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/*
* Copyright Amazon.com, Inc. or its affiliates. All Rights Reserved.
*
* Licensed under the Apache License, Version 2.0 (the "License").
* You may not use this file except in compliance with the License.
* A copy of the License is located at
*
* http://aws.amazon.com/apache2.0
*
* or in the "license" file accompanying this file. This file is distributed
* on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either
* express or implied. See the License for the specific language governing
* permissions and limitations under the License.
*/
#define _DEFAULT_SOURCE 1
#if defined(S2N_FEATURES_AVAILABLE)
#include <features.h>
#endif
#include <stdint.h>
#include <stdlib.h>
#include <sys/mman.h>
#include <unistd.h>
#include "error/s2n_errno.h"
#include "utils/s2n_blob.h"
#include "utils/s2n_mem.h"
#include "utils/s2n_safety.h"
static uint32_t page_size = 4096;
static bool initialized = false;
static int s2n_mem_init_impl(void);
static int s2n_mem_cleanup_impl(void);
static int s2n_mem_free_no_mlock_impl(void *ptr, uint32_t size);
static int s2n_mem_free_mlock_impl(void *ptr, uint32_t size);
static int s2n_mem_malloc_no_mlock_impl(void **ptr, uint32_t requested, uint32_t *allocated);
static int s2n_mem_malloc_mlock_impl(void **ptr, uint32_t requested, uint32_t *allocated);
static s2n_mem_init_callback s2n_mem_init_cb = s2n_mem_init_impl;
static s2n_mem_cleanup_callback s2n_mem_cleanup_cb = s2n_mem_cleanup_impl;
static s2n_mem_malloc_callback s2n_mem_malloc_cb = s2n_mem_malloc_mlock_impl;
static s2n_mem_free_callback s2n_mem_free_cb = s2n_mem_free_mlock_impl;
static int s2n_mem_init_impl(void)
{
long sysconf_rc = sysconf(_SC_PAGESIZE);
/* sysconf must not error, and page_size cannot be 0 */
POSIX_ENSURE(sysconf_rc > 0, S2N_FAILURE);
/* page_size must be a valid uint32 */
POSIX_ENSURE(sysconf_rc <= UINT32_MAX, S2N_FAILURE);
page_size = (uint32_t) sysconf_rc;
if (getenv("S2N_DONT_MLOCK") || s2n_in_unit_test()) {
s2n_mem_malloc_cb = s2n_mem_malloc_no_mlock_impl;
s2n_mem_free_cb = s2n_mem_free_no_mlock_impl;
}
return S2N_SUCCESS;
}
static int s2n_mem_cleanup_impl(void)
{
page_size = 4096;
s2n_mem_malloc_cb = s2n_mem_malloc_no_mlock_impl;
s2n_mem_free_cb = s2n_mem_free_no_mlock_impl;
return S2N_SUCCESS;
}
static int s2n_mem_free_mlock_impl(void *ptr, uint32_t size)
{
/* Perform a best-effort `munlock`: ignore any errors during unlocking. */
munlock(ptr, size);
free(ptr);
return S2N_SUCCESS;
}
static int s2n_mem_free_no_mlock_impl(void *ptr, uint32_t size)
{
free(ptr);
return S2N_SUCCESS;
}
static int s2n_mem_malloc_mlock_impl(void **ptr, uint32_t requested, uint32_t *allocated)
{
POSIX_ENSURE_REF(ptr);
/* Page aligned allocation required for mlock */
uint32_t allocate;
POSIX_GUARD(s2n_align_to(requested, page_size, &allocate));
*ptr = NULL;
POSIX_ENSURE(posix_memalign(ptr, page_size, allocate) == 0, S2N_ERR_ALLOC);
*allocated = allocate;
/*
** We disable MAD_DONTDUMP when fuzz-testing or using the address sanitizer because
** both need to be able to dump pages to function. It's how they map heap output.
*/
#if defined(MADV_DONTDUMP) && !defined(S2N_ADDRESS_SANITIZER) && !defined(S2N_FUZZ_TESTING)
if (madvise(*ptr, *allocated, MADV_DONTDUMP) != 0) {
POSIX_GUARD(s2n_mem_free_no_mlock_impl(*ptr, *allocated));
POSIX_BAIL(S2N_ERR_MADVISE);
}
#endif
if (mlock(*ptr, *allocated) != 0) {
/* When mlock fails, no memory will be locked, so we don't use munlock on free */
POSIX_GUARD(s2n_mem_free_no_mlock_impl(*ptr, *allocated));
POSIX_BAIL(S2N_ERR_MLOCK);
}
POSIX_ENSURE(*ptr != NULL, S2N_ERR_ALLOC);
return S2N_SUCCESS;
}
static int s2n_mem_malloc_no_mlock_impl(void **ptr, uint32_t requested, uint32_t *allocated)
{
*ptr = malloc(requested);
POSIX_ENSURE(*ptr != NULL, S2N_ERR_ALLOC);
*allocated = requested;
return S2N_SUCCESS;
}
int s2n_mem_set_callbacks(s2n_mem_init_callback mem_init_callback, s2n_mem_cleanup_callback mem_cleanup_callback,
s2n_mem_malloc_callback mem_malloc_callback, s2n_mem_free_callback mem_free_callback)
{
POSIX_ENSURE(!initialized, S2N_ERR_INITIALIZED);
POSIX_ENSURE_REF(mem_init_callback);
POSIX_ENSURE_REF(mem_cleanup_callback);
POSIX_ENSURE_REF(mem_malloc_callback);
POSIX_ENSURE_REF(mem_free_callback);
s2n_mem_init_cb = mem_init_callback;
s2n_mem_cleanup_cb = mem_cleanup_callback;
s2n_mem_malloc_cb = mem_malloc_callback;
s2n_mem_free_cb = mem_free_callback;
return S2N_SUCCESS;
}
int s2n_alloc(struct s2n_blob *b, uint32_t size)
{
POSIX_ENSURE(initialized, S2N_ERR_NOT_INITIALIZED);
POSIX_ENSURE_REF(b);
const struct s2n_blob temp = { 0 };
*b = temp;
POSIX_GUARD(s2n_realloc(b, size));
return S2N_SUCCESS;
}
/* A blob is growable if it is either explicitly marked as such, or if it contains no data */
bool s2n_blob_is_growable(const struct s2n_blob *b)
{
return b && (b->growable || (b->data == NULL && b->size == 0 && b->allocated == 0));
}
/* Tries to realloc the requested bytes.
* If successful, updates *b.
* If failed, *b remains unchanged
*/
int s2n_realloc(struct s2n_blob *b, uint32_t size)
{
POSIX_ENSURE(initialized, S2N_ERR_NOT_INITIALIZED);
POSIX_ENSURE_REF(b);
POSIX_ENSURE(s2n_blob_is_growable(b), S2N_ERR_RESIZE_STATIC_BLOB);
if (size == 0) {
return s2n_free(b);
}
/* blob already has space for the request */
if (size <= b->allocated) {
if (size < b->size) {
/* Zero the existing blob memory before the we release it */
struct s2n_blob slice = { 0 };
POSIX_GUARD(s2n_blob_slice(b, &slice, size, b->size - size));
POSIX_GUARD(s2n_blob_zero(&slice));
}
b->size = size;
return S2N_SUCCESS;
}
struct s2n_blob new_memory = { .data = NULL, .size = size, .allocated = 0, .growable = 1 };
if (s2n_mem_malloc_cb((void **) &new_memory.data, new_memory.size, &new_memory.allocated) != 0) {
S2N_ERROR_PRESERVE_ERRNO();
}
POSIX_ENSURE(new_memory.allocated >= new_memory.size, S2N_ERR_ALLOC);
POSIX_ENSURE(new_memory.data != NULL, S2N_ERR_ALLOC);
if (b->size) {
POSIX_CHECKED_MEMCPY(new_memory.data, b->data, b->size);
}
if (b->allocated) {
POSIX_GUARD(s2n_free(b));
}
*b = new_memory;
return S2N_SUCCESS;
}
int s2n_free_object(uint8_t **p_data, uint32_t size)
{
POSIX_ENSURE_REF(p_data);
if (*p_data == NULL) {
return S2N_SUCCESS;
}
POSIX_ENSURE(initialized, S2N_ERR_NOT_INITIALIZED);
struct s2n_blob b = { .data = *p_data, .allocated = size, .size = size, .growable = 1 };
/* s2n_free() will call free() even if it returns error (for a growable blob).
** This makes sure *p_data is not used after free() */
*p_data = NULL;
return s2n_free(&b);
}
int s2n_dup(struct s2n_blob *from, struct s2n_blob *to)
{
POSIX_ENSURE(initialized, S2N_ERR_NOT_INITIALIZED);
POSIX_ENSURE_EQ(to->size, 0);
POSIX_ENSURE_EQ(to->data, NULL);
POSIX_ENSURE_NE(from->size, 0);
POSIX_ENSURE_NE(from->data, NULL);
POSIX_GUARD(s2n_alloc(to, from->size));
POSIX_CHECKED_MEMCPY(to->data, from->data, to->size);
return S2N_SUCCESS;
}
int s2n_mem_init(void)
{
POSIX_ENSURE(s2n_mem_init_cb() >= S2N_SUCCESS, S2N_ERR_CANCELLED);
initialized = true;
return S2N_SUCCESS;
}
bool s2n_mem_is_init(void)
{
return initialized;
}
uint32_t s2n_mem_get_page_size(void)
{
return page_size;
}
int s2n_mem_cleanup(void)
{
POSIX_ENSURE(initialized, S2N_ERR_NOT_INITIALIZED);
POSIX_ENSURE(s2n_mem_cleanup_cb() >= S2N_SUCCESS, S2N_ERR_CANCELLED);
initialized = false;
return S2N_SUCCESS;
}
int s2n_free(struct s2n_blob *b)
{
/* To avoid memory leaks, don't exit the function until the memory
has been freed */
int zero_rc = s2n_blob_zero(b);
POSIX_GUARD(s2n_free_without_wipe(b));
return zero_rc;
}
int s2n_free_without_wipe(struct s2n_blob *b)
{
POSIX_PRECONDITION(s2n_blob_validate(b));
POSIX_ENSURE(initialized, S2N_ERR_NOT_INITIALIZED);
POSIX_ENSURE(s2n_blob_is_growable(b), S2N_ERR_FREE_STATIC_BLOB);
if (b->data) {
POSIX_ENSURE(s2n_mem_free_cb(b->data, b->allocated) >= S2N_SUCCESS, S2N_ERR_CANCELLED);
}
*b = (struct s2n_blob){ 0 };
return S2N_SUCCESS;
}
int s2n_free_or_wipe(struct s2n_blob *b)
{
POSIX_ENSURE_REF(b);
int zero_rc = s2n_blob_zero(b);
if (b->allocated) {
POSIX_GUARD(s2n_free_without_wipe(b));
}
return zero_rc;
}
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