Strings must contain a null-termination character at or before the address of the last element of the array before they can be safely passed as arguments to standard string-handling functions, such as strcpy()
or strlen()
. These functions, as well as other string-handling functions defined by the C Standard, depend on the existence of a null-termination character to determine the length of a string. Similarly, strings must be null-terminated before iterating on a character array where the termination condition of the loop depends on the existence of a null-termination character within the memory allocated for the string, as in the following example:
void func(void) { char ntbs[16]; for (size_t i = 0; i < sizeof(ntbs); ++i) { if (ntbs[i] == '\0') { break; } }
Failure to properly terminate null-terminated byte strings can result in buffer overflows and other undefined behavior.
Noncompliant Code Example (strncpy()
)
The strncpy()
function does not guarantee that the resulting string is null terminated. If no null character is contained in the first n
characters of the source
array, the result will not be null-terminated. Passing a non-null-terminated string to strlen()
results in undefined behavior, as shown by this noncompliant code example:
#include <string.h> enum { NTBS_SIZE = 32 }; size_t func(const char *source) { char ntbs[NTBS_SIZE]; ntbs[sizeof(ntbs) - 1] = '\0'; strncpy(ntbs, source, sizeof(ntbs)); return strlen( ntbs); }
Compliant Solution (Truncation)
The correct solution depends on the programmer's intent. If the intent is to truncate a string while ensuring that the result remains a null-terminated string, this solution can be used:
#include <string.h> enum { NTBS_SIZE = 32 }; size_t func(const char *source) { char ntbs[NTBS_SIZE]; strncpy(ntbs, source, sizeof(ntbs) - 1); ntbs[sizeof(ntbs) - 1] = '\0'; return strlen( ntbs); }
Compliant Solution (Copy without Truncation)
If the intent is to copy without truncation, this example copies the data and guarantees that the resulting string is null-terminated. If the string cannot be copied, it is handled as an error condition.
#include <string.h> enum { NTBS_SIZE = 32 }; size_t func(const char *source) { char ntbs[NTBS_SIZE]; if (source) { if (strlen(source) < sizeof(ntbs)) { strcpy(ntbs, source); } else { /* Handle string-too-large condition */ } } else { /* Handle NULL string condition */ } return strlen( ntbs); }
Compliant Solution (strncpy_s(),
C11 Annex K)
The C11 Annex K strncpy_s()
function copies up to n
characters from the source array to a destination array. If no null character was copied from the source array, then the n
th position in the destination array is set to a null character, guaranteeing that the resulting string is null-terminated.
#define __STDC_WANT_LIB_EXT1__ 1 #include <string.h> enum { NTBS_SIZE = 32 }; size_t func(const char *source) { char a[NTBS_SIZE]; if (source) { errno_t err = strncpy_s(a, sizeof(a), source, 5); if (err != 0) { /* Handle error */ } } else { /* Handle NULL string condition */ } return strlen_s( s, sizeof(a)); }
Noncompliant Code Example (realloc()
)
One method to decrease memory usage in critical situations when all available memory has been exhausted is to use the realloc()
function to halve the size of message strings. The standard realloc()
function has no concept of null-terminated byte strings. As a result, if realloc()
is called to decrease the memory allocated for a null-terminated byte string, the null-termination character may be truncated.
This noncompliant code example fails to ensure that cur_msg
is properly null-terminated:
#include <stdlib.h> char *cur_msg = NULL; size_t cur_msg_size = 1024; void lessen_memory_usage(void) { char *temp; size_t temp_size; if (cur_msg != NULL) { temp_size = cur_msg_size / 2 + 1; temp = realloc(cur_msg, temp_size); if (temp == NULL) { /* Handle error */ } cur_msg = temp; cur_msg_size = temp_size; fputs(stderr, cur_msg); } }
Because realloc()
does not guarantee that the string is properly null-terminated, and the function subsequently passes cur_msg
to a library function (fputs()
) that expects null-termination, the result is undefined behavior.
Compliant Solution (realloc()
)
In this compliant solution, the lessen_memory_usage()
function ensures that the resulting string is always properly null-terminated:
#include <stdlib.h> char *cur_msg = NULL; size_t cur_msg_size = 1024; void lessen_memory_usage(void) { char *temp; size_t temp_size; if (cur_msg != NULL) { temp_size = cur_msg_size / 2 + 1; temp = realloc(cur_msg, temp_size); if (temp == NULL) { /* Handle error */ } cur_msg = temp; cur_msg_size = temp_size; /* Ensure string is null-terminated */ cur_msg[cur_msg_size - 1] = '\0'; } fputs(stderr, cur_msg); }
Risk Assessment
Failure to properly null-terminate strings can result in buffer overflows and the execution of arbitrary code with the permissions of the vulnerable process. Null-termination errors can also result in unintended information disclosure.
Rule | Severity | Likelihood | Remediation Cost | Priority | Level |
---|---|---|---|---|---|
STR32-C | High | Probable | Medium | P12 | L1 |
Automated Detection
Tool | Version | Checker | Description |
---|---|---|---|
|
| Can detect some violations of this rule | |
Coverity | 6.5 | STRING_NULL | Fully Implemented |
2024.3 | NNTS |
| |
9.7.1 | 600 S | Fully implemented |
Related Vulnerabilities
Search for vulnerabilities resulting from the violation of this rule on the CERT website.
Related Guidelines
CERT C++ Secure Coding Standard | STR32-CPP. Null-terminate character arrays as required |
ISO/IEC TR 24772:2013 | String Termination [CMJ] |
ISO/IEC TS 17961 | Passing a non-null-terminated character sequence to a library function that expects a string [strmod] |
MITRE CWE | CWE-119, Failure to constrain operations within the bounds of an allocated memory buffer CWE-170, Improper null termination |
Bibliography
[Seacord 2013] | Chapter 2, "Strings" |
[Viega 2005] | Section 5.2.14, "Miscalculated NULL Termination" |