/*------------------------------------------------------------------------- * * float.h * Definitions for the built-in floating-point types * * Portions Copyright (c) 1996-2020, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * * IDENTIFICATION * src/include/utils/float.h * *------------------------------------------------------------------------- */ #ifndef FLOAT_H #define FLOAT_H #include #ifndef M_PI /* From my RH5.2 gcc math.h file - thomas 2000-04-03 */ #define M_PI 3.14159265358979323846 #endif /* Radians per degree, a.k.a. PI / 180 */ #define RADIANS_PER_DEGREE 0.0174532925199432957692 /* Visual C++ etc lacks NAN, and won't accept 0.0/0.0. */ #if defined(WIN32) && !defined(NAN) static const uint32 nan[2] = {0xffffffff, 0x7fffffff}; #define NAN (*(const float8 *) nan) #endif extern PGDLLIMPORT int extra_float_digits; /* * Utility functions in float.c */ extern void float_overflow_error(void) pg_attribute_noreturn(); extern void float_underflow_error(void) pg_attribute_noreturn(); extern void float_zero_divide_error(void) pg_attribute_noreturn(); extern int is_infinite(float8 val); extern float8 float8in_internal(char *num, char **endptr_p, const char *type_name, const char *orig_string); extern float8 float8in_internal_opt_error(char *num, char **endptr_p, const char *type_name, const char *orig_string, bool *have_error); extern char *float8out_internal(float8 num); extern int float4_cmp_internal(float4 a, float4 b); extern int float8_cmp_internal(float8 a, float8 b); /* * Routines to provide reasonably platform-independent handling of * infinity and NaN * * We assume that isinf() and isnan() are available and work per spec. * (On some platforms, we have to supply our own; see src/port.) However, * generating an Infinity or NaN in the first place is less well standardized; * pre-C99 systems tend not to have C99's INFINITY and NaN macros. We * centralize our workarounds for this here. */ /* * The funny placements of the two #pragmas is necessary because of a * long lived bug in the Microsoft compilers. * See http://support.microsoft.com/kb/120968/en-us for details */ #ifdef _MSC_VER #pragma warning(disable:4756) #endif static inline float4 get_float4_infinity(void) { #ifdef INFINITY /* C99 standard way */ return (float4) INFINITY; #else #ifdef _MSC_VER #pragma warning(default:4756) #endif /* * On some platforms, HUGE_VAL is an infinity, elsewhere it's just the * largest normal float8. We assume forcing an overflow will get us a * true infinity. */ return (float4) (HUGE_VAL * HUGE_VAL); #endif } static inline float8 get_float8_infinity(void) { #ifdef INFINITY /* C99 standard way */ return (float8) INFINITY; #else /* * On some platforms, HUGE_VAL is an infinity, elsewhere it's just the * largest normal float8. We assume forcing an overflow will get us a * true infinity. */ return (float8) (HUGE_VAL * HUGE_VAL); #endif } static inline float4 get_float4_nan(void) { #ifdef NAN /* C99 standard way */ return (float4) NAN; #else /* Assume we can get a NAN via zero divide */ return (float4) (0.0 / 0.0); #endif } static inline float8 get_float8_nan(void) { /* (float8) NAN doesn't work on some NetBSD/MIPS releases */ #if defined(NAN) && !(defined(__NetBSD__) && defined(__mips__)) /* C99 standard way */ return (float8) NAN; #else /* Assume we can get a NaN via zero divide */ return (float8) (0.0 / 0.0); #endif } /* * Floating-point arithmetic with overflow/underflow reported as errors * * There isn't any way to check for underflow of addition/subtraction * because numbers near the underflow value have already been rounded to * the point where we can't detect that the two values were originally * different, e.g. on x86, '1e-45'::float4 == '2e-45'::float4 == * 1.4013e-45. */ static inline float4 float4_pl(const float4 val1, const float4 val2) { float4 result; result = val1 + val2; if (unlikely(isinf(result)) && !isinf(val1) && !isinf(val2)) float_overflow_error(); return result; } static inline float8 float8_pl(const float8 val1, const float8 val2) { float8 result; result = val1 + val2; if (unlikely(isinf(result)) && !isinf(val1) && !isinf(val2)) float_overflow_error(); return result; } static inline float4 float4_mi(const float4 val1, const float4 val2) { float4 result; result = val1 - val2; if (unlikely(isinf(result)) && !isinf(val1) && !isinf(val2)) float_overflow_error(); return result; } static inline float8 float8_mi(const float8 val1, const float8 val2) { float8 result; result = val1 - val2; if (unlikely(isinf(result)) && !isinf(val1) && !isinf(val2)) float_overflow_error(); return result; } static inline float4 float4_mul(const float4 val1, const float4 val2) { float4 result; result = val1 * val2; if (unlikely(isinf(result)) && !isinf(val1) && !isinf(val2)) float_overflow_error(); if (unlikely(result == 0.0f) && val1 != 0.0f && val2 != 0.0f) float_underflow_error(); return result; } static inline float8 float8_mul(const float8 val1, const float8 val2) { float8 result; result = val1 * val2; if (unlikely(isinf(result)) && !isinf(val1) && !isinf(val2)) float_overflow_error(); if (unlikely(result == 0.0) && val1 != 0.0 && val2 != 0.0) float_underflow_error(); return result; } static inline float4 float4_div(const float4 val1, const float4 val2) { float4 result; if (unlikely(val2 == 0.0f)) float_zero_divide_error(); result = val1 / val2; if (unlikely(isinf(result)) && !isinf(val1) && !isinf(val2)) float_overflow_error(); if (unlikely(result == 0.0f) && val1 != 0.0f) float_underflow_error(); return result; } static inline float8 float8_div(const float8 val1, const float8 val2) { float8 result; if (unlikely(val2 == 0.0)) float_zero_divide_error(); result = val1 / val2; if (unlikely(isinf(result)) && !isinf(val1) && !isinf(val2)) float_overflow_error(); if (unlikely(result == 0.0) && val1 != 0.0) float_underflow_error(); return result; } /* * Routines for NaN-aware comparisons * * We consider all NaNs to be equal and larger than any non-NaN. This is * somewhat arbitrary; the important thing is to have a consistent sort * order. */ static inline bool float4_eq(const float4 val1, const float4 val2) { return isnan(val1) ? isnan(val2) : !isnan(val2) && val1 == val2; } static inline bool float8_eq(const float8 val1, const float8 val2) { return isnan(val1) ? isnan(val2) : !isnan(val2) && val1 == val2; } static inline bool float4_ne(const float4 val1, const float4 val2) { return isnan(val1) ? !isnan(val2) : isnan(val2) || val1 != val2; } static inline bool float8_ne(const float8 val1, const float8 val2) { return isnan(val1) ? !isnan(val2) : isnan(val2) || val1 != val2; } static inline bool float4_lt(const float4 val1, const float4 val2) { return !isnan(val1) && (isnan(val2) || val1 < val2); } static inline bool float8_lt(const float8 val1, const float8 val2) { return !isnan(val1) && (isnan(val2) || val1 < val2); } static inline bool float4_le(const float4 val1, const float4 val2) { return isnan(val2) || (!isnan(val1) && val1 <= val2); } static inline bool float8_le(const float8 val1, const float8 val2) { return isnan(val2) || (!isnan(val1) && val1 <= val2); } static inline bool float4_gt(const float4 val1, const float4 val2) { return !isnan(val2) && (isnan(val1) || val1 > val2); } static inline bool float8_gt(const float8 val1, const float8 val2) { return !isnan(val2) && (isnan(val1) || val1 > val2); } static inline bool float4_ge(const float4 val1, const float4 val2) { return isnan(val1) || (!isnan(val2) && val1 >= val2); } static inline bool float8_ge(const float8 val1, const float8 val2) { return isnan(val1) || (!isnan(val2) && val1 >= val2); } static inline float4 float4_min(const float4 val1, const float4 val2) { return float4_lt(val1, val2) ? val1 : val2; } static inline float8 float8_min(const float8 val1, const float8 val2) { return float8_lt(val1, val2) ? val1 : val2; } static inline float4 float4_max(const float4 val1, const float4 val2) { return float4_gt(val1, val2) ? val1 : val2; } static inline float8 float8_max(const float8 val1, const float8 val2) { return float8_gt(val1, val2) ? val1 : val2; } #endif /* FLOAT_H */