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Comment: fixed xorl reference

Integer conversions, both implicit and explicit (using a cast), must be guaranteed not to result in lost or misinterpreted data. This is particularly true for integer values that originate from untrusted sources and are used in any of the following ways:

  • as an array index
  • in any pointer arithmetic
  • as a length or size of an object
  • as the bound of an array (for example, a loop counter)
  • as an argument to a memory allocation function
  • in security-critical code

The only integer type conversions that are guaranteed to be safe for all data values and all possible conforming implementations are conversions of an integral value to a wider type of the same signedness. C99 Section 6.3.1.3 says

When a value with integer type is converted to another integer type other than _Bool, if the value can be represented by the new type, it is unchanged.

Otherwise, if the new type is unsigned, the value is converted by repeatedly adding or subtracting one more than the maximum value that can be represented in the new type until the value is in the range of the new type.

Otherwise, the new type is signed and the value cannot be represented in it; either the result is implementation-defined or an implementation-defined signal is raised.

Typically, converting an integer to a smaller type results in truncation of the high-order bits.

Noncompliant Code Example (Unsigned to Signed)

Type range errors, including loss of data (truncation) and loss of sign (sign errors), can occur when converting from an unsigned type to a signed type. The following noncompliant code example results in a truncation error on most implementations.

Code Block
bgColor#FFcccc
unsigned long int ul = ULONG_MAX;
signed char sc;
sc = (signed char)ul; /* cast eliminates warning */

Compliant Solution (Unsigned to Signed)

Validate ranges when converting from an unsigned type to a signed type. The following code, for example, can be used when converting from unsigned long int to a signed char.

Code Block
bgColor#ccccff
unsigned long int ul = ULONG_MAX;
signed char sc;
if (ul <= SCHAR_MAX) {
  sc = (signed char)ul;  /* use cast to eliminate warning */
}
else {
  /* handle error condition */
}

Noncompliant Code Example (Signed to Unsigned)

Type range errors, including loss of data (truncation) and loss of sign (sign errors), can occur when converting from a signed type to an unsigned type. The following code results in a loss of sign.

Code Block
bgColor#FFcccc
signed int si = INT_MIN;
unsigned int ui = (unsigned int)si;  /* cast eliminates warning */

Compliant Solution (Signed to Unsigned)

Validate ranges when converting from a signed type to an unsigned type. The following code, for example, can be used when converting from signed int to unsigned int.

Code Block
bgColor#ccccff
signed int si = INT_MIN;
unsigned int ui;
if ( (si < 0) || (si > UINT_MAX) ) {
  /* handle error condition */
}
else {
  ui = (unsigned int)si;  /* cast eliminates warning */
}

NOTE: While unsigned types can usually represent all positive values of the corresponding signed type, this relationship is not guaranteed by the C99 standard.

Noncompliant Code Example (Signed, Loss of Precision)

A loss of data (truncation) can occur when converting from a signed type to a signed type with less precision. The following code can result in truncation.

Code Block
bgColorFFcccc
signed long int sl = LONG_MAX;
signed char sc = (signed char)sl; /* cast eliminates warning */

Compliant Solution (Signed, Loss of Precision)

Validate ranges when converting from a signed type to a signed type with less precision. The following code can be used, for example, to convert from a signed long int to a signed char.

Code Block
bgColor#ccccff
signed long int sl = LONG_MAX;
signed char sc;
if ( (sl < SCHAR_MIN) || (sl > SCHAR_MAX) ) {
  /* handle error condition */
}
else {
  sc = (signed char)sl; /* use cast to eliminate warning */

}

Conversions from signed types with greater precision to signed types with lesser precision require both the upper and lower bounds to be checked.

Noncompliant Code Example (Unsigned, Loss of Precision)

A loss of data (truncation) can occur when converting from an unsigned type to an unsigned type with less precision. The following code results in a truncation error on most implementations.

Code Block
bgColorFFcccc
unsigned long int ul = ULONG_MAX;
unsigned char uc = (unsigned char)ul;  /* cast eliminates warning */

Compliant Solution (Unsigned, Loss of Precision)

Validate ranges when converting from an unsigned type to an unsigned type with lesser precision. The following code can be used, for example, to convert from an unsigned long int to an unsigned char.

Code Block
bgColor#ccccff
unsigned long int ul = ULONG_MAX;
unsigned char uc;
if (ul > UCHAR_MAX) ) {
  /* handle error condition */
}
else {
  uc = (unsigned char)ul; /* use cast to eliminate warning */
}

Conversions from unsigned types with greater precision to unsigned types with lesser precision require only the upper bounds to be checked.

Exceptions

INT31-EX1: C99 defines minimum ranges for standard integer types. For example, the minimum range for an object of type unsigned short int is 0 to 65,535, while the minimum range for int is --32,767 to +32,767. This means that it is not always possible to represent all possible values of an unsigned short int as an int-. However, on the IA-32 architecture, for example, the actual integer range is from ---2,147,483,648 to +2,147,483,647, meaning that it is quite possible to represent all the values of an unsigned short int as an int for this architecture. As a result, it is not necessary to provide a test for this conversion on IA-32. It is not possible to make assumptions about conversions without knowing the precision of the underlying types. If these tests are not provided, assumptions concerning precision must be clearly documented, as the resulting code cannot be safely ported to a system where these assumptions are invalid. A good way to document these assumptions is by using static assertions (see DCL03-C. Use a static assertion to test the value of a constant expression).

Risk Assessment

Integer truncation errors can lead to buffer overflows and the execution of arbitrary code by an attacker.

Rule

Severity

Likelihood

Remediation Cost

Priority

Level

INT31-C

high

probable

high

P6

L2

Automated Detection

Fortify SCA Version 5.0 with CERT C Rule Pack can detect violations of this rule.

Compass/ROSE can detect violations of this rule. However, false warnings may be raised if limits.h is included.

The Coverity Prevent NEGATIVE_RETURNS and REVERSE_NEGATIVE checkers both can find violations of this rule. The NEGATIVE_RETURNS checker can find array accesses, loop bounds, and other expressions that may contain dangerous implied integer conversions that would result in unexpected behavior. The REVERSE_NEGATIVE checker can find instances where a negativity check occurs after the negative value has been used for something else. Coverity Prevent cannot discover all violations of this rule, so further verification is necessary.

Klocwork Version 8.0.4.16 can detect violations of this rule with the PRECISION.LOSS checker.

Related Vulnerabilities

Wiki Markup
[CVE-2009-1376|http://web.nvd.nist.gov/view/vuln/detail?vulnId=CVE-2009-1376] results from a violation of this rule. In version 2.5.5 of Pidgin, an unsigned integer ({{offset}}) is set to the value of a 64-bit unsigned integer, which can lead to truncation \[[xorl 2009|http://xorl.wordpress.com/2009/05/28/cve-2009-1376-pidgin-msn-slp-integer-truncation/]\]. An attacker can execute arbitrary code by carefully choosing this value and causing a buffer overflow.

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

Other Languages

This rule appears in the C++ Secure Coding Standard as INT31-CPP. Ensure that integer conversions do not result in lost or misinterpreted data.

This rule appears in the Java Secure Coding Standard as INT30-J. Be careful while casting integers to narrower types.

References

Wiki Markup
\[[Dowd 06|AA. C References#Dowd 06]\] Chapter 6, "C Language Issues" (Type Conversions, pp. 223-270)
\[[ISO/IEC 9899:1999|AA. C References#ISO/IEC 9899-1999]\] 6.3, "Conversions"
\[[ISO/IEC PDTR 24772|AA. C References#ISO/IEC PDTR 24772]\] "FLC Numeric Conversion Errors"
\[[MISRA 04|AA. C References#MISRA 04]\] Rules 10.1, 10.3, 10.5, and 12.9
\[[MITRE 07|AA. C References#MITRE 07]\] [CWE ID 192|http://cwe.mitre.org/data/definitions/192.html], "Integer Coercion Error," [CWE ID 197|http://cwe.mitre.org/data/definitions/197.html], "Numeric Truncation Error," and [CWE ID 681|http://cwe.mitre.org/data/definitions/681.html], "Incorrect Conversion between Numeric Types"
\[[Seacord 05a|AA. C References#Seacord 05]\] Chapter 5, "Integers"
\[[Viega 05|AA. C References#Viega 05]\] Section 5.2.9, "Truncation error," Section 5.2.10, "Sign extension error," Section 5.2.11, "Signed to unsigned conversion error," and Section 5.2.12, "Unsigned to signed conversion error"
\[[Warren 02|AA. C References#Warren 02]\] Chapter 2, "Basics"
\[[xorl 2009|AA. C References#xorl 2009]\] ["CVE-2009-1376: Pidgin MSN SLP Integer Truncation"|http://xorl.wordpress.com/2009/05/28/cve-2009-1376-pidgin-msn-slp-integer-truncation/]


      04. Integers (INT)