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qemu / berkeley-testfloat-3 / 0d2862cdb35361d47548020b97dc60b58d53d048 / . / source / testfloat.c
blob: 352d7301c618a5184ffa7d5124ed0a8f15eec44c [file] [log] [blame]
/*============================================================================
This C source file is part of TestFloat, Release 3d, a package of programs for
testing the correctness of floating-point arithmetic complying with the IEEE
Standard for Floating-Point, by John R. Hauser.
Copyright 2011, 2012, 2013, 2014, 2015, 2016, 2017 The Regents of the
University of California. All rights reserved.
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are met:
1. Redistributions of source code must retain the above copyright notice,
this list of conditions, and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright notice,
this list of conditions, and the following disclaimer in the documentation
and/or other materials provided with the distribution.
3. Neither the name of the University nor the names of its contributors may
be used to endorse or promote products derived from this software without
specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS "AS IS", AND ANY
EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE, ARE
DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE FOR ANY
DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
=============================================================================*/
#include <stdbool.h>
#include <stdint.h>
#include <string.h>
#include <stdlib.h>
#include <stdio.h>
#include <signal.h>
#include "platform.h"
#include "fail.h"
#include "softfloat.h"
#include "subjfloat_config.h"
#include "subjfloat.h"
#include "functions.h"
#include "genCases.h"
#include "verCases.h"
#include "testLoops.h"
static void catchSIGINT( int signalCode )
{
if ( verCases_stop ) exit( EXIT_FAILURE );
verCases_stop = true;
}
static void (*subjFunctionPtr)();
#ifdef FLOAT16
typedef float16_t funcType_a_ui32_z_f16( uint32_t );
#endif
typedef float32_t funcType_a_ui32_z_f32( uint32_t );
#ifdef FLOAT64
typedef float64_t funcType_a_ui32_z_f64( uint32_t );
#endif
#ifdef EXTFLOAT80
typedef void funcType_a_ui32_z_extF80( uint32_t, extFloat80_t * );
#endif
#ifdef FLOAT128
typedef void funcType_a_ui32_z_f128( uint32_t, float128_t * );
#endif
#ifdef FLOAT16
typedef float16_t funcType_a_ui64_z_f16( uint64_t );
#endif
typedef float32_t funcType_a_ui64_z_f32( uint64_t );
#ifdef FLOAT64
typedef float64_t funcType_a_ui64_z_f64( uint64_t );
#endif
#ifdef EXTFLOAT80
typedef void funcType_a_ui64_z_extF80( uint64_t, extFloat80_t * );
#endif
#ifdef FLOAT128
typedef void funcType_a_ui64_z_f128( uint64_t, float128_t * );
#endif
#ifdef FLOAT16
typedef float16_t funcType_a_i32_z_f16( int32_t );
#endif
typedef float32_t funcType_a_i32_z_f32( int32_t );
#ifdef FLOAT64
typedef float64_t funcType_a_i32_z_f64( int32_t );
#endif
#ifdef EXTFLOAT80
typedef void funcType_a_i32_z_extF80( int32_t, extFloat80_t * );
#endif
#ifdef FLOAT128
typedef void funcType_a_i32_z_f128( int32_t, float128_t * );
#endif
#ifdef FLOAT16
typedef float16_t funcType_a_i64_z_f16( int64_t );
#endif
typedef float32_t funcType_a_i64_z_f32( int64_t );
#ifdef FLOAT64
typedef float64_t funcType_a_i64_z_f64( int64_t );
#endif
#ifdef EXTFLOAT80
typedef void funcType_a_i64_z_extF80( int64_t, extFloat80_t * );
#endif
#ifdef FLOAT128
typedef void funcType_a_i64_z_f128( int64_t, float128_t * );
#endif
#ifdef FLOAT16
typedef uint_fast32_t funcType_a_f16_z_ui32( float16_t );
typedef uint_fast64_t funcType_a_f16_z_ui64( float16_t );
typedef int_fast32_t funcType_a_f16_z_i32( float16_t );
typedef int_fast64_t funcType_a_f16_z_i64( float16_t );
typedef float32_t funcType_a_f16_z_f32( float16_t );
#ifdef FLOAT64
typedef float64_t funcType_a_f16_z_f64( float16_t );
#endif
#ifdef EXTFLOAT80
typedef void funcType_a_f16_z_extF80( float16_t, extFloat80_t * );
#endif
#ifdef FLOAT128
typedef void funcType_a_f16_z_f128( float16_t, float128_t * );
#endif
typedef float16_t funcType_az_f16( float16_t );
typedef float16_t funcType_abz_f16( float16_t, float16_t );
typedef float16_t funcType_abcz_f16( float16_t, float16_t, float16_t );
typedef bool funcType_ab_f16_z_bool( float16_t, float16_t );
#endif
typedef uint_fast32_t funcType_a_f32_z_ui32( float32_t );
typedef uint_fast64_t funcType_a_f32_z_ui64( float32_t );
typedef int_fast32_t funcType_a_f32_z_i32( float32_t );
typedef int_fast64_t funcType_a_f32_z_i64( float32_t );
#ifdef FLOAT16
typedef float16_t funcType_a_f32_z_f16( float32_t );
#endif
#ifdef FLOAT64
typedef float64_t funcType_a_f32_z_f64( float32_t );
#endif
#ifdef EXTFLOAT80
typedef void funcType_a_f32_z_extF80( float32_t, extFloat80_t * );
#endif
#ifdef FLOAT128
typedef void funcType_a_f32_z_f128( float32_t, float128_t * );
#endif
typedef float32_t funcType_az_f32( float32_t );
typedef float32_t funcType_abz_f32( float32_t, float32_t );
typedef float32_t funcType_abcz_f32( float32_t, float32_t, float32_t );
typedef bool funcType_ab_f32_z_bool( float32_t, float32_t );
#ifdef FLOAT64
typedef uint_fast32_t funcType_a_f64_z_ui32( float64_t );
typedef uint_fast64_t funcType_a_f64_z_ui64( float64_t );
typedef int_fast32_t funcType_a_f64_z_i32( float64_t );
typedef int_fast64_t funcType_a_f64_z_i64( float64_t );
#ifdef FLOAT16
typedef float16_t funcType_a_f64_z_f16( float64_t );
#endif
typedef float32_t funcType_a_f64_z_f32( float64_t );
#ifdef EXTFLOAT80
typedef void funcType_a_f64_z_extF80( float64_t, extFloat80_t * );
#endif
#ifdef FLOAT128
typedef void funcType_a_f64_z_f128( float64_t, float128_t * );
#endif
typedef float64_t funcType_az_f64( float64_t );
typedef float64_t funcType_abz_f64( float64_t, float64_t );
typedef float64_t funcType_abcz_f64( float64_t, float64_t, float64_t );
typedef bool funcType_ab_f64_z_bool( float64_t, float64_t );
#endif
#ifdef EXTFLOAT80
typedef uint_fast32_t funcType_a_extF80_z_ui32( const extFloat80_t * );
typedef uint_fast64_t funcType_a_extF80_z_ui64( const extFloat80_t * );
typedef int_fast32_t funcType_a_extF80_z_i32( const extFloat80_t * );
typedef int_fast64_t funcType_a_extF80_z_i64( const extFloat80_t * );
#ifdef FLOAT16
typedef float16_t funcType_a_extF80_z_f16( const extFloat80_t * );
#endif
typedef float32_t funcType_a_extF80_z_f32( const extFloat80_t * );
#ifdef FLOAT64
typedef float64_t funcType_a_extF80_z_f64( const extFloat80_t * );
#endif
#ifdef FLOAT128
typedef void funcType_a_extF80_z_f128( const extFloat80_t *, float128_t * );
#endif
typedef void funcType_az_extF80( const extFloat80_t *, extFloat80_t * );
typedef
void
funcType_abz_extF80(
const extFloat80_t *, const extFloat80_t *, extFloat80_t * );
typedef
bool funcType_ab_extF80_z_bool( const extFloat80_t *, const extFloat80_t * );
#endif
#ifdef FLOAT128
typedef uint_fast32_t funcType_a_f128_z_ui32( const float128_t * );
typedef uint_fast64_t funcType_a_f128_z_ui64( const float128_t * );
typedef int_fast32_t funcType_a_f128_z_i32( const float128_t * );
typedef int_fast64_t funcType_a_f128_z_i64( const float128_t * );
#ifdef FLOAT16
typedef float16_t funcType_a_f128_z_f16( const float128_t * );
#endif
typedef float32_t funcType_a_f128_z_f32( const float128_t * );
#ifdef FLOAT64
typedef float64_t funcType_a_f128_z_f64( const float128_t * );
#endif
#ifdef EXTFLOAT80
typedef void funcType_a_f128_z_extF80( const float128_t *, extFloat80_t * );
#endif
typedef void funcType_az_f128( const float128_t *, float128_t * );
typedef
void
funcType_abz_f128( const float128_t *, const float128_t *, float128_t * );
typedef
void
funcType_abcz_f128(
const float128_t *, const float128_t *, const float128_t *, float128_t *
);
typedef bool funcType_ab_f128_z_bool( const float128_t *, const float128_t * );
#endif
#ifdef FLOAT16
static
uint_fast32_t
subjFunction_a_f16_z_ui32_rx(
float16_t a, uint_fast8_t roundingMode, bool exact )
{
return ((funcType_a_f16_z_ui32 *) subjFunctionPtr)( a );
}
static
uint_fast64_t
subjFunction_a_f16_z_ui64_rx(
float16_t a, uint_fast8_t roundingMode, bool exact )
{
return ((funcType_a_f16_z_ui64 *) subjFunctionPtr)( a );
}
static
int_fast32_t
subjFunction_a_f16_z_i32_rx(
float16_t a, uint_fast8_t roundingMode, bool exact )
{
return ((funcType_a_f16_z_i32 *) subjFunctionPtr)( a );
}
static
int_fast64_t
subjFunction_a_f16_z_i64_rx(
float16_t a, uint_fast8_t roundingMode, bool exact )
{
return ((funcType_a_f16_z_i64 *) subjFunctionPtr)( a );
}
static
float16_t
subjFunction_az_f16_rx( float16_t a, uint_fast8_t roundingMode, bool exact )
{
return ((funcType_az_f16 *) subjFunctionPtr)( a );
}
#endif
static
uint_fast32_t
subjFunction_a_f32_z_ui32_rx(
float32_t a, uint_fast8_t roundingMode, bool exact )
{
return ((funcType_a_f32_z_ui32 *) subjFunctionPtr)( a );
}
static
uint_fast64_t
subjFunction_a_f32_z_ui64_rx(
float32_t a, uint_fast8_t roundingMode, bool exact )
{
return ((funcType_a_f32_z_ui64 *) subjFunctionPtr)( a );
}
static
int_fast32_t
subjFunction_a_f32_z_i32_rx(
float32_t a, uint_fast8_t roundingMode, bool exact )
{
return ((funcType_a_f32_z_i32 *) subjFunctionPtr)( a );
}
static
int_fast64_t
subjFunction_a_f32_z_i64_rx(
float32_t a, uint_fast8_t roundingMode, bool exact )
{
return ((funcType_a_f32_z_i64 *) subjFunctionPtr)( a );
}
static
float32_t
subjFunction_az_f32_rx( float32_t a, uint_fast8_t roundingMode, bool exact )
{
return ((funcType_az_f32 *) subjFunctionPtr)( a );
}
#ifdef FLOAT64
static
uint_fast32_t
subjFunction_a_f64_z_ui32_rx(
float64_t a, uint_fast8_t roundingMode, bool exact )
{
return ((funcType_a_f64_z_ui32 *) subjFunctionPtr)( a );
}
static
uint_fast64_t
subjFunction_a_f64_z_ui64_rx(
float64_t a, uint_fast8_t roundingMode, bool exact )
{
return ((funcType_a_f64_z_ui64 *) subjFunctionPtr)( a );
}
static
int_fast32_t
subjFunction_a_f64_z_i32_rx(
float64_t a, uint_fast8_t roundingMode, bool exact )
{
return ((funcType_a_f64_z_i32 *) subjFunctionPtr)( a );
}
static
int_fast64_t
subjFunction_a_f64_z_i64_rx(
float64_t a, uint_fast8_t roundingMode, bool exact )
{
return ((funcType_a_f64_z_i64 *) subjFunctionPtr)( a );
}
static
float64_t
subjFunction_az_f64_rx( float64_t a, uint_fast8_t roundingMode, bool exact )
{
return ((funcType_az_f64 *) subjFunctionPtr)( a );
}
#endif
#ifdef EXTFLOAT80
static
uint_fast32_t
subjFunction_a_extF80_z_ui32_rx(
const extFloat80_t *aPtr, uint_fast8_t roundingMode, bool exact )
{
return ((funcType_a_extF80_z_ui32 *) subjFunctionPtr)( aPtr );
}
static
uint_fast64_t
subjFunction_a_extF80_z_ui64_rx(
const extFloat80_t *aPtr, uint_fast8_t roundingMode, bool exact )
{
return ((funcType_a_extF80_z_ui64 *) subjFunctionPtr)( aPtr );
}
static
int_fast32_t
subjFunction_a_extF80_z_i32_rx(
const extFloat80_t *aPtr, uint_fast8_t roundingMode, bool exact )
{
return ((funcType_a_extF80_z_i32 *) subjFunctionPtr)( aPtr );
}
static
int_fast64_t
subjFunction_a_extF80_z_i64_rx(
const extFloat80_t *aPtr, uint_fast8_t roundingMode, bool exact )
{
return ((funcType_a_extF80_z_i64 *) subjFunctionPtr)( aPtr );
}
static
void
subjFunction_az_extF80_rx(
const extFloat80_t *aPtr,
uint_fast8_t roundingMode,
bool exact,
extFloat80_t *zPtr
)
{
return ((funcType_az_extF80 *) subjFunctionPtr)( aPtr, zPtr );
}
#endif
#ifdef FLOAT128
static
uint_fast32_t
subjFunction_a_f128_z_ui32_rx(
const float128_t *aPtr, uint_fast8_t roundingMode, bool exact )
{
return ((funcType_a_f128_z_ui32 *) subjFunctionPtr)( aPtr );
}
static
uint_fast64_t
subjFunction_a_f128_z_ui64_rx(
const float128_t *aPtr, uint_fast8_t roundingMode, bool exact )
{
return ((funcType_a_f128_z_ui64 *) subjFunctionPtr)( aPtr );
}
static
int_fast32_t
subjFunction_a_f128_z_i32_rx(
const float128_t *aPtr, uint_fast8_t roundingMode, bool exact )
{
return ((funcType_a_f128_z_i32 *) subjFunctionPtr)( aPtr );
}
static
int_fast64_t
subjFunction_a_f128_z_i64_rx(
const float128_t *aPtr, uint_fast8_t roundingMode, bool exact )
{
return ((funcType_a_f128_z_i64 *) subjFunctionPtr)( aPtr );
}
static
void
subjFunction_az_f128_rx(
const float128_t *aPtr,
uint_fast8_t roundingMode,
bool exact,
float128_t *zPtr
)
{
return ((funcType_az_f128 *) subjFunctionPtr)( aPtr, zPtr );
}
#endif
static
void
testFunctionInstance(
int functionCode, uint_fast8_t roundingMode, bool exact )
{
#ifdef FLOAT16
funcType_abz_f16 *trueFunction_abz_f16;
funcType_ab_f16_z_bool *trueFunction_ab_f16_z_bool;
#endif
funcType_abz_f32 *trueFunction_abz_f32;
funcType_ab_f32_z_bool *trueFunction_ab_f32_z_bool;
#ifdef FLOAT64
funcType_abz_f64 *trueFunction_abz_f64;
funcType_ab_f64_z_bool *trueFunction_ab_f64_z_bool;
#endif
#ifdef EXTFLOAT80
funcType_abz_extF80 *trueFunction_abz_extF80;
funcType_ab_extF80_z_bool *trueFunction_ab_extF80_z_bool;
#endif
#ifdef FLOAT128
funcType_abz_f128 *trueFunction_abz_f128;
funcType_ab_f128_z_bool *trueFunction_ab_f128_z_bool;
#endif
fputs( "Testing ", stderr );
verCases_writeFunctionName( stderr );
fputs( ".\n", stderr );
switch ( functionCode ) {
/*--------------------------------------------------------------------
*--------------------------------------------------------------------*/
#ifdef FLOAT16
#ifdef SUBJ_UI32_TO_F16
case UI32_TO_F16:
test_a_ui32_z_f16(
ui32_to_f16, (funcType_a_ui32_z_f16 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef SUBJ_UI32_TO_F32
case UI32_TO_F32:
test_a_ui32_z_f32(
ui32_to_f32, (funcType_a_ui32_z_f32 *) subjFunctionPtr );
break;
#endif
#ifdef FLOAT64
#ifdef SUBJ_UI32_TO_F64
case UI32_TO_F64:
test_a_ui32_z_f64(
ui32_to_f64, (funcType_a_ui32_z_f64 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef EXTFLOAT80
#ifdef SUBJ_UI32_TO_EXTF80
case UI32_TO_EXTF80:
test_a_ui32_z_extF80(
ui32_to_extF80M, (funcType_a_ui32_z_extF80 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef FLOAT128
#ifdef SUBJ_UI32_TO_F128
case UI32_TO_F128:
test_a_ui32_z_f128(
ui32_to_f128M, (funcType_a_ui32_z_f128 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef FLOAT16
#ifdef SUBJ_UI64_TO_F16
case UI64_TO_F16:
test_a_ui64_z_f16(
ui64_to_f16, (funcType_a_ui64_z_f16 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef SUBJ_UI64_TO_F32
case UI64_TO_F32:
test_a_ui64_z_f32(
ui64_to_f32, (funcType_a_ui64_z_f32 *) subjFunctionPtr );
break;
#endif
#ifdef FLOAT64
#ifdef SUBJ_UI64_TO_F64
case UI64_TO_F64:
test_a_ui64_z_f64(
ui64_to_f64, (funcType_a_ui64_z_f64 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef EXTFLOAT80
#ifdef SUBJ_UI64_TO_EXTF80
case UI64_TO_EXTF80:
test_a_ui64_z_extF80(
ui64_to_extF80M, (funcType_a_ui64_z_extF80 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef FLOAT128
#ifdef SUBJ_UI64_TO_F128
case UI64_TO_F128:
test_a_ui64_z_f128(
ui64_to_f128M, (funcType_a_ui64_z_f128 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef FLOAT16
#ifdef SUBJ_I32_TO_F16
case I32_TO_F16:
test_a_i32_z_f16(
i32_to_f16, (funcType_a_i32_z_f16 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef SUBJ_I32_TO_F32
case I32_TO_F32:
test_a_i32_z_f32(
i32_to_f32, (funcType_a_i32_z_f32 *) subjFunctionPtr );
break;
#endif
#ifdef FLOAT64
#ifdef SUBJ_I32_TO_F64
case I32_TO_F64:
test_a_i32_z_f64(
i32_to_f64, (funcType_a_i32_z_f64 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef EXTFLOAT80
#ifdef SUBJ_I32_TO_EXTF80
case I32_TO_EXTF80:
test_a_i32_z_extF80(
i32_to_extF80M, (funcType_a_i32_z_extF80 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef FLOAT128
#ifdef SUBJ_I32_TO_F128
case I32_TO_F128:
test_a_i32_z_f128(
i32_to_f128M, (funcType_a_i32_z_f128 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef FLOAT16
#ifdef SUBJ_I64_TO_F16
case I64_TO_F16:
test_a_i64_z_f16(
i64_to_f16, (funcType_a_i64_z_f16 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef SUBJ_I64_TO_F32
case I64_TO_F32:
test_a_i64_z_f32(
i64_to_f32, (funcType_a_i64_z_f32 *) subjFunctionPtr );
break;
#endif
#ifdef FLOAT64
#ifdef SUBJ_I64_TO_F64
case I64_TO_F64:
test_a_i64_z_f64(
i64_to_f64, (funcType_a_i64_z_f64 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef EXTFLOAT80
#ifdef SUBJ_I64_TO_EXTF80
case I64_TO_EXTF80:
test_a_i64_z_extF80(
i64_to_extF80M, (funcType_a_i64_z_extF80 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef FLOAT128
#ifdef SUBJ_I64_TO_F128
case I64_TO_F128:
test_a_i64_z_f128(
i64_to_f128M, (funcType_a_i64_z_f128 *) subjFunctionPtr );
break;
#endif
#endif
/*--------------------------------------------------------------------
*--------------------------------------------------------------------*/
#ifdef FLOAT16
case F16_TO_UI32:
test_a_f16_z_ui32_rx(
f16_to_ui32, subjFunction_a_f16_z_ui32_rx, roundingMode, exact );
break;
case F16_TO_UI64:
test_a_f16_z_ui64_rx(
f16_to_ui64, subjFunction_a_f16_z_ui64_rx, roundingMode, exact );
break;
case F16_TO_I32:
test_a_f16_z_i32_rx(
f16_to_i32, subjFunction_a_f16_z_i32_rx, roundingMode, exact );
break;
case F16_TO_I64:
test_a_f16_z_i64_rx(
f16_to_i64, subjFunction_a_f16_z_i64_rx, roundingMode, exact );
break;
#ifdef SUBJ_F16_TO_F32
case F16_TO_F32:
test_a_f16_z_f32(
f16_to_f32, (funcType_a_f16_z_f32 *) subjFunctionPtr );
break;
#endif
#ifdef FLOAT64
#ifdef SUBJ_F16_TO_F64
case F16_TO_F64:
test_a_f16_z_f64(
f16_to_f64, (funcType_a_f16_z_f64 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef EXTFLOAT80
#ifdef SUBJ_F16_TO_EXTF80
case F16_TO_EXTF80:
test_a_f16_z_extF80(
f16_to_extF80M, (funcType_a_f16_z_extF80 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef FLOAT128
#ifdef SUBJ_F16_TO_F128
case F16_TO_F128:
test_a_f16_z_f128(
f16_to_f128M, (funcType_a_f16_z_f128 *) subjFunctionPtr );
break;
#endif
#endif
case F16_ROUNDTOINT:
test_az_f16_rx(
f16_roundToInt, subjFunction_az_f16_rx, roundingMode, exact );
break;
#ifdef SUBJ_F16_ADD
case F16_ADD:
trueFunction_abz_f16 = f16_add;
goto test_abz_f16;
#endif
#ifdef SUBJ_F16_SUB
case F16_SUB:
trueFunction_abz_f16 = f16_sub;
goto test_abz_f16;
#endif
#ifdef SUBJ_F16_MUL
case F16_MUL:
trueFunction_abz_f16 = f16_mul;
goto test_abz_f16;
#endif
#ifdef SUBJ_F16_MULADD
case F16_MULADD:
test_abcz_f16( f16_mulAdd, (funcType_abcz_f16 *) subjFunctionPtr );
break;
#endif
#ifdef SUBJ_F16_DIV
case F16_DIV:
trueFunction_abz_f16 = f16_div;
goto test_abz_f16;
#endif
#ifdef SUBJ_F16_REM
case F16_REM:
trueFunction_abz_f16 = f16_rem;
goto test_abz_f16;
#endif
test_abz_f16:
test_abz_f16(
trueFunction_abz_f16, (funcType_abz_f16 *) subjFunctionPtr );
break;
#ifdef SUBJ_F16_SQRT
case F16_SQRT:
test_az_f16( f16_sqrt, (funcType_az_f16 *) subjFunctionPtr );
break;
#endif
#ifdef SUBJ_F16_EQ
case F16_EQ:
trueFunction_ab_f16_z_bool = f16_eq;
goto test_ab_f16_z_bool;
#endif
#ifdef SUBJ_F16_LE
case F16_LE:
trueFunction_ab_f16_z_bool = f16_le;
goto test_ab_f16_z_bool;
#endif
#ifdef SUBJ_F16_LT
case F16_LT:
trueFunction_ab_f16_z_bool = f16_lt;
goto test_ab_f16_z_bool;
#endif
#ifdef SUBJ_F16_EQ_SIGNALING
case F16_EQ_SIGNALING:
trueFunction_ab_f16_z_bool = f16_eq_signaling;
goto test_ab_f16_z_bool;
#endif
#ifdef SUBJ_F16_LE_QUIET
case F16_LE_QUIET:
trueFunction_ab_f16_z_bool = f16_le_quiet;
goto test_ab_f16_z_bool;
#endif
#ifdef SUBJ_F16_LT_QUIET
case F16_LT_QUIET:
trueFunction_ab_f16_z_bool = f16_lt_quiet;
goto test_ab_f16_z_bool;
#endif
test_ab_f16_z_bool:
test_ab_f16_z_bool(
trueFunction_ab_f16_z_bool,
(funcType_ab_f16_z_bool *) subjFunctionPtr
);
break;
#endif
/*--------------------------------------------------------------------
*--------------------------------------------------------------------*/
case F32_TO_UI32:
test_a_f32_z_ui32_rx(
f32_to_ui32, subjFunction_a_f32_z_ui32_rx, roundingMode, exact );
break;
case F32_TO_UI64:
test_a_f32_z_ui64_rx(
f32_to_ui64, subjFunction_a_f32_z_ui64_rx, roundingMode, exact );
break;
case F32_TO_I32:
test_a_f32_z_i32_rx(
f32_to_i32, subjFunction_a_f32_z_i32_rx, roundingMode, exact );
break;
case F32_TO_I64:
test_a_f32_z_i64_rx(
f32_to_i64, subjFunction_a_f32_z_i64_rx, roundingMode, exact );
break;
#ifdef FLOAT16
#ifdef SUBJ_F32_TO_F16
case F32_TO_F16:
test_a_f32_z_f16(
f32_to_f16, (funcType_a_f32_z_f16 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef FLOAT64
#ifdef SUBJ_F32_TO_F64
case F32_TO_F64:
test_a_f32_z_f64(
f32_to_f64, (funcType_a_f32_z_f64 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef EXTFLOAT80
#ifdef SUBJ_F32_TO_EXTF80
case F32_TO_EXTF80:
test_a_f32_z_extF80(
f32_to_extF80M, (funcType_a_f32_z_extF80 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef FLOAT128
#ifdef SUBJ_F32_TO_F128
case F32_TO_F128:
test_a_f32_z_f128(
f32_to_f128M, (funcType_a_f32_z_f128 *) subjFunctionPtr );
break;
#endif
#endif
case F32_ROUNDTOINT:
test_az_f32_rx(
f32_roundToInt, subjFunction_az_f32_rx, roundingMode, exact );
break;
#ifdef SUBJ_F32_ADD
case F32_ADD:
trueFunction_abz_f32 = f32_add;
goto test_abz_f32;
#endif
#ifdef SUBJ_F32_SUB
case F32_SUB:
trueFunction_abz_f32 = f32_sub;
goto test_abz_f32;
#endif
#ifdef SUBJ_F32_MUL
case F32_MUL:
trueFunction_abz_f32 = f32_mul;
goto test_abz_f32;
#endif
#ifdef SUBJ_F32_MULADD
case F32_MULADD:
test_abcz_f32( f32_mulAdd, (funcType_abcz_f32 *) subjFunctionPtr );
break;
#endif
#ifdef SUBJ_F32_DIV
case F32_DIV:
trueFunction_abz_f32 = f32_div;
goto test_abz_f32;
#endif
#ifdef SUBJ_F32_REM
case F32_REM:
trueFunction_abz_f32 = f32_rem;
goto test_abz_f32;
#endif
test_abz_f32:
test_abz_f32(
trueFunction_abz_f32, (funcType_abz_f32 *) subjFunctionPtr );
break;
#ifdef SUBJ_F32_SQRT
case F32_SQRT:
test_az_f32( f32_sqrt, (funcType_az_f32 *) subjFunctionPtr );
break;
#endif
#ifdef SUBJ_F32_EQ
case F32_EQ:
trueFunction_ab_f32_z_bool = f32_eq;
goto test_ab_f32_z_bool;
#endif
#ifdef SUBJ_F32_LE
case F32_LE:
trueFunction_ab_f32_z_bool = f32_le;
goto test_ab_f32_z_bool;
#endif
#ifdef SUBJ_F32_LT
case F32_LT:
trueFunction_ab_f32_z_bool = f32_lt;
goto test_ab_f32_z_bool;
#endif
#ifdef SUBJ_F32_EQ_SIGNALING
case F32_EQ_SIGNALING:
trueFunction_ab_f32_z_bool = f32_eq_signaling;
goto test_ab_f32_z_bool;
#endif
#ifdef SUBJ_F32_LE_QUIET
case F32_LE_QUIET:
trueFunction_ab_f32_z_bool = f32_le_quiet;
goto test_ab_f32_z_bool;
#endif
#ifdef SUBJ_F32_LT_QUIET
case F32_LT_QUIET:
trueFunction_ab_f32_z_bool = f32_lt_quiet;
goto test_ab_f32_z_bool;
#endif
test_ab_f32_z_bool:
test_ab_f32_z_bool(
trueFunction_ab_f32_z_bool,
(funcType_ab_f32_z_bool *) subjFunctionPtr
);
break;
/*--------------------------------------------------------------------
*--------------------------------------------------------------------*/
#ifdef FLOAT64
case F64_TO_UI32:
test_a_f64_z_ui32_rx(
f64_to_ui32, subjFunction_a_f64_z_ui32_rx, roundingMode, exact );
break;
case F64_TO_UI64:
test_a_f64_z_ui64_rx(
f64_to_ui64, subjFunction_a_f64_z_ui64_rx, roundingMode, exact );
break;
case F64_TO_I32:
test_a_f64_z_i32_rx(
f64_to_i32, subjFunction_a_f64_z_i32_rx, roundingMode, exact );
break;
case F64_TO_I64:
test_a_f64_z_i64_rx(
f64_to_i64, subjFunction_a_f64_z_i64_rx, roundingMode, exact );
break;
#ifdef FLOAT16
#ifdef SUBJ_F64_TO_F16
case F64_TO_F16:
test_a_f64_z_f16(
f64_to_f16, (funcType_a_f64_z_f16 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef SUBJ_F64_TO_F32
case F64_TO_F32:
test_a_f64_z_f32(
f64_to_f32, (funcType_a_f64_z_f32 *) subjFunctionPtr );
break;
#endif
#ifdef EXTFLOAT80
#ifdef SUBJ_F64_TO_EXTF80
case F64_TO_EXTF80:
test_a_f64_z_extF80(
f64_to_extF80M, (funcType_a_f64_z_extF80 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef FLOAT128
#ifdef SUBJ_F64_TO_F128
case F64_TO_F128:
test_a_f64_z_f128(
f64_to_f128M, (funcType_a_f64_z_f128 *) subjFunctionPtr );
break;
#endif
#endif
case F64_ROUNDTOINT:
test_az_f64_rx(
f64_roundToInt, subjFunction_az_f64_rx, roundingMode, exact );
break;
#ifdef SUBJ_F64_ADD
case F64_ADD:
trueFunction_abz_f64 = f64_add;
goto test_abz_f64;
#endif
#ifdef SUBJ_F64_SUB
case F64_SUB:
trueFunction_abz_f64 = f64_sub;
goto test_abz_f64;
#endif
#ifdef SUBJ_F64_MUL
case F64_MUL:
trueFunction_abz_f64 = f64_mul;
goto test_abz_f64;
#endif
#ifdef SUBJ_F64_MULADD
case F64_MULADD:
test_abcz_f64( f64_mulAdd, (funcType_abcz_f64 *) subjFunctionPtr );
break;
#endif
#ifdef SUBJ_F64_DIV
case F64_DIV:
trueFunction_abz_f64 = f64_div;
goto test_abz_f64;
#endif
#ifdef SUBJ_F64_REM
case F64_REM:
trueFunction_abz_f64 = f64_rem;
goto test_abz_f64;
#endif
test_abz_f64:
test_abz_f64(
trueFunction_abz_f64, (funcType_abz_f64 *) subjFunctionPtr );
break;
#ifdef SUBJ_F64_SQRT
case F64_SQRT:
test_az_f64( f64_sqrt, (funcType_az_f64 *) subjFunctionPtr );
break;
#endif
#ifdef SUBJ_F64_EQ
case F64_EQ:
trueFunction_ab_f64_z_bool = f64_eq;
goto test_ab_f64_z_bool;
#endif
#ifdef SUBJ_F64_LE
case F64_LE:
trueFunction_ab_f64_z_bool = f64_le;
goto test_ab_f64_z_bool;
#endif
#ifdef SUBJ_F64_LT
case F64_LT:
trueFunction_ab_f64_z_bool = f64_lt;
goto test_ab_f64_z_bool;
#endif
#ifdef SUBJ_F64_EQ_SIGNALING
case F64_EQ_SIGNALING:
trueFunction_ab_f64_z_bool = f64_eq_signaling;
goto test_ab_f64_z_bool;
#endif
#ifdef SUBJ_F64_LE_QUIET
case F64_LE_QUIET:
trueFunction_ab_f64_z_bool = f64_le_quiet;
goto test_ab_f64_z_bool;
#endif
#ifdef SUBJ_F64_LT_QUIET
case F64_LT_QUIET:
trueFunction_ab_f64_z_bool = f64_lt_quiet;
goto test_ab_f64_z_bool;
#endif
test_ab_f64_z_bool:
test_ab_f64_z_bool(
trueFunction_ab_f64_z_bool,
(funcType_ab_f64_z_bool *) subjFunctionPtr
);
break;
#endif
/*--------------------------------------------------------------------
*--------------------------------------------------------------------*/
#ifdef EXTFLOAT80
case EXTF80_TO_UI32:
test_a_extF80_z_ui32_rx(
extF80M_to_ui32,
subjFunction_a_extF80_z_ui32_rx,
roundingMode,
exact
);
break;
case EXTF80_TO_UI64:
test_a_extF80_z_ui64_rx(
extF80M_to_ui64,
subjFunction_a_extF80_z_ui64_rx,
roundingMode,
exact
);
break;
case EXTF80_TO_I32:
test_a_extF80_z_i32_rx(
extF80M_to_i32, subjFunction_a_extF80_z_i32_rx, roundingMode, exact
);
break;
case EXTF80_TO_I64:
test_a_extF80_z_i64_rx(
extF80M_to_i64, subjFunction_a_extF80_z_i64_rx, roundingMode, exact
);
break;
#ifdef FLOAT16
#ifdef SUBJ_EXTF80_TO_F16
case EXTF80_TO_F16:
test_a_extF80_z_f16(
extF80M_to_f16, (funcType_a_extF80_z_f16 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef SUBJ_EXTF80_TO_F32
case EXTF80_TO_F32:
test_a_extF80_z_f32(
extF80M_to_f32, (funcType_a_extF80_z_f32 *) subjFunctionPtr );
break;
#endif
#ifdef FLOAT64
#ifdef SUBJ_EXTF80_TO_F64
case EXTF80_TO_F64:
test_a_extF80_z_f64(
extF80M_to_f64, (funcType_a_extF80_z_f64 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef FLOAT128
#ifdef SUBJ_EXTF80_TO_F128
case EXTF80_TO_F128:
test_a_extF80_z_f128(
extF80M_to_f128M, (funcType_a_extF80_z_f128 *) subjFunctionPtr );
break;
#endif
#endif
case EXTF80_ROUNDTOINT:
test_az_extF80_rx(
extF80M_roundToInt, subjFunction_az_extF80_rx, roundingMode, exact
);
break;
#ifdef SUBJ_EXTF80_ADD
case EXTF80_ADD:
trueFunction_abz_extF80 = extF80M_add;
goto test_abz_extF80;
#endif
#ifdef SUBJ_EXTF80_SUB
case EXTF80_SUB:
trueFunction_abz_extF80 = extF80M_sub;
goto test_abz_extF80;
#endif
#ifdef SUBJ_EXTF80_MUL
case EXTF80_MUL:
trueFunction_abz_extF80 = extF80M_mul;
goto test_abz_extF80;
#endif
#ifdef SUBJ_EXTF80_DIV
case EXTF80_DIV:
trueFunction_abz_extF80 = extF80M_div;
goto test_abz_extF80;
#endif
#ifdef SUBJ_EXTF80_REM
case EXTF80_REM:
trueFunction_abz_extF80 = extF80M_rem;
goto test_abz_extF80;
#endif
test_abz_extF80:
test_abz_extF80(
trueFunction_abz_extF80, (funcType_abz_extF80 *) subjFunctionPtr );
break;
#ifdef SUBJ_EXTF80_SQRT
case EXTF80_SQRT:
test_az_extF80( extF80M_sqrt, (funcType_az_extF80 *) subjFunctionPtr );
break;
#endif
#ifdef SUBJ_EXTF80_EQ
case EXTF80_EQ:
trueFunction_ab_extF80_z_bool = extF80M_eq;
goto test_ab_extF80_z_bool;
#endif
#ifdef SUBJ_EXTF80_LE
case EXTF80_LE:
trueFunction_ab_extF80_z_bool = extF80M_le;
goto test_ab_extF80_z_bool;
#endif
#ifdef SUBJ_EXTF80_LT
case EXTF80_LT:
trueFunction_ab_extF80_z_bool = extF80M_lt;
goto test_ab_extF80_z_bool;
#endif
#ifdef SUBJ_EXTF80_EQ_SIGNALING
case EXTF80_EQ_SIGNALING:
trueFunction_ab_extF80_z_bool = extF80M_eq_signaling;
goto test_ab_extF80_z_bool;
#endif
#ifdef SUBJ_EXTF80_LE_QUIET
case EXTF80_LE_QUIET:
trueFunction_ab_extF80_z_bool = extF80M_le_quiet;
goto test_ab_extF80_z_bool;
#endif
#ifdef SUBJ_EXTF80_LT_QUIET
case EXTF80_LT_QUIET:
trueFunction_ab_extF80_z_bool = extF80M_lt_quiet;
goto test_ab_extF80_z_bool;
#endif
test_ab_extF80_z_bool:
test_ab_extF80_z_bool(
trueFunction_ab_extF80_z_bool,
(funcType_ab_extF80_z_bool *) subjFunctionPtr
);
break;
#endif
/*--------------------------------------------------------------------
*--------------------------------------------------------------------*/
#ifdef FLOAT128
case F128_TO_UI32:
test_a_f128_z_ui32_rx(
f128M_to_ui32, subjFunction_a_f128_z_ui32_rx, roundingMode, exact
);
break;
case F128_TO_UI64:
test_a_f128_z_ui64_rx(
f128M_to_ui64, subjFunction_a_f128_z_ui64_rx, roundingMode, exact
);
break;
case F128_TO_I32:
test_a_f128_z_i32_rx(
f128M_to_i32, subjFunction_a_f128_z_i32_rx, roundingMode, exact );
break;
case F128_TO_I64:
test_a_f128_z_i64_rx(
f128M_to_i64, subjFunction_a_f128_z_i64_rx, roundingMode, exact );
break;
#ifdef FLOAT16
#ifdef SUBJ_F128_TO_F16
case F128_TO_F16:
test_a_f128_z_f16(
f128M_to_f16, (funcType_a_f128_z_f16 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef SUBJ_F128_TO_F32
case F128_TO_F32:
test_a_f128_z_f32(
f128M_to_f32, (funcType_a_f128_z_f32 *) subjFunctionPtr );
break;
#endif
#ifdef FLOAT64
#ifdef SUBJ_F128_TO_F64
case F128_TO_F64:
test_a_f128_z_f64(
f128M_to_f64, (funcType_a_f128_z_f64 *) subjFunctionPtr );
break;
#endif
#endif
#ifdef EXTFLOAT80
#ifdef SUBJ_F128_TO_EXTF80
case F128_TO_EXTF80:
test_a_f128_z_extF80(
f128M_to_extF80M, (funcType_a_f128_z_extF80 *) subjFunctionPtr );
break;
#endif
#endif
case F128_ROUNDTOINT:
test_az_f128_rx(
f128M_roundToInt, subjFunction_az_f128_rx, roundingMode, exact );
break;
#ifdef SUBJ_F128_ADD
case F128_ADD:
trueFunction_abz_f128 = f128M_add;
goto test_abz_f128;
#endif
#ifdef SUBJ_F128_SUB
case F128_SUB:
trueFunction_abz_f128 = f128M_sub;
goto test_abz_f128;
#endif
#ifdef SUBJ_F128_MUL
case F128_MUL:
trueFunction_abz_f128 = f128M_mul;
goto test_abz_f128;
#endif
#ifdef SUBJ_F128_MULADD
case F128_MULADD:
test_abcz_f128( f128M_mulAdd, (funcType_abcz_f128 *) subjFunctionPtr );
break;
#endif
#ifdef SUBJ_F128_DIV
case F128_DIV:
trueFunction_abz_f128 = f128M_div;
goto test_abz_f128;
#endif
#ifdef SUBJ_F128_REM
case F128_REM:
trueFunction_abz_f128 = f128M_rem;
goto test_abz_f128;
#endif
test_abz_f128:
test_abz_f128(
trueFunction_abz_f128, (funcType_abz_f128 *) subjFunctionPtr );
break;
#ifdef SUBJ_F128_SQRT
case F128_SQRT:
test_az_f128( f128M_sqrt, (funcType_az_f128 *) subjFunctionPtr );
break;
#endif
#ifdef SUBJ_F128_EQ
case F128_EQ:
trueFunction_ab_f128_z_bool = f128M_eq;
goto test_ab_f128_z_bool;
#endif
#ifdef SUBJ_F128_LE
case F128_LE:
trueFunction_ab_f128_z_bool = f128M_le;
goto test_ab_f128_z_bool;
#endif
#ifdef SUBJ_F128_LT
case F128_LT:
trueFunction_ab_f128_z_bool = f128M_lt;
goto test_ab_f128_z_bool;
#endif
#ifdef SUBJ_F128_EQ_SIGNALING
case F128_EQ_SIGNALING:
trueFunction_ab_f128_z_bool = f128M_eq_signaling;
goto test_ab_f128_z_bool;
#endif
#ifdef SUBJ_F128_LE_QUIET
case F128_LE_QUIET:
trueFunction_ab_f128_z_bool = f128M_le_quiet;
goto test_ab_f128_z_bool;
#endif
#ifdef SUBJ_F128_LT_QUIET
case F128_LT_QUIET:
trueFunction_ab_f128_z_bool = f128M_lt_quiet;
goto test_ab_f128_z_bool;
#endif
test_ab_f128_z_bool:
test_ab_f128_z_bool(
trueFunction_ab_f128_z_bool,
(funcType_ab_f128_z_bool *) subjFunctionPtr
);
break;
#endif
}
if ( (verCases_errorStop && verCases_anyErrors) || verCases_stop ) {
verCases_exitWithStatus();
}
}
static
void
testFunction(
const struct standardFunctionInfo *standardFunctionInfoPtr,
uint_fast8_t roundingPrecisionIn,
int roundingCodeIn
)
{
int functionCode, functionAttribs;
bool standardFunctionHasFixedRounding;
int roundingCode;
bool exact;
uint_fast8_t roundingPrecision, roundingMode;
functionCode = standardFunctionInfoPtr->functionCode;
functionAttribs = functionInfos[functionCode].attribs;
standardFunctionHasFixedRounding = false;
if ( functionAttribs & FUNC_ARG_ROUNDINGMODE ) {
roundingCode = standardFunctionInfoPtr->roundingCode;
if ( roundingCode ) {
standardFunctionHasFixedRounding = true;
roundingCodeIn = roundingCode;
}
}
exact = standardFunctionInfoPtr->exact;
verCases_functionNamePtr = standardFunctionInfoPtr->namePtr;
roundingPrecision = 32;
for (;;) {
if ( functionAttribs & FUNC_EFF_ROUNDINGPRECISION ) {
if ( roundingPrecisionIn ) roundingPrecision = roundingPrecisionIn;
} else {
roundingPrecision = 0;
}
#ifdef EXTFLOAT80
verCases_roundingPrecision = roundingPrecision;
if ( roundingPrecision ) {
extF80_roundingPrecision = roundingPrecision;
subjfloat_setExtF80RoundingPrecision( roundingPrecision );
}
#endif
for (
roundingCode = 1; roundingCode < NUM_ROUNDINGMODES; ++roundingCode
) {
#ifndef SUBJFLOAT_ROUND_NEAR_MAXMAG
if ( roundingCode != ROUND_NEAR_MAXMAG ) {
#endif
#if defined FLOAT_ROUND_ODD && ! defined SUBJFLOAT_ROUND_NEAR_MAXMAG
if ( roundingCode != ROUND_ODD ) {
#endif
if (
functionAttribs
& (FUNC_ARG_ROUNDINGMODE | FUNC_EFF_ROUNDINGMODE)
) {
if ( roundingCodeIn ) roundingCode = roundingCodeIn;
} else {
roundingCode = 0;
}
verCases_roundingCode =
standardFunctionHasFixedRounding ? 0 : roundingCode;
if ( roundingCode ) {
roundingMode = roundingModes[roundingCode];
softfloat_roundingMode = roundingMode;
if ( ! standardFunctionHasFixedRounding ) {
subjfloat_setRoundingMode( roundingMode );
}
}
testFunctionInstance( functionCode, roundingMode, exact );
if ( roundingCodeIn || ! roundingCode ) break;
#if defined FLOAT_ROUND_ODD && ! defined SUBJFLOAT_ROUND_NEAR_MAXMAG
}
#endif
#ifndef SUBJFLOAT_ROUND_NEAR_MAXMAG
}
#endif
}
if ( roundingPrecisionIn || ! roundingPrecision ) break;
if ( roundingPrecision == 80 ) {
break;
} else if ( roundingPrecision == 64 ) {
roundingPrecision = 80;
} else if ( roundingPrecision == 32 ) {
roundingPrecision = 64;
}
}
}
int main( int argc, char *argv[] )
{
bool haveFunctionArg;
const struct standardFunctionInfo *standardFunctionInfoPtr;
int numOperands;
uint_fast8_t roundingPrecision;
int roundingCode;
const char *argPtr;
void (*const *subjFunctionPtrPtr)();
const char *functionNamePtr;
unsigned long ui;
long i;
/*------------------------------------------------------------------------
*------------------------------------------------------------------------*/
fail_programName = "testfloat";
if ( argc <= 1 ) goto writeHelpMessage;
genCases_setLevel( 1 );
verCases_maxErrorCount = 20;
testLoops_trueFlagsPtr = &softfloat_exceptionFlags;
testLoops_subjFlagsFunction = subjfloat_clearExceptionFlags;
haveFunctionArg = false;
standardFunctionInfoPtr = 0;
numOperands = 0;
roundingPrecision = 0;
roundingCode = 0;
for (;;) {
--argc;
if ( ! argc ) break;
argPtr = *++argv;
if ( ! argPtr ) break;
if ( argPtr[0] == '-' ) ++argPtr;
if (
! strcmp( argPtr, "help" ) || ! strcmp( argPtr, "-help" )
|| ! strcmp( argPtr, "h" )
) {
writeHelpMessage:
fputs(
"testfloat [<option>...] <function>\n"
" <option>: (* is default)\n"
" -help --Write this message and exit.\n"
" -list --List all testable subject functions and exit.\n"
" -seed <num> --Set pseudo-random number generator seed to <num>.\n"
" * -seed 1\n"
" -level <num> --Testing level <num> (1 or 2).\n"
" * -level 1\n"
" -errors <num> --Stop each function test after <num> errors.\n"
" * -errors 20\n"
" -errorstop --Exit after first function with any error.\n"
" -forever --Test one function repeatedly (implies '-level 2').\n"
" -checkNaNs --Check for bitwise correctness of NaN results.\n"
#ifdef EXTFLOAT80
" -precision32 --For extF80, test only 32-bit rounding precision.\n"
" -precision64 --For extF80, test only 64-bit rounding precision.\n"
" -precision80 --For extF80, test only 80-bit rounding precision.\n"
#endif
" -r<round> --Test only specified rounding (if not inherent to\n"
" function).\n"
" -tininessbefore --Underflow tininess is detected before rounding.\n"
" -tininessafter --Underflow tininess is detected after rounding.\n"
" <function>:\n"
" <int>_to_<float> <float>_add <float>_eq\n"
" <float>_to_<int>_r_<round> <float>_sub <float>_le\n"
" <float>_to_<int>_rx_<round> <float>_mul <float>_lt\n"
" <float>_to_<float> <float>_mulAdd <float>_eq_signaling\n"
" <float>_roundToInt_r_<round> <float>_div <float>_le_quiet\n"
" <float>_roundToInt_x <float>_rem <float>_lt_quiet\n"
" <float>_sqrt\n"
" -all1 --All unary functions.\n"
" -all2 --All binary functions.\n"
" <int>:\n"
" ui32 --Unsigned 32-bit integer.\n"
" ui64 --Unsigned 64-bit integer.\n"
" i32 --Signed 32-bit integer.\n"
" i64 --Signed 64-bit integer.\n"
" <float>:\n"
#ifdef FLOAT16
" f16 --Binary 16-bit floating-point (half-precision).\n"
#endif
" f32 --Binary 32-bit floating-point (single-precision).\n"
#ifdef FLOAT64
" f64 --Binary 64-bit floating-point (double-precision).\n"
#endif
#ifdef EXTFLOAT80
" extF80 --Binary 80-bit extended floating-point.\n"
#endif
#ifdef FLOAT128
" f128 --Binary 128-bit floating-point (quadruple-precision).\n"
#endif
" <round>:\n"
" near_even --Round to nearest/even.\n"
" minMag --Round to minimum magnitude (toward zero).\n"
" min --Round to minimum (down).\n"
" max --Round to maximum (up).\n"
#ifdef SUBJFLOAT_ROUND_NEAR_MAXMAG
" near_maxMag --Round to nearest/maximum magnitude (nearest/away).\n"
#endif
#if defined FLOAT_ROUND_ODD && defined SUBJFLOAT_ROUND_ODD
" odd --Round to odd (jamming). (Not allowed as an inherent\n"
" rounding mode. For 'roundToInt_x', rounds to minimum\n"
" magnitude instead.)\n"
#endif
,
stdout
);
return EXIT_SUCCESS;
} else if ( ! strcmp( argPtr, "list" ) ) {
standardFunctionInfoPtr = standardFunctionInfos;
subjFunctionPtrPtr = subjfloat_functions;
for (;;) {
functionNamePtr = standardFunctionInfoPtr->namePtr;
if ( ! functionNamePtr ) break;
if ( *subjFunctionPtrPtr ) puts( functionNamePtr );
++standardFunctionInfoPtr;
++subjFunctionPtrPtr;
}
return EXIT_SUCCESS;
} else if ( ! strcmp( argPtr, "seed" ) ) {
if ( argc < 2 ) goto optionError;
ui = strtoul( argv[1], (char **) &argPtr, 10 );
if ( *argPtr ) goto optionError;
srand( ui );
--argc;
++argv;
} else if ( ! strcmp( argPtr, "level" ) ) {
if ( argc < 2 ) goto optionError;
i = strtol( argv[1], (char **) &argPtr, 10 );
if ( *argPtr ) goto optionError;
genCases_setLevel( i );
--argc;
++argv;
} else if ( ! strcmp( argPtr, "level1" ) ) {
genCases_setLevel( 1 );
} else if ( ! strcmp( argPtr, "level2" ) ) {
genCases_setLevel( 2 );
} else if ( ! strcmp( argPtr, "errors" ) ) {
if ( argc < 2 ) goto optionError;
i = strtol( argv[1], (char **) &argPtr, 10 );
if ( *argPtr ) goto optionError;
verCases_maxErrorCount = i;
--argc;
++argv;
} else if ( ! strcmp( argPtr, "errorstop" ) ) {
verCases_errorStop = true;
} else if ( ! strcmp( argPtr, "forever" ) ) {
genCases_setLevel( 2 );
testLoops_forever = true;
} else if (
! strcmp( argPtr, "checkNaNs" ) || ! strcmp( argPtr, "checknans" )
) {
verCases_checkNaNs = true;
#ifdef EXTFLOAT80
} else if ( ! strcmp( argPtr, "precision32" ) ) {
roundingPrecision = 32;
} else if ( ! strcmp( argPtr, "precision64" ) ) {
roundingPrecision = 64;
} else if ( ! strcmp( argPtr, "precision80" ) ) {
roundingPrecision = 80;
#endif
} else if (
! strcmp( argPtr, "rnear_even" )
|| ! strcmp( argPtr, "rneareven" )
|| ! strcmp( argPtr, "rnearest_even" )
) {
roundingCode = ROUND_NEAR_EVEN;
} else if (
! strcmp( argPtr, "rminmag" ) || ! strcmp( argPtr, "rminMag" )
) {
roundingCode = ROUND_MINMAG;
} else if ( ! strcmp( argPtr, "rmin" ) ) {
roundingCode = ROUND_MIN;
} else if ( ! strcmp( argPtr, "rmax" ) ) {
roundingCode = ROUND_MAX;
} else if (
! strcmp( argPtr, "rnear_maxmag" )
|| ! strcmp( argPtr, "rnear_maxMag" )
|| ! strcmp( argPtr, "rnearmaxmag" )
|| ! strcmp( argPtr, "rnearest_maxmag" )
|| ! strcmp( argPtr, "rnearest_maxMag" )
) {
#ifdef SUBJFLOAT_ROUND_NEAR_MAXMAG
roundingCode = ROUND_NEAR_MAXMAG;
#else
fail(
"Rounding mode 'near_maxMag' is not supported or cannot be tested"
);
#endif
#ifdef FLOAT_ROUND_ODD
} else if ( ! strcmp( argPtr, "rodd" ) ) {
#ifdef SUBJFLOAT_ROUND_ODD
roundingCode = ROUND_ODD;
#else
fail( "Rounding mode 'odd' is not supported or cannot be tested" );
#endif
#endif
} else if ( ! strcmp( argPtr, "tininessbefore" ) ) {
softfloat_detectTininess = softfloat_tininess_beforeRounding;
} else if ( ! strcmp( argPtr, "tininessafter" ) ) {
softfloat_detectTininess = softfloat_tininess_afterRounding;
} else if ( ! strcmp( argPtr, "all1" ) ) {
haveFunctionArg = true;
standardFunctionInfoPtr = 0;
numOperands = 1;
} else if ( ! strcmp( argPtr, "all2" ) ) {
haveFunctionArg = true;
standardFunctionInfoPtr = 0;
numOperands = 2;
} else {
standardFunctionInfoPtr = standardFunctionInfos;
for (;;) {
functionNamePtr = standardFunctionInfoPtr->namePtr;
if ( ! functionNamePtr ) {
fail( "Invalid argument '%s'", *argv );
}
if ( ! strcmp( argPtr, functionNamePtr ) ) break;
++standardFunctionInfoPtr;
}
subjFunctionPtr =
subjfloat_functions
[standardFunctionInfoPtr - standardFunctionInfos];
if ( ! subjFunctionPtr ) {
fail(
"Function '%s' is not supported or cannot be tested",
argPtr
);
}
haveFunctionArg = true;
}
}
if ( ! haveFunctionArg ) fail( "Function argument required" );
/*------------------------------------------------------------------------
*------------------------------------------------------------------------*/
signal( SIGINT, catchSIGINT );
signal( SIGTERM, catchSIGINT );
if ( standardFunctionInfoPtr ) {
if ( testLoops_forever ) {
if ( ! roundingPrecision ) roundingPrecision = 80;
if ( ! roundingCode ) roundingCode = ROUND_NEAR_EVEN;
}
testFunction(
standardFunctionInfoPtr, roundingPrecision, roundingCode );
} else {
if ( testLoops_forever ) {
fail( "Can test only one function with '-forever' option" );
}
if ( numOperands == 1 ) {
standardFunctionInfoPtr = standardFunctionInfos;
subjFunctionPtrPtr = subjfloat_functions;
while ( standardFunctionInfoPtr->namePtr ) {
subjFunctionPtr = *subjFunctionPtrPtr;
if (
subjFunctionPtr
&& ! (functionInfos
[standardFunctionInfoPtr->functionCode]
.attribs
& FUNC_ARG_BINARY)
) {
testFunction(
standardFunctionInfoPtr,
roundingPrecision,
roundingCode
);
}
++standardFunctionInfoPtr;
++subjFunctionPtrPtr;
}
} else {
standardFunctionInfoPtr = standardFunctionInfos;
subjFunctionPtrPtr = subjfloat_functions;
while ( standardFunctionInfoPtr->namePtr ) {
subjFunctionPtr = *subjFunctionPtrPtr;
if (
subjFunctionPtr
&& (functionInfos
[standardFunctionInfoPtr->functionCode]
.attribs
& FUNC_ARG_BINARY)
) {
testFunction(
standardFunctionInfoPtr,
roundingPrecision,
roundingCode
);
}
++standardFunctionInfoPtr;
++subjFunctionPtrPtr;
}
}
}
verCases_exitWithStatus();
/*------------------------------------------------------------------------
*------------------------------------------------------------------------*/
optionError:
fail( "'%s' option requires numeric argument", *argv );
}