/* Tests for struct alloc_buffer.
Copyright (C) 2017-2018 Free Software Foundation, Inc.
This file is part of the GNU C Library.
The GNU C Library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
The GNU C Library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with the GNU C Library; if not, see
. */
#include
#include
#include
#include
#include
#include
#include
#include
/* Return true if PTR is sufficiently aligned for TYPE. */
#define IS_ALIGNED(ptr, type) \
((((uintptr_t) ptr) & (__alloc_buffer_assert_align (__alignof (type)) - 1)) \
== 0)
/* Structure with non-power-of-two size. */
struct twelve
{
uint32_t buffer[3] __attribute__ ((aligned (4)));
};
_Static_assert (sizeof (struct twelve) == 12, "struct twelve");
_Static_assert (__alignof__ (struct twelve) == 4, "struct twelve");
/* Check for success obtaining empty arrays. Does not assume the
buffer is empty. */
static void
test_empty_array (struct alloc_buffer refbuf)
{
bool refbuf_failed = alloc_buffer_has_failed (&refbuf);
if (test_verbose)
printf ("info: %s: current=0x%llx end=0x%llx refbuf_failed=%d\n",
__func__, (unsigned long long) refbuf.__alloc_buffer_current,
(unsigned long long) refbuf.__alloc_buffer_end, refbuf_failed);
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY ((alloc_buffer_alloc_bytes (&buf, 0) == NULL)
== refbuf_failed);
TEST_VERIFY (alloc_buffer_has_failed (&buf) == refbuf_failed);
}
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY ((alloc_buffer_alloc_array (&buf, char, 0) == NULL)
== refbuf_failed);
TEST_VERIFY (alloc_buffer_has_failed (&buf) == refbuf_failed);
}
/* The following tests can fail due to the need for aligning the
returned pointer. */
{
struct alloc_buffer buf = refbuf;
bool expect_failure = refbuf_failed
|| !IS_ALIGNED (alloc_buffer_next (&buf, void), double);
double *ptr = alloc_buffer_alloc_array (&buf, double, 0);
TEST_VERIFY (IS_ALIGNED (ptr, double));
TEST_VERIFY ((ptr == NULL) == expect_failure);
TEST_VERIFY (alloc_buffer_has_failed (&buf) == expect_failure);
}
{
struct alloc_buffer buf = refbuf;
bool expect_failure = refbuf_failed
|| !IS_ALIGNED (alloc_buffer_next (&buf, void), struct twelve);
struct twelve *ptr = alloc_buffer_alloc_array (&buf, struct twelve, 0);
TEST_VERIFY (IS_ALIGNED (ptr, struct twelve));
TEST_VERIFY ((ptr == NULL) == expect_failure);
TEST_VERIFY (alloc_buffer_has_failed (&buf) == expect_failure);
}
}
/* Test allocation of impossibly large arrays. */
static void
test_impossible_array (struct alloc_buffer refbuf)
{
if (test_verbose)
printf ("info: %s: current=0x%llx end=0x%llx\n",
__func__, (unsigned long long) refbuf.__alloc_buffer_current,
(unsigned long long) refbuf.__alloc_buffer_end);
static const size_t counts[] =
{ SIZE_MAX, SIZE_MAX - 1, SIZE_MAX - 2, SIZE_MAX - 3, SIZE_MAX - 4,
SIZE_MAX / 2, SIZE_MAX / 2 + 1, SIZE_MAX / 2 - 1, 0};
for (int i = 0; counts[i] != 0; ++i)
{
size_t count = counts[i];
if (test_verbose)
printf ("info: %s: count=%zu\n", __func__, count);
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc_bytes (&buf, count) == NULL);
TEST_VERIFY (alloc_buffer_has_failed (&buf));
}
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc_array (&buf, char, count) == NULL);
TEST_VERIFY (alloc_buffer_has_failed (&buf));
}
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc_array (&buf, short, count) == NULL);
TEST_VERIFY (alloc_buffer_has_failed (&buf));
}
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc_array (&buf, double, count) == NULL);
TEST_VERIFY (alloc_buffer_has_failed (&buf));
}
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc_array (&buf, struct twelve, count)
== NULL);
TEST_VERIFY (alloc_buffer_has_failed (&buf));
}
}
}
/* Check for failure to obtain anything from a failed buffer. */
static void
test_after_failure (struct alloc_buffer refbuf)
{
if (test_verbose)
printf ("info: %s: current=0x%llx end=0x%llx\n",
__func__, (unsigned long long) refbuf.__alloc_buffer_current,
(unsigned long long) refbuf.__alloc_buffer_end);
TEST_VERIFY (alloc_buffer_has_failed (&refbuf));
{
struct alloc_buffer buf = refbuf;
alloc_buffer_add_byte (&buf, 17);
TEST_VERIFY (alloc_buffer_has_failed (&buf));
}
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc (&buf, char) == NULL);
TEST_VERIFY (alloc_buffer_has_failed (&buf));
}
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc (&buf, double) == NULL);
TEST_VERIFY (alloc_buffer_has_failed (&buf));
}
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc (&buf, struct twelve) == NULL);
TEST_VERIFY (alloc_buffer_has_failed (&buf));
}
test_impossible_array (refbuf);
for (int count = 0; count <= 4; ++count)
{
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc_bytes (&buf, count) == NULL);
TEST_VERIFY (alloc_buffer_has_failed (&buf));
}
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc_array (&buf, char, count) == NULL);
TEST_VERIFY (alloc_buffer_has_failed (&buf));
}
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc_array (&buf, double, count) == NULL);
TEST_VERIFY (alloc_buffer_has_failed (&buf));
}
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc_array (&buf, struct twelve, count)
== NULL);
TEST_VERIFY (alloc_buffer_has_failed (&buf));
}
}
}
static void
test_empty (struct alloc_buffer refbuf)
{
TEST_VERIFY (alloc_buffer_size (&refbuf) == 0);
if (alloc_buffer_next (&refbuf, void) != NULL)
TEST_VERIFY (!alloc_buffer_has_failed (&refbuf));
test_empty_array (refbuf);
test_impossible_array (refbuf);
/* Failure to obtain non-empty objects. */
{
struct alloc_buffer buf = refbuf;
alloc_buffer_add_byte (&buf, 17);
test_after_failure (buf);
}
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc (&buf, char) == NULL);
test_after_failure (buf);
}
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc (&buf, double) == NULL);
test_after_failure (buf);
}
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc (&buf, struct twelve) == NULL);
test_after_failure (buf);
}
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc_array (&buf, char, 1) == NULL);
test_after_failure (buf);
}
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc_array (&buf, double, 1) == NULL);
test_after_failure (buf);
}
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc_array (&buf, struct twelve, 1) == NULL);
test_after_failure (buf);
}
}
static void
test_size_1 (struct alloc_buffer refbuf)
{
TEST_VERIFY (!alloc_buffer_has_failed (&refbuf));
TEST_VERIFY (alloc_buffer_size (&refbuf) == 1);
test_empty_array (refbuf);
test_impossible_array (refbuf);
/* Success adding a single byte. */
{
struct alloc_buffer buf = refbuf;
alloc_buffer_add_byte (&buf, 17);
TEST_VERIFY (!alloc_buffer_has_failed (&buf));
test_empty (buf);
}
TEST_VERIFY (memcmp (alloc_buffer_next (&refbuf, void), "\x11", 1) == 0);
{
struct alloc_buffer buf = refbuf;
signed char *ptr = alloc_buffer_alloc (&buf, signed char);
TEST_VERIFY_EXIT (ptr != NULL);
TEST_VERIFY (!alloc_buffer_has_failed (&buf));
*ptr = 126;
test_empty (buf);
}
TEST_VERIFY (memcmp (alloc_buffer_next (&refbuf, void), "\176", 1) == 0);
{
struct alloc_buffer buf = refbuf;
char *ptr = alloc_buffer_alloc_array (&buf, char, 1);
TEST_VERIFY_EXIT (ptr != NULL);
TEST_VERIFY (!alloc_buffer_has_failed (&buf));
*ptr = (char) 253;
test_empty (buf);
}
TEST_VERIFY (memcmp (alloc_buffer_next (&refbuf, void), "\xfd", 1) == 0);
/* Failure with larger objects. */
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc (&buf, short) == NULL);
test_after_failure (buf);
}
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc (&buf, double) == NULL);
test_after_failure (buf);
}
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc (&buf, struct twelve) == NULL);
test_after_failure (buf);
}
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc_array (&buf, short, 1) == NULL);
test_after_failure (buf);
}
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc_array (&buf, double, 1) == NULL);
test_after_failure (buf);
}
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc_array (&buf, struct twelve, 1) == NULL);
test_after_failure (buf);
}
}
static void
test_size_2 (struct alloc_buffer refbuf)
{
TEST_VERIFY (!alloc_buffer_has_failed (&refbuf));
TEST_VERIFY (alloc_buffer_size (&refbuf) == 2);
TEST_VERIFY (IS_ALIGNED (alloc_buffer_next (&refbuf, void), short));
test_empty_array (refbuf);
test_impossible_array (refbuf);
/* Success adding two bytes. */
{
struct alloc_buffer buf = refbuf;
alloc_buffer_add_byte (&buf, '@');
TEST_VERIFY (!alloc_buffer_has_failed (&buf));
test_size_1 (buf);
}
TEST_VERIFY (memcmp (alloc_buffer_next (&refbuf, void), "@\xfd", 2) == 0);
{
struct alloc_buffer buf = refbuf;
signed char *ptr = alloc_buffer_alloc (&buf, signed char);
TEST_VERIFY_EXIT (ptr != NULL);
TEST_VERIFY (!alloc_buffer_has_failed (&buf));
*ptr = 'A';
test_size_1 (buf);
}
TEST_VERIFY (memcmp (alloc_buffer_next (&refbuf, void), "A\xfd", 2) == 0);
{
struct alloc_buffer buf = refbuf;
char *ptr = alloc_buffer_alloc_array (&buf, char, 1);
TEST_VERIFY_EXIT (ptr != NULL);
TEST_VERIFY (!alloc_buffer_has_failed (&buf));
*ptr = 'B';
test_size_1 (buf);
}
TEST_VERIFY (memcmp (alloc_buffer_next (&refbuf, void), "B\xfd", 2) == 0);
{
struct alloc_buffer buf = refbuf;
unsigned short *ptr = alloc_buffer_alloc (&buf, unsigned short);
TEST_VERIFY_EXIT (ptr != NULL);
TEST_VERIFY (IS_ALIGNED (ptr, unsigned short));
TEST_VERIFY (!alloc_buffer_has_failed (&buf));
*ptr = htons (0x12f4);
test_empty (buf);
}
TEST_VERIFY (memcmp (alloc_buffer_next (&refbuf, void), "\x12\xf4", 2) == 0);
{
struct alloc_buffer buf = refbuf;
unsigned short *ptr = alloc_buffer_alloc_array (&buf, unsigned short, 1);
TEST_VERIFY_EXIT (ptr != NULL);
TEST_VERIFY (IS_ALIGNED (ptr, unsigned short));
TEST_VERIFY (!alloc_buffer_has_failed (&buf));
*ptr = htons (0x13f5);
test_empty (buf);
}
TEST_VERIFY (memcmp (alloc_buffer_next (&refbuf, void), "\x13\xf5", 2) == 0);
{
struct alloc_buffer buf = refbuf;
char *ptr = alloc_buffer_alloc_array (&buf, char, 2);
TEST_VERIFY_EXIT (ptr != NULL);
TEST_VERIFY (!alloc_buffer_has_failed (&buf));
memcpy (ptr, "12", 2);
test_empty (buf);
}
TEST_VERIFY (memcmp (alloc_buffer_next (&refbuf, void), "12", 2) == 0);
}
static void
test_misaligned (char pad)
{
enum { SIZE = 23 };
char *backing = xmalloc (SIZE + 2);
backing[0] = ~pad;
backing[SIZE + 1] = pad;
struct alloc_buffer refbuf = alloc_buffer_create (backing + 1, SIZE);
{
struct alloc_buffer buf = refbuf;
short *ptr = alloc_buffer_alloc_array (&buf, short, SIZE / sizeof (short));
TEST_VERIFY_EXIT (ptr != NULL);
TEST_VERIFY (IS_ALIGNED (ptr, short));
TEST_VERIFY (!alloc_buffer_has_failed (&buf));
for (int i = 0; i < SIZE / sizeof (short); ++i)
ptr[i] = htons (0xff01 + i);
TEST_VERIFY (memcmp (ptr,
"\xff\x01\xff\x02\xff\x03\xff\x04"
"\xff\x05\xff\x06\xff\x07\xff\x08"
"\xff\x09\xff\x0a\xff\x0b", 22) == 0);
}
{
struct alloc_buffer buf = refbuf;
uint32_t *ptr = alloc_buffer_alloc_array
(&buf, uint32_t, SIZE / sizeof (uint32_t));
TEST_VERIFY_EXIT (ptr != NULL);
TEST_VERIFY (IS_ALIGNED (ptr, uint32_t));
TEST_VERIFY (!alloc_buffer_has_failed (&buf));
for (int i = 0; i < SIZE / sizeof (uint32_t); ++i)
ptr[i] = htonl (0xf1e2d301 + i);
TEST_VERIFY (memcmp (ptr,
"\xf1\xe2\xd3\x01\xf1\xe2\xd3\x02"
"\xf1\xe2\xd3\x03\xf1\xe2\xd3\x04"
"\xf1\xe2\xd3\x05", 20) == 0);
}
{
struct alloc_buffer buf = refbuf;
struct twelve *ptr = alloc_buffer_alloc (&buf, struct twelve);
TEST_VERIFY_EXIT (ptr != NULL);
TEST_VERIFY (IS_ALIGNED (ptr, struct twelve));
TEST_VERIFY (!alloc_buffer_has_failed (&buf));
ptr->buffer[0] = htonl (0x11223344);
ptr->buffer[1] = htonl (0x55667788);
ptr->buffer[2] = htonl (0x99aabbcc);
TEST_VERIFY (memcmp (ptr,
"\x11\x22\x33\x44"
"\x55\x66\x77\x88"
"\x99\xaa\xbb\xcc", 12) == 0);
}
{
static const double nums[] = { 1, 2 };
struct alloc_buffer buf = refbuf;
double *ptr = alloc_buffer_alloc_array (&buf, double, 2);
TEST_VERIFY_EXIT (ptr != NULL);
TEST_VERIFY (IS_ALIGNED (ptr, double));
TEST_VERIFY (!alloc_buffer_has_failed (&buf));
ptr[0] = nums[0];
ptr[1] = nums[1];
TEST_VERIFY (memcmp (ptr, nums, sizeof (nums)) == 0);
}
/* Verify that padding was not overwritten. */
TEST_VERIFY (backing[0] == (char) ~pad);
TEST_VERIFY (backing[SIZE + 1] == pad);
free (backing);
}
/* Check that overflow during alignment is handled properly. */
static void
test_large_misaligned (void)
{
uintptr_t minus1 = -1;
uintptr_t start = minus1 & ~0xfe;
struct alloc_buffer refbuf = alloc_buffer_create ((void *) start, 16);
TEST_VERIFY (!alloc_buffer_has_failed (&refbuf));
struct __attribute__ ((aligned (256))) align256
{
int dymmy;
};
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc (&buf, struct align256) == NULL);
test_after_failure (buf);
}
for (int count = 0; count < 3; ++count)
{
struct alloc_buffer buf = refbuf;
TEST_VERIFY (alloc_buffer_alloc_array (&buf, struct align256, count)
== NULL);
test_after_failure (buf);
}
}
/* Check behavior of large allocations. */
static void
test_large (void)
{
{
/* Allocation which wraps around. */
struct alloc_buffer buf = { 1, SIZE_MAX };
TEST_VERIFY (alloc_buffer_alloc_array (&buf, char, SIZE_MAX) == NULL);
TEST_VERIFY (alloc_buffer_has_failed (&buf));
}
{
/* Successful very large allocation. */
struct alloc_buffer buf = { 1, SIZE_MAX };
uintptr_t val = (uintptr_t) alloc_buffer_alloc_array
(&buf, char, SIZE_MAX - 1);
TEST_VERIFY (val == 1);
TEST_VERIFY (!alloc_buffer_has_failed (&buf));
test_empty (buf);
}
{
typedef char __attribute__ ((aligned (2))) char2;
/* Overflow in array size computation. */
struct alloc_buffer buf = { 1, SIZE_MAX };
TEST_VERIFY (alloc_buffer_alloc_array (&buf, char2, SIZE_MAX - 1) == NULL);
TEST_VERIFY (alloc_buffer_has_failed (&buf));
/* Successful allocation after alignment. */
buf = (struct alloc_buffer) { 1, SIZE_MAX };
uintptr_t val = (uintptr_t) alloc_buffer_alloc_array
(&buf, char2, SIZE_MAX - 2);
TEST_VERIFY (val == 2);
test_empty (buf);
/* Alignment behavior near the top of the address space. */
buf = (struct alloc_buffer) { SIZE_MAX, SIZE_MAX };
TEST_VERIFY (alloc_buffer_next (&buf, char2) == NULL);
TEST_VERIFY (alloc_buffer_has_failed (&buf));
buf = (struct alloc_buffer) { SIZE_MAX, SIZE_MAX };
TEST_VERIFY (alloc_buffer_alloc_array (&buf, char2, 0) == NULL);
TEST_VERIFY (alloc_buffer_has_failed (&buf));
}
{
typedef short __attribute__ ((aligned (2))) short2;
/* Test overflow in size computation. */
struct alloc_buffer buf = { 1, SIZE_MAX };
TEST_VERIFY (alloc_buffer_alloc_array (&buf, short2, SIZE_MAX / 2)
== NULL);
TEST_VERIFY (alloc_buffer_has_failed (&buf));
/* A slightly smaller array fits within the allocation. */
buf = (struct alloc_buffer) { 2, SIZE_MAX - 1 };
uintptr_t val = (uintptr_t) alloc_buffer_alloc_array
(&buf, short2, SIZE_MAX / 2 - 1);
TEST_VERIFY (val == 2);
test_empty (buf);
}
}
static void
test_copy_bytes (void)
{
char backing[4];
{
memset (backing, '@', sizeof (backing));
struct alloc_buffer buf = alloc_buffer_create (backing, sizeof (backing));
alloc_buffer_copy_bytes (&buf, "1", 1);
TEST_VERIFY (!alloc_buffer_has_failed (&buf));
TEST_VERIFY (alloc_buffer_size (&buf) == 3);
TEST_VERIFY (memcmp (backing, "1@@@", 4) == 0);
}
{
memset (backing, '@', sizeof (backing));
struct alloc_buffer buf = alloc_buffer_create (backing, sizeof (backing));
alloc_buffer_copy_bytes (&buf, "12", 3);
TEST_VERIFY (!alloc_buffer_has_failed (&buf));
TEST_VERIFY (alloc_buffer_size (&buf) == 1);
TEST_VERIFY (memcmp (backing, "12\0@", 4) == 0);
}
{
memset (backing, '@', sizeof (backing));
struct alloc_buffer buf = alloc_buffer_create (backing, sizeof (backing));
alloc_buffer_copy_bytes (&buf, "1234", 4);
TEST_VERIFY (!alloc_buffer_has_failed (&buf));
TEST_VERIFY (alloc_buffer_size (&buf) == 0);
TEST_VERIFY (memcmp (backing, "1234", 4) == 0);
}
{
memset (backing, '@', sizeof (backing));
struct alloc_buffer buf = alloc_buffer_create (backing, sizeof (backing));
alloc_buffer_copy_bytes (&buf, "1234", 5);
TEST_VERIFY (alloc_buffer_has_failed (&buf));
TEST_VERIFY (memcmp (backing, "@@@@", 4) == 0);
}
{
memset (backing, '@', sizeof (backing));
struct alloc_buffer buf = alloc_buffer_create (backing, sizeof (backing));
alloc_buffer_copy_bytes (&buf, "1234", -1);
TEST_VERIFY (alloc_buffer_has_failed (&buf));
TEST_VERIFY (memcmp (backing, "@@@@", 4) == 0);
}
}
static void
test_copy_string (void)
{
char backing[4];
{
memset (backing, '@', sizeof (backing));
struct alloc_buffer buf = alloc_buffer_create (backing, sizeof (backing));
const char *p = alloc_buffer_copy_string (&buf, "");
TEST_VERIFY (p == backing);
TEST_VERIFY (strcmp (p, "") == 0);
TEST_VERIFY (!alloc_buffer_has_failed (&buf));
TEST_VERIFY (alloc_buffer_size (&buf) == 3);
TEST_VERIFY (memcmp (backing, "\0@@@", 4) == 0);
}
{
memset (backing, '@', sizeof (backing));
struct alloc_buffer buf = alloc_buffer_create (backing, sizeof (backing));
const char *p = alloc_buffer_copy_string (&buf, "1");
TEST_VERIFY (p == backing);
TEST_VERIFY (strcmp (p, "1") == 0);
TEST_VERIFY (!alloc_buffer_has_failed (&buf));
TEST_VERIFY (alloc_buffer_size (&buf) == 2);
TEST_VERIFY (memcmp (backing, "1\0@@", 4) == 0);
}
{
memset (backing, '@', sizeof (backing));
struct alloc_buffer buf = alloc_buffer_create (backing, sizeof (backing));
const char *p = alloc_buffer_copy_string (&buf, "12");
TEST_VERIFY (p == backing);
TEST_VERIFY (strcmp (p, "12") == 0);
TEST_VERIFY (!alloc_buffer_has_failed (&buf));
TEST_VERIFY (alloc_buffer_size (&buf) == 1);
TEST_VERIFY (memcmp (backing, "12\0@", 4) == 0);
}
{
memset (backing, '@', sizeof (backing));
struct alloc_buffer buf = alloc_buffer_create (backing, sizeof (backing));
const char *p = alloc_buffer_copy_string (&buf, "123");
TEST_VERIFY (p == backing);
TEST_VERIFY (strcmp (p, "123") == 0);
TEST_VERIFY (!alloc_buffer_has_failed (&buf));
TEST_VERIFY (alloc_buffer_size (&buf) == 0);
TEST_VERIFY (memcmp (backing, "123", 4) == 0);
}
{
memset (backing, '@', sizeof (backing));
struct alloc_buffer buf = alloc_buffer_create (backing, sizeof (backing));
TEST_VERIFY (alloc_buffer_copy_string (&buf, "1234") == NULL);
TEST_VERIFY (alloc_buffer_has_failed (&buf));
TEST_VERIFY (memcmp (backing, "@@@@", 4) == 0);
}
{
memset (backing, '@', sizeof (backing));
struct alloc_buffer buf = alloc_buffer_create (backing, sizeof (backing));
TEST_VERIFY (alloc_buffer_copy_string (&buf, "12345") == NULL);
TEST_VERIFY (alloc_buffer_has_failed (&buf));
TEST_VERIFY (memcmp (backing, "@@@@", 4) == 0);
}
}
static int
do_test (void)
{
test_empty (alloc_buffer_create (NULL, 0));
test_empty (alloc_buffer_create ((char *) "", 0));
test_empty (alloc_buffer_create ((void *) 1, 0));
{
void *ptr = (void *) ""; /* Cannot be freed. */
struct alloc_buffer buf = alloc_buffer_allocate (1, &ptr);
test_size_1 (buf);
free (ptr); /* Should have been overwritten. */
}
{
void *ptr= (void *) ""; /* Cannot be freed. */
struct alloc_buffer buf = alloc_buffer_allocate (2, &ptr);
test_size_2 (buf);
free (ptr); /* Should have been overwritten. */
}
test_misaligned (0);
test_misaligned (0xc7);
test_misaligned (0xff);
test_large_misaligned ();
test_large ();
test_copy_bytes ();
test_copy_string ();
return 0;
}
#include