glibc/math/gen-auto-libm-tests.c
Joseph Myers aa97dee16e Adjust how gen-auto-libm-tests handles before-rounding/after-rounding cases.
This patch changes gen-auto-libm-tests so that, when generating test
results that depend on whether the architecture has before-rounding or
after-rounding tininess detection, the :before-rounding or
:after-rounding conditions go on the exception / errno flags
generated, rather than generating two separate lines in
auto-libm-test-out for e.g. flt-32:before-rounding and
flt-32:after-rounding.

The rationale for this is as follows.  It would be desirable for
testing a libm function in all rounding modes to require just one
function and array in libm-test.inc, not four (or five), with the
array of test data including expected results for all rounding modes
rather than separate arrays for each rounding mode that also need to
repeat all the test inputs.  For gen-libm-test.pl to generate data for
such an array from auto-libm-test-out, it would be helpful if each
(format, test input) pair has exactly four lines in
auto-libm-test-out, one for each rounding mode, rather than some
rounding modes having just one line and some having two because the
exceptions depend on tininess detection.

Tested x86_64 and x86.

	* math/gen-auto-libm-tests.c: Update comment on output format.
	(output_for_one_input_case): Generate before-rounding and
	after-rounding information as conditions on output flags not
	floating-point format.
	* math/auto-libm-test-out: Regenerated.
	* math/gen-libm-test.pl (cond_value): New function.
	(or_cond_value): Use cond_value.
	(generate_testfile): Handle conditional exceptions.
2014-03-06 14:11:19 +00:00

2175 lines
67 KiB
C

/* Generate expected output for libm tests with MPFR and MPC.
Copyright (C) 2013-2014 Free Software Foundation, Inc.
This file is part of the GNU C Library.
The GNU C Library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
The GNU C Library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with the GNU C Library; if not, see
<http://www.gnu.org/licenses/>. */
/* Compile this program as:
gcc -std=gnu99 -O2 -Wall -Wextra gen-auto-libm-tests.c -lmpc -lmpfr -lgmp \
-o gen-auto-libm-tests
(use of current MPC and MPFR versions recommended) and run it as:
gen-auto-libm-tests auto-libm-test-in auto-libm-test-out
The input file auto-libm-test-in contains three kinds of lines:
Lines beginning with "#" are comments, and are ignored, as are
empty lines.
Other lines are test lines, of the form "function input1 input2
... [flag1 flag2 ...]". Inputs are either finite real numbers or
integers, depending on the function under test. Real numbers may
be in any form acceptable to mpfr_strtofr (base 0); integers in any
form acceptable to mpz_set_str (base 0). In addition, real numbers
may be certain special strings such as "pi", as listed in the
special_real_inputs array.
Each flag is a flag name possibly followed by a series of
":condition". Conditions may be any of the names of floating-point
formats in the floating_point_formats array, "long32" and "long64"
to indicate the number of bits in the "long" type, or other strings
for which libm-test.inc defines a TEST_COND_<condition> macro (with
"-"- changed to "_" in the condition name) evaluating to nonzero
when the condition is true and zero when the condition is false.
The meaning is that the flag applies to the test if all the listed
conditions are true. "flag:cond1:cond2 flag:cond3:cond4" means the
flag applies if ((cond1 && cond2) || (cond3 && cond4)).
A real number specified as an input is considered to represent the
set of real numbers arising from rounding the given number in any
direction for any supported floating-point format; any roundings
that give infinity are ignored. Each input on a test line has all
the possible roundings considered independently. Each resulting
choice of the tuple of inputs to the function is ignored if the
mathematical result of the function involves a NaN or an exact
infinity, and is otherwise considered for each floating-point
format for which all those inputs are exactly representable. Thus
tests may result in "overflow", "underflow" and "inexact"
exceptions; "invalid" may arise only when the final result type is
an integer type and it is the conversion of a mathematically
defined finite result to integer type that results in that
exception.
By default, it is assumed that "overflow" and "underflow"
exceptions should be correct, but that "inexact" exceptions should
only be correct for functions listed as exactly determined. For
such functions, "underflow" exceptions should respect whether the
machine has before-rounding or after-rounding tininess detection.
For other functions, it is considered that if the exact result is
somewhere between the greatest magnitude subnormal of a given sign
(exclusive) and the least magnitude normal of that sign
(inclusive), underflow exceptions are permitted but optional on all
machines, and they are also permitted but optional for smaller
subnormal exact results for functions that are not exactly
determined. errno setting is expected for overflow to infinity and
underflow to zero (for real functions), and for out-of-range
conversion of a finite result to integer type, and is considered
permitted but optional for all other cases where overflow
exceptions occur, and where underflow exceptions occur or are
permitted. In other cases (where no overflow or underflow is
permitted), errno is expected to be left unchanged.
The flag "no-test-inline" indicates a test is disabled for inline
function testing; "xfail" indicates the test is disabled as
expected to produce incorrect results, "xfail-rounding" indicates
the test is disabled only in rounding modes other than
round-to-nearest. Otherwise, test flags are of the form
"spurious-<exception>" and "missing-<exception>", for any exception
("overflow", "underflow", "inexact", "invalid", "divbyzero"),
"spurious-errno" and "missing-errno", to indicate when tests are
expected to deviate from the exception and errno settings
corresponding to the mathematical results. "xfail",
"xfail-rounding", "spurious-" and "missing-" flags should be
accompanied by a comment referring to an open bug in glibc
Bugzilla.
The output file auto-libm-test-out contains the test lines from
auto-libm-test-in, and, after the line for a given test, some
number of output test lines. An output test line is of the form "=
function rounding-mode format input1 input2 ... : output1 output2
... : flags". rounding-mode is "tonearest", "towardzero", "upward"
or "downward". format is a name from the floating_point_formats
array, possibly followed by a sequence of ":flag" for flags from
"long32" and "long64". Inputs and outputs are specified as hex
floats with the required suffix for the floating-point type, or
plus_infty or minus_infty for infinite expected results, or as
integer constant expressions (not necessarily with the right type)
or IGNORE for integer inputs and outputs. Flags are
"no-test-inline", "xfail", "<exception>", "<exception>-ok",
"errno-<value>", "errno-<value>-ok", which may be unconditional or
conditional. "<exception>" indicates that a correct result means
the given exception should be raised. "errno-<value>" indicates
that a correct result means errno should be set to the given value.
"-ok" means not to test for the given exception or errno value
(whether because it was marked as possibly missing or spurious, or
because the calculation of correct results indicated it was
optional). Conditions "before-rounding" and "after-rounding"
indicate tests where expectations for underflow exceptions depend
on how the architecture detects tininess. */
#define _GNU_SOURCE
#include <assert.h>
#include <ctype.h>
#include <errno.h>
#include <error.h>
#include <stdbool.h>
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <gmp.h>
#include <mpfr.h>
#include <mpc.h>
#define ARRAY_SIZE(A) (sizeof (A) / sizeof ((A)[0]))
/* The supported floating-point formats. */
typedef enum
{
fp_flt_32,
fp_dbl_64,
fp_ldbl_96_intel,
fp_ldbl_96_m68k,
fp_ldbl_128,
fp_ldbl_128ibm,
fp_num_formats,
fp_first_format = 0
} fp_format;
/* Structure describing a single floating-point format. */
typedef struct
{
/* The name of the format. */
const char *name;
/* The suffix to use on floating-point constants with this
format. */
const char *suffix;
/* A string for the largest normal value, or NULL for IEEE formats
where this can be determined automatically. */
const char *max_string;
/* The number of mantissa bits. */
int mant_dig;
/* The least N such that 2^N overflows. */
int max_exp;
/* One more than the least N such that 2^N is normal. */
int min_exp;
/* The largest normal value. */
mpfr_t max;
/* The least positive normal value, 2^(MIN_EXP-1). */
mpfr_t min;
/* The greatest positive subnormal value. */
mpfr_t subnorm_max;
/* The least positive subnormal value, 2^(MIN_EXP-MANT_DIG). */
mpfr_t subnorm_min;
} fp_format_desc;
/* List of floating-point formats, in the same order as the fp_format
enumeration. */
static fp_format_desc fp_formats[fp_num_formats] =
{
{ "flt-32", "f", NULL, 24, 128, -125, {}, {}, {}, {} },
{ "dbl-64", "", NULL, 53, 1024, -1021, {}, {}, {}, {} },
{ "ldbl-96-intel", "L", NULL, 64, 16384, -16381, {}, {}, {}, {} },
{ "ldbl-96-m68k", "L", NULL, 64, 16384, -16382, {}, {}, {}, {} },
{ "ldbl-128", "L", NULL, 113, 16384, -16381, {}, {}, {}, {} },
{ "ldbl-128ibm", "L", "0x1.fffffffffffff7ffffffffffff8p+1023",
106, 1024, -968, {}, {}, {}, {} },
};
/* The supported rounding modes. */
typedef enum
{
rm_downward,
rm_tonearest,
rm_towardzero,
rm_upward,
rm_num_modes,
rm_first_mode = 0
} rounding_mode;
/* Structure describing a single rounding mode. */
typedef struct
{
/* The name of the rounding mode. */
const char *name;
/* The MPFR rounding mode. */
mpfr_rnd_t mpfr_mode;
/* The MPC rounding mode. */
mpc_rnd_t mpc_mode;
} rounding_mode_desc;
/* List of rounding modes, in the same order as the rounding_mode
enumeration. */
static const rounding_mode_desc rounding_modes[rm_num_modes] =
{
{ "downward", MPFR_RNDD, MPC_RNDDD },
{ "tonearest", MPFR_RNDN, MPC_RNDNN },
{ "towardzero", MPFR_RNDZ, MPC_RNDZZ },
{ "upward", MPFR_RNDU, MPC_RNDUU },
};
/* The supported exceptions. */
typedef enum
{
exc_divbyzero,
exc_inexact,
exc_invalid,
exc_overflow,
exc_underflow,
exc_num_exceptions,
exc_first_exception = 0
} fp_exception;
/* List of exceptions, in the same order as the fp_exception
enumeration. */
static const char *const exceptions[exc_num_exceptions] =
{
"divbyzero",
"inexact",
"invalid",
"overflow",
"underflow",
};
/* The internal precision to use for most MPFR calculations, which
must be at least 2 more than the greatest precision of any
supported floating-point format. */
static int internal_precision;
/* A value that overflows all supported floating-point formats. */
static mpfr_t global_max;
/* A value that is at most half the least subnormal in any
floating-point format and so is rounded the same way as all
sufficiently small positive values. */
static mpfr_t global_min;
/* The maximum number of (real or integer) arguments to a function
handled by this program (complex arguments count as two real
arguments). */
#define MAX_NARGS 4
/* The maximum number of (real or integer) return values from a
function handled by this program. */
#define MAX_NRET 2
/* A type of a function argument or return value. */
typedef enum
{
/* No type (not a valid argument or return value). */
type_none,
/* A floating-point value with the type corresponding to that of
the function. */
type_fp,
/* An integer value of type int. */
type_int,
/* An integer value of type long. */
type_long,
/* An integer value of type long long. */
type_long_long,
} arg_ret_type;
/* A type of a generic real or integer value. */
typedef enum
{
/* No type. */
gtype_none,
/* Floating-point (represented with MPFR). */
gtype_fp,
/* Integer (represented with GMP). */
gtype_int,
} generic_value_type;
/* A generic value (argument or result). */
typedef struct
{
/* The type of this value. */
generic_value_type type;
/* Its value. */
union
{
mpfr_t f;
mpz_t i;
} value;
} generic_value;
/* A type of input flag. */
typedef enum
{
flag_no_test_inline,
flag_xfail,
flag_xfail_rounding,
/* The "spurious" and "missing" flags must be in the same order as
the fp_exception enumeration. */
flag_spurious_divbyzero,
flag_spurious_inexact,
flag_spurious_invalid,
flag_spurious_overflow,
flag_spurious_underflow,
flag_spurious_errno,
flag_missing_divbyzero,
flag_missing_inexact,
flag_missing_invalid,
flag_missing_overflow,
flag_missing_underflow,
flag_missing_errno,
num_input_flag_types,
flag_first_flag = 0,
flag_spurious_first = flag_spurious_divbyzero,
flag_missing_first = flag_missing_divbyzero
} input_flag_type;
/* List of flags, in the same order as the input_flag_type
enumeration. */
static const char *const input_flags[num_input_flag_types] =
{
"no-test-inline",
"xfail",
"xfail-rounding",
"spurious-divbyzero",
"spurious-inexact",
"spurious-invalid",
"spurious-overflow",
"spurious-underflow",
"spurious-errno",
"missing-divbyzero",
"missing-inexact",
"missing-invalid",
"missing-overflow",
"missing-underflow",
"missing-errno",
};
/* An input flag, possibly conditional. */
typedef struct
{
/* The type of this flag. */
input_flag_type type;
/* The conditions on this flag, as a string ":cond1:cond2..." or
NULL. */
const char *cond;
} input_flag;
/* Structure describing a single test from the input file (which may
expand into many tests in the output). The choice of function,
which implies the numbers and types of arguments and results, is
implicit rather than stored in this structure (except as part of
the source line). */
typedef struct
{
/* The text of the input line describing the test, including the
trailing newline. */
const char *line;
/* The number of combinations of interpretations of input values for
different floating-point formats and rounding modes. */
size_t num_input_cases;
/* The corresponding lists of inputs. */
generic_value **inputs;
/* The number of flags for this test. */
size_t num_flags;
/* The corresponding list of flags. */
input_flag *flags;
/* The old output for this test. */
const char *old_output;
} input_test;
/* Ways to calculate a function. */
typedef enum
{
/* MPFR function with a single argument and result. */
mpfr_f_f,
/* MPFR function with two arguments and one result. */
mpfr_ff_f,
/* MPFR function with three arguments and one result. */
mpfr_fff_f,
/* MPFR function with a single argument and floating-point and
integer results. */
mpfr_f_f1,
/* MPFR function with integer and floating-point arguments and one
result. */
mpfr_if_f,
/* MPFR function with a single argument and two floating-point
results. */
mpfr_f_11,
/* MPC function with a single complex argument and one real
result. */
mpc_c_f,
/* MPC function with a single complex argument and one complex
result. */
mpc_c_c,
/* MPC function with two complex arguments and one complex
result. */
mpc_cc_c,
} func_calc_method;
/* Description of how to calculate a function. */
typedef struct
{
/* Which method is used to calculate the function. */
func_calc_method method;
/* The specific function called. */
union
{
int (*mpfr_f_f) (mpfr_t, const mpfr_t, mpfr_rnd_t);
int (*mpfr_ff_f) (mpfr_t, const mpfr_t, const mpfr_t, mpfr_rnd_t);
int (*mpfr_fff_f) (mpfr_t, const mpfr_t, const mpfr_t, const mpfr_t,
mpfr_rnd_t);
int (*mpfr_f_f1) (mpfr_t, int *, const mpfr_t, mpfr_rnd_t);
int (*mpfr_if_f) (mpfr_t, long, const mpfr_t, mpfr_rnd_t);
int (*mpfr_f_11) (mpfr_t, mpfr_t, const mpfr_t, mpfr_rnd_t);
int (*mpc_c_f) (mpfr_t, const mpc_t, mpfr_rnd_t);
int (*mpc_c_c) (mpc_t, const mpc_t, mpc_rnd_t);
int (*mpc_cc_c) (mpc_t, const mpc_t, const mpc_t, mpc_rnd_t);
} func;
} func_calc_desc;
/* Structure describing a function handled by this program. */
typedef struct
{
/* The name of the function. */
const char *name;
/* The number of arguments. */
size_t num_args;
/* The types of the arguments. */
arg_ret_type arg_types[MAX_NARGS];
/* The number of return values. */
size_t num_ret;
/* The types of the return values. */
arg_ret_type ret_types[MAX_NRET];
/* Whether the function has exactly determined results and
exceptions. */
bool exact;
/* Whether the function is a complex function, so errno setting is
optional. */
bool complex_fn;
/* Whether to treat arguments given as floating-point constants as
exact only, rather than rounding them up and down to all
formats. */
bool exact_args;
/* How to calculate this function. */
func_calc_desc calc;
/* The number of tests allocated for this function. */
size_t num_tests_alloc;
/* The number of tests for this function. */
size_t num_tests;
/* The tests themselves. */
input_test *tests;
} test_function;
#define ARGS1(T1) 1, { T1 }
#define ARGS2(T1, T2) 2, { T1, T2 }
#define ARGS3(T1, T2, T3) 3, { T1, T2, T3 }
#define ARGS4(T1, T2, T3, T4) 4, { T1, T2, T3, T4 }
#define RET1(T1) 1, { T1 }
#define RET2(T1, T2) 2, { T1, T2 }
#define CALC(TYPE, FN) { TYPE, { .TYPE = FN } }
#define FUNC(NAME, ARGS, RET, EXACT, COMPLEX_FN, EXACT_ARGS, CALC) \
{ \
NAME, ARGS, RET, EXACT, COMPLEX_FN, EXACT_ARGS, CALC, 0, 0, NULL \
}
#define FUNC_mpfr_f_f(NAME, MPFR_FUNC, EXACT) \
FUNC (NAME, ARGS1 (type_fp), RET1 (type_fp), EXACT, false, false, \
CALC (mpfr_f_f, MPFR_FUNC))
#define FUNC_mpfr_ff_f(NAME, MPFR_FUNC, EXACT) \
FUNC (NAME, ARGS2 (type_fp, type_fp), RET1 (type_fp), EXACT, false, \
false, CALC (mpfr_ff_f, MPFR_FUNC))
#define FUNC_mpfr_if_f(NAME, MPFR_FUNC, EXACT) \
FUNC (NAME, ARGS2 (type_int, type_fp), RET1 (type_fp), EXACT, false, \
false, CALC (mpfr_if_f, MPFR_FUNC))
#define FUNC_mpc_c_f(NAME, MPFR_FUNC, EXACT) \
FUNC (NAME, ARGS2 (type_fp, type_fp), RET1 (type_fp), EXACT, true, \
false, CALC (mpc_c_f, MPFR_FUNC))
#define FUNC_mpc_c_c(NAME, MPFR_FUNC, EXACT) \
FUNC (NAME, ARGS2 (type_fp, type_fp), RET2 (type_fp, type_fp), EXACT, \
true, false, CALC (mpc_c_c, MPFR_FUNC))
/* List of functions handled by this program. */
static test_function test_functions[] =
{
FUNC_mpfr_f_f ("acos", mpfr_acos, false),
FUNC_mpfr_f_f ("acosh", mpfr_acosh, false),
FUNC_mpfr_f_f ("asin", mpfr_asin, false),
FUNC_mpfr_f_f ("asinh", mpfr_asinh, false),
FUNC_mpfr_f_f ("atan", mpfr_atan, false),
FUNC_mpfr_ff_f ("atan2", mpfr_atan2, false),
FUNC_mpfr_f_f ("atanh", mpfr_atanh, false),
FUNC_mpc_c_f ("cabs", mpc_abs, false),
FUNC_mpc_c_c ("cacos", mpc_acos, false),
FUNC_mpc_c_c ("cacosh", mpc_acosh, false),
FUNC_mpc_c_f ("carg", mpc_arg, false),
FUNC_mpc_c_c ("casin", mpc_asin, false),
FUNC_mpc_c_c ("casinh", mpc_asinh, false),
FUNC_mpc_c_c ("catan", mpc_atan, false),
FUNC_mpc_c_c ("catanh", mpc_atanh, false),
FUNC_mpfr_f_f ("cbrt", mpfr_cbrt, false),
FUNC_mpc_c_c ("ccos", mpc_cos, false),
FUNC_mpc_c_c ("ccosh", mpc_cosh, false),
FUNC_mpc_c_c ("cexp", mpc_exp, false),
FUNC_mpc_c_c ("clog", mpc_log, false),
FUNC_mpc_c_c ("clog10", mpc_log10, false),
FUNC_mpfr_f_f ("cos", mpfr_cos, false),
FUNC_mpfr_f_f ("cosh", mpfr_cosh, false),
FUNC ("cpow", ARGS4 (type_fp, type_fp, type_fp, type_fp),
RET2 (type_fp, type_fp), false, true, false,
CALC (mpc_cc_c, mpc_pow)),
FUNC_mpc_c_c ("csin", mpc_sin, false),
FUNC_mpc_c_c ("csinh", mpc_sinh, false),
FUNC_mpc_c_c ("csqrt", mpc_sqrt, false),
FUNC_mpc_c_c ("ctan", mpc_tan, false),
FUNC_mpc_c_c ("ctanh", mpc_tanh, false),
FUNC_mpfr_f_f ("erf", mpfr_erf, false),
FUNC_mpfr_f_f ("erfc", mpfr_erfc, false),
FUNC_mpfr_f_f ("exp", mpfr_exp, false),
FUNC_mpfr_f_f ("exp10", mpfr_exp10, false),
FUNC_mpfr_f_f ("exp2", mpfr_exp2, false),
FUNC_mpfr_f_f ("expm1", mpfr_expm1, false),
FUNC ("fma", ARGS3 (type_fp, type_fp, type_fp), RET1 (type_fp),
true, false, true, CALC (mpfr_fff_f, mpfr_fma)),
FUNC_mpfr_ff_f ("hypot", mpfr_hypot, false),
FUNC_mpfr_f_f ("j0", mpfr_j0, false),
FUNC_mpfr_f_f ("j1", mpfr_j1, false),
FUNC_mpfr_if_f ("jn", mpfr_jn, false),
FUNC ("lgamma", ARGS1 (type_fp), RET2 (type_fp, type_int), false, false,
false, CALC (mpfr_f_f1, mpfr_lgamma)),
FUNC_mpfr_f_f ("log", mpfr_log, false),
FUNC_mpfr_f_f ("log10", mpfr_log10, false),
FUNC_mpfr_f_f ("log1p", mpfr_log1p, false),
FUNC_mpfr_f_f ("log2", mpfr_log2, false),
FUNC_mpfr_ff_f ("pow", mpfr_pow, false),
FUNC_mpfr_f_f ("sin", mpfr_sin, false),
FUNC ("sincos", ARGS1 (type_fp), RET2 (type_fp, type_fp), false, false,
false, CALC (mpfr_f_11, mpfr_sin_cos)),
FUNC_mpfr_f_f ("sinh", mpfr_sinh, false),
FUNC_mpfr_f_f ("sqrt", mpfr_sqrt, true),
FUNC_mpfr_f_f ("tan", mpfr_tan, false),
FUNC_mpfr_f_f ("tanh", mpfr_tanh, false),
FUNC_mpfr_f_f ("tgamma", mpfr_gamma, false),
FUNC_mpfr_f_f ("y0", mpfr_y0, false),
FUNC_mpfr_f_f ("y1", mpfr_y1, false),
FUNC_mpfr_if_f ("yn", mpfr_yn, false),
};
/* Allocate memory, with error checking. */
static void *
xmalloc (size_t n)
{
void *p = malloc (n);
if (p == NULL)
error (EXIT_FAILURE, errno, "xmalloc failed");
return p;
}
static void *
xrealloc (void *p, size_t n)
{
p = realloc (p, n);
if (p == NULL)
error (EXIT_FAILURE, errno, "xrealloc failed");
return p;
}
static char *
xstrdup (const char *s)
{
char *p = strdup (s);
if (p == NULL)
error (EXIT_FAILURE, errno, "xstrdup failed");
return p;
}
/* Assert that the result of an MPFR operation was exact; that is,
that the returned ternary value was 0. */
static void
assert_exact (int i)
{
assert (i == 0);
}
/* Return the generic type of an argument or return value type T. */
static generic_value_type
generic_arg_ret_type (arg_ret_type t)
{
switch (t)
{
case type_fp:
return gtype_fp;
case type_int:
case type_long:
case type_long_long:
return gtype_int;
default:
abort ();
}
}
/* Free a generic_value *V. */
static void
generic_value_free (generic_value *v)
{
switch (v->type)
{
case gtype_fp:
mpfr_clear (v->value.f);
break;
case gtype_int:
mpz_clear (v->value.i);
break;
default:
abort ();
}
}
/* Copy a generic_value *SRC to *DEST. */
static void
generic_value_copy (generic_value *dest, const generic_value *src)
{
dest->type = src->type;
switch (src->type)
{
case gtype_fp:
mpfr_init (dest->value.f);
assert_exact (mpfr_set (dest->value.f, src->value.f, MPFR_RNDN));
break;
case gtype_int:
mpz_init (dest->value.i);
mpz_set (dest->value.i, src->value.i);
break;
default:
abort ();
}
}
/* Initialize data for floating-point formats. */
static void
init_fp_formats ()
{
int global_max_exp = 0, global_min_subnorm_exp = 0;
for (fp_format f = fp_first_format; f < fp_num_formats; f++)
{
if (fp_formats[f].mant_dig + 2 > internal_precision)
internal_precision = fp_formats[f].mant_dig + 2;
if (fp_formats[f].max_exp > global_max_exp)
global_max_exp = fp_formats[f].max_exp;
int min_subnorm_exp = fp_formats[f].min_exp - fp_formats[f].mant_dig;
if (min_subnorm_exp < global_min_subnorm_exp)
global_min_subnorm_exp = min_subnorm_exp;
mpfr_init2 (fp_formats[f].max, fp_formats[f].mant_dig);
if (fp_formats[f].max_string != NULL)
{
char *ep = NULL;
assert_exact (mpfr_strtofr (fp_formats[f].max,
fp_formats[f].max_string,
&ep, 0, MPFR_RNDN));
assert (*ep == 0);
}
else
{
assert_exact (mpfr_set_ui_2exp (fp_formats[f].max, 1,
fp_formats[f].max_exp,
MPFR_RNDN));
mpfr_nextbelow (fp_formats[f].max);
}
mpfr_init2 (fp_formats[f].min, fp_formats[f].mant_dig);
assert_exact (mpfr_set_ui_2exp (fp_formats[f].min, 1,
fp_formats[f].min_exp - 1,
MPFR_RNDN));
mpfr_init2 (fp_formats[f].subnorm_max, fp_formats[f].mant_dig);
assert_exact (mpfr_set (fp_formats[f].subnorm_max, fp_formats[f].min,
MPFR_RNDN));
mpfr_nextbelow (fp_formats[f].subnorm_max);
mpfr_nextbelow (fp_formats[f].subnorm_max);
mpfr_init2 (fp_formats[f].subnorm_min, fp_formats[f].mant_dig);
assert_exact (mpfr_set_ui_2exp (fp_formats[f].subnorm_min, 1,
min_subnorm_exp, MPFR_RNDN));
}
mpfr_set_default_prec (internal_precision);
mpfr_init (global_max);
assert_exact (mpfr_set_ui_2exp (global_max, 1, global_max_exp, MPFR_RNDN));
mpfr_init (global_min);
assert_exact (mpfr_set_ui_2exp (global_min, 1, global_min_subnorm_exp - 1,
MPFR_RNDN));
}
/* Fill in mpfr_t values for special strings in input arguments. */
static size_t
special_fill_max (mpfr_t res0, mpfr_t res1 __attribute__ ((unused)),
fp_format format)
{
mpfr_init2 (res0, fp_formats[format].mant_dig);
assert_exact (mpfr_set (res0, fp_formats[format].max, MPFR_RNDN));
return 1;
}
static size_t
special_fill_minus_max (mpfr_t res0, mpfr_t res1 __attribute__ ((unused)),
fp_format format)
{
mpfr_init2 (res0, fp_formats[format].mant_dig);
assert_exact (mpfr_neg (res0, fp_formats[format].max, MPFR_RNDN));
return 1;
}
static size_t
special_fill_min (mpfr_t res0, mpfr_t res1 __attribute__ ((unused)),
fp_format format)
{
mpfr_init2 (res0, fp_formats[format].mant_dig);
assert_exact (mpfr_set (res0, fp_formats[format].min, MPFR_RNDN));
return 1;
}
static size_t
special_fill_minus_min (mpfr_t res0, mpfr_t res1 __attribute__ ((unused)),
fp_format format)
{
mpfr_init2 (res0, fp_formats[format].mant_dig);
assert_exact (mpfr_neg (res0, fp_formats[format].min, MPFR_RNDN));
return 1;
}
static size_t
special_fill_min_subnorm (mpfr_t res0, mpfr_t res1 __attribute__ ((unused)),
fp_format format)
{
mpfr_init2 (res0, fp_formats[format].mant_dig);
assert_exact (mpfr_set (res0, fp_formats[format].subnorm_min, MPFR_RNDN));
return 1;
}
static size_t
special_fill_minus_min_subnorm (mpfr_t res0,
mpfr_t res1 __attribute__ ((unused)),
fp_format format)
{
mpfr_init2 (res0, fp_formats[format].mant_dig);
assert_exact (mpfr_neg (res0, fp_formats[format].subnorm_min, MPFR_RNDN));
return 1;
}
static size_t
special_fill_min_subnorm_p120 (mpfr_t res0,
mpfr_t res1 __attribute__ ((unused)),
fp_format format)
{
mpfr_init2 (res0, fp_formats[format].mant_dig);
assert_exact (mpfr_mul_2ui (res0, fp_formats[format].subnorm_min,
120, MPFR_RNDN));
return 1;
}
static size_t
special_fill_pi (mpfr_t res0, mpfr_t res1, fp_format format)
{
mpfr_init2 (res0, fp_formats[format].mant_dig);
mpfr_const_pi (res0, MPFR_RNDU);
mpfr_init2 (res1, fp_formats[format].mant_dig);
mpfr_const_pi (res1, MPFR_RNDD);
return 2;
}
static size_t
special_fill_minus_pi (mpfr_t res0, mpfr_t res1, fp_format format)
{
mpfr_init2 (res0, fp_formats[format].mant_dig);
mpfr_const_pi (res0, MPFR_RNDU);
assert_exact (mpfr_neg (res0, res0, MPFR_RNDN));
mpfr_init2 (res1, fp_formats[format].mant_dig);
mpfr_const_pi (res1, MPFR_RNDD);
assert_exact (mpfr_neg (res1, res1, MPFR_RNDN));
return 2;
}
static size_t
special_fill_pi_2 (mpfr_t res0, mpfr_t res1, fp_format format)
{
mpfr_init2 (res0, fp_formats[format].mant_dig);
mpfr_const_pi (res0, MPFR_RNDU);
assert_exact (mpfr_div_ui (res0, res0, 2, MPFR_RNDN));
mpfr_init2 (res1, fp_formats[format].mant_dig);
mpfr_const_pi (res1, MPFR_RNDD);
assert_exact (mpfr_div_ui (res1, res1, 2, MPFR_RNDN));
return 2;
}
static size_t
special_fill_minus_pi_2 (mpfr_t res0, mpfr_t res1, fp_format format)
{
mpfr_init2 (res0, fp_formats[format].mant_dig);
mpfr_const_pi (res0, MPFR_RNDU);
assert_exact (mpfr_div_ui (res0, res0, 2, MPFR_RNDN));
assert_exact (mpfr_neg (res0, res0, MPFR_RNDN));
mpfr_init2 (res1, fp_formats[format].mant_dig);
mpfr_const_pi (res1, MPFR_RNDD);
assert_exact (mpfr_div_ui (res1, res1, 2, MPFR_RNDN));
assert_exact (mpfr_neg (res1, res1, MPFR_RNDN));
return 2;
}
static size_t
special_fill_pi_4 (mpfr_t res0, mpfr_t res1, fp_format format)
{
mpfr_init2 (res0, fp_formats[format].mant_dig);
assert_exact (mpfr_set_si (res0, 1, MPFR_RNDN));
mpfr_atan (res0, res0, MPFR_RNDU);
mpfr_init2 (res1, fp_formats[format].mant_dig);
assert_exact (mpfr_set_si (res1, 1, MPFR_RNDN));
mpfr_atan (res1, res1, MPFR_RNDD);
return 2;
}
static size_t
special_fill_pi_6 (mpfr_t res0, mpfr_t res1, fp_format format)
{
mpfr_init2 (res0, fp_formats[format].mant_dig);
assert_exact (mpfr_set_si_2exp (res0, 1, -1, MPFR_RNDN));
mpfr_asin (res0, res0, MPFR_RNDU);
mpfr_init2 (res1, fp_formats[format].mant_dig);
assert_exact (mpfr_set_si_2exp (res1, 1, -1, MPFR_RNDN));
mpfr_asin (res1, res1, MPFR_RNDD);
return 2;
}
static size_t
special_fill_minus_pi_6 (mpfr_t res0, mpfr_t res1, fp_format format)
{
mpfr_init2 (res0, fp_formats[format].mant_dig);
assert_exact (mpfr_set_si_2exp (res0, -1, -1, MPFR_RNDN));
mpfr_asin (res0, res0, MPFR_RNDU);
mpfr_init2 (res1, fp_formats[format].mant_dig);
assert_exact (mpfr_set_si_2exp (res1, -1, -1, MPFR_RNDN));
mpfr_asin (res1, res1, MPFR_RNDD);
return 2;
}
static size_t
special_fill_pi_3 (mpfr_t res0, mpfr_t res1, fp_format format)
{
mpfr_init2 (res0, fp_formats[format].mant_dig);
assert_exact (mpfr_set_si_2exp (res0, 1, -1, MPFR_RNDN));
mpfr_acos (res0, res0, MPFR_RNDU);
mpfr_init2 (res1, fp_formats[format].mant_dig);
assert_exact (mpfr_set_si_2exp (res1, 1, -1, MPFR_RNDN));
mpfr_acos (res1, res1, MPFR_RNDD);
return 2;
}
static size_t
special_fill_2pi_3 (mpfr_t res0, mpfr_t res1, fp_format format)
{
mpfr_init2 (res0, fp_formats[format].mant_dig);
assert_exact (mpfr_set_si_2exp (res0, -1, -1, MPFR_RNDN));
mpfr_acos (res0, res0, MPFR_RNDU);
mpfr_init2 (res1, fp_formats[format].mant_dig);
assert_exact (mpfr_set_si_2exp (res1, -1, -1, MPFR_RNDN));
mpfr_acos (res1, res1, MPFR_RNDD);
return 2;
}
static size_t
special_fill_2pi (mpfr_t res0, mpfr_t res1, fp_format format)
{
mpfr_init2 (res0, fp_formats[format].mant_dig);
mpfr_const_pi (res0, MPFR_RNDU);
assert_exact (mpfr_mul_ui (res0, res0, 2, MPFR_RNDN));
mpfr_init2 (res1, fp_formats[format].mant_dig);
mpfr_const_pi (res1, MPFR_RNDD);
assert_exact (mpfr_mul_ui (res1, res1, 2, MPFR_RNDN));
return 2;
}
static size_t
special_fill_e (mpfr_t res0, mpfr_t res1, fp_format format)
{
mpfr_init2 (res0, fp_formats[format].mant_dig);
assert_exact (mpfr_set_si (res0, 1, MPFR_RNDN));
mpfr_exp (res0, res0, MPFR_RNDU);
mpfr_init2 (res1, fp_formats[format].mant_dig);
assert_exact (mpfr_set_si (res1, 1, MPFR_RNDN));
mpfr_exp (res1, res1, MPFR_RNDD);
return 2;
}
static size_t
special_fill_1_e (mpfr_t res0, mpfr_t res1, fp_format format)
{
mpfr_init2 (res0, fp_formats[format].mant_dig);
assert_exact (mpfr_set_si (res0, -1, MPFR_RNDN));
mpfr_exp (res0, res0, MPFR_RNDU);
mpfr_init2 (res1, fp_formats[format].mant_dig);
assert_exact (mpfr_set_si (res1, -1, MPFR_RNDN));
mpfr_exp (res1, res1, MPFR_RNDD);
return 2;
}
static size_t
special_fill_e_minus_1 (mpfr_t res0, mpfr_t res1, fp_format format)
{
mpfr_init2 (res0, fp_formats[format].mant_dig);
assert_exact (mpfr_set_si (res0, 1, MPFR_RNDN));
mpfr_expm1 (res0, res0, MPFR_RNDU);
mpfr_init2 (res1, fp_formats[format].mant_dig);
assert_exact (mpfr_set_si (res1, 1, MPFR_RNDN));
mpfr_expm1 (res1, res1, MPFR_RNDD);
return 2;
}
/* A special string accepted in input arguments. */
typedef struct
{
/* The string. */
const char *str;
/* The function that interprets it for a given floating-point
format, filling in up to two mpfr_t values and returning the
number of values filled. */
size_t (*func) (mpfr_t, mpfr_t, fp_format);
} special_real_input;
/* List of special strings accepted in input arguments. */
static const special_real_input special_real_inputs[] =
{
{ "max", special_fill_max },
{ "-max", special_fill_minus_max },
{ "min", special_fill_min },
{ "-min", special_fill_minus_min },
{ "min_subnorm", special_fill_min_subnorm },
{ "-min_subnorm", special_fill_minus_min_subnorm },
{ "min_subnorm_p120", special_fill_min_subnorm_p120 },
{ "pi", special_fill_pi },
{ "-pi", special_fill_minus_pi },
{ "pi/2", special_fill_pi_2 },
{ "-pi/2", special_fill_minus_pi_2 },
{ "pi/4", special_fill_pi_4 },
{ "pi/6", special_fill_pi_6 },
{ "-pi/6", special_fill_minus_pi_6 },
{ "pi/3", special_fill_pi_3 },
{ "2pi/3", special_fill_2pi_3 },
{ "2pi", special_fill_2pi },
{ "e", special_fill_e },
{ "1/e", special_fill_1_e },
{ "e-1", special_fill_e_minus_1 },
};
/* Given a real number R computed in round-to-zero mode, set the
lowest bit as a sticky bit if INEXACT, and saturate the exponent
range for very large or small values. */
static void
adjust_real (mpfr_t r, bool inexact)
{
if (!inexact)
return;
/* NaNs are exact, as are infinities in round-to-zero mode. */
assert (mpfr_number_p (r));
if (mpfr_cmpabs (r, global_min) < 0)
assert_exact (mpfr_copysign (r, global_min, r, MPFR_RNDN));
else if (mpfr_cmpabs (r, global_max) > 0)
assert_exact (mpfr_copysign (r, global_max, r, MPFR_RNDN));
else
{
mpz_t tmp;
mpz_init (tmp);
mpfr_exp_t e = mpfr_get_z_2exp (tmp, r);
if (mpz_sgn (tmp) < 0)
{
mpz_neg (tmp, tmp);
mpz_setbit (tmp, 0);
mpz_neg (tmp, tmp);
}
else
mpz_setbit (tmp, 0);
assert_exact (mpfr_set_z_2exp (r, tmp, e, MPFR_RNDN));
mpz_clear (tmp);
}
}
/* Given a finite real number R with sticky bit, compute the roundings
to FORMAT in each rounding mode, storing the results in RES, the
before-rounding exceptions in EXC_BEFORE and the after-rounding
exceptions in EXC_AFTER. */
static void
round_real (mpfr_t res[rm_num_modes],
unsigned int exc_before[rm_num_modes],
unsigned int exc_after[rm_num_modes],
mpfr_t r, fp_format format)
{
assert (mpfr_number_p (r));
for (rounding_mode m = rm_first_mode; m < rm_num_modes; m++)
{
mpfr_init2 (res[m], fp_formats[format].mant_dig);
exc_before[m] = exc_after[m] = 0;
bool inexact = mpfr_set (res[m], r, rounding_modes[m].mpfr_mode);
if (mpfr_cmpabs (res[m], fp_formats[format].max) > 0)
{
inexact = true;
exc_before[m] |= 1U << exc_overflow;
exc_after[m] |= 1U << exc_overflow;
bool overflow_inf;
switch (m)
{
case rm_tonearest:
overflow_inf = true;
break;
case rm_towardzero:
overflow_inf = false;
break;
case rm_downward:
overflow_inf = mpfr_signbit (res[m]);
break;
case rm_upward:
overflow_inf = !mpfr_signbit (res[m]);
break;
default:
abort ();
}
if (overflow_inf)
mpfr_set_inf (res[m], mpfr_signbit (res[m]) ? -1 : 1);
else
assert_exact (mpfr_copysign (res[m], fp_formats[format].max,
res[m], MPFR_RNDN));
}
if (mpfr_cmpabs (r, fp_formats[format].min) < 0)
{
/* Tiny before rounding; may or may not be tiny after
rounding, and underflow applies only if also inexact
around rounding to a possibly subnormal value. */
bool tiny_after_rounding
= mpfr_cmpabs (res[m], fp_formats[format].min) < 0;
/* To round to a possibly subnormal value, and determine
inexactness as a subnormal in the process, scale up and
round to integer, then scale back down. */
mpfr_t tmp;
mpfr_init (tmp);
assert_exact (mpfr_mul_2si (tmp, r, (fp_formats[format].mant_dig
- fp_formats[format].min_exp),
MPFR_RNDN));
int rint_res = mpfr_rint (tmp, tmp, rounding_modes[m].mpfr_mode);
/* The integer must be representable. */
assert (rint_res == 0 || rint_res == 2 || rint_res == -2);
/* If rounding to full precision was inexact, so must
rounding to subnormal precision be inexact. */
if (inexact)
assert (rint_res != 0);
else
inexact = rint_res != 0;
assert_exact (mpfr_mul_2si (res[m], tmp,
(fp_formats[format].min_exp
- fp_formats[format].mant_dig),
MPFR_RNDN));
mpfr_clear (tmp);
if (inexact)
{
exc_before[m] |= 1U << exc_underflow;
if (tiny_after_rounding)
exc_after[m] |= 1U << exc_underflow;
}
}
if (inexact)
{
exc_before[m] |= 1U << exc_inexact;
exc_after[m] |= 1U << exc_inexact;
}
}
}
/* Handle the input argument at ARG (NUL-terminated), updating the
lists of test inputs in IT accordingly. NUM_PREV_ARGS arguments
are already in those lists. If EXACT_ARGS, interpret a value given
as a floating-point constant exactly (it must be exact for some
supported format) rather than rounding up and down. The argument,
of type GTYPE, comes from file FILENAME, line LINENO. */
static void
handle_input_arg (const char *arg, input_test *it, size_t num_prev_args,
generic_value_type gtype, bool exact_args,
const char *filename, unsigned int lineno)
{
size_t num_values = 0;
generic_value values[2 * fp_num_formats];
bool check_empty_list = false;
switch (gtype)
{
case gtype_fp:
for (fp_format f = fp_first_format; f < fp_num_formats; f++)
{
mpfr_t extra_values[2];
size_t num_extra_values = 0;
for (size_t i = 0; i < ARRAY_SIZE (special_real_inputs); i++)
{
if (strcmp (arg, special_real_inputs[i].str) == 0)
{
num_extra_values
= special_real_inputs[i].func (extra_values[0],
extra_values[1], f);
assert (num_extra_values > 0
&& num_extra_values <= ARRAY_SIZE (extra_values));
break;
}
}
if (num_extra_values == 0)
{
mpfr_t tmp;
char *ep;
if (exact_args)
check_empty_list = true;
mpfr_init (tmp);
bool inexact = mpfr_strtofr (tmp, arg, &ep, 0, MPFR_RNDZ);
if (*ep != 0 || !mpfr_number_p (tmp))
error_at_line (EXIT_FAILURE, 0, filename, lineno,
"bad floating-point argument: '%s'", arg);
adjust_real (tmp, inexact);
mpfr_t rounded[rm_num_modes];
unsigned int exc_before[rm_num_modes];
unsigned int exc_after[rm_num_modes];
round_real (rounded, exc_before, exc_after, tmp, f);
mpfr_clear (tmp);
if (mpfr_number_p (rounded[rm_upward])
&& (!exact_args || mpfr_equal_p (rounded[rm_upward],
rounded[rm_downward])))
{
mpfr_init2 (extra_values[num_extra_values],
fp_formats[f].mant_dig);
assert_exact (mpfr_set (extra_values[num_extra_values],
rounded[rm_upward], MPFR_RNDN));
num_extra_values++;
}
if (mpfr_number_p (rounded[rm_downward]) && !exact_args)
{
mpfr_init2 (extra_values[num_extra_values],
fp_formats[f].mant_dig);
assert_exact (mpfr_set (extra_values[num_extra_values],
rounded[rm_downward], MPFR_RNDN));
num_extra_values++;
}
for (rounding_mode m = rm_first_mode; m < rm_num_modes; m++)
mpfr_clear (rounded[m]);
}
for (size_t i = 0; i < num_extra_values; i++)
{
bool found = false;
for (size_t j = 0; j < num_values; j++)
{
if (mpfr_equal_p (values[j].value.f, extra_values[i])
&& ((mpfr_signbit (values[j].value.f) != 0)
== (mpfr_signbit (extra_values[i]) != 0)))
{
found = true;
break;
}
}
if (!found)
{
assert (num_values < ARRAY_SIZE (values));
values[num_values].type = gtype_fp;
mpfr_init2 (values[num_values].value.f,
fp_formats[f].mant_dig);
assert_exact (mpfr_set (values[num_values].value.f,
extra_values[i], MPFR_RNDN));
num_values++;
}
mpfr_clear (extra_values[i]);
}
}
break;
case gtype_int:
num_values = 1;
values[0].type = gtype_int;
int ret = mpz_init_set_str (values[0].value.i, arg, 0);
if (ret != 0)
error_at_line (EXIT_FAILURE, 0, filename, lineno,
"bad integer argument: '%s'", arg);
break;
default:
abort ();
}
if (check_empty_list && num_values == 0)
error_at_line (EXIT_FAILURE, 0, filename, lineno,
"floating-point argument not exact for any format: '%s'",
arg);
assert (num_values > 0 && num_values <= ARRAY_SIZE (values));
if (it->num_input_cases >= SIZE_MAX / num_values)
error_at_line (EXIT_FAILURE, 0, filename, lineno, "too many input cases");
generic_value **old_inputs = it->inputs;
size_t new_num_input_cases = it->num_input_cases * num_values;
generic_value **new_inputs = xmalloc (new_num_input_cases
* sizeof (new_inputs[0]));
for (size_t i = 0; i < it->num_input_cases; i++)
{
for (size_t j = 0; j < num_values; j++)
{
size_t idx = i * num_values + j;
new_inputs[idx] = xmalloc ((num_prev_args + 1)
* sizeof (new_inputs[idx][0]));
for (size_t k = 0; k < num_prev_args; k++)
generic_value_copy (&new_inputs[idx][k], &old_inputs[i][k]);
generic_value_copy (&new_inputs[idx][num_prev_args], &values[j]);
}
for (size_t j = 0; j < num_prev_args; j++)
generic_value_free (&old_inputs[i][j]);
free (old_inputs[i]);
}
free (old_inputs);
for (size_t i = 0; i < num_values; i++)
generic_value_free (&values[i]);
it->inputs = new_inputs;
it->num_input_cases = new_num_input_cases;
}
/* Handle the input flag ARG (NUL-terminated), storing it in *FLAG.
The flag comes from file FILENAME, line LINENO. */
static void
handle_input_flag (char *arg, input_flag *flag,
const char *filename, unsigned int lineno)
{
char *ep = strchr (arg, ':');
if (ep == NULL)
{
ep = strchr (arg, 0);
assert (ep != NULL);
}
char c = *ep;
*ep = 0;
bool found = false;
for (input_flag_type i = flag_first_flag; i <= num_input_flag_types; i++)
{
if (strcmp (arg, input_flags[i]) == 0)
{
found = true;
flag->type = i;
break;
}
}
if (!found)
error_at_line (EXIT_FAILURE, 0, filename, lineno, "unknown flag: '%s'",
arg);
*ep = c;
if (c == 0)
flag->cond = NULL;
else
flag->cond = xstrdup (ep);
}
/* Add the test LINE (file FILENAME, line LINENO) to the test
data. */
static void
add_test (char *line, const char *filename, unsigned int lineno)
{
size_t num_tokens = 1;
char *p = line;
while ((p = strchr (p, ' ')) != NULL)
{
num_tokens++;
p++;
}
if (num_tokens < 2)
error_at_line (EXIT_FAILURE, 0, filename, lineno,
"line too short: '%s'", line);
p = strchr (line, ' ');
size_t func_name_len = p - line;
for (size_t i = 0; i < ARRAY_SIZE (test_functions); i++)
{
if (func_name_len == strlen (test_functions[i].name)
&& strncmp (line, test_functions[i].name, func_name_len) == 0)
{
test_function *tf = &test_functions[i];
if (num_tokens < 1 + tf->num_args)
error_at_line (EXIT_FAILURE, 0, filename, lineno,
"line too short: '%s'", line);
if (tf->num_tests == tf->num_tests_alloc)
{
tf->num_tests_alloc = 2 * tf->num_tests_alloc + 16;
tf->tests
= xrealloc (tf->tests,
tf->num_tests_alloc * sizeof (tf->tests[0]));
}
input_test *it = &tf->tests[tf->num_tests];
it->line = line;
it->num_input_cases = 1;
it->inputs = xmalloc (sizeof (it->inputs[0]));
it->inputs[0] = NULL;
it->old_output = NULL;
p++;
for (size_t j = 0; j < tf->num_args; j++)
{
char *ep = strchr (p, ' ');
if (ep == NULL)
{
ep = strchr (p, '\n');
assert (ep != NULL);
}
if (ep == p)
error_at_line (EXIT_FAILURE, 0, filename, lineno,
"empty token in line: '%s'", line);
for (char *t = p; t < ep; t++)
if (isspace ((unsigned char) *t))
error_at_line (EXIT_FAILURE, 0, filename, lineno,
"whitespace in token in line: '%s'", line);
char c = *ep;
*ep = 0;
handle_input_arg (p, it, j,
generic_arg_ret_type (tf->arg_types[j]),
tf->exact_args, filename, lineno);
*ep = c;
p = ep + 1;
}
it->num_flags = num_tokens - 1 - tf->num_args;
it->flags = xmalloc (it->num_flags * sizeof (it->flags[0]));
for (size_t j = 0; j < it->num_flags; j++)
{
char *ep = strchr (p, ' ');
if (ep == NULL)
{
ep = strchr (p, '\n');
assert (ep != NULL);
}
if (ep == p)
error_at_line (EXIT_FAILURE, 0, filename, lineno,
"empty token in line: '%s'", line);
for (char *t = p; t < ep; t++)
if (isspace ((unsigned char) *t))
error_at_line (EXIT_FAILURE, 0, filename, lineno,
"whitespace in token in line: '%s'", line);
char c = *ep;
*ep = 0;
handle_input_flag (p, &it->flags[j], filename, lineno);
*ep = c;
p = ep + 1;
}
assert (*p == 0);
tf->num_tests++;
return;
}
}
error_at_line (EXIT_FAILURE, 0, filename, lineno,
"unknown function in line: '%s'", line);
}
/* Read in the test input data from FILENAME. */
static void
read_input (const char *filename)
{
FILE *fp = fopen (filename, "r");
if (fp == NULL)
error (EXIT_FAILURE, errno, "open '%s'", filename);
unsigned int lineno = 0;
for (;;)
{
size_t size = 0;
char *line = NULL;
ssize_t ret = getline (&line, &size, fp);
if (ret == -1)
break;
lineno++;
if (line[0] == '#' || line[0] == '\n')
continue;
add_test (line, filename, lineno);
}
if (ferror (fp))
error (EXIT_FAILURE, errno, "read from '%s'", filename);
if (fclose (fp) != 0)
error (EXIT_FAILURE, errno, "close '%s'", filename);
}
/* Calculate the generic results (round-to-zero with sticky bit) for
the function described by CALC, with inputs INPUTS, if MODE is
rm_towardzero; for other modes, calculate results in that mode,
which must be exact zero results. */
static void
calc_generic_results (generic_value *outputs, generic_value *inputs,
const func_calc_desc *calc, rounding_mode mode)
{
bool inexact;
int mpc_ternary;
mpc_t ci1, ci2, co;
mpfr_rnd_t mode_mpfr = rounding_modes[mode].mpfr_mode;
mpc_rnd_t mode_mpc = rounding_modes[mode].mpc_mode;
switch (calc->method)
{
case mpfr_f_f:
assert (inputs[0].type == gtype_fp);
outputs[0].type = gtype_fp;
mpfr_init (outputs[0].value.f);
inexact = calc->func.mpfr_f_f (outputs[0].value.f, inputs[0].value.f,
mode_mpfr);
if (mode != rm_towardzero)
assert (!inexact && mpfr_zero_p (outputs[0].value.f));
adjust_real (outputs[0].value.f, inexact);
break;
case mpfr_ff_f:
assert (inputs[0].type == gtype_fp);
assert (inputs[1].type == gtype_fp);
outputs[0].type = gtype_fp;
mpfr_init (outputs[0].value.f);
inexact = calc->func.mpfr_ff_f (outputs[0].value.f, inputs[0].value.f,
inputs[1].value.f, mode_mpfr);
if (mode != rm_towardzero)
assert (!inexact && mpfr_zero_p (outputs[0].value.f));
adjust_real (outputs[0].value.f, inexact);
break;
case mpfr_fff_f:
assert (inputs[0].type == gtype_fp);
assert (inputs[1].type == gtype_fp);
assert (inputs[2].type == gtype_fp);
outputs[0].type = gtype_fp;
mpfr_init (outputs[0].value.f);
inexact = calc->func.mpfr_fff_f (outputs[0].value.f, inputs[0].value.f,
inputs[1].value.f, inputs[2].value.f,
mode_mpfr);
if (mode != rm_towardzero)
assert (!inexact && mpfr_zero_p (outputs[0].value.f));
adjust_real (outputs[0].value.f, inexact);
break;
case mpfr_f_f1:
assert (inputs[0].type == gtype_fp);
outputs[0].type = gtype_fp;
outputs[1].type = gtype_int;
mpfr_init (outputs[0].value.f);
int i = 0;
inexact = calc->func.mpfr_f_f1 (outputs[0].value.f, &i,
inputs[0].value.f, mode_mpfr);
if (mode != rm_towardzero)
assert (!inexact && mpfr_zero_p (outputs[0].value.f));
adjust_real (outputs[0].value.f, inexact);
mpz_init_set_si (outputs[1].value.i, i);
break;
case mpfr_if_f:
assert (inputs[0].type == gtype_int);
assert (inputs[1].type == gtype_fp);
outputs[0].type = gtype_fp;
mpfr_init (outputs[0].value.f);
assert (mpz_fits_slong_p (inputs[0].value.i));
long l = mpz_get_si (inputs[0].value.i);
inexact = calc->func.mpfr_if_f (outputs[0].value.f, l,
inputs[1].value.f, mode_mpfr);
if (mode != rm_towardzero)
assert (!inexact && mpfr_zero_p (outputs[0].value.f));
adjust_real (outputs[0].value.f, inexact);
break;
case mpfr_f_11:
assert (inputs[0].type == gtype_fp);
outputs[0].type = gtype_fp;
mpfr_init (outputs[0].value.f);
outputs[1].type = gtype_fp;
mpfr_init (outputs[1].value.f);
int comb_ternary = calc->func.mpfr_f_11 (outputs[0].value.f,
outputs[1].value.f,
inputs[0].value.f,
mode_mpfr);
if (mode != rm_towardzero)
assert (((comb_ternary & 0x3) == 0
&& mpfr_zero_p (outputs[0].value.f))
|| ((comb_ternary & 0xc) == 0
&& mpfr_zero_p (outputs[1].value.f)));
adjust_real (outputs[0].value.f, (comb_ternary & 0x3) != 0);
adjust_real (outputs[1].value.f, (comb_ternary & 0xc) != 0);
break;
case mpc_c_f:
assert (inputs[0].type == gtype_fp);
assert (inputs[1].type == gtype_fp);
outputs[0].type = gtype_fp;
mpfr_init (outputs[0].value.f);
mpc_init2 (ci1, internal_precision);
assert_exact (mpc_set_fr_fr (ci1, inputs[0].value.f, inputs[1].value.f,
MPC_RNDNN));
inexact = calc->func.mpc_c_f (outputs[0].value.f, ci1, mode_mpfr);
if (mode != rm_towardzero)
assert (!inexact && mpfr_zero_p (outputs[0].value.f));
adjust_real (outputs[0].value.f, inexact);
mpc_clear (ci1);
break;
case mpc_c_c:
assert (inputs[0].type == gtype_fp);
assert (inputs[1].type == gtype_fp);
outputs[0].type = gtype_fp;
mpfr_init (outputs[0].value.f);
outputs[1].type = gtype_fp;
mpfr_init (outputs[1].value.f);
mpc_init2 (ci1, internal_precision);
mpc_init2 (co, internal_precision);
assert_exact (mpc_set_fr_fr (ci1, inputs[0].value.f, inputs[1].value.f,
MPC_RNDNN));
mpc_ternary = calc->func.mpc_c_c (co, ci1, mode_mpc);
if (mode != rm_towardzero)
assert ((!MPC_INEX_RE (mpc_ternary)
&& mpfr_zero_p (mpc_realref (co)))
|| (!MPC_INEX_IM (mpc_ternary)
&& mpfr_zero_p (mpc_imagref (co))));
assert_exact (mpfr_set (outputs[0].value.f, mpc_realref (co),
MPFR_RNDN));
assert_exact (mpfr_set (outputs[1].value.f, mpc_imagref (co),
MPFR_RNDN));
adjust_real (outputs[0].value.f, MPC_INEX_RE (mpc_ternary));
adjust_real (outputs[1].value.f, MPC_INEX_IM (mpc_ternary));
mpc_clear (ci1);
mpc_clear (co);
break;
case mpc_cc_c:
assert (inputs[0].type == gtype_fp);
assert (inputs[1].type == gtype_fp);
assert (inputs[2].type == gtype_fp);
assert (inputs[3].type == gtype_fp);
outputs[0].type = gtype_fp;
mpfr_init (outputs[0].value.f);
outputs[1].type = gtype_fp;
mpfr_init (outputs[1].value.f);
mpc_init2 (ci1, internal_precision);
mpc_init2 (ci2, internal_precision);
mpc_init2 (co, internal_precision);
assert_exact (mpc_set_fr_fr (ci1, inputs[0].value.f, inputs[1].value.f,
MPC_RNDNN));
assert_exact (mpc_set_fr_fr (ci2, inputs[2].value.f, inputs[3].value.f,
MPC_RNDNN));
mpc_ternary = calc->func.mpc_cc_c (co, ci1, ci2, mode_mpc);
if (mode != rm_towardzero)
assert ((!MPC_INEX_RE (mpc_ternary)
&& mpfr_zero_p (mpc_realref (co)))
|| (!MPC_INEX_IM (mpc_ternary)
&& mpfr_zero_p (mpc_imagref (co))));
assert_exact (mpfr_set (outputs[0].value.f, mpc_realref (co),
MPFR_RNDN));
assert_exact (mpfr_set (outputs[1].value.f, mpc_imagref (co),
MPFR_RNDN));
adjust_real (outputs[0].value.f, MPC_INEX_RE (mpc_ternary));
adjust_real (outputs[1].value.f, MPC_INEX_IM (mpc_ternary));
mpc_clear (ci1);
mpc_clear (ci2);
mpc_clear (co);
break;
default:
abort ();
}
}
/* Return the number of bits for integer type TYPE, where "long" has
LONG_BITS bits (32 or 64). */
static int
int_type_bits (arg_ret_type type, int long_bits)
{
assert (long_bits == 32 || long_bits == 64);
switch (type)
{
case type_int:
return 32;
break;
case type_long:
return long_bits;
break;
case type_long_long:
return 64;
break;
default:
abort ();
}
}
/* Check whether an integer Z fits a given type TYPE, where "long" has
LONG_BITS bits (32 or 64). */
static bool
int_fits_type (mpz_t z, arg_ret_type type, int long_bits)
{
int bits = int_type_bits (type, long_bits);
bool ret = true;
mpz_t t;
mpz_init (t);
mpz_ui_pow_ui (t, 2, bits - 1);
if (mpz_cmp (z, t) >= 0)
ret = false;
mpz_neg (t, t);
if (mpz_cmp (z, t) < 0)
ret = false;
mpz_clear (t);
return ret;
}
/* Print a generic value V to FP (name FILENAME), preceded by a space,
for type TYPE, floating-point format FORMAT, LONG_BITS bits per
long, printing " IGNORE" instead if IGNORE. */
static void
output_generic_value (FILE *fp, const char *filename, const generic_value *v,
bool ignore, arg_ret_type type, fp_format format,
int long_bits)
{
if (ignore)
{
if (fputs (" IGNORE", fp) < 0)
error (EXIT_FAILURE, errno, "write to '%s'", filename);
return;
}
assert (v->type == generic_arg_ret_type (type));
const char *suffix;
switch (type)
{
case type_fp:
suffix = fp_formats[format].suffix;
break;
case type_int:
suffix = "";
break;
case type_long:
suffix = "L";
break;
case type_long_long:
suffix = "LL";
break;
default:
abort ();
}
switch (v->type)
{
case gtype_fp:
if (mpfr_inf_p (v->value.f))
{
if (fputs ((mpfr_signbit (v->value.f)
? " minus_infty" : " plus_infty"), fp) < 0)
error (EXIT_FAILURE, errno, "write to '%s'", filename);
}
else
{
assert (mpfr_number_p (v->value.f));
if (mpfr_fprintf (fp, " %Ra%s", v->value.f, suffix) < 0)
error (EXIT_FAILURE, errno, "mpfr_fprintf to '%s'", filename);
}
break;
case gtype_int: ;
int bits = int_type_bits (type, long_bits);
mpz_t tmp;
mpz_init (tmp);
mpz_ui_pow_ui (tmp, 2, bits - 1);
mpz_neg (tmp, tmp);
if (mpz_cmp (v->value.i, tmp) == 0)
{
mpz_add_ui (tmp, tmp, 1);
if (mpfr_fprintf (fp, " (%Zd%s-1)", tmp, suffix) < 0)
error (EXIT_FAILURE, errno, "mpfr_fprintf to '%s'", filename);
}
else
{
if (mpfr_fprintf (fp, " %Zd%s", v->value.i, suffix) < 0)
error (EXIT_FAILURE, errno, "mpfr_fprintf to '%s'", filename);
}
mpz_clear (tmp);
break;
default:
abort ();
}
}
/* Generate test output to FP (name FILENAME) for test function TF,
input test IT, choice of input values INPUTS. */
static void
output_for_one_input_case (FILE *fp, const char *filename, test_function *tf,
input_test *it, generic_value *inputs)
{
bool long_bits_matters = false;
bool fits_long32 = true;
for (size_t i = 0; i < tf->num_args; i++)
{
generic_value_type gtype = generic_arg_ret_type (tf->arg_types[i]);
assert (inputs[i].type == gtype);
if (gtype == gtype_int)
{
bool fits_64 = int_fits_type (inputs[i].value.i, tf->arg_types[i],
64);
if (!fits_64)
return;
if (tf->arg_types[i] == type_long
&& !int_fits_type (inputs[i].value.i, tf->arg_types[i], 32))
{
long_bits_matters = true;
fits_long32 = false;
}
}
}
generic_value generic_outputs[MAX_NRET];
calc_generic_results (generic_outputs, inputs, &tf->calc, rm_towardzero);
bool ignore_output_long32[MAX_NRET] = { false };
bool ignore_output_long64[MAX_NRET] = { false };
for (size_t i = 0; i < tf->num_ret; i++)
{
assert (generic_outputs[i].type
== generic_arg_ret_type (tf->ret_types[i]));
switch (generic_outputs[i].type)
{
case gtype_fp:
if (!mpfr_number_p (generic_outputs[i].value.f))
goto out; /* Result is NaN or exact infinity. */
break;
case gtype_int:
ignore_output_long32[i] = !int_fits_type (generic_outputs[i].value.i,
tf->ret_types[i], 32);
ignore_output_long64[i] = !int_fits_type (generic_outputs[i].value.i,
tf->ret_types[i], 64);
if (ignore_output_long32[i] != ignore_output_long64[i])
long_bits_matters = true;
break;
default:
abort ();
}
}
/* Iterate over relevant sizes of long and floating-point formats. */
for (int long_bits = 32; long_bits <= 64; long_bits += 32)
{
if (long_bits == 32 && !fits_long32)
continue;
if (long_bits == 64 && !long_bits_matters)
continue;
const char *long_cond;
if (long_bits_matters)
long_cond = (long_bits == 32 ? ":long32" : ":long64");
else
long_cond = "";
bool *ignore_output = (long_bits == 32
? ignore_output_long32
: ignore_output_long64);
for (fp_format f = fp_first_format; f < fp_num_formats; f++)
{
bool fits = true;
mpfr_t res[rm_num_modes];
unsigned int exc_before[rm_num_modes];
unsigned int exc_after[rm_num_modes];
for (size_t i = 0; i < tf->num_args; i++)
{
if (inputs[i].type == gtype_fp)
{
round_real (res, exc_before, exc_after, inputs[i].value.f,
f);
if (!mpfr_equal_p (res[rm_tonearest], inputs[i].value.f))
fits = false;
for (rounding_mode m = rm_first_mode; m < rm_num_modes; m++)
mpfr_clear (res[m]);
if (!fits)
break;
}
}
if (!fits)
continue;
/* The inputs fit this type, so compute the ideal outputs
and exceptions. */
mpfr_t all_res[MAX_NRET][rm_num_modes];
unsigned int all_exc_before[MAX_NRET][rm_num_modes];
unsigned int all_exc_after[MAX_NRET][rm_num_modes];
unsigned int merged_exc_before[rm_num_modes] = { 0 };
unsigned int merged_exc_after[rm_num_modes] = { 0 };
/* For functions not exactly determined, track whether
underflow is required (some result is inexact, and
magnitude does not exceed the greatest magnitude
subnormal), and permitted (not an exact zero, and
magnitude does not exceed the least magnitude
normal). */
bool must_underflow = false;
bool may_underflow = false;
for (size_t i = 0; i < tf->num_ret; i++)
{
switch (generic_outputs[i].type)
{
case gtype_fp:
round_real (all_res[i], all_exc_before[i], all_exc_after[i],
generic_outputs[i].value.f, f);
for (rounding_mode m = rm_first_mode; m < rm_num_modes; m++)
{
merged_exc_before[m] |= all_exc_before[i][m];
merged_exc_after[m] |= all_exc_after[i][m];
if (!tf->exact)
{
must_underflow
|= ((all_exc_before[i][m]
& (1U << exc_inexact)) != 0
&& (mpfr_cmpabs (generic_outputs[i].value.f,
fp_formats[f].subnorm_max)
<= 0));
may_underflow
|= (!mpfr_zero_p (generic_outputs[i].value.f)
&& mpfr_cmpabs (generic_outputs[i].value.f,
fp_formats[f].min) <= 0);
}
/* If the result is an exact zero, the sign may
depend on the rounding mode, so recompute it
directly in that mode. */
if (mpfr_zero_p (all_res[i][m])
&& (all_exc_before[i][m] & (1U << exc_inexact)) == 0)
{
generic_value outputs_rm[MAX_NRET];
calc_generic_results (outputs_rm, inputs,
&tf->calc, m);
assert_exact (mpfr_set (all_res[i][m],
outputs_rm[i].value.f,
MPFR_RNDN));
for (size_t j = 0; j < tf->num_ret; j++)
generic_value_free (&outputs_rm[j]);
}
}
break;
case gtype_int:
if (ignore_output[i])
for (rounding_mode m = rm_first_mode;
m < rm_num_modes;
m++)
{
merged_exc_before[m] |= 1U << exc_invalid;
merged_exc_after[m] |= 1U << exc_invalid;
}
break;
default:
abort ();
}
}
assert (may_underflow || !must_underflow);
for (rounding_mode m = rm_first_mode; m < rm_num_modes; m++)
{
bool before_after_matters
= tf->exact && merged_exc_before[m] != merged_exc_after[m];
if (before_after_matters)
{
assert ((merged_exc_before[m] ^ merged_exc_after[m])
== (1U << exc_underflow));
assert ((merged_exc_before[m] & (1U << exc_underflow)) != 0);
}
unsigned int merged_exc = merged_exc_before[m];
if (fprintf (fp, "= %s %s %s%s", tf->name,
rounding_modes[m].name, fp_formats[f].name,
long_cond) < 0)
error (EXIT_FAILURE, errno, "write to '%s'", filename);
/* Print inputs. */
for (size_t i = 0; i < tf->num_args; i++)
output_generic_value (fp, filename, &inputs[i], false,
tf->arg_types[i], f, long_bits);
if (fputs (" :", fp) < 0)
error (EXIT_FAILURE, errno, "write to '%s'", filename);
/* Print outputs. */
bool must_erange = false;
for (size_t i = 0; i < tf->num_ret; i++)
{
generic_value g;
g.type = generic_outputs[i].type;
switch (g.type)
{
case gtype_fp:
if (mpfr_inf_p (all_res[i][m])
&& (all_exc_before[i][m]
& (1U << exc_overflow)) != 0)
must_erange = true;
if (mpfr_zero_p (all_res[i][m])
&& (tf->exact
|| mpfr_zero_p (all_res[i][rm_tonearest]))
&& (all_exc_before[i][m]
& (1U << exc_underflow)) != 0)
must_erange = true;
mpfr_init2 (g.value.f, fp_formats[f].mant_dig);
assert_exact (mpfr_set (g.value.f, all_res[i][m],
MPFR_RNDN));
break;
case gtype_int:
mpz_init (g.value.i);
mpz_set (g.value.i, generic_outputs[i].value.i);
break;
default:
abort ();
}
output_generic_value (fp, filename, &g, ignore_output[i],
tf->ret_types[i], f, long_bits);
generic_value_free (&g);
}
if (fputs (" :", fp) < 0)
error (EXIT_FAILURE, errno, "write to '%s'", filename);
/* Print miscellaneous flags (passed through from
input). */
for (size_t i = 0; i < it->num_flags; i++)
switch (it->flags[i].type)
{
case flag_no_test_inline:
case flag_xfail:
if (fprintf (fp, " %s%s",
input_flags[it->flags[i].type],
(it->flags[i].cond
? it->flags[i].cond
: "")) < 0)
error (EXIT_FAILURE, errno, "write to '%s'",
filename);
break;
case flag_xfail_rounding:
if (m != rm_tonearest)
if (fprintf (fp, " xfail%s",
(it->flags[i].cond
? it->flags[i].cond
: "")) < 0)
error (EXIT_FAILURE, errno, "write to '%s'",
filename);
break;
default:
break;
}
/* Print exception flags and compute errno
expectations where not already computed. */
bool may_edom = false;
bool must_edom = false;
bool may_erange = must_erange || may_underflow;
for (fp_exception e = exc_first_exception;
e < exc_num_exceptions;
e++)
{
bool expect_e = (merged_exc & (1U << e)) != 0;
bool e_optional = false;
switch (e)
{
case exc_divbyzero:
if (expect_e)
may_erange = must_erange = true;
break;
case exc_inexact:
if (!tf->exact)
e_optional = true;
break;
case exc_invalid:
if (expect_e)
may_edom = must_edom = true;
break;
case exc_overflow:
if (expect_e)
may_erange = true;
break;
case exc_underflow:
if (expect_e)
may_erange = true;
if (must_underflow)
assert (expect_e);
if (may_underflow && !must_underflow)
e_optional = true;
break;
default:
abort ();
}
if (e_optional)
{
assert (!before_after_matters);
if (fprintf (fp, " %s-ok", exceptions[e]) < 0)
error (EXIT_FAILURE, errno, "write to '%s'",
filename);
}
else
{
if (expect_e)
if (fprintf (fp, " %s", exceptions[e]) < 0)
error (EXIT_FAILURE, errno, "write to '%s'",
filename);
if (before_after_matters && e == exc_underflow)
if (fputs (":before-rounding", fp) < 0)
error (EXIT_FAILURE, errno, "write to '%s'",
filename);
for (int after = 0; after <= 1; after++)
{
bool expect_e_here = expect_e;
if (after == 1 && (!before_after_matters
|| e != exc_underflow))
continue;
const char *after_cond;
if (before_after_matters && e == exc_underflow)
{
after_cond = (after
? ":after-rounding"
: ":before-rounding");
expect_e_here = !after;
}
else
after_cond = "";
input_flag_type okflag;
okflag = (expect_e_here
? flag_missing_first
: flag_spurious_first) + e;
for (size_t i = 0; i < it->num_flags; i++)
if (it->flags[i].type == okflag)
if (fprintf (fp, " %s-ok%s%s",
exceptions[e],
(it->flags[i].cond
? it->flags[i].cond
: ""), after_cond) < 0)
error (EXIT_FAILURE, errno, "write to '%s'",
filename);
}
}
}
/* Print errno expectations. */
if (tf->complex_fn)
{
must_edom = false;
must_erange = false;
}
if (may_edom && !must_edom)
{
if (fputs (" errno-edom-ok", fp) < 0)
error (EXIT_FAILURE, errno, "write to '%s'",
filename);
}
else
{
if (must_edom)
if (fputs (" errno-edom", fp) < 0)
error (EXIT_FAILURE, errno, "write to '%s'",
filename);
input_flag_type okflag = (must_edom
? flag_missing_errno
: flag_spurious_errno);
for (size_t i = 0; i < it->num_flags; i++)
if (it->flags[i].type == okflag)
if (fprintf (fp, " errno-edom-ok%s",
(it->flags[i].cond
? it->flags[i].cond
: "")) < 0)
error (EXIT_FAILURE, errno, "write to '%s'",
filename);
}
if (before_after_matters)
assert (may_erange && !must_erange);
if (may_erange && !must_erange)
{
if (fprintf (fp, " errno-erange-ok%s",
(before_after_matters
? ":before-rounding"
: "")) < 0)
error (EXIT_FAILURE, errno, "write to '%s'",
filename);
}
if (before_after_matters || !(may_erange && !must_erange))
{
if (must_erange)
if (fputs (" errno-erange", fp) < 0)
error (EXIT_FAILURE, errno, "write to '%s'",
filename);
input_flag_type okflag = (must_erange
? flag_missing_errno
: flag_spurious_errno);
for (size_t i = 0; i < it->num_flags; i++)
if (it->flags[i].type == okflag)
if (fprintf (fp, " errno-erange-ok%s%s",
(it->flags[i].cond
? it->flags[i].cond
: ""),
(before_after_matters
? ":after-rounding"
: "")) < 0)
error (EXIT_FAILURE, errno, "write to '%s'",
filename);
}
if (putc ('\n', fp) < 0)
error (EXIT_FAILURE, errno, "write to '%s'", filename);
}
for (size_t i = 0; i < tf->num_ret; i++)
{
if (generic_outputs[i].type == gtype_fp)
for (rounding_mode m = rm_first_mode; m < rm_num_modes; m++)
mpfr_clear (all_res[i][m]);
}
}
}
out:
for (size_t i = 0; i < tf->num_ret; i++)
generic_value_free (&generic_outputs[i]);
}
/* Generate test output data to FILENAME. */
static void
generate_output (const char *filename)
{
FILE *fp = fopen (filename, "w");
if (fp == NULL)
error (EXIT_FAILURE, errno, "open '%s'", filename);
for (size_t i = 0; i < ARRAY_SIZE (test_functions); i++)
{
test_function *tf = &test_functions[i];
for (size_t j = 0; j < tf->num_tests; j++)
{
input_test *it = &tf->tests[j];
if (fputs (it->line, fp) < 0)
error (EXIT_FAILURE, errno, "write to '%s'", filename);
for (size_t k = 0; k < it->num_input_cases; k++)
output_for_one_input_case (fp, filename, tf, it, it->inputs[k]);
}
}
if (fclose (fp) != 0)
error (EXIT_FAILURE, errno, "close '%s'", filename);
}
int
main (int argc, char **argv)
{
if (argc != 3)
error (EXIT_FAILURE, 0, "usage: gen-auto-libm-tests <input> <output>");
const char *input_filename = argv[1];
const char *output_filename = argv[2];
init_fp_formats ();
read_input (input_filename);
generate_output (output_filename);
exit (EXIT_SUCCESS);
}