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/*
* Configuration for math routines.
*
* Copyright (c) 2017-2020, Arm Limited.
* SPDX-License-Identifier: MIT
*/
#ifndef _MATH_CONFIG_H
#define _MATH_CONFIG_H
#include <math.h>
#include <stdint.h>
#ifndef WANT_ROUNDING
/* If defined to 1, return correct results for special cases in non-nearest
rounding modes (logf (1.0f) returns 0.0f with FE_DOWNWARD rather than -0.0f).
This may be set to 0 if there is no fenv support or if math functions only
get called in round to nearest mode. */
# define WANT_ROUNDING 1
#endif
#ifndef WANT_ERRNO
/* If defined to 1, set errno in math functions according to ISO C. Many math
libraries do not set errno, so this is 0 by default. It may need to be
set to 1 if math.h has (math_errhandling & MATH_ERRNO) != 0. */
# define WANT_ERRNO 0
#endif
#ifndef WANT_ERRNO_UFLOW
/* Set errno to ERANGE if result underflows to 0 (in all rounding modes). */
# define WANT_ERRNO_UFLOW (WANT_ROUNDING && WANT_ERRNO)
#endif
/* Compiler can inline round as a single instruction. */
#ifndef HAVE_FAST_ROUND
# if __aarch64__
# define HAVE_FAST_ROUND 1
# else
# define HAVE_FAST_ROUND 0
# endif
#endif
/* Compiler can inline lround, but not (long)round(x). */
#ifndef HAVE_FAST_LROUND
# if __aarch64__ && (100*__GNUC__ + __GNUC_MINOR__) >= 408 && __NO_MATH_ERRNO__
# define HAVE_FAST_LROUND 1
# else
# define HAVE_FAST_LROUND 0
# endif
#endif
/* Compiler can inline fma as a single instruction. */
#ifndef HAVE_FAST_FMA
# if defined FP_FAST_FMA || __aarch64__
# define HAVE_FAST_FMA 1
# else
# define HAVE_FAST_FMA 0
# endif
#endif
/* Provide *_finite symbols and some of the glibc hidden symbols
so libmathlib can be used with binaries compiled against glibc
to interpose math functions with both static and dynamic linking. */
#ifndef USE_GLIBC_ABI
# if __GNUC__
# define USE_GLIBC_ABI 1
# else
# define USE_GLIBC_ABI 0
# endif
#endif
/* Optionally used extensions. */
#ifdef __GNUC__
# define HIDDEN __attribute__ ((__visibility__ ("hidden")))
# define NOINLINE __attribute__ ((noinline))
# define UNUSED __attribute__ ((unused))
# define likely(x) __builtin_expect (!!(x), 1)
# define unlikely(x) __builtin_expect (x, 0)
# if __GNUC__ >= 9
# define attribute_copy(f) __attribute__ ((copy (f)))
# else
# define attribute_copy(f)
# endif
# define strong_alias(f, a) \
extern __typeof (f) a __attribute__ ((alias (#f))) attribute_copy (f);
# define hidden_alias(f, a) \
extern __typeof (f) a __attribute__ ((alias (#f), visibility ("hidden"))) \
attribute_copy (f);
#else
# define HIDDEN
# define NOINLINE
# define UNUSED
# define likely(x) (x)
# define unlikely(x) (x)
#endif
#if HAVE_FAST_ROUND
/* When set, the roundtoint and converttoint functions are provided with
the semantics documented below. */
# define TOINT_INTRINSICS 1
/* 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 inline double_t
roundtoint (double_t x)
{
return round (x);
}
/* 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 inline int32_t
converttoint (double_t x)
{
# if HAVE_FAST_LROUND
return lround (x);
# else
return (long) round (x);
# endif
}
#endif
static inline uint32_t
asuint (float f)
{
union
{
float f;
uint32_t i;
} u = {f};
return u.i;
}
static inline float
asfloat (uint32_t i)
{
union
{
uint32_t i;
float f;
} u = {i};
return u.f;
}
static inline uint64_t
asuint64 (double f)
{
union
{
double f;
uint64_t i;
} u = {f};
return u.i;
}
static inline double
asdouble (uint64_t i)
{
union
{
uint64_t i;
double f;
} u = {i};
return u.f;
}
#ifndef IEEE_754_2008_SNAN
# define IEEE_754_2008_SNAN 1
#endif
static inline int
issignalingf_inline (float x)
{
uint32_t ix = asuint (x);
if (!IEEE_754_2008_SNAN)
return (ix & 0x7fc00000) == 0x7fc00000;
return 2 * (ix ^ 0x00400000) > 2u * 0x7fc00000;
}
static inline int
issignaling_inline (double x)
{
uint64_t ix = asuint64 (x);
if (!IEEE_754_2008_SNAN)
return (ix & 0x7ff8000000000000) == 0x7ff8000000000000;
return 2 * (ix ^ 0x0008000000000000) > 2 * 0x7ff8000000000000ULL;
}
#if __aarch64__ && __GNUC__
/* Prevent the optimization of a floating-point expression. */
static inline float
opt_barrier_float (float x)
{
__asm__ __volatile__ ("" : "+w" (x));
return x;
}
static inline double
opt_barrier_double (double x)
{
__asm__ __volatile__ ("" : "+w" (x));
return x;
}
/* Force the evaluation of a floating-point expression for its side-effect. */
static inline void
force_eval_float (float x)
{
__asm__ __volatile__ ("" : "+w" (x));
}
static inline void
force_eval_double (double x)
{
__asm__ __volatile__ ("" : "+w" (x));
}
#else
static inline float
opt_barrier_float (float x)
{
volatile float y = x;
return y;
}
static inline double
opt_barrier_double (double x)
{
volatile double y = x;
return y;
}
static inline void
force_eval_float (float x)
{
volatile float y UNUSED = x;
}
static inline void
force_eval_double (double x)
{
volatile double y UNUSED = x;
}
#endif
/* Evaluate an expression as the specified type, normally a type
cast should be enough, but compilers implement non-standard
excess-precision handling, so when FLT_EVAL_METHOD != 0 then
these functions may need to be customized. */
static inline float
eval_as_float (float x)
{
return x;
}
static inline double
eval_as_double (double x)
{
return x;
}
/* Error handling tail calls for special cases, with a sign argument.
The sign of the return value is set if the argument is non-zero. */
/* The result overflows. */
HIDDEN float __math_oflowf (uint32_t);
/* The result underflows to 0 in nearest rounding mode. */
HIDDEN float __math_uflowf (uint32_t);
/* The result underflows to 0 in some directed rounding mode only. */
HIDDEN float __math_may_uflowf (uint32_t);
/* Division by zero. */
HIDDEN float __math_divzerof (uint32_t);
/* The result overflows. */
HIDDEN double __math_oflow (uint32_t);
/* The result underflows to 0 in nearest rounding mode. */
HIDDEN double __math_uflow (uint32_t);
/* The result underflows to 0 in some directed rounding mode only. */
HIDDEN double __math_may_uflow (uint32_t);
/* Division by zero. */
HIDDEN double __math_divzero (uint32_t);
/* Error handling using input checking. */
/* Invalid input unless it is a quiet NaN. */
HIDDEN float __math_invalidf (float);
/* Invalid input unless it is a quiet NaN. */
HIDDEN double __math_invalid (double);
/* Error handling using output checking, only for errno setting. */
/* Check if the result overflowed to infinity. */
HIDDEN double __math_check_oflow (double);
/* Check if the result underflowed to 0. */
HIDDEN double __math_check_uflow (double);
/* Check if the result overflowed to infinity. */
static inline double
check_oflow (double x)
{
return WANT_ERRNO ? __math_check_oflow (x) : x;
}
/* Check if the result underflowed to 0. */
static inline double
check_uflow (double x)
{
return WANT_ERRNO ? __math_check_uflow (x) : x;
}
/* Check if the result overflowed to infinity. */
HIDDEN float __math_check_oflowf (float);
/* Check if the result underflowed to 0. */
HIDDEN float __math_check_uflowf (float);
/* Check if the result overflowed to infinity. */
static inline float
check_oflowf (float x)
{
return WANT_ERRNO ? __math_check_oflowf (x) : x;
}
/* Check if the result underflowed to 0. */
static inline float
check_uflowf (float x)
{
return WANT_ERRNO ? __math_check_uflowf (x) : x;
}
/* Shared between expf, exp2f and powf. */
#define EXP2F_TABLE_BITS 5
#define EXP2F_POLY_ORDER 3
extern const struct exp2f_data
{
uint64_t tab[1 << EXP2F_TABLE_BITS];
double shift_scaled;
double poly[EXP2F_POLY_ORDER];
double shift;
double invln2_scaled;
double poly_scaled[EXP2F_POLY_ORDER];
} __exp2f_data HIDDEN;
#define LOGF_TABLE_BITS 4
#define LOGF_POLY_ORDER 4
extern const struct logf_data
{
struct
{
double invc, logc;
} tab[1 << LOGF_TABLE_BITS];
double ln2;
double poly[LOGF_POLY_ORDER - 1]; /* First order coefficient is 1. */
} __logf_data HIDDEN;
#define LOG2F_TABLE_BITS 4
#define LOG2F_POLY_ORDER 4
extern const struct log2f_data
{
struct
{
double invc, logc;
} tab[1 << LOG2F_TABLE_BITS];
double poly[LOG2F_POLY_ORDER];
} __log2f_data HIDDEN;
#define POWF_LOG2_TABLE_BITS 4
#define POWF_LOG2_POLY_ORDER 5
#if TOINT_INTRINSICS
# define POWF_SCALE_BITS EXP2F_TABLE_BITS
#else
# define POWF_SCALE_BITS 0
#endif
#define POWF_SCALE ((double) (1 << POWF_SCALE_BITS))
extern const struct powf_log2_data
{
struct
{
double invc, logc;
} tab[1 << POWF_LOG2_TABLE_BITS];
double poly[POWF_LOG2_POLY_ORDER];
} __powf_log2_data HIDDEN;
#define EXP_TABLE_BITS 7
#define EXP_POLY_ORDER 5
/* Use polynomial that is optimized for a wider input range. This may be
needed for good precision in non-nearest rounding and !TOINT_INTRINSICS. */
#define EXP_POLY_WIDE 0
/* Use close to nearest rounding toint when !TOINT_INTRINSICS. This may be
needed for good precision in non-nearest rouning and !EXP_POLY_WIDE. */
#define EXP_USE_TOINT_NARROW 0
#define EXP2_POLY_ORDER 5
#define EXP2_POLY_WIDE 0
extern const struct exp_data
{
double invln2N;
double shift;
double negln2hiN;
double negln2loN;
double poly[4]; /* Last four coefficients. */
double exp2_shift;
double exp2_poly[EXP2_POLY_ORDER];
uint64_t tab[2*(1 << EXP_TABLE_BITS)];
} __exp_data HIDDEN;
#define LOG_TABLE_BITS 7
#define LOG_POLY_ORDER 6
#define LOG_POLY1_ORDER 12
extern const struct log_data
{
double ln2hi;
double ln2lo;
double poly[LOG_POLY_ORDER - 1]; /* First coefficient is 1. */
double poly1[LOG_POLY1_ORDER - 1];
struct {double invc, logc;} tab[1 << LOG_TABLE_BITS];
#if !HAVE_FAST_FMA
struct {double chi, clo;} tab2[1 << LOG_TABLE_BITS];
#endif
} __log_data HIDDEN;
#define LOG2_TABLE_BITS 6
#define LOG2_POLY_ORDER 7
#define LOG2_POLY1_ORDER 11
extern const struct log2_data
{
double invln2hi;
double invln2lo;
double poly[LOG2_POLY_ORDER - 1];
double poly1[LOG2_POLY1_ORDER - 1];
struct {double invc, logc;} tab[1 << LOG2_TABLE_BITS];
#if !HAVE_FAST_FMA
struct {double chi, clo;} tab2[1 << LOG2_TABLE_BITS];
#endif
} __log2_data HIDDEN;
#define POW_LOG_TABLE_BITS 7
#define POW_LOG_POLY_ORDER 8
extern const struct pow_log_data
{
double ln2hi;
double ln2lo;
double poly[POW_LOG_POLY_ORDER - 1]; /* First coefficient is 1. */
/* Note: the pad field is unused, but allows slightly faster indexing. */
struct {double invc, pad, logc, logctail;} tab[1 << POW_LOG_TABLE_BITS];
} __pow_log_data HIDDEN;
extern const struct erff_data
{
float erff_poly_A[6];
float erff_poly_B[7];
} __erff_data HIDDEN;
#define ERF_POLY_A_ORDER 19
#define ERF_POLY_A_NCOEFFS 10
#define ERFC_POLY_C_NCOEFFS 16
#define ERFC_POLY_D_NCOEFFS 18
#define ERFC_POLY_E_NCOEFFS 14
#define ERFC_POLY_F_NCOEFFS 17
extern const struct erf_data
{
double erf_poly_A[ERF_POLY_A_NCOEFFS];
double erf_ratio_N_A[5];
double erf_ratio_D_A[5];
double erf_ratio_N_B[7];
double erf_ratio_D_B[6];
double erfc_poly_C[ERFC_POLY_C_NCOEFFS];
double erfc_poly_D[ERFC_POLY_D_NCOEFFS];
double erfc_poly_E[ERFC_POLY_E_NCOEFFS];
double erfc_poly_F[ERFC_POLY_F_NCOEFFS];
} __erf_data HIDDEN;
#endif