tests/tcg/multiarch/libs/float_helpers.c - qemu - Git at Google

 /*
  * Common Float Helpers
  *
  * This contains a series of useful utility routines and a set of
  * floating point constants useful for exercising the edge cases in
  * floating point tests.
  *
  * Copyright (c) 2019, 2024 Linaro
  *
  * SPDX-License-Identifier: GPL-2.0-or-later
  */

 /* we want additional float type definitions */
 #define __STDC_WANT_IEC_60559_BFP_EXT__
 #define __STDC_WANT_IEC_60559_TYPES_EXT__

 #define _GNU_SOURCE
 #include <stdio.h>
 #include <stdlib.h>
 #include <inttypes.h>
 #include <math.h>
 #include <float.h>
 #include <fenv.h>

 #include "../float_helpers.h"

 #define ARRAY_SIZE(x) (sizeof(x) / sizeof((x)[0]))

 /*
  * Half Precision Numbers
  *
  * Not yet well standardised so we return a plain uint16_t for now.
  */

 /* no handy defines for these numbers */
 static uint16_t f16_numbers[] = {
     0xffff, /* -NaN / AHP -Max */
     0xfcff, /* -NaN / AHP */
     0xfc01, /* -NaN / AHP */
     0xfc00, /* -Inf */
     0xfbff, /* -Max */
     0xc000, /* -2 */
     0xbc00, /* -1 */
     0x8001, /* -MIN subnormal */
     0x8000, /* -0 */
     0x0000, /* +0 */
     0x0001, /* MIN subnormal */
     0x3c00, /* 1 */
     0x7bff, /* Max */
     0x7c00, /* Inf */
     0x7c01, /* NaN / AHP */
     0x7cff, /* NaN / AHP */
     0x7fff, /* NaN / AHP +Max*/
 };

 static const int num_f16 = ARRAY_SIZE(f16_numbers);

 int get_num_f16(void)
 {
     return num_f16;
 }

 uint16_t get_f16(int i)
 {
     return f16_numbers[i % num_f16];
 }

 /* only display as hex */
 char *fmt_16(uint16_t num)
 {
     char *fmt;
     asprintf(&fmt, "f16(%#04x)", num);
     return fmt;
 }

 /*
  * Single Precision Numbers
  */

 #ifndef SNANF
 /* Signaling NaN macros, if supported.  */
 #  define SNANF (__builtin_nansf (""))
 #  define SNAN (__builtin_nans (""))
 #  define SNANL (__builtin_nansl (""))
 #endif

 static float f32_numbers[] = {
     -SNANF,
     -NAN,
     -INFINITY,
     -FLT_MAX,
     -0x1.1874b2p+103,
     -0x1.c0bab6p+99,
     -0x1.31f75p-40,
     -0x1.505444p-66,
     -FLT_MIN,
     0.0,
     FLT_MIN,
     0x1p-25,
     0x1.ffffe6p-25, /* min positive FP16 subnormal */
     0x1.ff801ap-15, /* max subnormal FP16 */
     0x1.00000cp-14, /* min positive normal FP16 */
     1.0,
     0x1.004p+0, /* smallest float after 1.0 FP16 */
     2.0,
     M_E, M_PI,
     0x1.ffbep+15,
     0x1.ffcp+15, /* max FP16 */
     0x1.ffc2p+15,
     0x1.ffbfp+16,
     0x1.ffcp+16, /* max AFP */
     0x1.ffc1p+16,
     0x1.c0bab6p+99,
     FLT_MAX,
     INFINITY,
     NAN,
     SNANF
 };

 static const int num_f32 = ARRAY_SIZE(f32_numbers);

 int get_num_f32(void)
 {
     return num_f32;
 }

 float get_f32(int i)
 {
     return f32_numbers[i % num_f32];
 }

 char *fmt_f32(float num)
 {
     uint32_t single_as_hex = *(uint32_t *) &num;
     char *fmt;
     asprintf(&fmt, "f32(%02.20a:%#010x)", num, single_as_hex);
     return fmt;
 }


 /* This allows us to initialise some doubles as pure hex */
 typedef union {
     double d;
     uint64_t h;
 } test_doubles;

 static test_doubles f64_numbers[] = {
     {SNAN},
     {-NAN},
     {-INFINITY},
     {-DBL_MAX},
     {-FLT_MAX-1.0},
     {-FLT_MAX},
     {-1.111E+31},
     {-1.111E+30}, /* half prec */
     {-2.0}, {-1.0},
     {-DBL_MIN},
     {-FLT_MIN},
     {0.0},
     {FLT_MIN},
     {2.98023224e-08},
     {5.96046E-8}, /* min positive FP16 subnormal */
     {6.09756E-5}, /* max subnormal FP16 */
     {6.10352E-5}, /* min positive normal FP16 */
     {1.0},
     {1.0009765625}, /* smallest float after 1.0 FP16 */
     {DBL_MIN},
     {1.3789972848607228e-308},
     {1.4914738736681624e-308},
     {1.0}, {2.0},
     {M_E}, {M_PI},
     {65503.0},
     {65504.0}, /* max FP16 */
     {65505.0},
     {131007.0},
     {131008.0}, /* max AFP */
     {131009.0},
     {.h = 0x41dfffffffc00000 }, /* to int = 0x7fffffff */
     {FLT_MAX},
     {FLT_MAX + 1.0},
     {DBL_MAX},
     {INFINITY},
     {NAN},
     {.h = 0x7ff0000000000001}, /* SNAN */
     {SNAN},
 };

 static const int num_f64 = ARRAY_SIZE(f64_numbers);

 int get_num_f64(void)
 {
     return num_f64;
 }

 double get_f64(int i)
 {
     return f64_numbers[i % num_f64].d;
 }

 char *fmt_f64(double num)
 {
     uint64_t double_as_hex = *(uint64_t *) &num;
     char *fmt;
     asprintf(&fmt, "f64(%02.20a:%#020" PRIx64 ")", num, double_as_hex);
     return fmt;
 }

 /*
  * Float flags
  */
 char *fmt_flags(void)
 {
     int flags = fetestexcept(FE_ALL_EXCEPT);
     char *fmt;

     if (flags) {
         asprintf(&fmt, "%s%s%s%s%s",
                  flags & FE_OVERFLOW ? "OVERFLOW " : "",
                  flags & FE_UNDERFLOW ? "UNDERFLOW " : "",
                  flags & FE_DIVBYZERO ? "DIV0 " : "",
                  flags & FE_INEXACT ? "INEXACT " : "",
                  flags & FE_INVALID ? "INVALID" : "");
     } else {
         asprintf(&fmt, "OK");
     }

     return fmt;
 }
	/*
	* Common Float Helpers
	*
	* This contains a series of useful utility routines and a set of
	* floating point constants useful for exercising the edge cases in
	* floating point tests.
	*
	* Copyright (c) 2019, 2024 Linaro
	*
	* SPDX-License-Identifier: GPL-2.0-or-later
	*/

	/* we want additional float type definitions */
	#define __STDC_WANT_IEC_60559_BFP_EXT__
	#define __STDC_WANT_IEC_60559_TYPES_EXT__

	#define _GNU_SOURCE
	#include <stdio.h>
	#include <stdlib.h>
	#include <inttypes.h>
	#include <math.h>
	#include <float.h>
	#include <fenv.h>

	#include "../float_helpers.h"

	#define ARRAY_SIZE(x) (sizeof(x) / sizeof((x)[0]))

	/*
	* Half Precision Numbers
	*
	* Not yet well standardised so we return a plain uint16_t for now.
	*/

	/* no handy defines for these numbers */
	static uint16_t f16_numbers[] = {
	0xffff, /* -NaN / AHP -Max */
	0xfcff, /* -NaN / AHP */
	0xfc01, /* -NaN / AHP */
	0xfc00, /* -Inf */
	0xfbff, /* -Max */
	0xc000, /* -2 */
	0xbc00, /* -1 */
	0x8001, /* -MIN subnormal */
	0x8000, /* -0 */
	0x0000, /* +0 */
	0x0001, /* MIN subnormal */
	0x3c00, /* 1 */
	0x7bff, /* Max */
	0x7c00, /* Inf */
	0x7c01, /* NaN / AHP */
	0x7cff, /* NaN / AHP */
	0x7fff, /* NaN / AHP +Max*/
	};

	static const int num_f16 = ARRAY_SIZE(f16_numbers);

	int get_num_f16(void)
	{
	return num_f16;
	}

	uint16_t get_f16(int i)
	{
	return f16_numbers[i % num_f16];
	}

	/* only display as hex */
	char *fmt_16(uint16_t num)
	{
	char *fmt;
	asprintf(&fmt, "f16(%#04x)", num);
	return fmt;
	}

	/*
	* Single Precision Numbers
	*/

	#ifndef SNANF
	/* Signaling NaN macros, if supported. */
	# define SNANF (__builtin_nansf (""))
	# define SNAN (__builtin_nans (""))
	# define SNANL (__builtin_nansl (""))
	#endif

	static float f32_numbers[] = {
	-SNANF,
	-NAN,
	-INFINITY,
	-FLT_MAX,
	-0x1.1874b2p+103,
	-0x1.c0bab6p+99,
	-0x1.31f75p-40,
	-0x1.505444p-66,
	-FLT_MIN,
	0.0,
	FLT_MIN,
	0x1p-25,
	0x1.ffffe6p-25, /* min positive FP16 subnormal */
	0x1.ff801ap-15, /* max subnormal FP16 */
	0x1.00000cp-14, /* min positive normal FP16 */
	1.0,
	0x1.004p+0, /* smallest float after 1.0 FP16 */
	2.0,
	M_E, M_PI,
	0x1.ffbep+15,
	0x1.ffcp+15, /* max FP16 */
	0x1.ffc2p+15,
	0x1.ffbfp+16,
	0x1.ffcp+16, /* max AFP */
	0x1.ffc1p+16,
	0x1.c0bab6p+99,
	FLT_MAX,
	INFINITY,
	NAN,
	SNANF
	};

	static const int num_f32 = ARRAY_SIZE(f32_numbers);

	int get_num_f32(void)
	{
	return num_f32;
	}

	float get_f32(int i)
	{
	return f32_numbers[i % num_f32];
	}

	char *fmt_f32(float num)
	{
	uint32_t single_as_hex = (uint32_t ) &num;
	char *fmt;
	asprintf(&fmt, "f32(%02.20a:%#010x)", num, single_as_hex);
	return fmt;
	}


	/* This allows us to initialise some doubles as pure hex */
	typedef union {
	double d;
	uint64_t h;
	} test_doubles;

	static test_doubles f64_numbers[] = {
	{SNAN},
	{-NAN},
	{-INFINITY},
	{-DBL_MAX},
	{-FLT_MAX-1.0},
	{-FLT_MAX},
	{-1.111E+31},
	{-1.111E+30}, /* half prec */
	{-2.0}, {-1.0},
	{-DBL_MIN},
	{-FLT_MIN},
	{0.0},
	{FLT_MIN},
	{2.98023224e-08},
	{5.96046E-8}, /* min positive FP16 subnormal */
	{6.09756E-5}, /* max subnormal FP16 */
	{6.10352E-5}, /* min positive normal FP16 */
	{1.0},
	{1.0009765625}, /* smallest float after 1.0 FP16 */
	{DBL_MIN},
	{1.3789972848607228e-308},
	{1.4914738736681624e-308},
	{1.0}, {2.0},
	{M_E}, {M_PI},
	{65503.0},
	{65504.0}, /* max FP16 */
	{65505.0},
	{131007.0},
	{131008.0}, /* max AFP */
	{131009.0},
	{.h = 0x41dfffffffc00000 }, /* to int = 0x7fffffff */
	{FLT_MAX},
	{FLT_MAX + 1.0},
	{DBL_MAX},
	{INFINITY},
	{NAN},
	{.h = 0x7ff0000000000001}, /* SNAN */
	{SNAN},
	};

	static const int num_f64 = ARRAY_SIZE(f64_numbers);

	int get_num_f64(void)
	{
	return num_f64;
	}

	double get_f64(int i)
	{
	return f64_numbers[i % num_f64].d;
	}

	char *fmt_f64(double num)
	{
	uint64_t double_as_hex = (uint64_t ) &num;
	char *fmt;
	asprintf(&fmt, "f64(%02.20a:%#020" PRIx64 ")", num, double_as_hex);
	return fmt;
	}

	/*
	* Float flags
	*/
	char *fmt_flags(void)
	{
	int flags = fetestexcept(FE_ALL_EXCEPT);
	char *fmt;

	if (flags) {
	asprintf(&fmt, "%s%s%s%s%s",
	flags & FE_OVERFLOW ? "OVERFLOW " : "",
	flags & FE_UNDERFLOW ? "UNDERFLOW " : "",
	flags & FE_DIVBYZERO ? "DIV0 " : "",
	flags & FE_INEXACT ? "INEXACT " : "",
	flags & FE_INVALID ? "INVALID" : "");
	} else {
	asprintf(&fmt, "OK");
	}

	return fmt;
	}