Allocating and freeing memory in different modules and levels of abstraction burdens the programmer with tracking the lifetime of that block of memory. This may cause confusion regarding when and if a block of memory has been allocated or freed, leading to programming defects such as double-free vulnerabilities, accessing freed memory, or writing to unallocated memory.
To avoid these situations, it is recommended that memory be allocated and freed at the same level of abstraction, and ideally in the same code module.
The affects of not following this recommendation are best demonstrated by an actual vulnerability. Freeing memory in different modules resulted in a vulnerability in MIT Kerberos 5 MITKRB5-SA-2004-002 . The problem was that the MIT Kerberos 5 code contained error-handling logic, which freed memory allocated by the ASN.1 decoders if pointers to the allocated memory were non-null. However, if a detectable error occured, the ASN.1 decoders freed the memory that they had allocated. When some library functions received errors from the ASN.1 decoders, they also attempted to free, causing a double-free vulnerability.
Non-Compliant Code Example
This example demonstrates an error that can occur when memory is freed in different functions. First, an array of integers is dynamically allocated. The array, which is referred to by list and its size, number, are then passed to func2. If the number of elements in the array is greater than the value MIN_SIZE_ALLOWED, the array is processed. Otherwise, it is assumed an error has occurred, list is freed, and the function returns. If the error occurs in func2, the dynamic memory referred to by list will be freed twice: once in func2 and again at the end of func1.
#define MIN_SIZE_ALLOWED 10
void func2(int *list, size_t list_size) {
if (size < MIN_SIZE_ALLOWED) {
/* Handle Error Condition */
free(list);
return;
}
/* Process list */
}
void func1 (size_t number) {
int *list = malloc (number * sizeof(int));
if (list == NULL) {
/* Handle Allocation Error */
}
func2(list,number);
/* Continue Processing list */
free(list);
}
Compliant Solution
To correct this problem, the logic in the error handling code should be changed so that it no longer frees list. This change ensures that list is freed only once, in func1.
#define MIN_SIZE_ALLOWED 10
void func2(int *list, size_t list_size) {
if (size < MIN_SIZE_ALLOWED) {
/* Handle Error Condition */
return;
}
/* Process list */
}
void func1 (size_t number) {
int *list = malloc (number * sizeof(int));
if (list == NULL) {
/* Handle Allocation Error */
}
func2(list,number);
/* Continue Processing list */
free(list);
}
Risk Assessment
The mismanagement of memory can lead to freeing memory multiple times or writing to already freed memory. Both of these problems can result in an attacker executing arbitrary code with the permissions of the vulnerable process. Memory management errors can also lead to resource depletion and denial-of-service attacks.
Rule |
Severity |
Likelihood |
Remediation Cost |
Priority |
Level |
|---|---|---|---|---|---|
MEM00-A |
3 (high) |
2 (probable) |
1 (high) |
P6 |
L2 |
References
- ISO/IEC 9899-1999 Section 7.20.3 Memory Management Functions
- Seacord 05 Chapter 4. Dynamic Memory Management
- Consistent Memory Management Conventions, Dan Plakosh
- MIT Kerberos 5 Security Advisory 2004-002