/* Test allocation failures with dynamic arrays.
Copyright (C) 2017-2019 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
. */
/* This test is separate from tst-dynarray because it cannot run under
valgrind. */
#include "tst-dynarray-shared.h"
#include
#include
#include
#include
#include
#include
#include
#include
/* Data structure to fill up the heap. */
struct heap_filler
{
struct heap_filler *next;
};
/* Allocate objects until the heap is full. */
static struct heap_filler *
fill_heap (void)
{
size_t pad = 4096;
struct heap_filler *head = NULL;
while (true)
{
struct heap_filler *new_head = malloc (sizeof (*new_head) + pad);
if (new_head == NULL)
{
if (pad > 0)
{
/* Try again with smaller allocations. */
pad = 0;
continue;
}
else
break;
}
new_head->next = head;
head = new_head;
}
return head;
}
/* Free the heap-filling allocations, so that we can continue testing
and detect memory leaks elsewhere. */
static void
free_fill_heap (struct heap_filler *head)
{
while (head != NULL)
{
struct heap_filler *next = head->next;
free (head);
head = next;
}
}
/* Check allocation failures for int arrays (without an element free
function). */
static void
test_int_fail (void)
{
/* Exercise failure in add/emplace.
do_add: Use emplace (false) or add (true) to add elements.
do_finalize: Perform finalization at the end (instead of free). */
for (int do_add = 0; do_add < 2; ++do_add)
for (int do_finalize = 0; do_finalize < 2; ++do_finalize)
{
struct dynarray_int dyn;
dynarray_int_init (&dyn);
size_t count = 0;
while (true)
{
if (do_add)
{
dynarray_int_add (&dyn, 0);
if (dynarray_int_has_failed (&dyn))
break;
}
else
{
int *place = dynarray_int_emplace (&dyn);
if (place == NULL)
break;
TEST_VERIFY_EXIT (!dynarray_int_has_failed (&dyn));
*place = 0;
}
++count;
}
printf ("info: %s: failure after %zu elements\n", __func__, count);
TEST_VERIFY_EXIT (dynarray_int_has_failed (&dyn));
if (do_finalize)
{
struct int_array result = { (int *) (uintptr_t) -1, -1 };
TEST_VERIFY_EXIT (!dynarray_int_finalize (&dyn, &result));
TEST_VERIFY_EXIT (result.array == (int *) (uintptr_t) -1);
TEST_VERIFY_EXIT (result.length == (size_t) -1);
}
else
dynarray_int_free (&dyn);
CHECK_INIT_STATE (int, &dyn);
}
/* Exercise failure in finalize. */
for (int do_add = 0; do_add < 2; ++do_add)
{
struct dynarray_int dyn;
dynarray_int_init (&dyn);
for (unsigned int i = 0; i < 10000; ++i)
{
if (do_add)
{
dynarray_int_add (&dyn, i);
TEST_VERIFY_EXIT (!dynarray_int_has_failed (&dyn));
}
else
{
int *place = dynarray_int_emplace (&dyn);
TEST_VERIFY_EXIT (place != NULL);
*place = i;
}
}
TEST_VERIFY_EXIT (!dynarray_int_has_failed (&dyn));
struct heap_filler *heap_filler = fill_heap ();
struct int_array result = { (int *) (uintptr_t) -1, -1 };
TEST_VERIFY_EXIT (!dynarray_int_finalize (&dyn, &result));
TEST_VERIFY_EXIT (result.array == (int *) (uintptr_t) -1);
TEST_VERIFY_EXIT (result.length == (size_t) -1);
CHECK_INIT_STATE (int, &dyn);
free_fill_heap (heap_filler);
}
/* Exercise failure in resize. */
{
struct dynarray_int dyn;
dynarray_int_init (&dyn);
struct heap_filler *heap_filler = fill_heap ();
TEST_VERIFY (!dynarray_int_resize (&dyn, 1000));
TEST_VERIFY (dynarray_int_has_failed (&dyn));
free_fill_heap (heap_filler);
dynarray_int_init (&dyn);
TEST_VERIFY (dynarray_int_resize (&dyn, 1));
heap_filler = fill_heap ();
TEST_VERIFY (!dynarray_int_resize (&dyn, 1000));
TEST_VERIFY (dynarray_int_has_failed (&dyn));
free_fill_heap (heap_filler);
dynarray_int_init (&dyn);
TEST_VERIFY (dynarray_int_resize (&dyn, 1000));
heap_filler = fill_heap ();
TEST_VERIFY (!dynarray_int_resize (&dyn, 2000));
TEST_VERIFY (dynarray_int_has_failed (&dyn));
free_fill_heap (heap_filler);
}
}
/* Check allocation failures for char * arrays (which automatically
free the pointed-to strings). */
static void
test_str_fail (void)
{
/* Exercise failure in add/emplace.
do_add: Use emplace (false) or add (true) to add elements.
do_finalize: Perform finalization at the end (instead of free). */
for (int do_add = 0; do_add < 2; ++do_add)
for (int do_finalize = 0; do_finalize < 2; ++do_finalize)
{
struct dynarray_str dyn;
dynarray_str_init (&dyn);
size_t count = 0;
while (true)
{
char **place;
if (do_add)
{
dynarray_str_add (&dyn, NULL);
if (dynarray_str_has_failed (&dyn))
break;
else
place = dynarray_str_at (&dyn, dynarray_str_size (&dyn) - 1);
}
else
{
place = dynarray_str_emplace (&dyn);
if (place == NULL)
break;
}
TEST_VERIFY_EXIT (!dynarray_str_has_failed (&dyn));
TEST_VERIFY_EXIT (*place == NULL);
*place = strdup ("placeholder");
if (*place == NULL)
{
/* Second loop to wait for failure of
dynarray_str_emplace. */
while (true)
{
if (do_add)
{
dynarray_str_add (&dyn, NULL);
if (dynarray_str_has_failed (&dyn))
break;
}
else
{
char **place = dynarray_str_emplace (&dyn);
if (place == NULL)
break;
TEST_VERIFY_EXIT (!dynarray_str_has_failed (&dyn));
*place = NULL;
}
++count;
}
break;
}
++count;
}
printf ("info: %s: failure after %zu elements\n", __func__, count);
TEST_VERIFY_EXIT (dynarray_str_has_failed (&dyn));
if (do_finalize)
{
struct str_array result = { (char **) (uintptr_t) -1, -1 };
TEST_VERIFY_EXIT (!dynarray_str_finalize (&dyn, &result));
TEST_VERIFY_EXIT (result.array == (char **) (uintptr_t) -1);
TEST_VERIFY_EXIT (result.length == (size_t) -1);
}
else
dynarray_str_free (&dyn);
TEST_VERIFY_EXIT (!dynarray_str_has_failed (&dyn));
TEST_VERIFY_EXIT (dyn.dynarray_header.array == dyn.scratch);
TEST_VERIFY_EXIT (dynarray_str_size (&dyn) == 0);
TEST_VERIFY_EXIT (dyn.dynarray_header.allocated > 0);
}
/* Exercise failure in finalize. */
for (int do_add = 0; do_add < 2; ++do_add)
{
struct dynarray_str dyn;
dynarray_str_init (&dyn);
for (unsigned int i = 0; i < 1000; ++i)
{
if (do_add)
dynarray_str_add (&dyn, xstrdup ("placeholder"));
else
{
char **place = dynarray_str_emplace (&dyn);
TEST_VERIFY_EXIT (place != NULL);
TEST_VERIFY_EXIT (*place == NULL);
*place = xstrdup ("placeholder");
}
}
TEST_VERIFY_EXIT (!dynarray_str_has_failed (&dyn));
struct heap_filler *heap_filler = fill_heap ();
struct str_array result = { (char **) (uintptr_t) -1, -1 };
TEST_VERIFY_EXIT (!dynarray_str_finalize (&dyn, &result));
TEST_VERIFY_EXIT (result.array == (char **) (uintptr_t) -1);
TEST_VERIFY_EXIT (result.length == (size_t) -1);
TEST_VERIFY_EXIT (!dynarray_str_has_failed (&dyn));
TEST_VERIFY_EXIT (dyn.dynarray_header.array == dyn.scratch);
TEST_VERIFY_EXIT (dynarray_str_size (&dyn) == 0);
TEST_VERIFY_EXIT (dyn.dynarray_header.allocated > 0);
free_fill_heap (heap_filler);
}
/* Exercise failure in resize. */
{
struct dynarray_str dyn;
dynarray_str_init (&dyn);
struct heap_filler *heap_filler = fill_heap ();
TEST_VERIFY (!dynarray_str_resize (&dyn, 1000));
TEST_VERIFY (dynarray_str_has_failed (&dyn));
free_fill_heap (heap_filler);
dynarray_str_init (&dyn);
TEST_VERIFY (dynarray_str_resize (&dyn, 1));
*dynarray_str_at (&dyn, 0) = xstrdup ("allocated");
heap_filler = fill_heap ();
TEST_VERIFY (!dynarray_str_resize (&dyn, 1000));
TEST_VERIFY (dynarray_str_has_failed (&dyn));
free_fill_heap (heap_filler);
dynarray_str_init (&dyn);
TEST_VERIFY (dynarray_str_resize (&dyn, 1000));
*dynarray_str_at (&dyn, 0) = xstrdup ("allocated");
heap_filler = fill_heap ();
TEST_VERIFY (!dynarray_str_resize (&dyn, 2000));
TEST_VERIFY (dynarray_str_has_failed (&dyn));
free_fill_heap (heap_filler);
}
}
/* Test if mmap can allocate a page. This is necessary because
setrlimit does not fail even if it reduces the RLIMIT_AS limit
below what is currently needed by the process. */
static bool
mmap_works (void)
{
void *ptr = mmap (NULL, 1, PROT_READ | PROT_WRITE,
MAP_ANONYMOUS | MAP_PRIVATE, -1, 0);
if (ptr == MAP_FAILED)
return false;
xmunmap (ptr, 1);
return true;
}
/* Set the RLIMIT_AS limit to the value in *LIMIT. */
static void
xsetrlimit_as (const struct rlimit *limit)
{
if (setrlimit (RLIMIT_AS, limit) != 0)
FAIL_EXIT1 ("setrlimit (RLIMIT_AS, %lu): %m",
(unsigned long) limit->rlim_cur);
}
/* Approximately this many bytes can be allocated after
reduce_rlimit_as has run. */
enum { as_limit_reserve = 2 * 1024 * 1024 };
/* Limit the size of the process, so that memory allocation in
allocate_thread will eventually fail, without impacting the entire
system. By default, a dynamic limit which leaves room for 2 MiB is
activated. The TEST_RLIMIT_AS environment variable overrides
it. */
static void
reduce_rlimit_as (void)
{
struct rlimit limit;
if (getrlimit (RLIMIT_AS, &limit) != 0)
FAIL_EXIT1 ("getrlimit (RLIMIT_AS) failed: %m");
/* Use the TEST_RLIMIT_AS setting if available. */
{
long target = 0;
const char *variable = "TEST_RLIMIT_AS";
const char *target_str = getenv (variable);
if (target_str != NULL)
{
target = atoi (target_str);
if (target <= 0)
FAIL_EXIT1 ("invalid %s value: \"%s\"", variable, target_str);
printf ("info: setting RLIMIT_AS to %ld MiB\n", target);
target *= 1024 * 1024; /* Convert to megabytes. */
limit.rlim_cur = target;
xsetrlimit_as (&limit);
return;
}
}
/* Otherwise, try to find the limit with a binary search. */
unsigned long low = 1 << 20;
limit.rlim_cur = low;
xsetrlimit_as (&limit);
/* Find working upper limit. */
unsigned long high = 1 << 30;
while (true)
{
limit.rlim_cur = high;
xsetrlimit_as (&limit);
if (mmap_works ())
break;
if (2 * high < high)
FAIL_EXIT1 ("cannot find upper AS limit");
high *= 2;
}
/* Perform binary search. */
while ((high - low) > 128 * 1024)
{
unsigned long middle = (low + high) / 2;
limit.rlim_cur = middle;
xsetrlimit_as (&limit);
if (mmap_works ())
high = middle;
else
low = middle;
}
unsigned long target = high + as_limit_reserve;
limit.rlim_cur = target;
xsetrlimit_as (&limit);
printf ("info: RLIMIT_AS limit: %lu bytes\n", target);
}
static int
do_test (void)
{
mtrace ();
reduce_rlimit_as ();
test_int_fail ();
test_str_fail ();
return 0;
}
#define TIMEOUT 90
#include