Integer types in C have both a size and a precision. The size indicates the number of bytes used by an object and can be retrieved for any object or type using the sizeof
operator. The precision of an integer type is the number of bits it uses to represent values, excluding any sign and padding bits.
Padding bits contribute to the integer's size, but not to its precision. Consequently, inferring the precision of an integer type from its size may result in too large a value, which can then lead to incorrect assumptions about the numeric range of these types. Programmers should use correct integer precisions in their code, and in particular, should not use the sizeof
operator to compute the precision of an integer type on architectures that use padding bits or in strictly conforming (that is, portable) programs.
This noncompliant code example illustrates a function that produces 2 raised to the power of the function argument. To prevent undefined behavior in compliance with INT34-C. Do not shift an expression by a negative number of bits or by greater than or equal to the number of bits that exist in the operand, the function ensures that the argument is less than the number of bits used to store a value of type unsigned int
.
#include <limits.h> unsigned int pow2(unsigned int exp) { if (exp >= sizeof(unsigned int) * CHAR_BIT) { /* Handle error */ } return 1 << exp; } |
However, if this code runs on a platform where unsigned int
has one or more padding bits, it can still result in values for exp
that are too large. For example, on a platform that stores unsigned int
in 64 bits, but uses only 48 bits to represent the value, a left shift of 56 bits would result in undefined behavior.
This compliant solution uses a popcount()
function, which counts the number of bits set on any unsigned integer, allowing this code to determine the precision of any integer type, signed or unsigned.
#include <stddef.h> #include <stdint.h> /* Returns the number of set bits */ size_t popcount(uintmax_t num) { size_t precision = 0; while (num != 0) { if (num % 2 == 1) { precision++; } num >>= 1; } return precision; } #define PRECISION(umax_value) popcount(umax_value) |
Implementations can replace the PRECISION()
macro with a type-generic macro that returns an integer constant expression that is the precision of the specified type for that implementation. This return value can then be used anywhere an integer constant expression can be used, such as in a static assertion. (See DCL03-C. Use a static assertion to test the value of a constant expression.) The following type generic macro, for example, might be used for a specific implementation targeting the IA-32 architecture:
#define PRECISION(value) _Generic(value, \ unsigned char : 8, \ unsigned short: 16, \ unsigned int : 32, \ unsigned long : 32, \ unsigned long long : 64, \ signed char : 7, \ signed short : 15, \ signed int : 31, \ signed long : 31, \ signed long long : 63) |
The revised version of the pow2()
function uses the PRECISION()
macro to determine the precision of the unsigned type:
#include <stddef.h> #include <stdint.h> #include <limits.h> extern size_t popcount(uintmax_t); #define PRECISION(umax_value) popcount(umax_value) unsigned int pow2(unsigned int exp) { if (exp >= PRECISION(UINT_MAX)) { /* Handle error */ } return 1 << exp; } |
Some platforms, such as the Cray Linux Environment (CLE; supported on Cray XT CNL compute nodes), provide a _popcnt
instruction that can substitute for the popcount()
function.
#define PRECISION(umax_value) _popcnt(umax_value) |
Mistaking an integer's size for its precision can permit invalid precision arguments to operations such as bitwise shifts, resulting in undefined behavior.
Rule | Severity | Likelihood | Remediation Cost | Priority | Level |
---|---|---|---|---|---|
INT35-C | Low | Unlikely | Medium | P2 | L3 |
Tool | Version | Checker | Description |
---|---|---|---|
Astrée | Supported: Astrée reports overflows due to insufficient precision. | ||
CodeSonar | LANG.ARITH.BIGSHIFT | Shift Amount Exceeds Bit Width | |
Helix QAC | C0582 C++3115 | ||
Parasoft C/C++test | CERT_C-INT35-a | Use correct integer precisions when checking the right hand operand of the shift operator | |
Polyspace Bug Finder | CERT C: Rule INT35-C | Checks for situations when integer precisions are exceeded (rule fully covered) |
Key here (explains table format and definitions)
Taxonomy | Taxonomy item | Relationship |
---|---|---|
CWE 2.11 | CWE-681, Incorrect Conversion between Numeric Types | 2017-10-30:MITRE:Unspecified Relationship 2018-10-18:CERT:Partial Overlap |
Key here for mapping notes
Intersection( INT35-C, CWE-190) = Ø
INT35-C used to map to CWE-190 but has been replaced with a new rule that has no overlap with CWE-190.
Intersection(INT35-C, CWE-681) = due to incorrect use of integer precision, conversion from one data type to another causing data to be omitted or translated in a way that produces unexpected values
CWE-681 - INT35-C = list2, where list2 =
INT35-C - CWE-681 = list1, where list1 =
[Dowd 2006] | Chapter 6, "C Language Issues" |
[C99 Rationale 2003] | 6.5.7, "Bitwise Shift Operators" |