
   INSERT_WORDS(d, hi, (uint32_t)asuint64(d))

 #define SET_LOW_WORD(d,lo)                        \
   INSERT_WORDS(d, asuint64(d)>>32, lo)

 #define GET_FLOAT_WORD(w,d)                       \
 do {                                              \
   (w) = asuint(d);                                \
 } while (0)

 #define SET_FLOAT_WORD(d,w)                       \
 do {                                              \
   (d) = asfloat(w);                               \
 } while (0)

 hidden int    __rem_pio2_large(double*,double*,int,int,int);

 hidden int    __rem_pio2(double,double*);
 hidden double __sin(double,double,int);
 hidden double __cos(double,double);
 hidden double __tan(double,double,int);
 hidden double __expo2(double,double);

 hidden int    __rem_pio2f(float,double*);
 hidden float  __sindf(double);
 hidden float  __cosdf(double);
 hidden float  __tandf(double,int);
 hidden float  __expo2f(float,float);

 hidden int __rem_pio2l(long double, long double *);
 hidden long double __sinl(long double, long double, int);
 hidden long double __cosl(long double, long double);
 hidden long double __tanl(long double, long double, int);

 hidden long double __polevll(long double, const long double *, int);
 hidden long double __p1evll(long double, const long double *, int);

 extern int __signgam;
 hidden double __lgamma_r(double, int *);
 hidden float __lgammaf_r(float, int *);

 /* error handling functions */
 hidden float __math_xflowf(uint32_t, float);
 hidden float __math_uflowf(uint32_t);
 hidden float __math_oflowf(uint32_t);
 hidden float __math_divzerof(uint32_t);
 hidden float __math_invalidf(float);
 hidden double __math_xflow(uint32_t, double);
 hidden double __math_uflow(uint32_t);
 hidden double __math_oflow(uint32_t);
 hidden double __math_divzero(uint32_t);
 hidden double __math_invalid(double);
 #if LDBL_MANT_DIG != DBL_MANT_DIG
 hidden long double __math_invalidl(long double);
 #endif

 #endif
	#ifndef _LIBM_H
	#define _LIBM_H

	#include <stdint.h>
	#include <float.h>
	#include <math.h>
	#include <endian.h>
	#include "fp_arch.h"

	#if LDBL_MANT_DIG == 53 && LDBL_MAX_EXP == 1024
	#elif LDBL_MANT_DIG == 64 && LDBL_MAX_EXP == 16384 && __BYTE_ORDER == __LITTLE_ENDIAN
	union ldshape {
	long double f;
	struct {
	uint64_t m;
	uint16_t se;
	} i;
	};
	#elif LDBL_MANT_DIG == 64 && LDBL_MAX_EXP == 16384 && __BYTE_ORDER == __BIG_ENDIAN
	/* This is the m68k variant of 80-bit long double, and this definition only works
	* on archs where the alignment requirement of uint64_t is <= 4. */
	union ldshape {
	long double f;
	struct {
	uint16_t se;
	uint16_t pad;
	uint64_t m;
	} i;
	};
	#elif LDBL_MANT_DIG == 113 && LDBL_MAX_EXP == 16384 && __BYTE_ORDER == __LITTLE_ENDIAN
	union ldshape {
	long double f;
	struct {
	uint64_t lo;
	uint32_t mid;
	uint16_t top;
	uint16_t se;
	} i;
	struct {
	uint64_t lo;
	uint64_t hi;
	} i2;
	};
	#elif LDBL_MANT_DIG == 113 && LDBL_MAX_EXP == 16384 && __BYTE_ORDER == __BIG_ENDIAN
	union ldshape {
	long double f;
	struct {
	uint16_t se;
	uint16_t top;
	uint32_t mid;
	uint64_t lo;
	} i;
	struct {
	uint64_t hi;
	uint64_t lo;
	} i2;
	};
	#else
	#error Unsupported long double representation
	#endif

	/* Support non-nearest rounding mode. */
	#define WANT_ROUNDING 1
	/* Support signaling NaNs. */
	#define WANT_SNAN 0

	#if WANT_SNAN
	#error SNaN is unsupported
	#else
	#define issignalingf_inline(x) 0
	#define issignaling_inline(x) 0
	#endif

	#ifndef TOINT_INTRINSICS
	#define TOINT_INTRINSICS 0
	#endif

	#if TOINT_INTRINSICS
	/* Round x to nearest int in all rounding modes, ties have to be rounded
	consistently with converttoint so the results match. If the result
	would be outside of [-2^31, 2^31-1] then the semantics is unspecified. */
	static double_t roundtoint(double_t);

	/* Convert x to nearest int in all rounding modes, ties have to be rounded
	consistently with roundtoint. If the result is not representible in an
	int32_t then the semantics is unspecified. */
	static int32_t converttoint(double_t);
	#endif

	/* Helps static branch prediction so hot path can be better optimized. */
	#ifdef __GNUC__
	#define predict_true(x) __builtin_expect(!!(x), 1)
	#define predict_false(x) __builtin_expect(x, 0)
	#else
	#define predict_true(x) (x)
	#define predict_false(x) (x)
	#endif

	/* Evaluate an expression as the specified type. With standard excess
	precision handling a type cast or assignment is enough (with
	-ffloat-store an assignment is required, in old compilers argument
	passing and return statement may not drop excess precision). */

	static inline float eval_as_float(float x)
	{
	float y = x;
	return y;
	}

	static inline double eval_as_double(double x)
	{
	double y = x;
	return y;
	}

	/* fp_barrier returns its input, but limits code transformations
	as if it had a side-effect (e.g. observable io) and returned
	an arbitrary value. */

	#ifndef fp_barrierf
	#define fp_barrierf fp_barrierf
	static inline float fp_barrierf(float x)
	{
	volatile float y = x;
	return y;
	}
	#endif

	#ifndef fp_barrier
	#define fp_barrier fp_barrier
	static inline double fp_barrier(double x)
	{
	volatile double y = x;
	return y;
	}
	#endif

	#ifndef fp_barrierl
	#define fp_barrierl fp_barrierl
	static inline long double fp_barrierl(long double x)
	{
	volatile long double y = x;
	return y;
	}
	#endif

	/* fp_force_eval ensures that the input value is computed when that's
	otherwise unused. To prevent the constant folding of the input
	expression, an additional fp_barrier may be needed or a compilation
	mode that does so (e.g. -frounding-math in gcc). Then it can be
	used to evaluate an expression for its fenv side-effects only. */

	#ifndef fp_force_evalf
	#define fp_force_evalf fp_force_evalf
	static inline void fp_force_evalf(float x)
	{
	volatile float y;
	y = x;
	}
	#endif

	#ifndef fp_force_eval
	#define fp_force_eval fp_force_eval
	static inline void fp_force_eval(double x)
	{
	volatile double y;
	y = x;
	}
	#endif

	#ifndef fp_force_evall
	#define fp_force_evall fp_force_evall
	static inline void fp_force_evall(long double x)
	{
	volatile long double y;
	y = x;
	}
	#endif

	#define FORCE_EVAL(x) do { \
	if (sizeof(x) == sizeof(float)) { \
	fp_force_evalf(x); \
	} else if (sizeof(x) == sizeof(double)) { \
	fp_force_eval(x); \
	} else { \
	fp_force_evall(x); \
	} \
	} while(0)

	#define asuint(f) ((union{float _f; uint32_t _i;}){f})._i
	#define asfloat(i) ((union{uint32_t _i; float _f;}){i})._f
	#define asuint64(f) ((union{double _f; uint64_t _i;}){f})._i
	#define asdouble(i) ((union{uint64_t _i; double _f;}){i})._f

	#define EXTRACT_WORDS(hi,lo,d) \
	do { \
	uint64_t __u = asuint64(d); \
	(hi) = __u >> 32; \
	(lo) = (uint32_t)__u; \
	} while (0)

	#define GET_HIGH_WORD(hi,d) \
	do { \
	(hi) = asuint64(d) >> 32; \
	} while (0)

	#define GET_LOW_WORD(lo,d) \
	do { \
	(lo) = (uint32_t)asuint64(d); \
	} while (0)

	#define INSERT_WORDS(d,hi,lo) \
	do { \
	(d) = asdouble(((uint64_t)(hi)<<32) \| (uint32_t)(lo)); \
	} while (0)

	#define SET_HIGH_WORD(d,hi) \
	INSERT_WORDS(d, hi, (uint32_t)asuint64(d))

	#define SET_LOW_WORD(d,lo) \
	INSERT_WORDS(d, asuint64(d)>>32, lo)

	#define GET_FLOAT_WORD(w,d) \
	do { \
	(w) = asuint(d); \
	} while (0)

	#define SET_FLOAT_WORD(d,w) \
	do { \
	(d) = asfloat(w); \
	} while (0)

	hidden int __rem_pio2_large(double,double,int,int,int);

	hidden int __rem_pio2(double,double*);
	hidden double __sin(double,double,int);
	hidden double __cos(double,double);
	hidden double __tan(double,double,int);
	hidden double __expo2(double,double);

	hidden int __rem_pio2f(float,double*);
	hidden float __sindf(double);
	hidden float __cosdf(double);
	hidden float __tandf(double,int);
	hidden float __expo2f(float,float);

	hidden int __rem_pio2l(long double, long double *);
	hidden long double __sinl(long double, long double, int);
	hidden long double __cosl(long double, long double);
	hidden long double __tanl(long double, long double, int);

	hidden long double __polevll(long double, const long double *, int);
	hidden long double __p1evll(long double, const long double *, int);

	extern int __signgam;
	hidden double __lgamma_r(double, int *);
	hidden float __lgammaf_r(float, int *);

	/* error handling functions */
	hidden float __math_xflowf(uint32_t, float);
	hidden float __math_uflowf(uint32_t);
	hidden float __math_oflowf(uint32_t);
	hidden float __math_divzerof(uint32_t);
	hidden float __math_invalidf(float);
	hidden double __math_xflow(uint32_t, double);
	hidden double __math_uflow(uint32_t);
	hidden double __math_oflow(uint32_t);
	hidden double __math_divzero(uint32_t);
	hidden double __math_invalid(double);
	#if LDBL_MANT_DIG != DBL_MANT_DIG
	hidden long double __math_invalidl(long double);
	#endif

	#endif