The stack is frequently used for convenient temporary storage, because allocated memory is automatically freed when the function returns. Generally, the operating system will grow the stack as needed. However, this can fail due to a lack of memory or collision with other allocated areas of the address space (depending on the architecture). When this occurs, the operating system may terminate the program abnormally. If user input is able to influence the amount of stack memory allocated, then an attacker could use this in a denial-of-service attack.
Non-Compliant Code Example
C99 includes support for variable length arrays. If the value used for the length of the array is influenced by user input, an attacker could cause the program to use a large number of stack pages, possibly resulting in the process being killed due to lack of memory, or simply cause the stack pointer to point to a different region of memory. The latter could be used to write to an arbitrary memory location.
The following non-compliant code copies a file. It allocates a buffer of user-defined size on the stack to temporarily store data read from the source file.
int copy_file(FILE *src, FILE *dst, size_t bufsize) {
char buf[bufsize];
while (fgets(buf, bufsize, src))
fputs(buf, dst);
return 0;
}
If the size of the buffer is not constrained, a malicious user could specify a buffer of several gigabytes which might cause a crash. If the architecture is set up in a way that the heap exists "below" the stack in memory, a buffer exactly long enough to place the stack pointer into the heap could be used to overwrite memory there with what fputs() and fgets() store on the stack.
Compliant Solution
This compliant solution replaces the dynamic array with a call to malloc(). A malloc() failure should not cause a program to terminate abnormally, and the return value of malloc() can be checked for success to see if it is safe to continue.
int copy_file(FILE *src, FILE *dst, size_t bufsize) {
char *buf = malloc(bufsize);
if (!buf) {
return -1;
}
while (fgets(buf, bufsize, src)) {
fputs(buf, dst);
}
return 0;
}
Non-Compliant Code Example
Using recursion can also lead to large stack allocations. It needs to be ensured that functions which are recursive do not recurse so deep that the stack grows too large.
The following implementation of the Fibonacci function uses recursion.
unsigned long fib1(unsigned int n) {
if (n == 0) {
return 0;
}
else if (n == 1 || n == 2) {
return 1;
}
else {
return fib1(n-1) + fib1(n-2);
}
}
The stack space needed grows exponentially with respect to the parameter n. When tested on a Linux system, fib1(100) crashes with a segmentation fault.
Compliant Solution
This implementation of the Fibonacci functions eliminates the use of recursion.
unsigned long fib2(unsigned int n) {
if (n == 0) {
return 0;
}
else if (n == 1 || n == 2) {
return 1;
}
unsigned long prev = 1;
unsigned long cur = 1;
unsigned int i;
for (i = 3; i <= n; i++) {
unsigned long tmp = cur;
cur = cur + prev;
prev = tmp;
}
return cur;
}
Because there is no recursion, the amount of stack space needed does not depend on the parameter n, greatly reducing the risk of stack overflow.
Risk Assessment
Stack overflow caused by excessive stack allocations or recursion could lead to abnormal termination and denial-of-service attacks.
Rule |
Severity |
Likelihood |
Remediation Cost |
Priority |
Level |
|---|---|---|---|---|---|
MEM05-A |
1 (low) |
1 (unlikely) |
2 (medium) |
P2 |
L3 |
Related Vulnerabilities
Search for vulnerabilities resulting from the violation of this rule on the CERT website.
Automated Detection
The Coverity Prevent STACK_USE checker can help detect single stack allocations that are dangerously large, although it will not detect excessive stack use resulting from recursion. Coverity Prevent cannot discover all violations of this rule so further verification is necessary.
References
[van Sprundel 06
] "Stack Overflow"