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When performing pointer arithmetic, the size of the value to add to a pointer is automatically scaled to the size of the type of the pointed-to object. For instance, when adding a value to the byte address of a 4-byte integer, the value is scaled by a factor 4 and then added to the pointer. Failing to understand how pointer arithmetic works can lead to miscalculations that result in serious errors, such as buffer overflows.

Noncompliant Code Example

In this noncompliant code example, integer values returned by parseint(getdata()) are stored into an array of INTBUFSIZE elements of type int called buf [Dowd 2006]. If data is available for insertion into buf (which is indicated by havedata()) and buf_ptr has not been incremented past buf + sizeof(buf), an integer value is stored at the address referenced by buf_ptr. However, the sizeof operator returns the total number of bytes in buf, which is typically a multiple of the number of elements in buf. This value is scaled to the size of an integer and added to buf. As a result, the check to make sure integers are not written past the end of buf is incorrect and a buffer overflow is possible.

int buf[INTBUFSIZE];
int *buf_ptr = buf;

while (havedata() && buf_ptr < (buf + sizeof(buf))) {
    *buf_ptr++ = parseint(getdata());
}

Compliant Solution

In this compliant solution, the size of buf, INTBUFSIZE is added directly to buf and used as an upper bound. The integer literal INTBUFSIZE is scaled to the size of an integer and the upper bound of buf is checked correctly.

int buf[INTBUFSIZE];
int *buf_ptr = buf;

while (havedata() && buf_ptr < (buf + INTBUFSIZE)) {
  *buf_ptr++ = parseint(getdata());
}

An arguably better solution is to use the address of the nonexistent element following the end of the array as follows:

int buf[INTBUFSIZE];
int *buf_ptr = buf;

while (havedata() && buf_ptr < &buf[INTBUFSIZE] {
  *buf_ptr++ = parseint(getdata());
}

This works because C99 guarantees the address of buf[INTBUFSIZE] even though no such element exists.

Noncompliant Code Example

The following example is based on a flaw in the OpenBSD operating system. An integer, skip, is added as an offset to a pointer of type struct big. The adjusted pointer is then used as a destination address in a call to memset(). However, when skip is added to the struct big pointer, it is automatically scaled by the size of struct big, which is 32 bytes (assuming 4-byte integers, 8-byte long long integers, and no structure padding). This results in the call to memset() writing to unintended memory.

struct big {
  unsigned long long ull_1; /* typically 8 bytes */
  unsigned long long ull_2; /* typically 8 bytes */
  unsigned long long ull_3; /* typically 8 bytes */
  int si_4; /* typically 4 bytes */
  int si_5; /* typically 4 bytes */
};
/* ... */
size_t skip = offsetof(struct big, ull_2);
struct big *s = (struct big *)malloc(sizeof(struct big));
if (!s) {
  /* Handle malloc() error */
}

memset(s + skip, 0, sizeof(struct big) - skip);
/* ... */
free(s);
s = NULL;

A similar situation occurred in OpenBSD's make command [Murenin 2007].

Compliant Solution

To correct this example, the struct big pointer is cast as a char *. This causes skip to be scaled by a factor of 1.

struct big {
  unsigned long long ull_1; /* typically 8 bytes */
  unsigned long long ull_2; /* typically 8 bytes */
  unsigned long long ull_3; /* typically 8 bytes */
  int si_4; /* typically 4 bytes */
  int si_5; /* typically 4 bytes */
};
/* ... */
size_t skip = offsetof(struct big, ull_2);
struct big *s = (struct big *)malloc(sizeof(struct big));
if (!s) {
  /* Handle malloc() error */
}

memset((char *)s + skip, 0, sizeof(struct big) - skip);
/* ... */
free(s);
s = NULL;

Risk Assessment

Failure to understand and properly use pointer arithmetic can allow an attacker to execute arbitrary code.

Recommendation

Severity

Likelihood

Remediation Cost

Priority

Level

EXP08-C

high

probable

high

P6

L2

Automated Detection

How long is 4 yards plus 3 feet? It is obvious from elementary arithmetic that any answer involving '7' is wrong, as the student did not take the units into account. The right method is to convert both numbers to reflect the same units.

The examples in this rule reflect both a correct and wrong way to handle comparisons of numbers representing different things (either single bytes or multibyte data structures). The NCEs just add the numbers without regard to units, whereas the compliant solutions use type casts to convert one number to the appropriate unit of the other number.

ROSE can catch both NCE's by searching for pointer arithmetic expressions involving different units. The 'different units' is the tricky part, but you can try to identify an expression's units using some simple heuristics:

  • A pointer to a 'foo' object has 'foo' as the unit.
  • A pointer to char * has unit 'byte'.
  • Any sizeof or offsetof expression also has unit 'byte'.
  • Any variable used in an index to an array of foo objects (eg foo[variable]) has 'foo' as the unit.

In addition to pointer arithmetic expressions, one can also hunt for array index expressions, as array[index] is merely shorthand for 'array + index'.

Related Vulnerabilities

Search for vulnerabilities resulting from the violation of this rule on the CERT website.

Related Guidelines

CERT C++ Secure Coding Standard: EXP08-CPP. Ensure pointer arithmetic is used correctly

ISO/IEC PDTR 24772 "HFC Pointer casting and pointer type changes" and "RVG Pointer Arithmetic"

MISRA Rules 17.1-17.4

MITRE CWE: CWE-468, "Incorrect Pointer Scaling"

Bibliography

[Dowd 2006] Chapter 6, "C Language Issues"
[Murenin 2007]


      03. Expressions (EXP)      

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