qemu/tests/unit/test-cutils.c

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/*
* cutils.c unit-tests
*
* Copyright (C) 2013 Red Hat Inc.
*
* Authors:
* Eduardo Habkost <ehabkost@redhat.com>
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*/
#include "qemu/osdep.h"
#include "qemu/units.h"
#include "qemu/cutils.h"
#include "qemu/units.h"
static void test_parse_uint_null(void)
{
unsigned long long i = 999;
char f = 'X';
char *endptr = &f;
int r;
r = parse_uint(NULL, &i, &endptr, 0);
g_assert_cmpint(r, ==, -EINVAL);
g_assert_cmpint(i, ==, 0);
g_assert(endptr == NULL);
}
static void test_parse_uint_empty(void)
{
unsigned long long i = 999;
char f = 'X';
char *endptr = &f;
const char *str = "";
int r;
r = parse_uint(str, &i, &endptr, 0);
g_assert_cmpint(r, ==, -EINVAL);
g_assert_cmpint(i, ==, 0);
g_assert(endptr == str);
}
static void test_parse_uint_whitespace(void)
{
unsigned long long i = 999;
char f = 'X';
char *endptr = &f;
const char *str = " \t ";
int r;
r = parse_uint(str, &i, &endptr, 0);
g_assert_cmpint(r, ==, -EINVAL);
g_assert_cmpint(i, ==, 0);
g_assert(endptr == str);
}
static void test_parse_uint_invalid(void)
{
unsigned long long i = 999;
char f = 'X';
char *endptr = &f;
const char *str = " \t xxx";
int r;
r = parse_uint(str, &i, &endptr, 0);
g_assert_cmpint(r, ==, -EINVAL);
g_assert_cmpint(i, ==, 0);
g_assert(endptr == str);
}
static void test_parse_uint_trailing(void)
{
unsigned long long i = 999;
char f = 'X';
char *endptr = &f;
const char *str = "123xxx";
int r;
r = parse_uint(str, &i, &endptr, 0);
g_assert_cmpint(r, ==, 0);
g_assert_cmpint(i, ==, 123);
g_assert(endptr == str + 3);
}
static void test_parse_uint_correct(void)
{
unsigned long long i = 999;
char f = 'X';
char *endptr = &f;
const char *str = "123";
int r;
r = parse_uint(str, &i, &endptr, 0);
g_assert_cmpint(r, ==, 0);
g_assert_cmpint(i, ==, 123);
g_assert(endptr == str + strlen(str));
}
static void test_parse_uint_octal(void)
{
unsigned long long i = 999;
char f = 'X';
char *endptr = &f;
const char *str = "0123";
int r;
r = parse_uint(str, &i, &endptr, 0);
g_assert_cmpint(r, ==, 0);
g_assert_cmpint(i, ==, 0123);
g_assert(endptr == str + strlen(str));
}
static void test_parse_uint_decimal(void)
{
unsigned long long i = 999;
char f = 'X';
char *endptr = &f;
const char *str = "0123";
int r;
r = parse_uint(str, &i, &endptr, 10);
g_assert_cmpint(r, ==, 0);
g_assert_cmpint(i, ==, 123);
g_assert(endptr == str + strlen(str));
}
static void test_parse_uint_llong_max(void)
{
unsigned long long i = 999;
char f = 'X';
char *endptr = &f;
char *str = g_strdup_printf("%llu", (unsigned long long)LLONG_MAX + 1);
int r;
r = parse_uint(str, &i, &endptr, 0);
g_assert_cmpint(r, ==, 0);
g_assert_cmpint(i, ==, (unsigned long long)LLONG_MAX + 1);
g_assert(endptr == str + strlen(str));
g_free(str);
}
static void test_parse_uint_overflow(void)
{
unsigned long long i = 999;
char f = 'X';
char *endptr = &f;
const char *str = "99999999999999999999999999999999999999";
int r;
r = parse_uint(str, &i, &endptr, 0);
g_assert_cmpint(r, ==, -ERANGE);
g_assert_cmpint(i, ==, ULLONG_MAX);
g_assert(endptr == str + strlen(str));
}
static void test_parse_uint_negative(void)
{
unsigned long long i = 999;
char f = 'X';
char *endptr = &f;
const char *str = " \t -321";
int r;
r = parse_uint(str, &i, &endptr, 0);
g_assert_cmpint(r, ==, -ERANGE);
g_assert_cmpint(i, ==, 0);
g_assert(endptr == str + strlen(str));
}
static void test_parse_uint_full_trailing(void)
{
unsigned long long i = 999;
const char *str = "123xxx";
int r;
r = parse_uint_full(str, &i, 0);
g_assert_cmpint(r, ==, -EINVAL);
g_assert_cmpint(i, ==, 0);
}
static void test_parse_uint_full_correct(void)
{
unsigned long long i = 999;
const char *str = "123";
int r;
r = parse_uint_full(str, &i, 0);
g_assert_cmpint(r, ==, 0);
g_assert_cmpint(i, ==, 123);
}
static void test_qemu_strtoi_correct(void)
{
const char *str = "12345 foo";
char f = 'X';
const char *endptr = &f;
int res = 999;
int err;
err = qemu_strtoi(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 12345);
g_assert(endptr == str + 5);
}
static void test_qemu_strtoi_null(void)
{
char f = 'X';
const char *endptr = &f;
int res = 999;
int err;
err = qemu_strtoi(NULL, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == NULL);
}
static void test_qemu_strtoi_empty(void)
{
const char *str = "";
char f = 'X';
const char *endptr = &f;
int res = 999;
int err;
err = qemu_strtoi(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == str);
}
static void test_qemu_strtoi_whitespace(void)
{
const char *str = " \t ";
char f = 'X';
const char *endptr = &f;
int res = 999;
int err;
err = qemu_strtoi(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == str);
}
static void test_qemu_strtoi_invalid(void)
{
const char *str = " xxxx \t abc";
char f = 'X';
const char *endptr = &f;
int res = 999;
int err;
err = qemu_strtoi(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == str);
}
static void test_qemu_strtoi_trailing(void)
{
const char *str = "123xxx";
char f = 'X';
const char *endptr = &f;
int res = 999;
int err;
err = qemu_strtoi(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 123);
g_assert(endptr == str + 3);
}
static void test_qemu_strtoi_octal(void)
{
const char *str = "0123";
char f = 'X';
const char *endptr = &f;
int res = 999;
int err;
err = qemu_strtoi(str, &endptr, 8, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 0123);
g_assert(endptr == str + strlen(str));
res = 999;
endptr = &f;
err = qemu_strtoi(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 0123);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtoi_decimal(void)
{
const char *str = "0123";
char f = 'X';
const char *endptr = &f;
int res = 999;
int err;
err = qemu_strtoi(str, &endptr, 10, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 123);
g_assert(endptr == str + strlen(str));
str = "123";
res = 999;
endptr = &f;
err = qemu_strtoi(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 123);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtoi_hex(void)
{
const char *str = "0123";
char f = 'X';
const char *endptr = &f;
int res = 999;
int err;
err = qemu_strtoi(str, &endptr, 16, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 0x123);
g_assert(endptr == str + strlen(str));
str = "0x123";
res = 999;
endptr = &f;
err = qemu_strtoi(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 0x123);
g_assert(endptr == str + strlen(str));
str = "0x";
res = 999;
endptr = &f;
err = qemu_strtoi(str, &endptr, 16, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 0);
g_assert(endptr == str + 1);
}
static void test_qemu_strtoi_max(void)
{
char *str = g_strdup_printf("%d", INT_MAX);
char f = 'X';
const char *endptr = &f;
int res = 999;
int err;
err = qemu_strtoi(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, INT_MAX);
g_assert(endptr == str + strlen(str));
g_free(str);
}
static void test_qemu_strtoi_overflow(void)
{
char *str = g_strdup_printf("%lld", (long long)INT_MAX + 1ll);
char f = 'X';
const char *endptr = &f;
int res = 999;
int err;
err = qemu_strtoi(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -ERANGE);
g_assert_cmpint(res, ==, INT_MAX);
g_assert(endptr == str + strlen(str));
g_free(str);
}
static void test_qemu_strtoi_underflow(void)
{
char *str = g_strdup_printf("%lld", (long long)INT_MIN - 1ll);
char f = 'X';
const char *endptr = &f;
int res = 999;
int err;
err = qemu_strtoi(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -ERANGE);
g_assert_cmpint(res, ==, INT_MIN);
g_assert(endptr == str + strlen(str));
g_free(str);
}
static void test_qemu_strtoi_negative(void)
{
const char *str = " \t -321";
char f = 'X';
const char *endptr = &f;
int res = 999;
int err;
err = qemu_strtoi(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, -321);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtoi_full_correct(void)
{
const char *str = "123";
int res = 999;
int err;
err = qemu_strtoi(str, NULL, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 123);
}
static void test_qemu_strtoi_full_null(void)
{
char f = 'X';
const char *endptr = &f;
int res = 999;
int err;
err = qemu_strtoi(NULL, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == NULL);
}
static void test_qemu_strtoi_full_empty(void)
{
const char *str = "";
int res = 999L;
int err;
err = qemu_strtoi(str, NULL, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
}
static void test_qemu_strtoi_full_negative(void)
{
const char *str = " \t -321";
int res = 999;
int err;
err = qemu_strtoi(str, NULL, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, -321);
}
static void test_qemu_strtoi_full_trailing(void)
{
const char *str = "123xxx";
int res;
int err;
err = qemu_strtoi(str, NULL, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
}
static void test_qemu_strtoi_full_max(void)
{
char *str = g_strdup_printf("%d", INT_MAX);
int res;
int err;
err = qemu_strtoi(str, NULL, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, INT_MAX);
g_free(str);
}
static void test_qemu_strtoui_correct(void)
{
const char *str = "12345 foo";
char f = 'X';
const char *endptr = &f;
unsigned int res = 999;
int err;
err = qemu_strtoui(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, 12345);
g_assert(endptr == str + 5);
}
static void test_qemu_strtoui_null(void)
{
char f = 'X';
const char *endptr = &f;
unsigned int res = 999;
int err;
err = qemu_strtoui(NULL, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == NULL);
}
static void test_qemu_strtoui_empty(void)
{
const char *str = "";
char f = 'X';
const char *endptr = &f;
unsigned int res = 999;
int err;
err = qemu_strtoui(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == str);
}
static void test_qemu_strtoui_whitespace(void)
{
const char *str = " \t ";
char f = 'X';
const char *endptr = &f;
unsigned int res = 999;
int err;
err = qemu_strtoui(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == str);
}
static void test_qemu_strtoui_invalid(void)
{
const char *str = " xxxx \t abc";
char f = 'X';
const char *endptr = &f;
unsigned int res = 999;
int err;
err = qemu_strtoui(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == str);
}
static void test_qemu_strtoui_trailing(void)
{
const char *str = "123xxx";
char f = 'X';
const char *endptr = &f;
unsigned int res = 999;
int err;
err = qemu_strtoui(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, 123);
g_assert(endptr == str + 3);
}
static void test_qemu_strtoui_octal(void)
{
const char *str = "0123";
char f = 'X';
const char *endptr = &f;
unsigned int res = 999;
int err;
err = qemu_strtoui(str, &endptr, 8, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, 0123);
g_assert(endptr == str + strlen(str));
res = 999;
endptr = &f;
err = qemu_strtoui(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, 0123);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtoui_decimal(void)
{
const char *str = "0123";
char f = 'X';
const char *endptr = &f;
unsigned int res = 999;
int err;
err = qemu_strtoui(str, &endptr, 10, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, 123);
g_assert(endptr == str + strlen(str));
str = "123";
res = 999;
endptr = &f;
err = qemu_strtoui(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, 123);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtoui_hex(void)
{
const char *str = "0123";
char f = 'X';
const char *endptr = &f;
unsigned int res = 999;
int err;
err = qemu_strtoui(str, &endptr, 16, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmphex(res, ==, 0x123);
g_assert(endptr == str + strlen(str));
str = "0x123";
res = 999;
endptr = &f;
err = qemu_strtoui(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmphex(res, ==, 0x123);
g_assert(endptr == str + strlen(str));
str = "0x";
res = 999;
endptr = &f;
err = qemu_strtoui(str, &endptr, 16, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmphex(res, ==, 0);
g_assert(endptr == str + 1);
}
static void test_qemu_strtoui_max(void)
{
char *str = g_strdup_printf("%u", UINT_MAX);
char f = 'X';
const char *endptr = &f;
unsigned int res = 999;
int err;
err = qemu_strtoui(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmphex(res, ==, UINT_MAX);
g_assert(endptr == str + strlen(str));
g_free(str);
}
static void test_qemu_strtoui_overflow(void)
{
char *str = g_strdup_printf("%lld", (long long)UINT_MAX + 1ll);
char f = 'X';
const char *endptr = &f;
unsigned int res = 999;
int err;
err = qemu_strtoui(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -ERANGE);
g_assert_cmphex(res, ==, UINT_MAX);
g_assert(endptr == str + strlen(str));
g_free(str);
}
static void test_qemu_strtoui_underflow(void)
{
char *str = g_strdup_printf("%lld", (long long)INT_MIN - 1ll);
char f = 'X';
const char *endptr = &f;
unsigned int res = 999;
int err;
err = qemu_strtoui(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -ERANGE);
g_assert_cmpuint(res, ==, (unsigned int)-1);
g_assert(endptr == str + strlen(str));
g_free(str);
}
static void test_qemu_strtoui_negative(void)
{
const char *str = " \t -321";
char f = 'X';
const char *endptr = &f;
unsigned int res = 999;
int err;
err = qemu_strtoui(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, (unsigned int)-321);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtoui_full_correct(void)
{
const char *str = "123";
unsigned int res = 999;
int err;
err = qemu_strtoui(str, NULL, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, 123);
}
static void test_qemu_strtoui_full_null(void)
{
unsigned int res = 999;
int err;
err = qemu_strtoui(NULL, NULL, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
}
static void test_qemu_strtoui_full_empty(void)
{
const char *str = "";
unsigned int res = 999;
int err;
err = qemu_strtoui(str, NULL, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
}
static void test_qemu_strtoui_full_negative(void)
{
const char *str = " \t -321";
unsigned int res = 999;
int err;
err = qemu_strtoui(str, NULL, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, (unsigned int)-321);
}
static void test_qemu_strtoui_full_trailing(void)
{
const char *str = "123xxx";
unsigned int res;
int err;
err = qemu_strtoui(str, NULL, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
}
static void test_qemu_strtoui_full_max(void)
{
char *str = g_strdup_printf("%u", UINT_MAX);
unsigned int res = 999;
int err;
err = qemu_strtoui(str, NULL, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmphex(res, ==, UINT_MAX);
g_free(str);
}
static void test_qemu_strtol_correct(void)
{
const char *str = "12345 foo";
char f = 'X';
const char *endptr = &f;
long res = 999;
int err;
err = qemu_strtol(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 12345);
g_assert(endptr == str + 5);
}
static void test_qemu_strtol_null(void)
{
char f = 'X';
const char *endptr = &f;
long res = 999;
int err;
err = qemu_strtol(NULL, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == NULL);
}
static void test_qemu_strtol_empty(void)
{
const char *str = "";
char f = 'X';
const char *endptr = &f;
long res = 999;
int err;
err = qemu_strtol(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == str);
}
static void test_qemu_strtol_whitespace(void)
{
const char *str = " \t ";
char f = 'X';
const char *endptr = &f;
long res = 999;
int err;
err = qemu_strtol(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == str);
}
static void test_qemu_strtol_invalid(void)
{
const char *str = " xxxx \t abc";
char f = 'X';
const char *endptr = &f;
long res = 999;
int err;
err = qemu_strtol(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == str);
}
static void test_qemu_strtol_trailing(void)
{
const char *str = "123xxx";
char f = 'X';
const char *endptr = &f;
long res = 999;
int err;
err = qemu_strtol(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 123);
g_assert(endptr == str + 3);
}
static void test_qemu_strtol_octal(void)
{
const char *str = "0123";
char f = 'X';
const char *endptr = &f;
long res = 999;
int err;
err = qemu_strtol(str, &endptr, 8, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 0123);
g_assert(endptr == str + strlen(str));
res = 999;
endptr = &f;
err = qemu_strtol(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 0123);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtol_decimal(void)
{
const char *str = "0123";
char f = 'X';
const char *endptr = &f;
long res = 999;
int err;
err = qemu_strtol(str, &endptr, 10, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 123);
g_assert(endptr == str + strlen(str));
str = "123";
res = 999;
endptr = &f;
err = qemu_strtol(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 123);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtol_hex(void)
{
const char *str = "0123";
char f = 'X';
const char *endptr = &f;
long res = 999;
int err;
err = qemu_strtol(str, &endptr, 16, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 0x123);
g_assert(endptr == str + strlen(str));
str = "0x123";
res = 999;
endptr = &f;
err = qemu_strtol(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 0x123);
g_assert(endptr == str + strlen(str));
str = "0x";
res = 999;
endptr = &f;
err = qemu_strtol(str, &endptr, 16, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 0);
g_assert(endptr == str + 1);
}
static void test_qemu_strtol_max(void)
{
char *str = g_strdup_printf("%ld", LONG_MAX);
char f = 'X';
const char *endptr = &f;
long res = 999;
int err;
err = qemu_strtol(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, LONG_MAX);
g_assert(endptr == str + strlen(str));
g_free(str);
}
static void test_qemu_strtol_overflow(void)
{
const char *str = "99999999999999999999999999999999999999999999";
char f = 'X';
const char *endptr = &f;
long res = 999;
int err;
err = qemu_strtol(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -ERANGE);
g_assert_cmpint(res, ==, LONG_MAX);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtol_underflow(void)
{
const char *str = "-99999999999999999999999999999999999999999999";
char f = 'X';
const char *endptr = &f;
long res = 999;
int err;
err = qemu_strtol(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -ERANGE);
g_assert_cmpint(res, ==, LONG_MIN);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtol_negative(void)
{
const char *str = " \t -321";
char f = 'X';
const char *endptr = &f;
long res = 999;
int err;
err = qemu_strtol(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, -321);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtol_full_correct(void)
{
const char *str = "123";
long res = 999;
int err;
err = qemu_strtol(str, NULL, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 123);
}
static void test_qemu_strtol_full_null(void)
{
char f = 'X';
const char *endptr = &f;
long res = 999;
int err;
err = qemu_strtol(NULL, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == NULL);
}
static void test_qemu_strtol_full_empty(void)
{
const char *str = "";
long res = 999L;
int err;
err = qemu_strtol(str, NULL, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
}
static void test_qemu_strtol_full_negative(void)
{
const char *str = " \t -321";
long res = 999;
int err;
err = qemu_strtol(str, NULL, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, -321);
}
static void test_qemu_strtol_full_trailing(void)
{
const char *str = "123xxx";
long res;
int err;
err = qemu_strtol(str, NULL, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
}
static void test_qemu_strtol_full_max(void)
{
char *str = g_strdup_printf("%ld", LONG_MAX);
long res;
int err;
err = qemu_strtol(str, NULL, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, LONG_MAX);
g_free(str);
}
static void test_qemu_strtoul_correct(void)
{
const char *str = "12345 foo";
char f = 'X';
const char *endptr = &f;
unsigned long res = 999;
int err;
err = qemu_strtoul(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, 12345);
g_assert(endptr == str + 5);
}
static void test_qemu_strtoul_null(void)
{
char f = 'X';
const char *endptr = &f;
unsigned long res = 999;
int err;
err = qemu_strtoul(NULL, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == NULL);
}
static void test_qemu_strtoul_empty(void)
{
const char *str = "";
char f = 'X';
const char *endptr = &f;
unsigned long res = 999;
int err;
err = qemu_strtoul(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == str);
}
static void test_qemu_strtoul_whitespace(void)
{
const char *str = " \t ";
char f = 'X';
const char *endptr = &f;
unsigned long res = 999;
int err;
err = qemu_strtoul(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == str);
}
static void test_qemu_strtoul_invalid(void)
{
const char *str = " xxxx \t abc";
char f = 'X';
const char *endptr = &f;
unsigned long res = 999;
int err;
err = qemu_strtoul(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == str);
}
static void test_qemu_strtoul_trailing(void)
{
const char *str = "123xxx";
char f = 'X';
const char *endptr = &f;
unsigned long res = 999;
int err;
err = qemu_strtoul(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, 123);
g_assert(endptr == str + 3);
}
static void test_qemu_strtoul_octal(void)
{
const char *str = "0123";
char f = 'X';
const char *endptr = &f;
unsigned long res = 999;
int err;
err = qemu_strtoul(str, &endptr, 8, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, 0123);
g_assert(endptr == str + strlen(str));
res = 999;
endptr = &f;
err = qemu_strtoul(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, 0123);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtoul_decimal(void)
{
const char *str = "0123";
char f = 'X';
const char *endptr = &f;
unsigned long res = 999;
int err;
err = qemu_strtoul(str, &endptr, 10, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, 123);
g_assert(endptr == str + strlen(str));
str = "123";
res = 999;
endptr = &f;
err = qemu_strtoul(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, 123);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtoul_hex(void)
{
const char *str = "0123";
char f = 'X';
const char *endptr = &f;
unsigned long res = 999;
int err;
err = qemu_strtoul(str, &endptr, 16, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmphex(res, ==, 0x123);
g_assert(endptr == str + strlen(str));
str = "0x123";
res = 999;
endptr = &f;
err = qemu_strtoul(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmphex(res, ==, 0x123);
g_assert(endptr == str + strlen(str));
str = "0x";
res = 999;
endptr = &f;
err = qemu_strtoul(str, &endptr, 16, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmphex(res, ==, 0);
g_assert(endptr == str + 1);
}
static void test_qemu_strtoul_max(void)
{
char *str = g_strdup_printf("%lu", ULONG_MAX);
char f = 'X';
const char *endptr = &f;
unsigned long res = 999;
int err;
err = qemu_strtoul(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmphex(res, ==, ULONG_MAX);
g_assert(endptr == str + strlen(str));
g_free(str);
}
static void test_qemu_strtoul_overflow(void)
{
const char *str = "99999999999999999999999999999999999999999999";
char f = 'X';
const char *endptr = &f;
unsigned long res = 999;
int err;
err = qemu_strtoul(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -ERANGE);
g_assert_cmphex(res, ==, ULONG_MAX);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtoul_underflow(void)
{
const char *str = "-99999999999999999999999999999999999999999999";
char f = 'X';
const char *endptr = &f;
unsigned long res = 999;
int err;
err = qemu_strtoul(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -ERANGE);
g_assert_cmpuint(res, ==, -1ul);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtoul_negative(void)
{
const char *str = " \t -321";
char f = 'X';
const char *endptr = &f;
unsigned long res = 999;
int err;
err = qemu_strtoul(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, -321ul);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtoul_full_correct(void)
{
const char *str = "123";
unsigned long res = 999;
int err;
err = qemu_strtoul(str, NULL, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, 123);
}
static void test_qemu_strtoul_full_null(void)
{
unsigned long res = 999;
int err;
err = qemu_strtoul(NULL, NULL, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
}
static void test_qemu_strtoul_full_empty(void)
{
const char *str = "";
unsigned long res = 999;
int err;
err = qemu_strtoul(str, NULL, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
}
static void test_qemu_strtoul_full_negative(void)
{
const char *str = " \t -321";
unsigned long res = 999;
int err;
err = qemu_strtoul(str, NULL, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, -321ul);
}
static void test_qemu_strtoul_full_trailing(void)
{
const char *str = "123xxx";
unsigned long res;
int err;
err = qemu_strtoul(str, NULL, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
}
static void test_qemu_strtoul_full_max(void)
{
char *str = g_strdup_printf("%lu", ULONG_MAX);
unsigned long res = 999;
int err;
err = qemu_strtoul(str, NULL, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmphex(res, ==, ULONG_MAX);
g_free(str);
}
static void test_qemu_strtoi64_correct(void)
{
const char *str = "12345 foo";
char f = 'X';
const char *endptr = &f;
int64_t res = 999;
int err;
err = qemu_strtoi64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 12345);
g_assert(endptr == str + 5);
}
static void test_qemu_strtoi64_null(void)
{
char f = 'X';
const char *endptr = &f;
int64_t res = 999;
int err;
err = qemu_strtoi64(NULL, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == NULL);
}
static void test_qemu_strtoi64_empty(void)
{
const char *str = "";
char f = 'X';
const char *endptr = &f;
int64_t res = 999;
int err;
err = qemu_strtoi64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == str);
}
static void test_qemu_strtoi64_whitespace(void)
{
const char *str = " \t ";
char f = 'X';
const char *endptr = &f;
int64_t res = 999;
int err;
err = qemu_strtoi64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == str);
}
static void test_qemu_strtoi64_invalid(void)
{
const char *str = " xxxx \t abc";
char f = 'X';
const char *endptr = &f;
int64_t res = 999;
int err;
err = qemu_strtoi64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == str);
}
static void test_qemu_strtoi64_trailing(void)
{
const char *str = "123xxx";
char f = 'X';
const char *endptr = &f;
int64_t res = 999;
int err;
err = qemu_strtoi64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 123);
g_assert(endptr == str + 3);
}
static void test_qemu_strtoi64_octal(void)
{
const char *str = "0123";
char f = 'X';
const char *endptr = &f;
int64_t res = 999;
int err;
err = qemu_strtoi64(str, &endptr, 8, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 0123);
g_assert(endptr == str + strlen(str));
endptr = &f;
res = 999;
err = qemu_strtoi64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 0123);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtoi64_decimal(void)
{
const char *str = "0123";
char f = 'X';
const char *endptr = &f;
int64_t res = 999;
int err;
err = qemu_strtoi64(str, &endptr, 10, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 123);
g_assert(endptr == str + strlen(str));
str = "123";
endptr = &f;
res = 999;
err = qemu_strtoi64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 123);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtoi64_hex(void)
{
const char *str = "0123";
char f = 'X';
const char *endptr = &f;
int64_t res = 999;
int err;
err = qemu_strtoi64(str, &endptr, 16, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 0x123);
g_assert(endptr == str + strlen(str));
str = "0x123";
endptr = &f;
res = 999;
err = qemu_strtoi64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 0x123);
g_assert(endptr == str + strlen(str));
str = "0x";
endptr = &f;
res = 999;
err = qemu_strtoi64(str, &endptr, 16, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 0);
g_assert(endptr == str + 1);
}
static void test_qemu_strtoi64_max(void)
{
char *str = g_strdup_printf("%lld", LLONG_MAX);
char f = 'X';
const char *endptr = &f;
int64_t res = 999;
int err;
err = qemu_strtoi64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, LLONG_MAX);
g_assert(endptr == str + strlen(str));
g_free(str);
}
static void test_qemu_strtoi64_overflow(void)
{
const char *str = "99999999999999999999999999999999999999999999";
char f = 'X';
const char *endptr = &f;
int64_t res = 999;
int err;
err = qemu_strtoi64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -ERANGE);
g_assert_cmpint(res, ==, LLONG_MAX);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtoi64_underflow(void)
{
const char *str = "-99999999999999999999999999999999999999999999";
char f = 'X';
const char *endptr = &f;
int64_t res = 999;
int err;
err = qemu_strtoi64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -ERANGE);
g_assert_cmpint(res, ==, LLONG_MIN);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtoi64_negative(void)
{
const char *str = " \t -321";
char f = 'X';
const char *endptr = &f;
int64_t res = 999;
int err;
err = qemu_strtoi64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, -321);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtoi64_full_correct(void)
{
const char *str = "123";
int64_t res = 999;
int err;
err = qemu_strtoi64(str, NULL, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 123);
}
static void test_qemu_strtoi64_full_null(void)
{
int64_t res = 999;
int err;
err = qemu_strtoi64(NULL, NULL, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
}
static void test_qemu_strtoi64_full_empty(void)
{
const char *str = "";
int64_t res = 999;
int err;
err = qemu_strtoi64(str, NULL, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
}
static void test_qemu_strtoi64_full_negative(void)
{
const char *str = " \t -321";
int64_t res = 999;
int err;
err = qemu_strtoi64(str, NULL, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, -321);
}
static void test_qemu_strtoi64_full_trailing(void)
{
const char *str = "123xxx";
int64_t res = 999;
int err;
err = qemu_strtoi64(str, NULL, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
}
static void test_qemu_strtoi64_full_max(void)
{
char *str = g_strdup_printf("%lld", LLONG_MAX);
int64_t res;
int err;
err = qemu_strtoi64(str, NULL, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, LLONG_MAX);
g_free(str);
}
static void test_qemu_strtou64_correct(void)
{
const char *str = "12345 foo";
char f = 'X';
const char *endptr = &f;
uint64_t res = 999;
int err;
err = qemu_strtou64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, 12345);
g_assert(endptr == str + 5);
}
static void test_qemu_strtou64_null(void)
{
char f = 'X';
const char *endptr = &f;
uint64_t res = 999;
int err;
err = qemu_strtou64(NULL, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == NULL);
}
static void test_qemu_strtou64_empty(void)
{
const char *str = "";
char f = 'X';
const char *endptr = &f;
uint64_t res = 999;
int err;
err = qemu_strtou64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == str);
}
static void test_qemu_strtou64_whitespace(void)
{
const char *str = " \t ";
char f = 'X';
const char *endptr = &f;
uint64_t res = 999;
int err;
err = qemu_strtou64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == str);
}
static void test_qemu_strtou64_invalid(void)
{
const char *str = " xxxx \t abc";
char f = 'X';
const char *endptr = &f;
uint64_t res = 999;
int err;
err = qemu_strtou64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert(endptr == str);
}
static void test_qemu_strtou64_trailing(void)
{
const char *str = "123xxx";
char f = 'X';
const char *endptr = &f;
uint64_t res = 999;
int err;
err = qemu_strtou64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, 123);
g_assert(endptr == str + 3);
}
static void test_qemu_strtou64_octal(void)
{
const char *str = "0123";
char f = 'X';
const char *endptr = &f;
uint64_t res = 999;
int err;
err = qemu_strtou64(str, &endptr, 8, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, 0123);
g_assert(endptr == str + strlen(str));
endptr = &f;
res = 999;
err = qemu_strtou64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, 0123);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtou64_decimal(void)
{
const char *str = "0123";
char f = 'X';
const char *endptr = &f;
uint64_t res = 999;
int err;
err = qemu_strtou64(str, &endptr, 10, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, 123);
g_assert(endptr == str + strlen(str));
str = "123";
endptr = &f;
res = 999;
err = qemu_strtou64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, 123);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtou64_hex(void)
{
const char *str = "0123";
char f = 'X';
const char *endptr = &f;
uint64_t res = 999;
int err;
err = qemu_strtou64(str, &endptr, 16, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmphex(res, ==, 0x123);
g_assert(endptr == str + strlen(str));
str = "0x123";
endptr = &f;
res = 999;
err = qemu_strtou64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmphex(res, ==, 0x123);
g_assert(endptr == str + strlen(str));
str = "0x";
endptr = &f;
res = 999;
err = qemu_strtou64(str, &endptr, 16, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmphex(res, ==, 0);
g_assert(endptr == str + 1);
}
static void test_qemu_strtou64_max(void)
{
char *str = g_strdup_printf("%llu", ULLONG_MAX);
char f = 'X';
const char *endptr = &f;
uint64_t res = 999;
int err;
err = qemu_strtou64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmphex(res, ==, ULLONG_MAX);
g_assert(endptr == str + strlen(str));
g_free(str);
}
static void test_qemu_strtou64_overflow(void)
{
const char *str = "99999999999999999999999999999999999999999999";
char f = 'X';
const char *endptr = &f;
uint64_t res = 999;
int err;
err = qemu_strtou64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -ERANGE);
g_assert_cmphex(res, ==, ULLONG_MAX);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtou64_underflow(void)
{
const char *str = "-99999999999999999999999999999999999999999999";
char f = 'X';
const char *endptr = &f;
uint64_t res = 999;
int err;
err = qemu_strtou64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, -ERANGE);
g_assert_cmphex(res, ==, -1ull);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtou64_negative(void)
{
const char *str = " \t -321";
char f = 'X';
const char *endptr = &f;
uint64_t res = 999;
int err;
err = qemu_strtou64(str, &endptr, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, -321ull);
g_assert(endptr == str + strlen(str));
}
static void test_qemu_strtou64_full_correct(void)
{
const char *str = "18446744073709551614";
uint64_t res = 999;
int err;
err = qemu_strtou64(str, NULL, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, 18446744073709551614ull);
}
static void test_qemu_strtou64_full_null(void)
{
uint64_t res = 999;
int err;
err = qemu_strtou64(NULL, NULL, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
}
static void test_qemu_strtou64_full_empty(void)
{
const char *str = "";
uint64_t res = 999;
int err;
err = qemu_strtou64(str, NULL, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
}
static void test_qemu_strtou64_full_negative(void)
{
const char *str = " \t -321";
uint64_t res = 999;
int err;
err = qemu_strtou64(str, NULL, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpuint(res, ==, -321ull);
}
static void test_qemu_strtou64_full_trailing(void)
{
const char *str = "18446744073709551614xxxxxx";
uint64_t res = 999;
int err;
err = qemu_strtou64(str, NULL, 0, &res);
g_assert_cmpint(err, ==, -EINVAL);
}
static void test_qemu_strtou64_full_max(void)
{
char *str = g_strdup_printf("%lld", ULLONG_MAX);
uint64_t res = 999;
int err;
err = qemu_strtou64(str, NULL, 0, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmphex(res, ==, ULLONG_MAX);
g_free(str);
}
static void test_qemu_strtosz_simple(void)
{
const char *str;
const char *endptr;
int err;
uint64_t res;
str = "0";
endptr = str;
res = 0xbaadf00d;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 0);
g_assert(endptr == str + 1);
/* Leading 0 gives decimal results, not octal */
str = "08";
endptr = str;
res = 0xbaadf00d;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 8);
g_assert(endptr == str + 2);
/* Leading space is ignored */
str = " 12345";
endptr = str;
res = 0xbaadf00d;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 12345);
g_assert(endptr == str + 6);
res = 0xbaadf00d;
err = qemu_strtosz(str, NULL, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 12345);
str = "9007199254740991"; /* 2^53-1 */
endptr = str;
res = 0xbaadf00d;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 0x1fffffffffffff);
g_assert(endptr == str + 16);
str = "9007199254740992"; /* 2^53 */
endptr = str;
res = 0xbaadf00d;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 0x20000000000000);
g_assert(endptr == str + 16);
utils: Improve qemu_strtosz() to have 64 bits of precision We have multiple clients of qemu_strtosz (qemu-io, the opts visitor, the keyval visitor), and it gets annoying that edge-case testing is impacted by implicit rounding to 53 bits of precision due to parsing with strtod(). As an example posted by Rich Jones: $ nbdkit memory $(( 2**63 - 2**30 )) --run \ 'build/qemu-io -f raw "$uri" -c "w -P 3 $(( 2**63 - 2**30 - 512 )) 512" ' write failed: Input/output error because 9223372035781033472 got rounded to 0x7fffffffc0000000 which is out of bounds. It is also worth noting that our existing parser, by virtue of using strtod(), accepts decimal AND hex numbers, even though test-cutils previously lacked any coverage of the latter until the previous patch. We do have existing clients that expect a hex parse to work (for example, iotest 33 using qemu-io -c "write -P 0xa 0x200 0x400"), but strtod() parses "08" as 8 rather than as an invalid octal number, so we know there are no clients that depend on octal. Our use of strtod() also means that "0x1.8k" would actually parse as 1536 (the fraction is 8/16), rather than 1843 (if the fraction were 8/10); but as this was not covered in the testsuite, I have no qualms forbidding hex fractions as invalid, so this patch declares that the use of fractions is only supported with decimal input, and enhances the testsuite to document that. Our previous use of strtod() meant that -1 parsed as a negative; now that we parse with strtoull(), negative values can wrap around modulo 2^64, so we have to explicitly check whether the user passed in a '-'; and make it consistent to also reject '-0'. This has the minor effect of treating negative values as EINVAL (with no change to endptr) rather than ERANGE (with endptr advanced to what was parsed), visible in the updated iotest output. We also had no testsuite coverage of "1.1e0k", which happened to parse under strtod() but is unlikely to occur in practice; as long as we are making things more robust, it is easy enough to reject the use of exponents in a strtod parse. The fix is done by breaking the parse into an integer prefix (no loss in precision), rejecting negative values (since we can no longer rely on strtod() to do that), determining if a decimal or hexadecimal parse was intended (with the new restriction that a fractional hex parse is not allowed), and where appropriate, using a floating point fractional parse (where we also scan to reject use of exponents in the fraction). The bulk of the patch is then updates to the testsuite to match our new precision, as well as adding new cases we reject (whether they were rejected or inadvertently accepted before). Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <20210211204438.1184395-3-eblake@redhat.com> Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
2021-02-11 23:44:36 +03:00
str = "9007199254740993"; /* 2^53+1 */
endptr = str;
res = 0xbaadf00d;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, 0);
utils: Improve qemu_strtosz() to have 64 bits of precision We have multiple clients of qemu_strtosz (qemu-io, the opts visitor, the keyval visitor), and it gets annoying that edge-case testing is impacted by implicit rounding to 53 bits of precision due to parsing with strtod(). As an example posted by Rich Jones: $ nbdkit memory $(( 2**63 - 2**30 )) --run \ 'build/qemu-io -f raw "$uri" -c "w -P 3 $(( 2**63 - 2**30 - 512 )) 512" ' write failed: Input/output error because 9223372035781033472 got rounded to 0x7fffffffc0000000 which is out of bounds. It is also worth noting that our existing parser, by virtue of using strtod(), accepts decimal AND hex numbers, even though test-cutils previously lacked any coverage of the latter until the previous patch. We do have existing clients that expect a hex parse to work (for example, iotest 33 using qemu-io -c "write -P 0xa 0x200 0x400"), but strtod() parses "08" as 8 rather than as an invalid octal number, so we know there are no clients that depend on octal. Our use of strtod() also means that "0x1.8k" would actually parse as 1536 (the fraction is 8/16), rather than 1843 (if the fraction were 8/10); but as this was not covered in the testsuite, I have no qualms forbidding hex fractions as invalid, so this patch declares that the use of fractions is only supported with decimal input, and enhances the testsuite to document that. Our previous use of strtod() meant that -1 parsed as a negative; now that we parse with strtoull(), negative values can wrap around modulo 2^64, so we have to explicitly check whether the user passed in a '-'; and make it consistent to also reject '-0'. This has the minor effect of treating negative values as EINVAL (with no change to endptr) rather than ERANGE (with endptr advanced to what was parsed), visible in the updated iotest output. We also had no testsuite coverage of "1.1e0k", which happened to parse under strtod() but is unlikely to occur in practice; as long as we are making things more robust, it is easy enough to reject the use of exponents in a strtod parse. The fix is done by breaking the parse into an integer prefix (no loss in precision), rejecting negative values (since we can no longer rely on strtod() to do that), determining if a decimal or hexadecimal parse was intended (with the new restriction that a fractional hex parse is not allowed), and where appropriate, using a floating point fractional parse (where we also scan to reject use of exponents in the fraction). The bulk of the patch is then updates to the testsuite to match our new precision, as well as adding new cases we reject (whether they were rejected or inadvertently accepted before). Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <20210211204438.1184395-3-eblake@redhat.com> Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
2021-02-11 23:44:36 +03:00
g_assert_cmpint(res, ==, 0x20000000000001);
g_assert(endptr == str + 16);
str = "18446744073709549568"; /* 0xfffffffffffff800 (53 msbs set) */
endptr = str;
res = 0xbaadf00d;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 0xfffffffffffff800);
g_assert(endptr == str + 20);
utils: Improve qemu_strtosz() to have 64 bits of precision We have multiple clients of qemu_strtosz (qemu-io, the opts visitor, the keyval visitor), and it gets annoying that edge-case testing is impacted by implicit rounding to 53 bits of precision due to parsing with strtod(). As an example posted by Rich Jones: $ nbdkit memory $(( 2**63 - 2**30 )) --run \ 'build/qemu-io -f raw "$uri" -c "w -P 3 $(( 2**63 - 2**30 - 512 )) 512" ' write failed: Input/output error because 9223372035781033472 got rounded to 0x7fffffffc0000000 which is out of bounds. It is also worth noting that our existing parser, by virtue of using strtod(), accepts decimal AND hex numbers, even though test-cutils previously lacked any coverage of the latter until the previous patch. We do have existing clients that expect a hex parse to work (for example, iotest 33 using qemu-io -c "write -P 0xa 0x200 0x400"), but strtod() parses "08" as 8 rather than as an invalid octal number, so we know there are no clients that depend on octal. Our use of strtod() also means that "0x1.8k" would actually parse as 1536 (the fraction is 8/16), rather than 1843 (if the fraction were 8/10); but as this was not covered in the testsuite, I have no qualms forbidding hex fractions as invalid, so this patch declares that the use of fractions is only supported with decimal input, and enhances the testsuite to document that. Our previous use of strtod() meant that -1 parsed as a negative; now that we parse with strtoull(), negative values can wrap around modulo 2^64, so we have to explicitly check whether the user passed in a '-'; and make it consistent to also reject '-0'. This has the minor effect of treating negative values as EINVAL (with no change to endptr) rather than ERANGE (with endptr advanced to what was parsed), visible in the updated iotest output. We also had no testsuite coverage of "1.1e0k", which happened to parse under strtod() but is unlikely to occur in practice; as long as we are making things more robust, it is easy enough to reject the use of exponents in a strtod parse. The fix is done by breaking the parse into an integer prefix (no loss in precision), rejecting negative values (since we can no longer rely on strtod() to do that), determining if a decimal or hexadecimal parse was intended (with the new restriction that a fractional hex parse is not allowed), and where appropriate, using a floating point fractional parse (where we also scan to reject use of exponents in the fraction). The bulk of the patch is then updates to the testsuite to match our new precision, as well as adding new cases we reject (whether they were rejected or inadvertently accepted before). Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <20210211204438.1184395-3-eblake@redhat.com> Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
2021-02-11 23:44:36 +03:00
str = "18446744073709550591"; /* 0xfffffffffffffbff */
endptr = str;
res = 0xbaadf00d;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, 0);
utils: Improve qemu_strtosz() to have 64 bits of precision We have multiple clients of qemu_strtosz (qemu-io, the opts visitor, the keyval visitor), and it gets annoying that edge-case testing is impacted by implicit rounding to 53 bits of precision due to parsing with strtod(). As an example posted by Rich Jones: $ nbdkit memory $(( 2**63 - 2**30 )) --run \ 'build/qemu-io -f raw "$uri" -c "w -P 3 $(( 2**63 - 2**30 - 512 )) 512" ' write failed: Input/output error because 9223372035781033472 got rounded to 0x7fffffffc0000000 which is out of bounds. It is also worth noting that our existing parser, by virtue of using strtod(), accepts decimal AND hex numbers, even though test-cutils previously lacked any coverage of the latter until the previous patch. We do have existing clients that expect a hex parse to work (for example, iotest 33 using qemu-io -c "write -P 0xa 0x200 0x400"), but strtod() parses "08" as 8 rather than as an invalid octal number, so we know there are no clients that depend on octal. Our use of strtod() also means that "0x1.8k" would actually parse as 1536 (the fraction is 8/16), rather than 1843 (if the fraction were 8/10); but as this was not covered in the testsuite, I have no qualms forbidding hex fractions as invalid, so this patch declares that the use of fractions is only supported with decimal input, and enhances the testsuite to document that. Our previous use of strtod() meant that -1 parsed as a negative; now that we parse with strtoull(), negative values can wrap around modulo 2^64, so we have to explicitly check whether the user passed in a '-'; and make it consistent to also reject '-0'. This has the minor effect of treating negative values as EINVAL (with no change to endptr) rather than ERANGE (with endptr advanced to what was parsed), visible in the updated iotest output. We also had no testsuite coverage of "1.1e0k", which happened to parse under strtod() but is unlikely to occur in practice; as long as we are making things more robust, it is easy enough to reject the use of exponents in a strtod parse. The fix is done by breaking the parse into an integer prefix (no loss in precision), rejecting negative values (since we can no longer rely on strtod() to do that), determining if a decimal or hexadecimal parse was intended (with the new restriction that a fractional hex parse is not allowed), and where appropriate, using a floating point fractional parse (where we also scan to reject use of exponents in the fraction). The bulk of the patch is then updates to the testsuite to match our new precision, as well as adding new cases we reject (whether they were rejected or inadvertently accepted before). Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <20210211204438.1184395-3-eblake@redhat.com> Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
2021-02-11 23:44:36 +03:00
g_assert_cmpint(res, ==, 0xfffffffffffffbff);
g_assert(endptr == str + 20);
utils: Improve qemu_strtosz() to have 64 bits of precision We have multiple clients of qemu_strtosz (qemu-io, the opts visitor, the keyval visitor), and it gets annoying that edge-case testing is impacted by implicit rounding to 53 bits of precision due to parsing with strtod(). As an example posted by Rich Jones: $ nbdkit memory $(( 2**63 - 2**30 )) --run \ 'build/qemu-io -f raw "$uri" -c "w -P 3 $(( 2**63 - 2**30 - 512 )) 512" ' write failed: Input/output error because 9223372035781033472 got rounded to 0x7fffffffc0000000 which is out of bounds. It is also worth noting that our existing parser, by virtue of using strtod(), accepts decimal AND hex numbers, even though test-cutils previously lacked any coverage of the latter until the previous patch. We do have existing clients that expect a hex parse to work (for example, iotest 33 using qemu-io -c "write -P 0xa 0x200 0x400"), but strtod() parses "08" as 8 rather than as an invalid octal number, so we know there are no clients that depend on octal. Our use of strtod() also means that "0x1.8k" would actually parse as 1536 (the fraction is 8/16), rather than 1843 (if the fraction were 8/10); but as this was not covered in the testsuite, I have no qualms forbidding hex fractions as invalid, so this patch declares that the use of fractions is only supported with decimal input, and enhances the testsuite to document that. Our previous use of strtod() meant that -1 parsed as a negative; now that we parse with strtoull(), negative values can wrap around modulo 2^64, so we have to explicitly check whether the user passed in a '-'; and make it consistent to also reject '-0'. This has the minor effect of treating negative values as EINVAL (with no change to endptr) rather than ERANGE (with endptr advanced to what was parsed), visible in the updated iotest output. We also had no testsuite coverage of "1.1e0k", which happened to parse under strtod() but is unlikely to occur in practice; as long as we are making things more robust, it is easy enough to reject the use of exponents in a strtod parse. The fix is done by breaking the parse into an integer prefix (no loss in precision), rejecting negative values (since we can no longer rely on strtod() to do that), determining if a decimal or hexadecimal parse was intended (with the new restriction that a fractional hex parse is not allowed), and where appropriate, using a floating point fractional parse (where we also scan to reject use of exponents in the fraction). The bulk of the patch is then updates to the testsuite to match our new precision, as well as adding new cases we reject (whether they were rejected or inadvertently accepted before). Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <20210211204438.1184395-3-eblake@redhat.com> Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
2021-02-11 23:44:36 +03:00
str = "18446744073709551615"; /* 0xffffffffffffffff */
endptr = str;
res = 0xbaadf00d;
utils: Improve qemu_strtosz() to have 64 bits of precision We have multiple clients of qemu_strtosz (qemu-io, the opts visitor, the keyval visitor), and it gets annoying that edge-case testing is impacted by implicit rounding to 53 bits of precision due to parsing with strtod(). As an example posted by Rich Jones: $ nbdkit memory $(( 2**63 - 2**30 )) --run \ 'build/qemu-io -f raw "$uri" -c "w -P 3 $(( 2**63 - 2**30 - 512 )) 512" ' write failed: Input/output error because 9223372035781033472 got rounded to 0x7fffffffc0000000 which is out of bounds. It is also worth noting that our existing parser, by virtue of using strtod(), accepts decimal AND hex numbers, even though test-cutils previously lacked any coverage of the latter until the previous patch. We do have existing clients that expect a hex parse to work (for example, iotest 33 using qemu-io -c "write -P 0xa 0x200 0x400"), but strtod() parses "08" as 8 rather than as an invalid octal number, so we know there are no clients that depend on octal. Our use of strtod() also means that "0x1.8k" would actually parse as 1536 (the fraction is 8/16), rather than 1843 (if the fraction were 8/10); but as this was not covered in the testsuite, I have no qualms forbidding hex fractions as invalid, so this patch declares that the use of fractions is only supported with decimal input, and enhances the testsuite to document that. Our previous use of strtod() meant that -1 parsed as a negative; now that we parse with strtoull(), negative values can wrap around modulo 2^64, so we have to explicitly check whether the user passed in a '-'; and make it consistent to also reject '-0'. This has the minor effect of treating negative values as EINVAL (with no change to endptr) rather than ERANGE (with endptr advanced to what was parsed), visible in the updated iotest output. We also had no testsuite coverage of "1.1e0k", which happened to parse under strtod() but is unlikely to occur in practice; as long as we are making things more robust, it is easy enough to reject the use of exponents in a strtod parse. The fix is done by breaking the parse into an integer prefix (no loss in precision), rejecting negative values (since we can no longer rely on strtod() to do that), determining if a decimal or hexadecimal parse was intended (with the new restriction that a fractional hex parse is not allowed), and where appropriate, using a floating point fractional parse (where we also scan to reject use of exponents in the fraction). The bulk of the patch is then updates to the testsuite to match our new precision, as well as adding new cases we reject (whether they were rejected or inadvertently accepted before). Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <20210211204438.1184395-3-eblake@redhat.com> Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
2021-02-11 23:44:36 +03:00
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 0xffffffffffffffff);
g_assert(endptr == str + 20);
}
static void test_qemu_strtosz_hex(void)
{
const char *str;
const char *endptr;
int err;
uint64_t res;
str = "0x0";
endptr = str;
res = 0xbaadf00d;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 0);
g_assert(endptr == str + 3);
str = "0xab";
endptr = str;
res = 0xbaadf00d;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 171);
g_assert(endptr == str + 4);
str = "0xae";
endptr = str;
res = 0xbaadf00d;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 174);
g_assert(endptr == str + 4);
}
static void test_qemu_strtosz_units(void)
{
const char *none = "1";
const char *b = "1B";
const char *k = "1K";
const char *m = "1M";
const char *g = "1G";
const char *t = "1T";
const char *p = "1P";
const char *e = "1E";
int err;
const char *endptr;
uint64_t res;
/* default is M */
endptr = NULL;
res = 0xbaadf00d;
err = qemu_strtosz_MiB(none, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, MiB);
g_assert(endptr == none + 1);
endptr = NULL;
res = 0xbaadf00d;
err = qemu_strtosz(b, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 1);
g_assert(endptr == b + 2);
endptr = NULL;
res = 0xbaadf00d;
err = qemu_strtosz(k, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, KiB);
g_assert(endptr == k + 2);
endptr = NULL;
res = 0xbaadf00d;
err = qemu_strtosz(m, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, MiB);
g_assert(endptr == m + 2);
endptr = NULL;
res = 0xbaadf00d;
err = qemu_strtosz(g, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, GiB);
g_assert(endptr == g + 2);
endptr = NULL;
res = 0xbaadf00d;
err = qemu_strtosz(t, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, TiB);
g_assert(endptr == t + 2);
endptr = NULL;
res = 0xbaadf00d;
err = qemu_strtosz(p, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, PiB);
g_assert(endptr == p + 2);
endptr = NULL;
res = 0xbaadf00d;
err = qemu_strtosz(e, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, EiB);
g_assert(endptr == e + 2);
}
static void test_qemu_strtosz_float(void)
{
const char *str;
int err;
const char *endptr;
uint64_t res;
str = "0.5E";
endptr = str;
res = 0xbaadf00d;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, EiB / 2);
g_assert(endptr == str + 4);
/* For convenience, a fraction of 0 is tolerated even on bytes */
str = "1.0B";
endptr = str;
res = 0xbaadf00d;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 1);
g_assert(endptr == str + 4);
/* An empty fraction is tolerated */
str = "1.k";
endptr = str;
res = 0xbaadf00d;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 1024);
g_assert(endptr == str + 3);
/* For convenience, we permit values that are not byte-exact */
str = "12.345M";
endptr = str;
res = 0xbaadf00d;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, (uint64_t) (12.345 * MiB + 0.5));
g_assert(endptr == str + 7);
}
static void test_qemu_strtosz_invalid(void)
{
const char *str;
const char *endptr;
int err;
uint64_t res = 0xbaadf00d;
str = "";
endptr = NULL;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert_cmpint(res, ==, 0xbaadf00d);
g_assert(endptr == str);
str = " \t ";
endptr = NULL;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert_cmpint(res, ==, 0xbaadf00d);
g_assert(endptr == str);
str = "crap";
endptr = NULL;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert_cmpint(res, ==, 0xbaadf00d);
g_assert(endptr == str);
str = "inf";
endptr = NULL;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert_cmpint(res, ==, 0xbaadf00d);
g_assert(endptr == str);
str = "NaN";
endptr = NULL;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert_cmpint(res, ==, 0xbaadf00d);
g_assert(endptr == str);
/* Fractional values require scale larger than bytes */
str = "1.1B";
endptr = NULL;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert_cmpint(res, ==, 0xbaadf00d);
utils: Improve qemu_strtosz() to have 64 bits of precision We have multiple clients of qemu_strtosz (qemu-io, the opts visitor, the keyval visitor), and it gets annoying that edge-case testing is impacted by implicit rounding to 53 bits of precision due to parsing with strtod(). As an example posted by Rich Jones: $ nbdkit memory $(( 2**63 - 2**30 )) --run \ 'build/qemu-io -f raw "$uri" -c "w -P 3 $(( 2**63 - 2**30 - 512 )) 512" ' write failed: Input/output error because 9223372035781033472 got rounded to 0x7fffffffc0000000 which is out of bounds. It is also worth noting that our existing parser, by virtue of using strtod(), accepts decimal AND hex numbers, even though test-cutils previously lacked any coverage of the latter until the previous patch. We do have existing clients that expect a hex parse to work (for example, iotest 33 using qemu-io -c "write -P 0xa 0x200 0x400"), but strtod() parses "08" as 8 rather than as an invalid octal number, so we know there are no clients that depend on octal. Our use of strtod() also means that "0x1.8k" would actually parse as 1536 (the fraction is 8/16), rather than 1843 (if the fraction were 8/10); but as this was not covered in the testsuite, I have no qualms forbidding hex fractions as invalid, so this patch declares that the use of fractions is only supported with decimal input, and enhances the testsuite to document that. Our previous use of strtod() meant that -1 parsed as a negative; now that we parse with strtoull(), negative values can wrap around modulo 2^64, so we have to explicitly check whether the user passed in a '-'; and make it consistent to also reject '-0'. This has the minor effect of treating negative values as EINVAL (with no change to endptr) rather than ERANGE (with endptr advanced to what was parsed), visible in the updated iotest output. We also had no testsuite coverage of "1.1e0k", which happened to parse under strtod() but is unlikely to occur in practice; as long as we are making things more robust, it is easy enough to reject the use of exponents in a strtod parse. The fix is done by breaking the parse into an integer prefix (no loss in precision), rejecting negative values (since we can no longer rely on strtod() to do that), determining if a decimal or hexadecimal parse was intended (with the new restriction that a fractional hex parse is not allowed), and where appropriate, using a floating point fractional parse (where we also scan to reject use of exponents in the fraction). The bulk of the patch is then updates to the testsuite to match our new precision, as well as adding new cases we reject (whether they were rejected or inadvertently accepted before). Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <20210211204438.1184395-3-eblake@redhat.com> Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
2021-02-11 23:44:36 +03:00
g_assert(endptr == str);
str = "1.1";
endptr = NULL;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert_cmpint(res, ==, 0xbaadf00d);
utils: Improve qemu_strtosz() to have 64 bits of precision We have multiple clients of qemu_strtosz (qemu-io, the opts visitor, the keyval visitor), and it gets annoying that edge-case testing is impacted by implicit rounding to 53 bits of precision due to parsing with strtod(). As an example posted by Rich Jones: $ nbdkit memory $(( 2**63 - 2**30 )) --run \ 'build/qemu-io -f raw "$uri" -c "w -P 3 $(( 2**63 - 2**30 - 512 )) 512" ' write failed: Input/output error because 9223372035781033472 got rounded to 0x7fffffffc0000000 which is out of bounds. It is also worth noting that our existing parser, by virtue of using strtod(), accepts decimal AND hex numbers, even though test-cutils previously lacked any coverage of the latter until the previous patch. We do have existing clients that expect a hex parse to work (for example, iotest 33 using qemu-io -c "write -P 0xa 0x200 0x400"), but strtod() parses "08" as 8 rather than as an invalid octal number, so we know there are no clients that depend on octal. Our use of strtod() also means that "0x1.8k" would actually parse as 1536 (the fraction is 8/16), rather than 1843 (if the fraction were 8/10); but as this was not covered in the testsuite, I have no qualms forbidding hex fractions as invalid, so this patch declares that the use of fractions is only supported with decimal input, and enhances the testsuite to document that. Our previous use of strtod() meant that -1 parsed as a negative; now that we parse with strtoull(), negative values can wrap around modulo 2^64, so we have to explicitly check whether the user passed in a '-'; and make it consistent to also reject '-0'. This has the minor effect of treating negative values as EINVAL (with no change to endptr) rather than ERANGE (with endptr advanced to what was parsed), visible in the updated iotest output. We also had no testsuite coverage of "1.1e0k", which happened to parse under strtod() but is unlikely to occur in practice; as long as we are making things more robust, it is easy enough to reject the use of exponents in a strtod parse. The fix is done by breaking the parse into an integer prefix (no loss in precision), rejecting negative values (since we can no longer rely on strtod() to do that), determining if a decimal or hexadecimal parse was intended (with the new restriction that a fractional hex parse is not allowed), and where appropriate, using a floating point fractional parse (where we also scan to reject use of exponents in the fraction). The bulk of the patch is then updates to the testsuite to match our new precision, as well as adding new cases we reject (whether they were rejected or inadvertently accepted before). Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <20210211204438.1184395-3-eblake@redhat.com> Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
2021-02-11 23:44:36 +03:00
g_assert(endptr == str);
utils: Improve qemu_strtosz() to have 64 bits of precision We have multiple clients of qemu_strtosz (qemu-io, the opts visitor, the keyval visitor), and it gets annoying that edge-case testing is impacted by implicit rounding to 53 bits of precision due to parsing with strtod(). As an example posted by Rich Jones: $ nbdkit memory $(( 2**63 - 2**30 )) --run \ 'build/qemu-io -f raw "$uri" -c "w -P 3 $(( 2**63 - 2**30 - 512 )) 512" ' write failed: Input/output error because 9223372035781033472 got rounded to 0x7fffffffc0000000 which is out of bounds. It is also worth noting that our existing parser, by virtue of using strtod(), accepts decimal AND hex numbers, even though test-cutils previously lacked any coverage of the latter until the previous patch. We do have existing clients that expect a hex parse to work (for example, iotest 33 using qemu-io -c "write -P 0xa 0x200 0x400"), but strtod() parses "08" as 8 rather than as an invalid octal number, so we know there are no clients that depend on octal. Our use of strtod() also means that "0x1.8k" would actually parse as 1536 (the fraction is 8/16), rather than 1843 (if the fraction were 8/10); but as this was not covered in the testsuite, I have no qualms forbidding hex fractions as invalid, so this patch declares that the use of fractions is only supported with decimal input, and enhances the testsuite to document that. Our previous use of strtod() meant that -1 parsed as a negative; now that we parse with strtoull(), negative values can wrap around modulo 2^64, so we have to explicitly check whether the user passed in a '-'; and make it consistent to also reject '-0'. This has the minor effect of treating negative values as EINVAL (with no change to endptr) rather than ERANGE (with endptr advanced to what was parsed), visible in the updated iotest output. We also had no testsuite coverage of "1.1e0k", which happened to parse under strtod() but is unlikely to occur in practice; as long as we are making things more robust, it is easy enough to reject the use of exponents in a strtod parse. The fix is done by breaking the parse into an integer prefix (no loss in precision), rejecting negative values (since we can no longer rely on strtod() to do that), determining if a decimal or hexadecimal parse was intended (with the new restriction that a fractional hex parse is not allowed), and where appropriate, using a floating point fractional parse (where we also scan to reject use of exponents in the fraction). The bulk of the patch is then updates to the testsuite to match our new precision, as well as adding new cases we reject (whether they were rejected or inadvertently accepted before). Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <20210211204438.1184395-3-eblake@redhat.com> Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
2021-02-11 23:44:36 +03:00
/* No floating point exponents */
str = "1.5e1k";
endptr = NULL;
err = qemu_strtosz(str, &endptr, &res);
utils: Improve qemu_strtosz() to have 64 bits of precision We have multiple clients of qemu_strtosz (qemu-io, the opts visitor, the keyval visitor), and it gets annoying that edge-case testing is impacted by implicit rounding to 53 bits of precision due to parsing with strtod(). As an example posted by Rich Jones: $ nbdkit memory $(( 2**63 - 2**30 )) --run \ 'build/qemu-io -f raw "$uri" -c "w -P 3 $(( 2**63 - 2**30 - 512 )) 512" ' write failed: Input/output error because 9223372035781033472 got rounded to 0x7fffffffc0000000 which is out of bounds. It is also worth noting that our existing parser, by virtue of using strtod(), accepts decimal AND hex numbers, even though test-cutils previously lacked any coverage of the latter until the previous patch. We do have existing clients that expect a hex parse to work (for example, iotest 33 using qemu-io -c "write -P 0xa 0x200 0x400"), but strtod() parses "08" as 8 rather than as an invalid octal number, so we know there are no clients that depend on octal. Our use of strtod() also means that "0x1.8k" would actually parse as 1536 (the fraction is 8/16), rather than 1843 (if the fraction were 8/10); but as this was not covered in the testsuite, I have no qualms forbidding hex fractions as invalid, so this patch declares that the use of fractions is only supported with decimal input, and enhances the testsuite to document that. Our previous use of strtod() meant that -1 parsed as a negative; now that we parse with strtoull(), negative values can wrap around modulo 2^64, so we have to explicitly check whether the user passed in a '-'; and make it consistent to also reject '-0'. This has the minor effect of treating negative values as EINVAL (with no change to endptr) rather than ERANGE (with endptr advanced to what was parsed), visible in the updated iotest output. We also had no testsuite coverage of "1.1e0k", which happened to parse under strtod() but is unlikely to occur in practice; as long as we are making things more robust, it is easy enough to reject the use of exponents in a strtod parse. The fix is done by breaking the parse into an integer prefix (no loss in precision), rejecting negative values (since we can no longer rely on strtod() to do that), determining if a decimal or hexadecimal parse was intended (with the new restriction that a fractional hex parse is not allowed), and where appropriate, using a floating point fractional parse (where we also scan to reject use of exponents in the fraction). The bulk of the patch is then updates to the testsuite to match our new precision, as well as adding new cases we reject (whether they were rejected or inadvertently accepted before). Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <20210211204438.1184395-3-eblake@redhat.com> Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
2021-02-11 23:44:36 +03:00
g_assert_cmpint(err, ==, -EINVAL);
g_assert_cmpint(res, ==, 0xbaadf00d);
utils: Improve qemu_strtosz() to have 64 bits of precision We have multiple clients of qemu_strtosz (qemu-io, the opts visitor, the keyval visitor), and it gets annoying that edge-case testing is impacted by implicit rounding to 53 bits of precision due to parsing with strtod(). As an example posted by Rich Jones: $ nbdkit memory $(( 2**63 - 2**30 )) --run \ 'build/qemu-io -f raw "$uri" -c "w -P 3 $(( 2**63 - 2**30 - 512 )) 512" ' write failed: Input/output error because 9223372035781033472 got rounded to 0x7fffffffc0000000 which is out of bounds. It is also worth noting that our existing parser, by virtue of using strtod(), accepts decimal AND hex numbers, even though test-cutils previously lacked any coverage of the latter until the previous patch. We do have existing clients that expect a hex parse to work (for example, iotest 33 using qemu-io -c "write -P 0xa 0x200 0x400"), but strtod() parses "08" as 8 rather than as an invalid octal number, so we know there are no clients that depend on octal. Our use of strtod() also means that "0x1.8k" would actually parse as 1536 (the fraction is 8/16), rather than 1843 (if the fraction were 8/10); but as this was not covered in the testsuite, I have no qualms forbidding hex fractions as invalid, so this patch declares that the use of fractions is only supported with decimal input, and enhances the testsuite to document that. Our previous use of strtod() meant that -1 parsed as a negative; now that we parse with strtoull(), negative values can wrap around modulo 2^64, so we have to explicitly check whether the user passed in a '-'; and make it consistent to also reject '-0'. This has the minor effect of treating negative values as EINVAL (with no change to endptr) rather than ERANGE (with endptr advanced to what was parsed), visible in the updated iotest output. We also had no testsuite coverage of "1.1e0k", which happened to parse under strtod() but is unlikely to occur in practice; as long as we are making things more robust, it is easy enough to reject the use of exponents in a strtod parse. The fix is done by breaking the parse into an integer prefix (no loss in precision), rejecting negative values (since we can no longer rely on strtod() to do that), determining if a decimal or hexadecimal parse was intended (with the new restriction that a fractional hex parse is not allowed), and where appropriate, using a floating point fractional parse (where we also scan to reject use of exponents in the fraction). The bulk of the patch is then updates to the testsuite to match our new precision, as well as adding new cases we reject (whether they were rejected or inadvertently accepted before). Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <20210211204438.1184395-3-eblake@redhat.com> Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
2021-02-11 23:44:36 +03:00
g_assert(endptr == str);
str = "1.5E+0k";
endptr = NULL;
err = qemu_strtosz(str, &endptr, &res);
utils: Improve qemu_strtosz() to have 64 bits of precision We have multiple clients of qemu_strtosz (qemu-io, the opts visitor, the keyval visitor), and it gets annoying that edge-case testing is impacted by implicit rounding to 53 bits of precision due to parsing with strtod(). As an example posted by Rich Jones: $ nbdkit memory $(( 2**63 - 2**30 )) --run \ 'build/qemu-io -f raw "$uri" -c "w -P 3 $(( 2**63 - 2**30 - 512 )) 512" ' write failed: Input/output error because 9223372035781033472 got rounded to 0x7fffffffc0000000 which is out of bounds. It is also worth noting that our existing parser, by virtue of using strtod(), accepts decimal AND hex numbers, even though test-cutils previously lacked any coverage of the latter until the previous patch. We do have existing clients that expect a hex parse to work (for example, iotest 33 using qemu-io -c "write -P 0xa 0x200 0x400"), but strtod() parses "08" as 8 rather than as an invalid octal number, so we know there are no clients that depend on octal. Our use of strtod() also means that "0x1.8k" would actually parse as 1536 (the fraction is 8/16), rather than 1843 (if the fraction were 8/10); but as this was not covered in the testsuite, I have no qualms forbidding hex fractions as invalid, so this patch declares that the use of fractions is only supported with decimal input, and enhances the testsuite to document that. Our previous use of strtod() meant that -1 parsed as a negative; now that we parse with strtoull(), negative values can wrap around modulo 2^64, so we have to explicitly check whether the user passed in a '-'; and make it consistent to also reject '-0'. This has the minor effect of treating negative values as EINVAL (with no change to endptr) rather than ERANGE (with endptr advanced to what was parsed), visible in the updated iotest output. We also had no testsuite coverage of "1.1e0k", which happened to parse under strtod() but is unlikely to occur in practice; as long as we are making things more robust, it is easy enough to reject the use of exponents in a strtod parse. The fix is done by breaking the parse into an integer prefix (no loss in precision), rejecting negative values (since we can no longer rely on strtod() to do that), determining if a decimal or hexadecimal parse was intended (with the new restriction that a fractional hex parse is not allowed), and where appropriate, using a floating point fractional parse (where we also scan to reject use of exponents in the fraction). The bulk of the patch is then updates to the testsuite to match our new precision, as well as adding new cases we reject (whether they were rejected or inadvertently accepted before). Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <20210211204438.1184395-3-eblake@redhat.com> Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
2021-02-11 23:44:36 +03:00
g_assert_cmpint(err, ==, -EINVAL);
g_assert_cmpint(res, ==, 0xbaadf00d);
utils: Improve qemu_strtosz() to have 64 bits of precision We have multiple clients of qemu_strtosz (qemu-io, the opts visitor, the keyval visitor), and it gets annoying that edge-case testing is impacted by implicit rounding to 53 bits of precision due to parsing with strtod(). As an example posted by Rich Jones: $ nbdkit memory $(( 2**63 - 2**30 )) --run \ 'build/qemu-io -f raw "$uri" -c "w -P 3 $(( 2**63 - 2**30 - 512 )) 512" ' write failed: Input/output error because 9223372035781033472 got rounded to 0x7fffffffc0000000 which is out of bounds. It is also worth noting that our existing parser, by virtue of using strtod(), accepts decimal AND hex numbers, even though test-cutils previously lacked any coverage of the latter until the previous patch. We do have existing clients that expect a hex parse to work (for example, iotest 33 using qemu-io -c "write -P 0xa 0x200 0x400"), but strtod() parses "08" as 8 rather than as an invalid octal number, so we know there are no clients that depend on octal. Our use of strtod() also means that "0x1.8k" would actually parse as 1536 (the fraction is 8/16), rather than 1843 (if the fraction were 8/10); but as this was not covered in the testsuite, I have no qualms forbidding hex fractions as invalid, so this patch declares that the use of fractions is only supported with decimal input, and enhances the testsuite to document that. Our previous use of strtod() meant that -1 parsed as a negative; now that we parse with strtoull(), negative values can wrap around modulo 2^64, so we have to explicitly check whether the user passed in a '-'; and make it consistent to also reject '-0'. This has the minor effect of treating negative values as EINVAL (with no change to endptr) rather than ERANGE (with endptr advanced to what was parsed), visible in the updated iotest output. We also had no testsuite coverage of "1.1e0k", which happened to parse under strtod() but is unlikely to occur in practice; as long as we are making things more robust, it is easy enough to reject the use of exponents in a strtod parse. The fix is done by breaking the parse into an integer prefix (no loss in precision), rejecting negative values (since we can no longer rely on strtod() to do that), determining if a decimal or hexadecimal parse was intended (with the new restriction that a fractional hex parse is not allowed), and where appropriate, using a floating point fractional parse (where we also scan to reject use of exponents in the fraction). The bulk of the patch is then updates to the testsuite to match our new precision, as well as adding new cases we reject (whether they were rejected or inadvertently accepted before). Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <20210211204438.1184395-3-eblake@redhat.com> Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
2021-02-11 23:44:36 +03:00
g_assert(endptr == str);
utils: Improve qemu_strtosz() to have 64 bits of precision We have multiple clients of qemu_strtosz (qemu-io, the opts visitor, the keyval visitor), and it gets annoying that edge-case testing is impacted by implicit rounding to 53 bits of precision due to parsing with strtod(). As an example posted by Rich Jones: $ nbdkit memory $(( 2**63 - 2**30 )) --run \ 'build/qemu-io -f raw "$uri" -c "w -P 3 $(( 2**63 - 2**30 - 512 )) 512" ' write failed: Input/output error because 9223372035781033472 got rounded to 0x7fffffffc0000000 which is out of bounds. It is also worth noting that our existing parser, by virtue of using strtod(), accepts decimal AND hex numbers, even though test-cutils previously lacked any coverage of the latter until the previous patch. We do have existing clients that expect a hex parse to work (for example, iotest 33 using qemu-io -c "write -P 0xa 0x200 0x400"), but strtod() parses "08" as 8 rather than as an invalid octal number, so we know there are no clients that depend on octal. Our use of strtod() also means that "0x1.8k" would actually parse as 1536 (the fraction is 8/16), rather than 1843 (if the fraction were 8/10); but as this was not covered in the testsuite, I have no qualms forbidding hex fractions as invalid, so this patch declares that the use of fractions is only supported with decimal input, and enhances the testsuite to document that. Our previous use of strtod() meant that -1 parsed as a negative; now that we parse with strtoull(), negative values can wrap around modulo 2^64, so we have to explicitly check whether the user passed in a '-'; and make it consistent to also reject '-0'. This has the minor effect of treating negative values as EINVAL (with no change to endptr) rather than ERANGE (with endptr advanced to what was parsed), visible in the updated iotest output. We also had no testsuite coverage of "1.1e0k", which happened to parse under strtod() but is unlikely to occur in practice; as long as we are making things more robust, it is easy enough to reject the use of exponents in a strtod parse. The fix is done by breaking the parse into an integer prefix (no loss in precision), rejecting negative values (since we can no longer rely on strtod() to do that), determining if a decimal or hexadecimal parse was intended (with the new restriction that a fractional hex parse is not allowed), and where appropriate, using a floating point fractional parse (where we also scan to reject use of exponents in the fraction). The bulk of the patch is then updates to the testsuite to match our new precision, as well as adding new cases we reject (whether they were rejected or inadvertently accepted before). Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <20210211204438.1184395-3-eblake@redhat.com> Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
2021-02-11 23:44:36 +03:00
/* No hex fractions */
str = "0x1.8k";
endptr = NULL;
err = qemu_strtosz(str, &endptr, &res);
utils: Improve qemu_strtosz() to have 64 bits of precision We have multiple clients of qemu_strtosz (qemu-io, the opts visitor, the keyval visitor), and it gets annoying that edge-case testing is impacted by implicit rounding to 53 bits of precision due to parsing with strtod(). As an example posted by Rich Jones: $ nbdkit memory $(( 2**63 - 2**30 )) --run \ 'build/qemu-io -f raw "$uri" -c "w -P 3 $(( 2**63 - 2**30 - 512 )) 512" ' write failed: Input/output error because 9223372035781033472 got rounded to 0x7fffffffc0000000 which is out of bounds. It is also worth noting that our existing parser, by virtue of using strtod(), accepts decimal AND hex numbers, even though test-cutils previously lacked any coverage of the latter until the previous patch. We do have existing clients that expect a hex parse to work (for example, iotest 33 using qemu-io -c "write -P 0xa 0x200 0x400"), but strtod() parses "08" as 8 rather than as an invalid octal number, so we know there are no clients that depend on octal. Our use of strtod() also means that "0x1.8k" would actually parse as 1536 (the fraction is 8/16), rather than 1843 (if the fraction were 8/10); but as this was not covered in the testsuite, I have no qualms forbidding hex fractions as invalid, so this patch declares that the use of fractions is only supported with decimal input, and enhances the testsuite to document that. Our previous use of strtod() meant that -1 parsed as a negative; now that we parse with strtoull(), negative values can wrap around modulo 2^64, so we have to explicitly check whether the user passed in a '-'; and make it consistent to also reject '-0'. This has the minor effect of treating negative values as EINVAL (with no change to endptr) rather than ERANGE (with endptr advanced to what was parsed), visible in the updated iotest output. We also had no testsuite coverage of "1.1e0k", which happened to parse under strtod() but is unlikely to occur in practice; as long as we are making things more robust, it is easy enough to reject the use of exponents in a strtod parse. The fix is done by breaking the parse into an integer prefix (no loss in precision), rejecting negative values (since we can no longer rely on strtod() to do that), determining if a decimal or hexadecimal parse was intended (with the new restriction that a fractional hex parse is not allowed), and where appropriate, using a floating point fractional parse (where we also scan to reject use of exponents in the fraction). The bulk of the patch is then updates to the testsuite to match our new precision, as well as adding new cases we reject (whether they were rejected or inadvertently accepted before). Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <20210211204438.1184395-3-eblake@redhat.com> Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
2021-02-11 23:44:36 +03:00
g_assert_cmpint(err, ==, -EINVAL);
g_assert_cmpint(res, ==, 0xbaadf00d);
utils: Improve qemu_strtosz() to have 64 bits of precision We have multiple clients of qemu_strtosz (qemu-io, the opts visitor, the keyval visitor), and it gets annoying that edge-case testing is impacted by implicit rounding to 53 bits of precision due to parsing with strtod(). As an example posted by Rich Jones: $ nbdkit memory $(( 2**63 - 2**30 )) --run \ 'build/qemu-io -f raw "$uri" -c "w -P 3 $(( 2**63 - 2**30 - 512 )) 512" ' write failed: Input/output error because 9223372035781033472 got rounded to 0x7fffffffc0000000 which is out of bounds. It is also worth noting that our existing parser, by virtue of using strtod(), accepts decimal AND hex numbers, even though test-cutils previously lacked any coverage of the latter until the previous patch. We do have existing clients that expect a hex parse to work (for example, iotest 33 using qemu-io -c "write -P 0xa 0x200 0x400"), but strtod() parses "08" as 8 rather than as an invalid octal number, so we know there are no clients that depend on octal. Our use of strtod() also means that "0x1.8k" would actually parse as 1536 (the fraction is 8/16), rather than 1843 (if the fraction were 8/10); but as this was not covered in the testsuite, I have no qualms forbidding hex fractions as invalid, so this patch declares that the use of fractions is only supported with decimal input, and enhances the testsuite to document that. Our previous use of strtod() meant that -1 parsed as a negative; now that we parse with strtoull(), negative values can wrap around modulo 2^64, so we have to explicitly check whether the user passed in a '-'; and make it consistent to also reject '-0'. This has the minor effect of treating negative values as EINVAL (with no change to endptr) rather than ERANGE (with endptr advanced to what was parsed), visible in the updated iotest output. We also had no testsuite coverage of "1.1e0k", which happened to parse under strtod() but is unlikely to occur in practice; as long as we are making things more robust, it is easy enough to reject the use of exponents in a strtod parse. The fix is done by breaking the parse into an integer prefix (no loss in precision), rejecting negative values (since we can no longer rely on strtod() to do that), determining if a decimal or hexadecimal parse was intended (with the new restriction that a fractional hex parse is not allowed), and where appropriate, using a floating point fractional parse (where we also scan to reject use of exponents in the fraction). The bulk of the patch is then updates to the testsuite to match our new precision, as well as adding new cases we reject (whether they were rejected or inadvertently accepted before). Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <20210211204438.1184395-3-eblake@redhat.com> Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
2021-02-11 23:44:36 +03:00
g_assert(endptr == str);
utils: Improve qemu_strtosz() to have 64 bits of precision We have multiple clients of qemu_strtosz (qemu-io, the opts visitor, the keyval visitor), and it gets annoying that edge-case testing is impacted by implicit rounding to 53 bits of precision due to parsing with strtod(). As an example posted by Rich Jones: $ nbdkit memory $(( 2**63 - 2**30 )) --run \ 'build/qemu-io -f raw "$uri" -c "w -P 3 $(( 2**63 - 2**30 - 512 )) 512" ' write failed: Input/output error because 9223372035781033472 got rounded to 0x7fffffffc0000000 which is out of bounds. It is also worth noting that our existing parser, by virtue of using strtod(), accepts decimal AND hex numbers, even though test-cutils previously lacked any coverage of the latter until the previous patch. We do have existing clients that expect a hex parse to work (for example, iotest 33 using qemu-io -c "write -P 0xa 0x200 0x400"), but strtod() parses "08" as 8 rather than as an invalid octal number, so we know there are no clients that depend on octal. Our use of strtod() also means that "0x1.8k" would actually parse as 1536 (the fraction is 8/16), rather than 1843 (if the fraction were 8/10); but as this was not covered in the testsuite, I have no qualms forbidding hex fractions as invalid, so this patch declares that the use of fractions is only supported with decimal input, and enhances the testsuite to document that. Our previous use of strtod() meant that -1 parsed as a negative; now that we parse with strtoull(), negative values can wrap around modulo 2^64, so we have to explicitly check whether the user passed in a '-'; and make it consistent to also reject '-0'. This has the minor effect of treating negative values as EINVAL (with no change to endptr) rather than ERANGE (with endptr advanced to what was parsed), visible in the updated iotest output. We also had no testsuite coverage of "1.1e0k", which happened to parse under strtod() but is unlikely to occur in practice; as long as we are making things more robust, it is easy enough to reject the use of exponents in a strtod parse. The fix is done by breaking the parse into an integer prefix (no loss in precision), rejecting negative values (since we can no longer rely on strtod() to do that), determining if a decimal or hexadecimal parse was intended (with the new restriction that a fractional hex parse is not allowed), and where appropriate, using a floating point fractional parse (where we also scan to reject use of exponents in the fraction). The bulk of the patch is then updates to the testsuite to match our new precision, as well as adding new cases we reject (whether they were rejected or inadvertently accepted before). Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <20210211204438.1184395-3-eblake@redhat.com> Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
2021-02-11 23:44:36 +03:00
/* No negative values */
str = "-0";
endptr = NULL;
err = qemu_strtosz(str, &endptr, &res);
utils: Improve qemu_strtosz() to have 64 bits of precision We have multiple clients of qemu_strtosz (qemu-io, the opts visitor, the keyval visitor), and it gets annoying that edge-case testing is impacted by implicit rounding to 53 bits of precision due to parsing with strtod(). As an example posted by Rich Jones: $ nbdkit memory $(( 2**63 - 2**30 )) --run \ 'build/qemu-io -f raw "$uri" -c "w -P 3 $(( 2**63 - 2**30 - 512 )) 512" ' write failed: Input/output error because 9223372035781033472 got rounded to 0x7fffffffc0000000 which is out of bounds. It is also worth noting that our existing parser, by virtue of using strtod(), accepts decimal AND hex numbers, even though test-cutils previously lacked any coverage of the latter until the previous patch. We do have existing clients that expect a hex parse to work (for example, iotest 33 using qemu-io -c "write -P 0xa 0x200 0x400"), but strtod() parses "08" as 8 rather than as an invalid octal number, so we know there are no clients that depend on octal. Our use of strtod() also means that "0x1.8k" would actually parse as 1536 (the fraction is 8/16), rather than 1843 (if the fraction were 8/10); but as this was not covered in the testsuite, I have no qualms forbidding hex fractions as invalid, so this patch declares that the use of fractions is only supported with decimal input, and enhances the testsuite to document that. Our previous use of strtod() meant that -1 parsed as a negative; now that we parse with strtoull(), negative values can wrap around modulo 2^64, so we have to explicitly check whether the user passed in a '-'; and make it consistent to also reject '-0'. This has the minor effect of treating negative values as EINVAL (with no change to endptr) rather than ERANGE (with endptr advanced to what was parsed), visible in the updated iotest output. We also had no testsuite coverage of "1.1e0k", which happened to parse under strtod() but is unlikely to occur in practice; as long as we are making things more robust, it is easy enough to reject the use of exponents in a strtod parse. The fix is done by breaking the parse into an integer prefix (no loss in precision), rejecting negative values (since we can no longer rely on strtod() to do that), determining if a decimal or hexadecimal parse was intended (with the new restriction that a fractional hex parse is not allowed), and where appropriate, using a floating point fractional parse (where we also scan to reject use of exponents in the fraction). The bulk of the patch is then updates to the testsuite to match our new precision, as well as adding new cases we reject (whether they were rejected or inadvertently accepted before). Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <20210211204438.1184395-3-eblake@redhat.com> Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
2021-02-11 23:44:36 +03:00
g_assert_cmpint(err, ==, -EINVAL);
g_assert_cmpint(res, ==, 0xbaadf00d);
utils: Improve qemu_strtosz() to have 64 bits of precision We have multiple clients of qemu_strtosz (qemu-io, the opts visitor, the keyval visitor), and it gets annoying that edge-case testing is impacted by implicit rounding to 53 bits of precision due to parsing with strtod(). As an example posted by Rich Jones: $ nbdkit memory $(( 2**63 - 2**30 )) --run \ 'build/qemu-io -f raw "$uri" -c "w -P 3 $(( 2**63 - 2**30 - 512 )) 512" ' write failed: Input/output error because 9223372035781033472 got rounded to 0x7fffffffc0000000 which is out of bounds. It is also worth noting that our existing parser, by virtue of using strtod(), accepts decimal AND hex numbers, even though test-cutils previously lacked any coverage of the latter until the previous patch. We do have existing clients that expect a hex parse to work (for example, iotest 33 using qemu-io -c "write -P 0xa 0x200 0x400"), but strtod() parses "08" as 8 rather than as an invalid octal number, so we know there are no clients that depend on octal. Our use of strtod() also means that "0x1.8k" would actually parse as 1536 (the fraction is 8/16), rather than 1843 (if the fraction were 8/10); but as this was not covered in the testsuite, I have no qualms forbidding hex fractions as invalid, so this patch declares that the use of fractions is only supported with decimal input, and enhances the testsuite to document that. Our previous use of strtod() meant that -1 parsed as a negative; now that we parse with strtoull(), negative values can wrap around modulo 2^64, so we have to explicitly check whether the user passed in a '-'; and make it consistent to also reject '-0'. This has the minor effect of treating negative values as EINVAL (with no change to endptr) rather than ERANGE (with endptr advanced to what was parsed), visible in the updated iotest output. We also had no testsuite coverage of "1.1e0k", which happened to parse under strtod() but is unlikely to occur in practice; as long as we are making things more robust, it is easy enough to reject the use of exponents in a strtod parse. The fix is done by breaking the parse into an integer prefix (no loss in precision), rejecting negative values (since we can no longer rely on strtod() to do that), determining if a decimal or hexadecimal parse was intended (with the new restriction that a fractional hex parse is not allowed), and where appropriate, using a floating point fractional parse (where we also scan to reject use of exponents in the fraction). The bulk of the patch is then updates to the testsuite to match our new precision, as well as adding new cases we reject (whether they were rejected or inadvertently accepted before). Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <20210211204438.1184395-3-eblake@redhat.com> Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
2021-02-11 23:44:36 +03:00
g_assert(endptr == str);
str = "-1";
endptr = NULL;
utils: Improve qemu_strtosz() to have 64 bits of precision We have multiple clients of qemu_strtosz (qemu-io, the opts visitor, the keyval visitor), and it gets annoying that edge-case testing is impacted by implicit rounding to 53 bits of precision due to parsing with strtod(). As an example posted by Rich Jones: $ nbdkit memory $(( 2**63 - 2**30 )) --run \ 'build/qemu-io -f raw "$uri" -c "w -P 3 $(( 2**63 - 2**30 - 512 )) 512" ' write failed: Input/output error because 9223372035781033472 got rounded to 0x7fffffffc0000000 which is out of bounds. It is also worth noting that our existing parser, by virtue of using strtod(), accepts decimal AND hex numbers, even though test-cutils previously lacked any coverage of the latter until the previous patch. We do have existing clients that expect a hex parse to work (for example, iotest 33 using qemu-io -c "write -P 0xa 0x200 0x400"), but strtod() parses "08" as 8 rather than as an invalid octal number, so we know there are no clients that depend on octal. Our use of strtod() also means that "0x1.8k" would actually parse as 1536 (the fraction is 8/16), rather than 1843 (if the fraction were 8/10); but as this was not covered in the testsuite, I have no qualms forbidding hex fractions as invalid, so this patch declares that the use of fractions is only supported with decimal input, and enhances the testsuite to document that. Our previous use of strtod() meant that -1 parsed as a negative; now that we parse with strtoull(), negative values can wrap around modulo 2^64, so we have to explicitly check whether the user passed in a '-'; and make it consistent to also reject '-0'. This has the minor effect of treating negative values as EINVAL (with no change to endptr) rather than ERANGE (with endptr advanced to what was parsed), visible in the updated iotest output. We also had no testsuite coverage of "1.1e0k", which happened to parse under strtod() but is unlikely to occur in practice; as long as we are making things more robust, it is easy enough to reject the use of exponents in a strtod parse. The fix is done by breaking the parse into an integer prefix (no loss in precision), rejecting negative values (since we can no longer rely on strtod() to do that), determining if a decimal or hexadecimal parse was intended (with the new restriction that a fractional hex parse is not allowed), and where appropriate, using a floating point fractional parse (where we also scan to reject use of exponents in the fraction). The bulk of the patch is then updates to the testsuite to match our new precision, as well as adding new cases we reject (whether they were rejected or inadvertently accepted before). Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <20210211204438.1184395-3-eblake@redhat.com> Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
2021-02-11 23:44:36 +03:00
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert_cmpint(res, ==, 0xbaadf00d);
utils: Improve qemu_strtosz() to have 64 bits of precision We have multiple clients of qemu_strtosz (qemu-io, the opts visitor, the keyval visitor), and it gets annoying that edge-case testing is impacted by implicit rounding to 53 bits of precision due to parsing with strtod(). As an example posted by Rich Jones: $ nbdkit memory $(( 2**63 - 2**30 )) --run \ 'build/qemu-io -f raw "$uri" -c "w -P 3 $(( 2**63 - 2**30 - 512 )) 512" ' write failed: Input/output error because 9223372035781033472 got rounded to 0x7fffffffc0000000 which is out of bounds. It is also worth noting that our existing parser, by virtue of using strtod(), accepts decimal AND hex numbers, even though test-cutils previously lacked any coverage of the latter until the previous patch. We do have existing clients that expect a hex parse to work (for example, iotest 33 using qemu-io -c "write -P 0xa 0x200 0x400"), but strtod() parses "08" as 8 rather than as an invalid octal number, so we know there are no clients that depend on octal. Our use of strtod() also means that "0x1.8k" would actually parse as 1536 (the fraction is 8/16), rather than 1843 (if the fraction were 8/10); but as this was not covered in the testsuite, I have no qualms forbidding hex fractions as invalid, so this patch declares that the use of fractions is only supported with decimal input, and enhances the testsuite to document that. Our previous use of strtod() meant that -1 parsed as a negative; now that we parse with strtoull(), negative values can wrap around modulo 2^64, so we have to explicitly check whether the user passed in a '-'; and make it consistent to also reject '-0'. This has the minor effect of treating negative values as EINVAL (with no change to endptr) rather than ERANGE (with endptr advanced to what was parsed), visible in the updated iotest output. We also had no testsuite coverage of "1.1e0k", which happened to parse under strtod() but is unlikely to occur in practice; as long as we are making things more robust, it is easy enough to reject the use of exponents in a strtod parse. The fix is done by breaking the parse into an integer prefix (no loss in precision), rejecting negative values (since we can no longer rely on strtod() to do that), determining if a decimal or hexadecimal parse was intended (with the new restriction that a fractional hex parse is not allowed), and where appropriate, using a floating point fractional parse (where we also scan to reject use of exponents in the fraction). The bulk of the patch is then updates to the testsuite to match our new precision, as well as adding new cases we reject (whether they were rejected or inadvertently accepted before). Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <20210211204438.1184395-3-eblake@redhat.com> Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
2021-02-11 23:44:36 +03:00
g_assert(endptr == str);
}
static void test_qemu_strtosz_trailing(void)
{
const char *str;
const char *endptr;
int err;
uint64_t res;
str = "123xxx";
endptr = NULL;
res = 0xbaadf00d;
err = qemu_strtosz_MiB(str, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 123 * MiB);
g_assert(endptr == str + 3);
res = 0xbaadf00d;
err = qemu_strtosz(str, NULL, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert_cmpint(res, ==, 0xbaadf00d);
str = "1kiB";
endptr = NULL;
res = 0xbaadf00d;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 1024);
g_assert(endptr == str + 2);
res = 0xbaadf00d;
err = qemu_strtosz(str, NULL, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert_cmpint(res, ==, 0xbaadf00d);
str = "0x";
endptr = NULL;
res = 0xbaadf00d;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 0);
g_assert(endptr == str + 1);
res = 0xbaadf00d;
err = qemu_strtosz(str, NULL, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert_cmpint(res, ==, 0xbaadf00d);
str = "0.NaN";
endptr = NULL;
res = 0xbaadf00d;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 0);
g_assert(endptr == str + 2);
res = 0xbaadf00d;
err = qemu_strtosz(str, NULL, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert_cmpint(res, ==, 0xbaadf00d);
str = "123-45";
endptr = NULL;
res = 0xbaadf00d;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 123);
g_assert(endptr == str + 3);
res = 0xbaadf00d;
err = qemu_strtosz(str, NULL, &res);
g_assert_cmpint(err, ==, -EINVAL);
g_assert_cmpint(res, ==, 0xbaadf00d);
}
static void test_qemu_strtosz_erange(void)
{
const char *str;
const char *endptr;
int err;
uint64_t res = 0xbaadf00d;
utils: Improve qemu_strtosz() to have 64 bits of precision We have multiple clients of qemu_strtosz (qemu-io, the opts visitor, the keyval visitor), and it gets annoying that edge-case testing is impacted by implicit rounding to 53 bits of precision due to parsing with strtod(). As an example posted by Rich Jones: $ nbdkit memory $(( 2**63 - 2**30 )) --run \ 'build/qemu-io -f raw "$uri" -c "w -P 3 $(( 2**63 - 2**30 - 512 )) 512" ' write failed: Input/output error because 9223372035781033472 got rounded to 0x7fffffffc0000000 which is out of bounds. It is also worth noting that our existing parser, by virtue of using strtod(), accepts decimal AND hex numbers, even though test-cutils previously lacked any coverage of the latter until the previous patch. We do have existing clients that expect a hex parse to work (for example, iotest 33 using qemu-io -c "write -P 0xa 0x200 0x400"), but strtod() parses "08" as 8 rather than as an invalid octal number, so we know there are no clients that depend on octal. Our use of strtod() also means that "0x1.8k" would actually parse as 1536 (the fraction is 8/16), rather than 1843 (if the fraction were 8/10); but as this was not covered in the testsuite, I have no qualms forbidding hex fractions as invalid, so this patch declares that the use of fractions is only supported with decimal input, and enhances the testsuite to document that. Our previous use of strtod() meant that -1 parsed as a negative; now that we parse with strtoull(), negative values can wrap around modulo 2^64, so we have to explicitly check whether the user passed in a '-'; and make it consistent to also reject '-0'. This has the minor effect of treating negative values as EINVAL (with no change to endptr) rather than ERANGE (with endptr advanced to what was parsed), visible in the updated iotest output. We also had no testsuite coverage of "1.1e0k", which happened to parse under strtod() but is unlikely to occur in practice; as long as we are making things more robust, it is easy enough to reject the use of exponents in a strtod parse. The fix is done by breaking the parse into an integer prefix (no loss in precision), rejecting negative values (since we can no longer rely on strtod() to do that), determining if a decimal or hexadecimal parse was intended (with the new restriction that a fractional hex parse is not allowed), and where appropriate, using a floating point fractional parse (where we also scan to reject use of exponents in the fraction). The bulk of the patch is then updates to the testsuite to match our new precision, as well as adding new cases we reject (whether they were rejected or inadvertently accepted before). Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <20210211204438.1184395-3-eblake@redhat.com> Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
2021-02-11 23:44:36 +03:00
str = "18446744073709551616"; /* 2^64; see strtosz_simple for 2^64-1 */
endptr = NULL;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, -ERANGE);
g_assert_cmpint(res, ==, 0xbaadf00d);
g_assert(endptr == str + 20);
str = "20E";
endptr = NULL;
err = qemu_strtosz(str, &endptr, &res);
g_assert_cmpint(err, ==, -ERANGE);
g_assert_cmpint(res, ==, 0xbaadf00d);
g_assert(endptr == str + 3);
}
static void test_qemu_strtosz_metric(void)
{
const char *str;
int err;
const char *endptr;
uint64_t res;
str = "12345k";
endptr = str;
res = 0xbaadf00d;
err = qemu_strtosz_metric(str, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 12345000);
g_assert(endptr == str + 6);
str = "12.345M";
endptr = str;
res = 0xbaadf00d;
err = qemu_strtosz_metric(str, &endptr, &res);
g_assert_cmpint(err, ==, 0);
g_assert_cmpint(res, ==, 12345000);
g_assert(endptr == str + 7);
}
static void test_freq_to_str(void)
{
char *str;
str = freq_to_str(999);
g_assert_cmpstr(str, ==, "999 Hz");
g_free(str);
str = freq_to_str(1000);
g_assert_cmpstr(str, ==, "1 KHz");
g_free(str);
str = freq_to_str(1010);
g_assert_cmpstr(str, ==, "1.01 KHz");
g_free(str);
}
static void test_size_to_str(void)
{
char *str;
str = size_to_str(0);
g_assert_cmpstr(str, ==, "0 B");
g_free(str);
str = size_to_str(1);
g_assert_cmpstr(str, ==, "1 B");
g_free(str);
str = size_to_str(1016);
g_assert_cmpstr(str, ==, "0.992 KiB");
g_free(str);
str = size_to_str(1024);
g_assert_cmpstr(str, ==, "1 KiB");
g_free(str);
str = size_to_str(512ull << 20);
g_assert_cmpstr(str, ==, "512 MiB");
g_free(str);
}
static void test_iec_binary_prefix(void)
{
g_assert_cmpstr(iec_binary_prefix(0), ==, "");
g_assert_cmpstr(iec_binary_prefix(10), ==, "Ki");
g_assert_cmpstr(iec_binary_prefix(20), ==, "Mi");
g_assert_cmpstr(iec_binary_prefix(30), ==, "Gi");
g_assert_cmpstr(iec_binary_prefix(40), ==, "Ti");
g_assert_cmpstr(iec_binary_prefix(50), ==, "Pi");
g_assert_cmpstr(iec_binary_prefix(60), ==, "Ei");
}
static void test_si_prefix(void)
{
g_assert_cmpstr(si_prefix(-18), ==, "a");
g_assert_cmpstr(si_prefix(-15), ==, "f");
g_assert_cmpstr(si_prefix(-12), ==, "p");
g_assert_cmpstr(si_prefix(-9), ==, "n");
g_assert_cmpstr(si_prefix(-6), ==, "u");
g_assert_cmpstr(si_prefix(-3), ==, "m");
g_assert_cmpstr(si_prefix(0), ==, "");
g_assert_cmpstr(si_prefix(3), ==, "K");
g_assert_cmpstr(si_prefix(6), ==, "M");
g_assert_cmpstr(si_prefix(9), ==, "G");
g_assert_cmpstr(si_prefix(12), ==, "T");
g_assert_cmpstr(si_prefix(15), ==, "P");
g_assert_cmpstr(si_prefix(18), ==, "E");
}
int main(int argc, char **argv)
{
g_test_init(&argc, &argv, NULL);
g_test_add_func("/cutils/parse_uint/null", test_parse_uint_null);
g_test_add_func("/cutils/parse_uint/empty", test_parse_uint_empty);
g_test_add_func("/cutils/parse_uint/whitespace",
test_parse_uint_whitespace);
g_test_add_func("/cutils/parse_uint/invalid", test_parse_uint_invalid);
g_test_add_func("/cutils/parse_uint/trailing", test_parse_uint_trailing);
g_test_add_func("/cutils/parse_uint/correct", test_parse_uint_correct);
g_test_add_func("/cutils/parse_uint/octal", test_parse_uint_octal);
g_test_add_func("/cutils/parse_uint/decimal", test_parse_uint_decimal);
g_test_add_func("/cutils/parse_uint/llong_max", test_parse_uint_llong_max);
g_test_add_func("/cutils/parse_uint/overflow", test_parse_uint_overflow);
g_test_add_func("/cutils/parse_uint/negative", test_parse_uint_negative);
g_test_add_func("/cutils/parse_uint_full/trailing",
test_parse_uint_full_trailing);
g_test_add_func("/cutils/parse_uint_full/correct",
test_parse_uint_full_correct);
/* qemu_strtoi() tests */
g_test_add_func("/cutils/qemu_strtoi/correct",
test_qemu_strtoi_correct);
g_test_add_func("/cutils/qemu_strtoi/null",
test_qemu_strtoi_null);
g_test_add_func("/cutils/qemu_strtoi/empty",
test_qemu_strtoi_empty);
g_test_add_func("/cutils/qemu_strtoi/whitespace",
test_qemu_strtoi_whitespace);
g_test_add_func("/cutils/qemu_strtoi/invalid",
test_qemu_strtoi_invalid);
g_test_add_func("/cutils/qemu_strtoi/trailing",
test_qemu_strtoi_trailing);
g_test_add_func("/cutils/qemu_strtoi/octal",
test_qemu_strtoi_octal);
g_test_add_func("/cutils/qemu_strtoi/decimal",
test_qemu_strtoi_decimal);
g_test_add_func("/cutils/qemu_strtoi/hex",
test_qemu_strtoi_hex);
g_test_add_func("/cutils/qemu_strtoi/max",
test_qemu_strtoi_max);
g_test_add_func("/cutils/qemu_strtoi/overflow",
test_qemu_strtoi_overflow);
g_test_add_func("/cutils/qemu_strtoi/underflow",
test_qemu_strtoi_underflow);
g_test_add_func("/cutils/qemu_strtoi/negative",
test_qemu_strtoi_negative);
g_test_add_func("/cutils/qemu_strtoi_full/correct",
test_qemu_strtoi_full_correct);
g_test_add_func("/cutils/qemu_strtoi_full/null",
test_qemu_strtoi_full_null);
g_test_add_func("/cutils/qemu_strtoi_full/empty",
test_qemu_strtoi_full_empty);
g_test_add_func("/cutils/qemu_strtoi_full/negative",
test_qemu_strtoi_full_negative);
g_test_add_func("/cutils/qemu_strtoi_full/trailing",
test_qemu_strtoi_full_trailing);
g_test_add_func("/cutils/qemu_strtoi_full/max",
test_qemu_strtoi_full_max);
/* qemu_strtoui() tests */
g_test_add_func("/cutils/qemu_strtoui/correct",
test_qemu_strtoui_correct);
g_test_add_func("/cutils/qemu_strtoui/null",
test_qemu_strtoui_null);
g_test_add_func("/cutils/qemu_strtoui/empty",
test_qemu_strtoui_empty);
g_test_add_func("/cutils/qemu_strtoui/whitespace",
test_qemu_strtoui_whitespace);
g_test_add_func("/cutils/qemu_strtoui/invalid",
test_qemu_strtoui_invalid);
g_test_add_func("/cutils/qemu_strtoui/trailing",
test_qemu_strtoui_trailing);
g_test_add_func("/cutils/qemu_strtoui/octal",
test_qemu_strtoui_octal);
g_test_add_func("/cutils/qemu_strtoui/decimal",
test_qemu_strtoui_decimal);
g_test_add_func("/cutils/qemu_strtoui/hex",
test_qemu_strtoui_hex);
g_test_add_func("/cutils/qemu_strtoui/max",
test_qemu_strtoui_max);
g_test_add_func("/cutils/qemu_strtoui/overflow",
test_qemu_strtoui_overflow);
g_test_add_func("/cutils/qemu_strtoui/underflow",
test_qemu_strtoui_underflow);
g_test_add_func("/cutils/qemu_strtoui/negative",
test_qemu_strtoui_negative);
g_test_add_func("/cutils/qemu_strtoui_full/correct",
test_qemu_strtoui_full_correct);
g_test_add_func("/cutils/qemu_strtoui_full/null",
test_qemu_strtoui_full_null);
g_test_add_func("/cutils/qemu_strtoui_full/empty",
test_qemu_strtoui_full_empty);
g_test_add_func("/cutils/qemu_strtoui_full/negative",
test_qemu_strtoui_full_negative);
g_test_add_func("/cutils/qemu_strtoui_full/trailing",
test_qemu_strtoui_full_trailing);
g_test_add_func("/cutils/qemu_strtoui_full/max",
test_qemu_strtoui_full_max);
/* qemu_strtol() tests */
g_test_add_func("/cutils/qemu_strtol/correct",
test_qemu_strtol_correct);
g_test_add_func("/cutils/qemu_strtol/null",
test_qemu_strtol_null);
g_test_add_func("/cutils/qemu_strtol/empty",
test_qemu_strtol_empty);
g_test_add_func("/cutils/qemu_strtol/whitespace",
test_qemu_strtol_whitespace);
g_test_add_func("/cutils/qemu_strtol/invalid",
test_qemu_strtol_invalid);
g_test_add_func("/cutils/qemu_strtol/trailing",
test_qemu_strtol_trailing);
g_test_add_func("/cutils/qemu_strtol/octal",
test_qemu_strtol_octal);
g_test_add_func("/cutils/qemu_strtol/decimal",
test_qemu_strtol_decimal);
g_test_add_func("/cutils/qemu_strtol/hex",
test_qemu_strtol_hex);
g_test_add_func("/cutils/qemu_strtol/max",
test_qemu_strtol_max);
g_test_add_func("/cutils/qemu_strtol/overflow",
test_qemu_strtol_overflow);
g_test_add_func("/cutils/qemu_strtol/underflow",
test_qemu_strtol_underflow);
g_test_add_func("/cutils/qemu_strtol/negative",
test_qemu_strtol_negative);
g_test_add_func("/cutils/qemu_strtol_full/correct",
test_qemu_strtol_full_correct);
g_test_add_func("/cutils/qemu_strtol_full/null",
test_qemu_strtol_full_null);
g_test_add_func("/cutils/qemu_strtol_full/empty",
test_qemu_strtol_full_empty);
g_test_add_func("/cutils/qemu_strtol_full/negative",
test_qemu_strtol_full_negative);
g_test_add_func("/cutils/qemu_strtol_full/trailing",
test_qemu_strtol_full_trailing);
g_test_add_func("/cutils/qemu_strtol_full/max",
test_qemu_strtol_full_max);
/* qemu_strtoul() tests */
g_test_add_func("/cutils/qemu_strtoul/correct",
test_qemu_strtoul_correct);
g_test_add_func("/cutils/qemu_strtoul/null",
test_qemu_strtoul_null);
g_test_add_func("/cutils/qemu_strtoul/empty",
test_qemu_strtoul_empty);
g_test_add_func("/cutils/qemu_strtoul/whitespace",
test_qemu_strtoul_whitespace);
g_test_add_func("/cutils/qemu_strtoul/invalid",
test_qemu_strtoul_invalid);
g_test_add_func("/cutils/qemu_strtoul/trailing",
test_qemu_strtoul_trailing);
g_test_add_func("/cutils/qemu_strtoul/octal",
test_qemu_strtoul_octal);
g_test_add_func("/cutils/qemu_strtoul/decimal",
test_qemu_strtoul_decimal);
g_test_add_func("/cutils/qemu_strtoul/hex",
test_qemu_strtoul_hex);
g_test_add_func("/cutils/qemu_strtoul/max",
test_qemu_strtoul_max);
g_test_add_func("/cutils/qemu_strtoul/overflow",
test_qemu_strtoul_overflow);
g_test_add_func("/cutils/qemu_strtoul/underflow",
test_qemu_strtoul_underflow);
g_test_add_func("/cutils/qemu_strtoul/negative",
test_qemu_strtoul_negative);
g_test_add_func("/cutils/qemu_strtoul_full/correct",
test_qemu_strtoul_full_correct);
g_test_add_func("/cutils/qemu_strtoul_full/null",
test_qemu_strtoul_full_null);
g_test_add_func("/cutils/qemu_strtoul_full/empty",
test_qemu_strtoul_full_empty);
g_test_add_func("/cutils/qemu_strtoul_full/negative",
test_qemu_strtoul_full_negative);
g_test_add_func("/cutils/qemu_strtoul_full/trailing",
test_qemu_strtoul_full_trailing);
g_test_add_func("/cutils/qemu_strtoul_full/max",
test_qemu_strtoul_full_max);
/* qemu_strtoi64() tests */
g_test_add_func("/cutils/qemu_strtoi64/correct",
test_qemu_strtoi64_correct);
g_test_add_func("/cutils/qemu_strtoi64/null",
test_qemu_strtoi64_null);
g_test_add_func("/cutils/qemu_strtoi64/empty",
test_qemu_strtoi64_empty);
g_test_add_func("/cutils/qemu_strtoi64/whitespace",
test_qemu_strtoi64_whitespace);
g_test_add_func("/cutils/qemu_strtoi64/invalid"
,
test_qemu_strtoi64_invalid);
g_test_add_func("/cutils/qemu_strtoi64/trailing",
test_qemu_strtoi64_trailing);
g_test_add_func("/cutils/qemu_strtoi64/octal",
test_qemu_strtoi64_octal);
g_test_add_func("/cutils/qemu_strtoi64/decimal",
test_qemu_strtoi64_decimal);
g_test_add_func("/cutils/qemu_strtoi64/hex",
test_qemu_strtoi64_hex);
g_test_add_func("/cutils/qemu_strtoi64/max",
test_qemu_strtoi64_max);
g_test_add_func("/cutils/qemu_strtoi64/overflow",
test_qemu_strtoi64_overflow);
g_test_add_func("/cutils/qemu_strtoi64/underflow",
test_qemu_strtoi64_underflow);
g_test_add_func("/cutils/qemu_strtoi64/negative",
test_qemu_strtoi64_negative);
g_test_add_func("/cutils/qemu_strtoi64_full/correct",
test_qemu_strtoi64_full_correct);
g_test_add_func("/cutils/qemu_strtoi64_full/null",
test_qemu_strtoi64_full_null);
g_test_add_func("/cutils/qemu_strtoi64_full/empty",
test_qemu_strtoi64_full_empty);
g_test_add_func("/cutils/qemu_strtoi64_full/negative",
test_qemu_strtoi64_full_negative);
g_test_add_func("/cutils/qemu_strtoi64_full/trailing",
test_qemu_strtoi64_full_trailing);
g_test_add_func("/cutils/qemu_strtoi64_full/max",
test_qemu_strtoi64_full_max);
/* qemu_strtou64() tests */
g_test_add_func("/cutils/qemu_strtou64/correct",
test_qemu_strtou64_correct);
g_test_add_func("/cutils/qemu_strtou64/null",
test_qemu_strtou64_null);
g_test_add_func("/cutils/qemu_strtou64/empty",
test_qemu_strtou64_empty);
g_test_add_func("/cutils/qemu_strtou64/whitespace",
test_qemu_strtou64_whitespace);
g_test_add_func("/cutils/qemu_strtou64/invalid",
test_qemu_strtou64_invalid);
g_test_add_func("/cutils/qemu_strtou64/trailing",
test_qemu_strtou64_trailing);
g_test_add_func("/cutils/qemu_strtou64/octal",
test_qemu_strtou64_octal);
g_test_add_func("/cutils/qemu_strtou64/decimal",
test_qemu_strtou64_decimal);
g_test_add_func("/cutils/qemu_strtou64/hex",
test_qemu_strtou64_hex);
g_test_add_func("/cutils/qemu_strtou64/max",
test_qemu_strtou64_max);
g_test_add_func("/cutils/qemu_strtou64/overflow",
test_qemu_strtou64_overflow);
g_test_add_func("/cutils/qemu_strtou64/underflow",
test_qemu_strtou64_underflow);
g_test_add_func("/cutils/qemu_strtou64/negative",
test_qemu_strtou64_negative);
g_test_add_func("/cutils/qemu_strtou64_full/correct",
test_qemu_strtou64_full_correct);
g_test_add_func("/cutils/qemu_strtou64_full/null",
test_qemu_strtou64_full_null);
g_test_add_func("/cutils/qemu_strtou64_full/empty",
test_qemu_strtou64_full_empty);
g_test_add_func("/cutils/qemu_strtou64_full/negative",
test_qemu_strtou64_full_negative);
g_test_add_func("/cutils/qemu_strtou64_full/trailing",
test_qemu_strtou64_full_trailing);
g_test_add_func("/cutils/qemu_strtou64_full/max",
test_qemu_strtou64_full_max);
g_test_add_func("/cutils/strtosz/simple",
test_qemu_strtosz_simple);
g_test_add_func("/cutils/strtosz/hex",
test_qemu_strtosz_hex);
g_test_add_func("/cutils/strtosz/units",
test_qemu_strtosz_units);
g_test_add_func("/cutils/strtosz/float",
test_qemu_strtosz_float);
g_test_add_func("/cutils/strtosz/invalid",
test_qemu_strtosz_invalid);
g_test_add_func("/cutils/strtosz/trailing",
test_qemu_strtosz_trailing);
g_test_add_func("/cutils/strtosz/erange",
test_qemu_strtosz_erange);
g_test_add_func("/cutils/strtosz/metric",
test_qemu_strtosz_metric);
g_test_add_func("/cutils/size_to_str",
test_size_to_str);
g_test_add_func("/cutils/freq_to_str",
test_freq_to_str);
g_test_add_func("/cutils/iec_binary_prefix",
test_iec_binary_prefix);
g_test_add_func("/cutils/si_prefix",
test_si_prefix);
return g_test_run();
}