Enumerations in C++ come in two forms: scoped enumerations in which the underlying type is fixed and unscoped enumerations in which the underlying type may or may not be fixed. The range of values that can be represented by either form of enumeration may include enumerator values not specified by the enumeration itself. The range of valid enumeration values for an enumeration type is defined by the C++ Standard, [dcl.enum], paragraph 8 [ISO/IEC 14882-2014]:
For an enumeration whose underlying type is fixed, the values of the enumeration are the values of the underlying type. Otherwise, for an enumeration where emin is the smallest enumerator and emax is the largest, the values of the enumeration are the values in the range bmin to bmax, defined as follows: Let K be
1for a two’s complement representation and0for a one’s complement or sign-magnitude representation. bmax is the smallest value greater than or equal to max(|emin| − K, |emax|) and equal to 2M − 1, where M is a non-negative integer. bmin is zero if emin is non-negative and −(bmax + K) otherwise. The size of the smallest bit-field large enough to hold all the values of the enumeration type is max(M, 1) if bmin is zero and M + 1 otherwise. It is possible to define an enumeration that has values not defined by any of its enumerators. If the enumerator-list is empty, the values of the enumeration are as if the enumeration had a single enumerator with value0.
According to the C++ Standard, [expr.static.cast], paragraph 10,
A value of integral or enumeration type can be explicitly converted to an enumeration type. The value is unchanged if the original value is within the range of the enumeration values (7.2). Otherwise, the resulting value is unspecified (and might not be in that range). A value of floating-point type can also be explicitly converted to an enumeration type. The resulting value is the same as converting the original value to the underlying type of the enumeration (4.9), and subsequently to the enumeration type.
To avoid operating on unspecified values, the arithmetic value being cast must be within the range of values the enumeration can represent. When dynamically checking for out-of-range values, checking must be performed before the cast expression.
Noncompliant Code Example (Bounds Checking)
This noncompliant code example attempts to check whether a given value is within the range of acceptable enumeration values. However, it is doing so after casting to the enumeration type, which may not be able to represent the given integer value. On a two's complement system, the valid range of values that can be represented by EnumType are [0..3], so if a value outside of that range were passed to f(), the cast to EnumType would result in an unspecified value, and using that value within the if statement results in unspecified behavior.
enum EnumType {
First,
Second,
Third
};
void f(int intVar) {
EnumType enumVar = static_cast<EnumType>(intVar);
if (enumVar < First || enumVar > Third) {
// Handle error
}
}
Compliant Solution (Bounds Checking)
This compliant solution checks that the value can be represented by the enumeration type before performing the conversion to guarantee the conversion does not result in an unspecified value. It does this by restricting the converted value to one for which there is a specific enumerator value.
enum EnumType {
First,
Second,
Third
};
void f(int intVar) {
if (intVar < First || intVar > Third) {
// Handle error
}
EnumType enumVar = static_cast<EnumType>(intVar);
}
Compliant Solution (Scoped Enumeration)
This compliant solution uses a scoped enumeration, which has a fixed underlying type of type int by default, allowing any value from the parameter to be converted into a valid enumeration value. It does not restrict the converted value to one for which there is a specific enumerator value, but it could do so as shown in the previous compliant solution.
enum class EnumType {
First,
Second,
Third
};
void f(int intVar) {
EnumType enumVar = static_cast<EnumType>(intVar);
}
Compliant Solution (Fixed Unscoped Enumeration)
Similar to the previous compliant solution, this compliant solution uses an unscoped enumeration but provides a fixed underlying type of type int, allowing any value from the parameter to be converted to a valid enumeration value:
enum EnumType : int {
First,
Second,
Third
};
void f(int intVar) {
EnumType enumVar = static_cast<EnumType>(intVar);
}
Although similar to the previous compliant solution, this compliant solution differs from the noncompliant code example in the way the enumerator values are expressed in code and which implicit conversions are allowed. The previous compliant solution requires a nested name specifier to identify the enumerator (for example, EnumType::First) and will not implicitly convert the enumerator value to int. As with the noncompliant code example, this compliant solution does not allow a nested name specifier and will implicitly convert the enumerator value to int.
Risk Assessment
It is possible for unspecified values to result in a buffer overflow, leading to the execution of arbitrary code by an attacker. However, because enumerators are rarely used for indexing into arrays or other forms of pointer arithmetic, it is more likely that this scenario will result in data integrity violations rather than arbitrary code execution.
Rule | Severity | Likelihood | Remediation Cost | Priority | Level |
|---|---|---|---|---|---|
INT50-CPP | Medium | Unlikely | Medium | P4 | L3 |
Automated Detection
Automated detection should be possible for most cases, but it might not be able to guarantee that the value is in range.
Related Vulnerabilities
Search for vulnerabilities resulting from the violation of this rule on the CERT website.
Bibliography
| [Becker 2009] | Section 7.2, "Enumeration Declarations" |
| [ISO/IEC 14882-2014] | Subclause 5.2.9, "Static Cast" |
