glibc/string/test-strncmp.c
Siddhesh Poyarekar 67e3b0c63c tests/string: Drop simple/stupid/builtin tests
In most cases the simple/stupid/builtin functions were in there to
benchmark optimized implementations against.  Only in some cases the
functions are used to check expected results.

Remove these tests from IMPL() and only keep them in wherever they're
used for a specific purpose, e.g. to generate expected results.

This improves timing of `make subdirs=string` by over a minute and a
half (over 15%) on a Whiskey Lake laptop.

Signed-off-by: Siddhesh Poyarekar <siddhesh@sourceware.org>
Reviewed-by: Noah Goldstein <libc-alpha@sourceware.org>
2022-04-06 20:53:24 +05:30

768 lines
23 KiB
C

/* Test strncmp and wcsncmp functions.
Copyright (C) 1999-2022 Free Software Foundation, Inc.
This file is part of the GNU C Library.
The GNU C Library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
The GNU C Library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with the GNU C Library; if not, see
<https://www.gnu.org/licenses/>. */
#define TEST_LEN (getpagesize () * 3)
#define MIN_PAGE_SIZE (TEST_LEN + 2 * getpagesize ())
#define TEST_MAIN
#ifdef WIDE
# define TEST_NAME "wcsncmp"
#else
# define TEST_NAME "strncmp"
#endif
#define TIMEOUT (5 * 60)
#include "test-string.h"
#ifdef WIDE
# include <wchar.h>
# define L(str) L##str
# define STRNCMP wcsncmp
# define STRCPY wcscpy
# define STRDUP wcsdup
# define MEMCPY wmemcpy
# define SIMPLE_STRNCMP simple_wcsncmp
# define CHAR wchar_t
# define UCHAR wchar_t
# define CHARBYTES 4
# define CHAR__MAX WCHAR_MAX
# define CHAR__MIN WCHAR_MIN
/* Wcsncmp uses signed semantics for comparison, not unsigned.
Avoid using substraction since possible overflow */
int
simple_wcsncmp (const CHAR *s1, const CHAR *s2, size_t n)
{
wchar_t c1, c2;
while (n--)
{
c1 = *s1++;
c2 = *s2++;
if (c1 == L('\0') || c1 != c2)
return c1 > c2 ? 1 : (c1 < c2 ? -1 : 0);
}
return 0;
}
#else
# define L(str) str
# define STRNCMP strncmp
# define STRCPY strcpy
# define STRDUP strdup
# define MEMCPY memcpy
# define SIMPLE_STRNCMP simple_strncmp
# define CHAR char
# define UCHAR unsigned char
# define CHARBYTES 1
# define CHAR__MAX CHAR_MAX
# define CHAR__MIN CHAR_MIN
/* Strncmp uses unsigned semantics for comparison. */
int
simple_strncmp (const char *s1, const char *s2, size_t n)
{
int ret = 0;
while (n-- && (ret = *(unsigned char *) s1 - * (unsigned char *) s2++) == 0
&& *s1++);
return ret;
}
#endif
typedef int (*proto_t) (const CHAR *, const CHAR *, size_t);
IMPL (STRNCMP, 1)
static int
check_result (impl_t *impl, const CHAR *s1, const CHAR *s2, size_t n,
int exp_result)
{
int result = CALL (impl, s1, s2, n);
if ((exp_result == 0 && result != 0)
|| (exp_result < 0 && result >= 0)
|| (exp_result > 0 && result <= 0))
{
error (0, 0, "Wrong result in function %s %d %d", impl->name,
result, exp_result);
ret = 1;
return -1;
}
return 0;
}
static void
do_one_test (impl_t *impl, const CHAR *s1, const CHAR *s2, size_t n,
int exp_result)
{
if (check_result (impl, s1, s2, n, exp_result) < 0)
return;
}
static void
do_test_limit (size_t align1, size_t align2, size_t len, size_t n, int max_char,
int exp_result)
{
size_t i, align_n;
CHAR *s1, *s2;
align1 &= ~(CHARBYTES - 1);
align2 &= ~(CHARBYTES - 1);
if (n == 0)
{
s1 = (CHAR *) (buf1 + page_size);
s2 = (CHAR *) (buf2 + page_size);
FOR_EACH_IMPL (impl, 0)
do_one_test (impl, s1, s2, n, 0);
return;
}
align1 &= 15;
align2 &= 15;
align_n = (page_size - n * CHARBYTES) & 15;
s1 = (CHAR *) (buf1 + page_size - n * CHARBYTES);
s2 = (CHAR *) (buf2 + page_size - n * CHARBYTES);
if (align1 < align_n)
s1 = (CHAR *) ((char *) s1 - (align_n - align1));
if (align2 < align_n)
s2 = (CHAR *) ((char *) s2 - (align_n - align2));
for (i = 0; i < n; i++)
s1[i] = s2[i] = 1 + 23 * i % max_char;
if (len < n)
{
s1[len] = 0;
s2[len] = 0;
if (exp_result < 0)
s2[len] = 32;
else if (exp_result > 0)
s1[len] = 64;
}
FOR_EACH_IMPL (impl, 0)
do_one_test (impl, s1, s2, n, exp_result);
}
static void
do_test_n (size_t align1, size_t align2, size_t len, size_t n, int n_in_bounds,
int max_char, int exp_result)
{
size_t i, buf_bound;
CHAR *s1, *s2, *s1_end, *s2_end;
align1 &= ~(CHARBYTES - 1);
align2 &= ~(CHARBYTES - 1);
if (n == 0)
return;
buf_bound = n_in_bounds ? n : len;
align1 &= getpagesize () - 1;
if (align1 + (buf_bound + 2) * CHARBYTES >= page_size)
return;
align2 &= getpagesize () - 1;
if (align2 + (buf_bound + 2) * CHARBYTES >= page_size)
return;
s1 = (CHAR *)(buf1 + align1);
s2 = (CHAR *)(buf2 + align2);
if (n_in_bounds)
{
s1[n] = 24 + exp_result;
s2[n] = 23;
}
for (i = 0; i < buf_bound; i++)
s1[i] = s2[i] = 1 + (23 << ((CHARBYTES - 1) * 8)) * i % max_char;
s1[len] = 0;
s2[len] = 0;
if (exp_result < 0)
s2[len] = 32;
else if (exp_result > 0)
s1[len] = 64;
if (len >= n)
s2[n - 1] -= exp_result;
/* Ensure that both s1 and s2 are valid null terminated strings. This is
* required by the standard. */
s1_end = (CHAR *)(buf1 + MIN_PAGE_SIZE - CHARBYTES);
s2_end = (CHAR *)(buf2 + MIN_PAGE_SIZE - CHARBYTES);
*s1_end = 0;
*s2_end = 0;
FOR_EACH_IMPL (impl, 0)
do_one_test (impl, s1, s2, n, exp_result);
}
static void
do_test (size_t align1, size_t align2, size_t len, size_t n, int max_char,
int exp_result)
{
do_test_n (align1, align2, len, n, 1, max_char, exp_result);
}
static void
do_page_test (size_t offset1, size_t offset2, CHAR *s2)
{
CHAR *s1;
int exp_result;
if (offset1 * CHARBYTES >= page_size || offset2 * CHARBYTES >= page_size)
return;
s1 = (CHAR *) buf1;
s1 += offset1;
s2 += offset2;
exp_result= *s1;
FOR_EACH_IMPL (impl, 0)
{
check_result (impl, s1, s2, page_size, -exp_result);
check_result (impl, s2, s1, page_size, exp_result);
}
}
static void
do_random_tests (void)
{
size_t i, j, n, align1, align2, pos, len1, len2, size;
int result;
long r;
UCHAR *p1 = (UCHAR *) (buf1 + page_size - 512 * CHARBYTES);
UCHAR *p2 = (UCHAR *) (buf2 + page_size - 512 * CHARBYTES);
for (n = 0; n < ITERATIONS; n++)
{
align1 = random () & 31;
if (random () & 1)
align2 = random () & 31;
else
align2 = align1 + (random () & 24);
pos = random () & 511;
size = random () & 511;
j = align1 > align2 ? align1 : align2;
if (pos + j >= 511)
pos = 510 - j - (random () & 7);
len1 = random () & 511;
if (pos >= len1 && (random () & 1))
len1 = pos + (random () & 7);
if (len1 + j >= 512)
len1 = 511 - j - (random () & 7);
if (pos >= len1)
len2 = len1;
else
len2 = len1 + (len1 != 511 - j ? random () % (511 - j - len1) : 0);
j = (pos > len2 ? pos : len2) + align1 + 64;
if (j > 512)
j = 512;
for (i = 0; i < j; ++i)
{
p1[i] = random () & 255;
if (i < len1 + align1 && !p1[i])
{
p1[i] = random () & 255;
if (!p1[i])
p1[i] = 1 + (random () & 127);
}
}
for (i = 0; i < j; ++i)
{
p2[i] = random () & 255;
if (i < len2 + align2 && !p2[i])
{
p2[i] = random () & 255;
if (!p2[i])
p2[i] = 1 + (random () & 127);
}
}
result = 0;
MEMCPY (p2 + align2, p1 + align1, pos);
if (pos < len1)
{
if (p2[align2 + pos] == p1[align1 + pos])
{
p2[align2 + pos] = random () & 255;
if (p2[align2 + pos] == p1[align1 + pos])
p2[align2 + pos] = p1[align1 + pos] + 3 + (random () & 127);
}
if (pos < size)
{
if (p1[align1 + pos] < p2[align2 + pos])
result = -1;
else
result = 1;
}
}
p1[len1 + align1] = 0;
p2[len2 + align2] = 0;
FOR_EACH_IMPL (impl, 1)
{
r = CALL (impl, (CHAR *) (p1 + align1), (CHAR *) (p2 + align2), size);
/* Test whether on 64-bit architectures where ABI requires
callee to promote has the promotion been done. */
asm ("" : "=g" (r) : "0" (r));
if ((r == 0 && result)
|| (r < 0 && result >= 0)
|| (r > 0 && result <= 0))
{
error (0, 0, "Iteration %zd - wrong result in function %s (%zd, %zd, %zd, %zd, %zd, %zd) %ld != %d, p1 %p p2 %p",
n, impl->name, align1, align2, len1, len2, pos, size, r, result, p1, p2);
ret = 1;
}
}
}
}
static void
check1 (void)
{
CHAR *s1 = (CHAR *) (buf1 + 0xb2c);
CHAR *s2 = (CHAR *) (buf1 + 0xfd8);
size_t i, offset;
int exp_result;
STRCPY(s1, L("abcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrs"));
STRCPY(s2, L("abcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyzabcdefghijkLMNOPQRSTUV"));
/* Check possible overflow bug for wcsncmp */
s1[4] = CHAR__MAX;
s2[4] = CHAR__MIN;
for (offset = 0; offset < 6; offset++)
{
for (i = 0; i < 80; i++)
{
exp_result = SIMPLE_STRNCMP (s1 + offset, s2 + offset, i);
FOR_EACH_IMPL (impl, 0)
check_result (impl, s1 + offset, s2 + offset, i, exp_result);
}
}
}
static void
check2 (void)
{
size_t i;
CHAR *s1, *s2;
s1 = (CHAR *) buf1;
for (i = 0; i < (page_size / CHARBYTES) - 1; i++)
s1[i] = 23;
s1[i] = 0;
s2 = STRDUP (s1);
for (i = 0; i < 64; ++i)
do_page_test ((3988 / CHARBYTES) + i, (2636 / CHARBYTES), s2);
free (s2);
}
static void
check3 (void)
{
/* To trigger bug 25933, we need a size that is equal to the vector
length times 4. In the case of AVX2 for Intel, we need 32 * 4. We
make this test generic and run it for all architectures as additional
boundary testing for such related algorithms. */
size_t size = 32 * 4;
CHAR *s1 = (CHAR *) (buf1 + (BUF1PAGES - 1) * page_size);
CHAR *s2 = (CHAR *) (buf2 + (BUF1PAGES - 1) * page_size);
int exp_result;
memset (s1, 'a', page_size);
memset (s2, 'a', page_size);
s1[(page_size / CHARBYTES) - 1] = (CHAR) 0;
/* Iterate over a size that is just below where we expect the bug to
trigger up to the size we expect will trigger the bug e.g. [99-128].
Likewise iterate the start of two strings between 30 and 31 bytes
away from the boundary to simulate alignment changes. */
for (size_t s = 99; s <= size; s++)
for (size_t s1a = 30; s1a < 32; s1a++)
for (size_t s2a = 30; s2a < 32; s2a++)
{
CHAR *s1p = s1 + (page_size / CHARBYTES - s) - s1a;
CHAR *s2p = s2 + (page_size / CHARBYTES - s) - s2a;
exp_result = SIMPLE_STRNCMP (s1p, s2p, s);
FOR_EACH_IMPL (impl, 0)
check_result (impl, s1p, s2p, s, exp_result);
}
}
static void
check4 (void)
{
/* To trigger bug 28895; We need 1) both s1 and s2 to be within 32 bytes of
the end of the page. 2) For there to be no mismatch/null byte before the
first page cross. 3) For length (`n`) to be large enough for one string to
cross the page. And 4) for there to be either mismatch/null bytes before
the start of the strings. */
size_t size = 10;
size_t addr_mask = (getpagesize () - 1) ^ (sizeof (CHAR) - 1);
CHAR *s1 = (CHAR *)(buf1 + (addr_mask & 0xffa));
CHAR *s2 = (CHAR *)(buf2 + (addr_mask & 0xfed));
int exp_result;
STRCPY (s1, L ("tst-tlsmod%"));
STRCPY (s2, L ("tst-tls-manydynamic73mod"));
exp_result = SIMPLE_STRNCMP (s1, s2, size);
FOR_EACH_IMPL (impl, 0)
check_result (impl, s1, s2, size, exp_result);
}
static void
check5 (void)
{
const CHAR *s1 = L ("abc");
CHAR *s2 = STRDUP (s1);
FOR_EACH_IMPL (impl, 0)
check_result (impl, s1, s2, SIZE_MAX, 0);
free (s2);
}
static void
check_overflow (void)
{
size_t i, j, of_mask, of_idx;
const size_t of_masks[]
= { ULONG_MAX, LONG_MIN, ULONG_MAX - (ULONG_MAX >> 2),
((size_t)LONG_MAX) >> 1 };
const size_t test_len = MIN(TEST_LEN, 3 * 4096);
for (of_idx = 0; of_idx < sizeof (of_masks) / sizeof (of_masks[0]); ++of_idx)
{
of_mask = of_masks[of_idx];
for (j = 0; j < 160; ++j)
{
for (i = 1; i <= 161; i += (32 / sizeof (CHAR)))
{
do_test_n (j, 0, i, of_mask, 0, 127, 0);
do_test_n (j, 0, i, of_mask, 0, 127, 1);
do_test_n (j, 0, i, of_mask, 0, 127, -1);
do_test_n (j, 0, i, of_mask - j / 2, 0, 127, 0);
do_test_n (j, 0, i, of_mask - j * 2, 0, 127, 1);
do_test_n (j, 0, i, of_mask - j, 0, 127, -1);
do_test_n (j / 2, j, i, of_mask, 0, 127, 0);
do_test_n (j / 2, j, i, of_mask, 0, 127, 1);
do_test_n (j / 2, j, i, of_mask, 0, 127, -1);
do_test_n (j / 2, j, i, of_mask - j, 0, 127, 0);
do_test_n (j / 2, j, i, of_mask - j / 2, 0, 127, 1);
do_test_n (j / 2, j, i, of_mask - j * 2, 0, 127, -1);
do_test_n (0, j, i, of_mask - j * 2, 0, 127, 0);
do_test_n (0, j, i, of_mask - j, 0, 127, 1);
do_test_n (0, j, i, of_mask - j / 2, 0, 127, -1);
do_test_n (getpagesize () - j - 1, 0, i, of_mask, 0, 127, 0);
do_test_n (getpagesize () - j - 1, 0, i, of_mask, 0, 127, 1);
do_test_n (getpagesize () - j - 1, 0, i, of_mask, 0, 127, -1);
do_test_n (getpagesize () - j - 1, 0, i, of_mask - j / 2, 0, 127,
0);
do_test_n (getpagesize () - j - 1, 0, i, of_mask - j * 2, 0, 127,
1);
do_test_n (getpagesize () - j - 1, 0, i, of_mask - j, 0, 127,
-1);
do_test_n (getpagesize () - j - 1, getpagesize () - 2 * j - 1, i,
of_mask, 0, 127, 0);
do_test_n (getpagesize () - j - 1, getpagesize () - 2 * j - 1, i,
of_mask, 0, 127, 1);
do_test_n (getpagesize () - j - 1, getpagesize () - 2 * j - 1, i,
of_mask, 0, 127, -1);
do_test_n (getpagesize () - j - 1, getpagesize () - 2 * j - 1, i,
of_mask - j, 0, 127, 0);
do_test_n (getpagesize () - j - 1, getpagesize () - 2 * j - 1, i,
of_mask - j / 2, 0, 127, 1);
do_test_n (getpagesize () - j - 1, getpagesize () - 2 * j - 1, i,
of_mask - j * 2, 0, 127, -1);
}
for (i = 1; i < test_len; i += i)
{
do_test_n (j, 0, i - 1, of_mask, 0, 127, 0);
do_test_n (j, 0, i - 1, of_mask, 0, 127, 1);
do_test_n (j, 0, i - 1, of_mask, 0, 127, -1);
do_test_n (j, 0, i - 1, of_mask - j / 2, 0, 127, 0);
do_test_n (j, 0, i - 1, of_mask - j * 2, 0, 127, 1);
do_test_n (j, 0, i - 1, of_mask - j, 0, 127, -1);
do_test_n (j / 2, j, i - 1, of_mask, 0, 127, 0);
do_test_n (j / 2, j, i - 1, of_mask, 0, 127, 1);
do_test_n (j / 2, j, i - 1, of_mask, 0, 127, -1);
do_test_n (j / 2, j, i - 1, of_mask - j, 0, 127, 0);
do_test_n (j / 2, j, i - 1, of_mask - j / 2, 0, 127, 1);
do_test_n (j / 2, j, i - 1, of_mask - j * 2, 0, 127, -1);
do_test_n (0, j, i - 1, of_mask - j * 2, 0, 127, 0);
do_test_n (0, j, i - 1, of_mask - j, 0, 127, 1);
do_test_n (0, j, i - 1, of_mask - j / 2, 0, 127, -1);
do_test_n (getpagesize () - j - 1, 0, i - 1, of_mask, 0, 127, 0);
do_test_n (getpagesize () - j - 1, 0, i - 1, of_mask, 0, 127, 1);
do_test_n (getpagesize () - j - 1, 0, i - 1, of_mask, 0, 127,
-1);
do_test_n (getpagesize () - j - 1, 0, i - 1, of_mask - j / 2, 0,
127, 0);
do_test_n (getpagesize () - j - 1, 0, i - 1, of_mask - j * 2, 0,
127, 1);
do_test_n (getpagesize () - j - 1, 0, i - 1, of_mask - j, 0, 127,
-1);
do_test_n (getpagesize () - j - 1, getpagesize () - 2 * j - 1,
i - 1, of_mask, 0, 127, 0);
do_test_n (getpagesize () - j - 1, getpagesize () - 2 * j - 1,
i - 1, of_mask, 0, 127, 1);
do_test_n (getpagesize () - j - 1, getpagesize () - 2 * j - 1,
i - 1, of_mask, 0, 127, -1);
do_test_n (getpagesize () - j - 1, getpagesize () - 2 * j - 1,
i - 1, of_mask - j, 0, 127, 0);
do_test_n (getpagesize () - j - 1, getpagesize () - 2 * j - 1,
i - 1, of_mask - j / 2, 0, 127, 1);
do_test_n (getpagesize () - j - 1, getpagesize () - 2 * j - 1,
i - 1, of_mask - j * 2, 0, 127, -1);
}
}
}
}
int
test_main (void)
{
size_t i, j, k;
const size_t test_len = MIN(TEST_LEN, 3 * 4096);
test_init ();
check1 ();
check2 ();
check3 ();
check4 ();
check5 ();
printf ("%23s", "");
FOR_EACH_IMPL (impl, 0)
printf ("\t%s", impl->name);
putchar ('\n');
for (i =0; i < 16; ++i)
{
do_test (0, 0, 8, i, 127, 0);
do_test (0, 0, 8, i, 127, -1);
do_test (0, 0, 8, i, 127, 1);
do_test (i, i, 8, i, 127, 0);
do_test (i, i, 8, i, 127, 1);
do_test (i, i, 8, i, 127, -1);
do_test (i, 2 * i, 8, i, 127, 0);
do_test (2 * i, i, 8, i, 127, 1);
do_test (i, 3 * i, 8, i, 127, -1);
do_test (0, 0, 8, i, 255, 0);
do_test (0, 0, 8, i, 255, -1);
do_test (0, 0, 8, i, 255, 1);
do_test (i, i, 8, i, 255, 0);
do_test (i, i, 8, i, 255, 1);
do_test (i, i, 8, i, 255, -1);
do_test (i, 2 * i, 8, i, 255, 0);
do_test (2 * i, i, 8, i, 255, 1);
do_test (i, 3 * i, 8, i, 255, -1);
}
for (i = 1; i < 8; ++i)
{
do_test (0, 0, 8 << i, 16 << i, 127, 0);
do_test (0, 0, 8 << i, 16 << i, 127, 1);
do_test (0, 0, 8 << i, 16 << i, 127, -1);
do_test (0, 0, 8 << i, 16 << i, 255, 0);
do_test (0, 0, 8 << i, 16 << i, 255, 1);
do_test (0, 0, 8 << i, 16 << i, 255, -1);
do_test (8 - i, 2 * i, 8 << i, 16 << i, 127, 0);
do_test (8 - i, 2 * i, 8 << i, 16 << i, 127, 1);
do_test (2 * i, i, 8 << i, 16 << i, 255, 0);
do_test (2 * i, i, 8 << i, 16 << i, 255, 1);
}
do_test_limit (0, 0, 0, 0, 127, 0);
do_test_limit (4, 0, 21, 20, 127, 0);
do_test_limit (0, 4, 21, 20, 127, 0);
do_test_limit (8, 0, 25, 24, 127, 0);
do_test_limit (0, 8, 25, 24, 127, 0);
for (i = 0; i < 8; ++i)
{
do_test_limit (0, 0, 17 - i, 16 - i, 127, 0);
do_test_limit (0, 0, 17 - i, 16 - i, 255, 0);
do_test_limit (0, 0, 15 - i, 16 - i, 127, 0);
do_test_limit (0, 0, 15 - i, 16 - i, 127, 1);
do_test_limit (0, 0, 15 - i, 16 - i, 127, -1);
do_test_limit (0, 0, 15 - i, 16 - i, 255, 0);
do_test_limit (0, 0, 15 - i, 16 - i, 255, 1);
do_test_limit (0, 0, 15 - i, 16 - i, 255, -1);
}
for (j = 0; j < 160; ++j)
{
for (i = 0; i < test_len;)
{
do_test_n (getpagesize () - j - 1, 0, i, i + 1, 0, 127, 0);
do_test_n (getpagesize () - j - 1, 0, i, i + 1, 0, 127, 1);
do_test_n (getpagesize () - j - 1, 0, i, i + 1, 0, 127, -1);
do_test_n (getpagesize () - j - 1, 0, i, i, 0, 127, 0);
do_test_n (getpagesize () - j - 1, 0, i, i - 1, 0, 127, 0);
do_test_n (getpagesize () - j - 1, 0, i, ULONG_MAX, 0, 127, 0);
do_test_n (getpagesize () - j - 1, 0, i, ULONG_MAX, 0, 127, 1);
do_test_n (getpagesize () - j - 1, 0, i, ULONG_MAX, 0, 127, -1);
do_test_n (getpagesize () - j - 1, 0, i, ULONG_MAX - i, 0, 127, 0);
do_test_n (getpagesize () - j - 1, 0, i, ULONG_MAX - i, 0, 127, 1);
do_test_n (getpagesize () - j - 1, 0, i, ULONG_MAX - i, 0, 127, -1);
do_test_n (getpagesize () - j - 1, j, i, i + 1, 0, 127, 0);
do_test_n (getpagesize () - j - 1, j, i, i + 1, 0, 127, 1);
do_test_n (getpagesize () - j - 1, j, i, i + 1, 0, 127, -1);
do_test_n (getpagesize () - j - 1, j, i, i, 0, 127, 0);
do_test_n (getpagesize () - j - 1, j, i, i - 1, 0, 127, 0);
do_test_n (getpagesize () - j - 1, j, i, ULONG_MAX, 0, 127, 0);
do_test_n (getpagesize () - j - 1, j, i, ULONG_MAX, 0, 127, 1);
do_test_n (getpagesize () - j - 1, j, i, ULONG_MAX, 0, 127, -1);
do_test_n (getpagesize () - j - 1, j, i, ULONG_MAX - i, 0, 127, 0);
do_test_n (getpagesize () - j - 1, j, i, ULONG_MAX - i, 0, 127, 1);
do_test_n (getpagesize () - j - 1, j, i, ULONG_MAX - i, 0, 127, -1);
do_test_n (0, getpagesize () - j - 1, i, i + 1, 0, 127, 0);
do_test_n (0, getpagesize () - j - 1, i, i + 1, 0, 127, 1);
do_test_n (0, getpagesize () - j - 1, i, i + 1, 0, 127, -1);
do_test_n (0, getpagesize () - j - 1, i, i, 0, 127, 0);
do_test_n (0, getpagesize () - j - 1, i, i - 1, 0, 127, 0);
do_test_n (0, getpagesize () - j - 1, i, ULONG_MAX, 0, 127, 0);
do_test_n (0, getpagesize () - j - 1, i, ULONG_MAX, 0, 127, 1);
do_test_n (0, getpagesize () - j - 1, i, ULONG_MAX, 0, 127, -1);
do_test_n (0, getpagesize () - j - 1, i, ULONG_MAX - i, 0, 127, 0);
do_test_n (0, getpagesize () - j - 1, i, ULONG_MAX - i, 0, 127, 1);
do_test_n (0, getpagesize () - j - 1, i, ULONG_MAX - i, 0, 127, -1);
do_test_n (j, getpagesize () - j - 1, i, i + 1, 0, 127, 0);
do_test_n (j, getpagesize () - j - 1, i, i + 1, 0, 127, 1);
do_test_n (j, getpagesize () - j - 1, i, i + 1, 0, 127, -1);
do_test_n (j, getpagesize () - j - 1, i, i, 0, 127, 0);
do_test_n (j, getpagesize () - j - 1, i, i - 1, 0, 127, 0);
do_test_n (j, getpagesize () - j - 1, i, ULONG_MAX, 0, 127, 0);
do_test_n (j, getpagesize () - j - 1, i, ULONG_MAX, 0, 127, 1);
do_test_n (j, getpagesize () - j - 1, i, ULONG_MAX, 0, 127, -1);
do_test_n (j, getpagesize () - j - 1, i, ULONG_MAX - i, 0, 127, 0);
do_test_n (j, getpagesize () - j - 1, i, ULONG_MAX - i, 0, 127, 1);
do_test_n (j, getpagesize () - j - 1, i, ULONG_MAX - i, 0, 127, -1);
for (k = 2; k <= 128; k += k)
{
do_test (getpagesize () - k, getpagesize () - j - 1, i - 1, i,
127, 0);
do_test (getpagesize () - k - 1, getpagesize () - j - 1, i - 1,
i, 127, 0);
do_test (getpagesize () - k, getpagesize () - j - 1, i + 1, i,
127, 0);
do_test (getpagesize () - k - 1, getpagesize () - j - 1, i + 1,
i, 127, 0);
do_test (getpagesize () - k, getpagesize () - j - 1, i, i, 127,
0);
do_test (getpagesize () - k - 1, getpagesize () - j - 1, i, i,
127, 0);
do_test (getpagesize () - k, getpagesize () - j - 1, i + 1, i,
127, -1);
do_test (getpagesize () - k - 1, getpagesize () - j - 1, i + 1,
i, 127, -1);
do_test (getpagesize () - k, getpagesize () - j - 1, i + 1, i,
127, 1);
do_test (getpagesize () - k - 1, getpagesize () - j - 1, i + 1,
i, 127, 1);
}
if (i < 32)
{
i += 1;
}
else if (i < 161)
{
i += 7;
}
else if (i + 161 < test_len)
{
i += 31;
i *= 17;
i /= 16;
if (i + 161 > test_len)
{
i = test_len - 160;
}
}
else if (i + 32 < test_len)
{
i += 7;
}
else
{
i += 1;
}
}
}
check_overflow ();
do_random_tests ();
return ret;
}
#include <support/test-driver.c>