#!/usr/bin/python
# Generate tests for libm functions.
# Copyright (C) 2018 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
# .
import argparse
from collections import defaultdict
import os
import re
# Sorted list of all float types in ulps files.
ALL_FLOATS = ('double', 'float', 'float128', 'idouble',
'ifloat', 'ifloat128', 'ildouble', 'ldouble')
# Map float types in ulps files to C-like prefix for macros.
ALL_FLOATS_PFX = {'double': 'DBL',
'ldouble': 'LDBL',
'float': 'FLT',
'float128': 'FLT128'}
# Float types in the order used in the generated ulps tables in the
# manual.
ALL_FLOATS_MANUAL = ('float', 'double', 'ldouble', 'float128')
# Map float types in ulps files to C function suffix.
ALL_FLOATS_SUFFIX = {'double': '',
'ldouble': 'l',
'float': 'f',
'float128': 'f128'}
# Number of arguments in structure (as opposed to arguments that are
# pointers to return values) for an argument descriptor.
DESCR_NUM_ARGS = {'f': 1, 'a': 1, 'j': 1, 'i': 1, 'u': 1, 'l': 1, 'L': 1,
'p': 0, 'F': 0, 'I': 0,
'c': 2}
# Number of results in structure for a result descriptor.
DESCR_NUM_RES = {'f': 1, 'i': 1, 'l': 1, 'L': 1, 'M': 1, 'U': 1, 'b': 1,
'1': 1,
'c': 2}
# Rounding modes, in the form in which they appear in
# auto-libm-test-out-* and the order in which expected results appear
# in structures and TEST_* calls.
ROUNDING_MODES = ('downward', 'tonearest', 'towardzero', 'upward')
# Map from special text in TEST_* calls for rounding-mode-specific
# results and flags, to those results for each mode.
ROUNDING_MAP = {
'plus_oflow': ('max_value', 'plus_infty', 'max_value', 'plus_infty'),
'minus_oflow': ('minus_infty', 'minus_infty', '-max_value', '-max_value'),
'plus_uflow': ('plus_zero', 'plus_zero', 'plus_zero', 'min_subnorm_value'),
'minus_uflow': ('-min_subnorm_value', 'minus_zero', 'minus_zero',
'minus_zero'),
'ERRNO_PLUS_OFLOW': ('0', 'ERRNO_ERANGE', '0', 'ERRNO_ERANGE'),
'ERRNO_MINUS_OFLOW': ('ERRNO_ERANGE', 'ERRNO_ERANGE', '0', '0'),
'ERRNO_PLUS_UFLOW': ('ERRNO_ERANGE', 'ERRNO_ERANGE', 'ERRNO_ERANGE', '0'),
'ERRNO_MINUS_UFLOW': ('0', 'ERRNO_ERANGE', 'ERRNO_ERANGE', 'ERRNO_ERANGE'),
'XFAIL_ROUNDING_IBM128_LIBGCC': ('XFAIL_IBM128_LIBGCC', '0',
'XFAIL_IBM128_LIBGCC',
'XFAIL_IBM128_LIBGCC')
}
# Map from raw test arguments to a nicer form to use when displaying
# test results.
BEAUTIFY_MAP = {'minus_zero': '-0',
'plus_zero': '+0',
'-0x0p+0f': '-0',
'-0x0p+0': '-0',
'-0x0p+0L': '-0',
'0x0p+0f': '+0',
'0x0p+0': '+0',
'0x0p+0L': '+0',
'minus_infty': '-inf',
'plus_infty': 'inf',
'qnan_value': 'qNaN',
'snan_value': 'sNaN',
'snan_value_ld': 'sNaN'}
# Flags in auto-libm-test-out that map directly to C flags.
FLAGS_SIMPLE = {'ignore-zero-inf-sign': 'IGNORE_ZERO_INF_SIGN',
'no-test-inline': 'NO_TEST_INLINE',
'xfail': 'XFAIL_TEST'}
# Exceptions in auto-libm-test-out, and their corresponding C flags
# for being required, OK or required to be absent.
EXC_EXPECTED = {'divbyzero': 'DIVBYZERO_EXCEPTION',
'inexact': 'INEXACT_EXCEPTION',
'invalid': 'INVALID_EXCEPTION',
'overflow': 'OVERFLOW_EXCEPTION',
'underflow': 'UNDERFLOW_EXCEPTION'}
EXC_OK = {'divbyzero': 'DIVBYZERO_EXCEPTION_OK',
'inexact': '0',
'invalid': 'INVALID_EXCEPTION_OK',
'overflow': 'OVERFLOW_EXCEPTION_OK',
'underflow': 'UNDERFLOW_EXCEPTION_OK'}
EXC_NO = {'divbyzero': '0',
'inexact': 'NO_INEXACT_EXCEPTION',
'invalid': '0',
'overflow': '0',
'underflow': '0'}
class Ulps(object):
"""Maximum expected errors of libm functions."""
def __init__(self):
"""Initialize an Ulps object."""
# normal[function][float_type] is the ulps value, and likewise
# for real and imag.
self.normal = defaultdict(lambda: defaultdict(lambda: 0))
self.real = defaultdict(lambda: defaultdict(lambda: 0))
self.imag = defaultdict(lambda: defaultdict(lambda: 0))
# List of ulps kinds, in the order in which they appear in
# sorted ulps files.
self.ulps_kinds = (('Real part of ', self.real),
('Imaginary part of ', self.imag),
('', self.normal))
self
def read(self, ulps_file):
"""Read ulps from a file into an Ulps object."""
self.ulps_file = ulps_file
with open(ulps_file, 'r') as f:
ulps_dict = None
ulps_fn = None
for line in f:
# Ignore comments.
if line.startswith('#'):
continue
line = line.rstrip()
# Ignore empty lines.
if line == '':
continue
m = re.match(r'([^:]*): (.*)\Z', line)
if not m:
raise ValueError('bad ulps line: %s' % line)
line_first = m.group(1)
line_second = m.group(2)
if line_first == 'Function':
fn = None
ulps_dict = None
for k_prefix, k_dict in self.ulps_kinds:
if line_second.startswith(k_prefix):
ulps_dict = k_dict
fn = line_second[len(k_prefix):]
break
if not fn.startswith('"') or not fn.endswith('":'):
raise ValueError('bad ulps line: %s' % line)
ulps_fn = fn[1:-2]
else:
if line_first not in ALL_FLOATS:
raise ValueError('bad ulps line: %s' % line)
ulps_val = int(line_second)
if ulps_val > 0:
ulps_dict[ulps_fn][line_first] = max(
ulps_dict[ulps_fn][line_first],
ulps_val)
def all_functions(self):
"""Return the set of functions with ulps and whether they are
complex."""
funcs = set()
complex = {}
for k_prefix, k_dict in self.ulps_kinds:
for f in k_dict:
funcs.add(f)
complex[f] = True if k_prefix else False
return funcs, complex
def write(self, ulps_file):
"""Write ulps back out as a sorted ulps file."""
# Output is sorted first by function name, then by (real,
# imag, normal), then by float type.
out_data = {}
for order, (prefix, d) in enumerate(self.ulps_kinds):
for fn in d.keys():
fn_data = ['%s: %d' % (f, d[fn][f])
for f in sorted(d[fn].keys())]
fn_text = 'Function: %s"%s":\n%s' % (prefix, fn,
'\n'.join(fn_data))
out_data[(fn, order)] = fn_text
out_list = [out_data[fn_order] for fn_order in sorted(out_data.keys())]
out_text = ('# Begin of automatic generation\n\n'
'# Maximal error of functions:\n'
'%s\n\n'
'# end of automatic generation\n'
% '\n\n'.join(out_list))
with open(ulps_file, 'w') as f:
f.write(out_text)
@staticmethod
def ulps_table(name, ulps_dict):
"""Return text of a C table of ulps."""
ulps_list = []
for fn in sorted(ulps_dict.keys()):
fn_ulps = [str(ulps_dict[fn][f]) for f in ALL_FLOATS]
ulps_list.append(' { "%s", {%s} },' % (fn, ', '.join(fn_ulps)))
ulps_text = ('static const struct ulp_data %s[] =\n'
' {\n'
'%s\n'
' };'
% (name, '\n'.join(ulps_list)))
return ulps_text
def write_header(self, ulps_header):
"""Write header file with ulps data."""
header_text_1 = ('/* This file is automatically generated\n'
' from %s with gen-libm-test.py.\n'
' Don\'t change it - change instead the master '
'files. */\n\n'
'struct ulp_data\n'
'{\n'
' const char *name;\n'
' FLOAT max_ulp[%d];\n'
'};'
% (self.ulps_file, len(ALL_FLOATS)))
macro_list = []
for i, f in enumerate(ALL_FLOATS):
if f.startswith('i'):
itxt = 'I_'
f = f[1:]
else:
itxt = ''
macro_list.append('#define ULP_%s%s %d'
% (itxt, ALL_FLOATS_PFX[f], i))
header_text = ('%s\n\n'
'%s\n\n'
'/* Maximal error of functions. */\n'
'%s\n'
'%s\n'
'%s\n'
% (header_text_1, '\n'.join(macro_list),
self.ulps_table('func_ulps', self.normal),
self.ulps_table('func_real_ulps', self.real),
self.ulps_table('func_imag_ulps', self.imag)))
with open(ulps_header, 'w') as f:
f.write(header_text)
def read_all_ulps(srcdir):
"""Read all platforms' libm-test-ulps files."""
all_ulps = {}
for dirpath, dirnames, filenames in os.walk(srcdir):
if 'libm-test-ulps' in filenames:
with open(os.path.join(dirpath, 'libm-test-ulps-name')) as f:
name = f.read().rstrip()
all_ulps[name] = Ulps()
all_ulps[name].read(os.path.join(dirpath, 'libm-test-ulps'))
return all_ulps
def read_auto_tests(test_file):
"""Read tests from auto-libm-test-out- (possibly None)."""
auto_tests = defaultdict(lambda: defaultdict(dict))
if test_file is None:
return auto_tests
with open(test_file, 'r') as f:
for line in f:
if not line.startswith('= '):
continue
line = line[len('= '):].rstrip()
# Function, rounding mode, condition and inputs, outputs
# and flags.
m = re.match(r'([^ ]+) ([^ ]+) ([^: ][^ ]* [^:]*) : (.*)\Z', line)
if not m:
raise ValueError('bad automatic test line: %s' % line)
auto_tests[m.group(1)][m.group(2)][m.group(3)] = m.group(4)
return auto_tests
def beautify(arg):
"""Return a nicer representation of a test argument."""
if arg in BEAUTIFY_MAP:
return BEAUTIFY_MAP[arg]
if arg.startswith('-') and arg[1:] in BEAUTIFY_MAP:
return '-' + BEAUTIFY_MAP[arg[1:]]
if re.match(r'-?0x[0-9a-f.]*p[-+][0-9]+f\Z', arg):
return arg[:-1]
if re.search(r'[0-9]L\Z', arg):
return arg[:-1]
return arg
def complex_beautify(arg_real, arg_imag):
"""Return a nicer representation of a complex test argument."""
res_real = beautify(arg_real)
res_imag = beautify(arg_imag)
if res_imag.startswith('-'):
return '%s - %s i' % (res_real, res_imag[1:])
else:
return '%s + %s i' % (res_real, res_imag)
def apply_lit_token(arg, macro):
"""Apply the LIT or ARG_LIT macro to a single token."""
# The macro must only be applied to a floating-point constant, not
# to an integer constant or lit_* value.
sign_re = r'[+-]?'
exp_re = r'([+-])?[0-9]+'
suffix_re = r'[lLfF]?'
dec_exp_re = r'[eE]' + exp_re
hex_exp_re = r'[pP]' + exp_re
dec_frac_re = r'(?:[0-9]*\.[0-9]+|[0-9]+\.)'
hex_frac_re = r'(?:[0-9a-fA-F]*\.[0-9a-fA-F]+|[0-9a-fA-F]+\.)'
dec_int_re = r'[0-9]+'
hex_int_re = r'[0-9a-fA-F]+'
dec_cst_re = r'(?:%s(?:%s)?|%s%s)' % (dec_frac_re, dec_exp_re,
dec_int_re, dec_exp_re)
hex_cst_re = r'0[xX](?:%s|%s)%s' % (hex_frac_re, hex_int_re, hex_exp_re)
fp_cst_re = r'(%s(?:%s|%s))%s\Z' % (sign_re, dec_cst_re, hex_cst_re,
suffix_re)
m = re.match(fp_cst_re, arg)
if m:
return '%s (%s)' % (macro, m.group(1))
else:
return arg
def apply_lit(arg, macro):
"""Apply the LIT or ARG_LIT macro to constants within an expression."""
# Assume expressions follow the GNU Coding Standards, with tokens
# separated by spaces.
return ' '.join([apply_lit_token(t, macro) for t in arg.split()])
def gen_test_args_res(descr_args, descr_res, args, res_rm):
"""Generate a test given the arguments and per-rounding-mode results."""
# Determine whether any arguments or results, for any rounding
# mode, are non-finite.
non_finite = False
test_snan = False
all_args_res = list(args)
for r in res_rm:
all_args_res.extend(r[:len(r)-1])
for a in all_args_res:
if 'snan_value' in a:
test_snan = True
non_finite = True
elif ('qnan_value' in a or 'plus_infty' in a or 'minus_infty' in a
or 'plus_oflow' in a or 'minus_oflow' in a):
non_finite = True
# Process the arguments.
args_disp = []
args_c = []
arg_pos = 0
for d in descr_args:
if DESCR_NUM_ARGS[d] == 0:
continue
if d == 'c':
args_disp.append(complex_beautify(args[arg_pos],
args[arg_pos + 1]))
args_c.append(apply_lit(args[arg_pos], 'LIT'))
args_c.append(apply_lit(args[arg_pos + 1], 'LIT'))
else:
args_disp.append(beautify(args[arg_pos]))
if d == 'f':
args_c.append(apply_lit(args[arg_pos], 'LIT'))
elif d == 'a':
args_c.append(apply_lit(args[arg_pos], 'ARG_LIT'))
else:
args_c.append(args[arg_pos])
arg_pos += DESCR_NUM_ARGS[d]
args_disp_text = ', '.join(args_disp).replace('"', '\\"')
# Process the results.
for rm in range(len(ROUNDING_MODES)):
res = res_rm[rm]
res_pos = 0
rm_args = []
ignore_result_any = False
ignore_result_all = True
special = []
for d in descr_res:
if d == '1':
special.append(res[res_pos])
elif DESCR_NUM_RES[d] == 1:
result = res[res_pos]
if result == 'IGNORE':
ignore_result_any = True
result = '0'
else:
ignore_result_all = False
if d == 'f':
result = apply_lit(result, 'LIT')
rm_args.append(result)
else:
# Complex result.
result1 = res[res_pos]
if result1 == 'IGNORE':
ignore_result_any = True
result1 = '0'
else:
ignore_result_all = False
result1 = apply_lit(result1, 'LIT')
rm_args.append(result1)
result2 = res[res_pos + 1]
if result2 == 'IGNORE':
ignore_result_any = True
result2 = '0'
else:
ignore_result_all = False
result2 = apply_lit(result2, 'LIT')
rm_args.append(result2)
res_pos += DESCR_NUM_RES[d]
if ignore_result_any and not ignore_result_all:
raise ValueError('some but not all function results ignored')
flags = []
if ignore_result_any:
flags.append('IGNORE_RESULT')
if non_finite:
flags.append('NON_FINITE')
if test_snan:
flags.append('TEST_SNAN')
flags.append(res[res_pos])
rm_args.append('|'.join(flags))
for sp in special:
if sp == 'IGNORE':
rm_args.extend(['0', '0'])
else:
rm_args.extend(['1', apply_lit(sp, 'LIT')])
for k in sorted(ROUNDING_MAP.keys()):
rm_args = [arg.replace(k, ROUNDING_MAP[k][rm]) for arg in rm_args]
args_c.append('{ %s }' % ', '.join(rm_args))
return ' { "%s", %s },\n' % (args_disp_text, ', '.join(args_c))
def convert_condition(cond):
"""Convert a condition from auto-libm-test-out to C form."""
conds = cond.split(':')
conds_c = []
for c in conds:
if not c.startswith('arg_fmt('):
c = c.replace('-', '_')
conds_c.append('TEST_COND_' + c)
return '(%s)' % ' && '.join(conds_c)
def cond_value(cond, if_val, else_val):
"""Return a C conditional expression between two values."""
if cond == '1':
return if_val
elif cond == '0':
return else_val
else:
return '(%s ? %s : %s)' % (cond, if_val, else_val)
def gen_auto_tests(auto_tests, descr_args, descr_res, fn):
"""Generate C code for the auto-libm-test-out-* tests for a function."""
for rm_idx, rm_name in enumerate(ROUNDING_MODES):
this_tests = sorted(auto_tests[fn][rm_name].keys())
if rm_idx == 0:
rm_tests = this_tests
if not rm_tests:
raise ValueError('no automatic tests for %s' % fn)
else:
if rm_tests != this_tests:
raise ValueError('inconsistent lists of tests of %s' % fn)
test_list = []
for test in rm_tests:
fmt_args = test.split()
fmt = fmt_args[0]
args = fmt_args[1:]
test_list.append('#if %s\n' % convert_condition(fmt))
res_rm = []
for rm in ROUNDING_MODES:
test_out = auto_tests[fn][rm][test]
out_str, flags_str = test_out.split(':', 1)
this_res = out_str.split()
flags = flags_str.split()
flag_cond = {}
for flag in flags:
m = re.match(r'([^:]*):(.*)\Z', flag)
if m:
f_name = m.group(1)
cond = convert_condition(m.group(2))
if f_name in flag_cond:
if flag_cond[f_name] != '1':
flag_cond[f_name] = ('%s || %s'
% (flag_cond[f_name], cond))
else:
flag_cond[f_name] = cond
else:
flag_cond[flag] = '1'
flags_c = []
for flag in sorted(FLAGS_SIMPLE.keys()):
if flag in flag_cond:
flags_c.append(cond_value(flag_cond[flag],
FLAGS_SIMPLE[flag], '0'))
for exc in sorted(EXC_EXPECTED.keys()):
exc_expected = EXC_EXPECTED[exc]
exc_ok = EXC_OK[exc]
no_exc = EXC_NO[exc]
exc_cond = flag_cond.get(exc, '0')
exc_ok_cond = flag_cond.get(exc + '-ok', '0')
flags_c.append(cond_value(exc_cond,
cond_value(exc_ok_cond, exc_ok,
exc_expected),
cond_value(exc_ok_cond, exc_ok,
no_exc)))
if 'errno-edom' in flag_cond and 'errno-erange' in flag_cond:
raise ValueError('multiple errno values expected')
if 'errno-edom' in flag_cond:
if flag_cond['errno-edom'] != '1':
raise ValueError('unexpected condition for errno-edom')
errno_expected = 'ERRNO_EDOM'
elif 'errno-erange' in flag_cond:
if flag_cond['errno-erange'] != '1':
raise ValueError('unexpected condition for errno-erange')
errno_expected = 'ERRNO_ERANGE'
else:
errno_expected = 'ERRNO_UNCHANGED'
if 'errno-edom-ok' in flag_cond:
if ('errno-erange-ok' in flag_cond
and (flag_cond['errno-erange-ok']
!= flag_cond['errno-edom-ok'])):
errno_unknown_cond = ('%s || %s'
% (flag_cond['errno-edom-ok'],
flag_cond['errno-erange-ok']))
else:
errno_unknown_cond = flag_cond['errno-edom-ok']
else:
errno_unknown_cond = flag_cond.get('errno-erange-ok', '0')
flags_c.append(cond_value(errno_unknown_cond, '0', errno_expected))
flags_c = [flag for flag in flags_c if flag != '0']
if not flags_c:
flags_c = ['NO_EXCEPTION']
this_res.append(' | '.join(flags_c))
res_rm.append(this_res)
test_list.append(gen_test_args_res(descr_args, descr_res, args,
res_rm))
test_list.append('#endif\n')
return ''.join(test_list)
def gen_test_line(descr_args, descr_res, args_str):
"""Generate C code for the tests for a single TEST_* line."""
test_args = args_str.split(',')
test_args = test_args[1:]
test_args = [a.strip() for a in test_args]
num_args = sum([DESCR_NUM_ARGS[c] for c in descr_args])
num_res = sum([DESCR_NUM_RES[c] for c in descr_res])
args = test_args[:num_args]
res = test_args[num_args:]
if len(res) == num_res:
# One set of results for all rounding modes, no flags.
res.append('0')
res_rm = [res, res, res, res]
elif len(res) == num_res + 1:
# One set of results for all rounding modes, with flags.
if not ('EXCEPTION' in res[-1]
or 'ERRNO' in res[-1]
or 'IGNORE_ZERO_INF_SIGN' in res[-1]
or 'TEST_NAN_SIGN' in res[-1]
or 'NO_TEST_INLINE' in res[-1]
or 'XFAIL' in res[-1]):
raise ValueError('wrong number of arguments: %s' % args_str)
res_rm = [res, res, res, res]
elif len(res) == (num_res + 1) * 4:
# One set of results per rounding mode, with flags.
nr_plus = num_res + 1
res_rm = [res[:nr_plus], res[nr_plus:2*nr_plus],
res[2*nr_plus:3*nr_plus], res[3*nr_plus:]]
return gen_test_args_res(descr_args, descr_res, args, res_rm)
def generate_testfile(inc_input, auto_tests, c_output):
"""Generate test .c file from .inc input."""
test_list = []
with open(inc_input, 'r') as f:
for line in f:
line_strip = line.strip()
if line_strip.startswith('AUTO_TESTS_'):
m = re.match(r'AUTO_TESTS_([^_]*)_([^_ ]*) *\(([^)]*)\),\Z',
line_strip)
if not m:
raise ValueError('bad AUTO_TESTS line: %s' % line)
test_list.append(gen_auto_tests(auto_tests, m.group(1),
m.group(2), m.group(3)))
elif line_strip.startswith('TEST_'):
m = re.match(r'TEST_([^_]*)_([^_ ]*) *\((.*)\),\Z', line_strip)
if not m:
raise ValueError('bad TEST line: %s' % line)
test_list.append(gen_test_line(m.group(1), m.group(2),
m.group(3)))
else:
test_list.append(line)
with open(c_output, 'w') as f:
f.write(''.join(test_list))
def generate_err_table_sub(all_ulps, all_functions, fns_complex, platforms):
"""Generate a single table within the overall ulps table section."""
plat_width = [' {1000 + i 1000}' for p in platforms]
plat_header = [' @tab %s' % p for p in platforms]
table_list = ['@multitable {nexttowardf} %s\n' % ''.join(plat_width),
'@item Function %s\n' % ''.join(plat_header)]
for func in all_functions:
for flt in ALL_FLOATS_MANUAL:
func_ulps = []
for p in platforms:
p_ulps = all_ulps[p]
if fns_complex[func]:
ulp_real = p_ulps.real[func][flt]
ulp_imag = p_ulps.imag[func][flt]
ulp_str = '%d + i %d' % (ulp_real, ulp_imag)
ulp_str = ulp_str if ulp_real or ulp_imag else '-'
else:
ulp = p_ulps.normal[func][flt]
ulp_str = str(ulp) if ulp else '-'
func_ulps.append(ulp_str)
table_list.append('@item %s%s @tab %s\n'
% (func, ALL_FLOATS_SUFFIX[flt],
' @tab '.join(func_ulps)))
table_list.append('@end multitable\n')
return ''.join(table_list)
def generate_err_table(all_ulps, err_table):
"""Generate ulps table for manual."""
all_platforms = sorted(all_ulps.keys())
functions_set = set()
functions_complex = {}
for p in all_platforms:
p_functions, p_complex = all_ulps[p].all_functions()
functions_set.update(p_functions)
functions_complex.update(p_complex)
all_functions = sorted([f for f in functions_set
if ('_downward' not in f
and '_towardzero' not in f
and '_upward' not in f
and '_vlen' not in f)])
err_table_list = []
# Print five platforms at a time.
num_platforms = len(all_platforms)
for i in range((num_platforms + 4) // 5):
start = i * 5
end = i * 5 + 5 if num_platforms >= i * 5 + 5 else num_platforms
err_table_list.append(generate_err_table_sub(all_ulps, all_functions,
functions_complex,
all_platforms[start:end]))
with open(err_table, 'w') as f:
f.write(''.join(err_table_list))
def main():
"""The main entry point."""
parser = argparse.ArgumentParser(description='Generate libm tests.')
parser.add_argument('-a', dest='auto_input', metavar='FILE',
help='input file with automatically generated tests')
parser.add_argument('-c', dest='inc_input', metavar='FILE',
help='input file .inc file with tests')
parser.add_argument('-u', dest='ulps_file', metavar='FILE',
help='input file with ulps')
parser.add_argument('-s', dest='srcdir', metavar='DIR',
help='input source directory with all ulps')
parser.add_argument('-n', dest='ulps_output', metavar='FILE',
help='generate sorted ulps file FILE')
parser.add_argument('-C', dest='c_output', metavar='FILE',
help='generate output C file FILE from .inc file')
parser.add_argument('-H', dest='ulps_header', metavar='FILE',
help='generate output ulps header FILE')
parser.add_argument('-m', dest='err_table', metavar='FILE',
help='generate output ulps table for manual FILE')
args = parser.parse_args()
ulps = Ulps()
if args.ulps_file is not None:
ulps.read(args.ulps_file)
auto_tests = read_auto_tests(args.auto_input)
if args.srcdir is not None:
all_ulps = read_all_ulps(args.srcdir)
if args.ulps_output is not None:
ulps.write(args.ulps_output)
if args.ulps_header is not None:
ulps.write_header(args.ulps_header)
if args.c_output is not None:
generate_testfile(args.inc_input, auto_tests, args.c_output)
if args.err_table is not None:
generate_err_table(all_ulps, args.err_table)
if __name__ == '__main__':
main()