/* * Configuration for math routines. * * Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. * See https://llvm.org/LICENSE.txt for license information. * SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception */ #ifndef _MATH_CONFIG_H #define _MATH_CONFIG_H #include #include #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 representable 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; } /* 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 rounding 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; #endif