Many library functions accept a string or wide string argument with the constraint that the string they receive is properly null-terminated. Passing a character sequence or wide character sequence that is not null-terminated to such a function can result in accessing memory that is outside the bounds of the object. Do not pass a character sequence or wide character sequence that is not null-terminated to a library function that expects a string or wide string argument.
Noncompliant Code Example
This code example is noncompliant because the character sequence c_str
will not be null-terminated when passed as an argument to printf().
(See STR11-C. Do not specify the bound of a character array initialized with a string literal on how to properly initialize character arrays.)
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#include <stdio.h>
void func(void) {
char c_str[3] = "abc";
printf("%s\n", c_str);
}
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Compliant Solution
This compliant solution does not specify the bound of the character array in the array declaration. If the array bound is omitted, the compiler allocates sufficient storage to store the entire string literal, including the terminating null character.
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#include <stdio.h>
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Character arrays must be null-terminated before they may 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 the string's null-termination character to determine the length of the string. Likewise, character sequences must be null-terminated before iterating on the sequence where the termination condition of the loop depends on the existence of a null-termination character within the memory allocated for the sequence, as in the following example:
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void func(void) { char ntbsc_str[16] = "abc"; printf("%s\n", c_str); } |
Noncompliant Code Example
This code example is noncompliant because the wide character sequence cur_msg
will not be null-terminated when passed to wcslen()
. This will occur if lessen_memory_usage()
is invoked while cur_msg_size
still has its initial value of 1024.
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#include <stdlib.h> #include <wchar.h> wchar_t *cur_msg for (size_t i = 0; i < sizeof(ntbs); ++i) {= NULL; size_t cur_msg_size = 1024; size_t cur_msg_len = 0; void lessen_memory_usage(void) { wchar_t *temp; size_t temp_size; /* ... */ if (cur_msg != NULL) { temp_size = cur_msg_size / 2 + 1; temp = realloc(cur_msg, temp_size * sizeof(wchar_t)); /* temp &and cur_msg may no longer be null-terminated */ if (ntbs[i]temp == '\0'NULL) { /* Handle error */ } break; } cur_msg = temp; cur_msg_size = temp_size; cur_msg_len = wcslen(cur_msg); } } |
Compliant Solution
In this compliant solution, cur_msg
will always be Passing a non- null-terminated character array to a function that expects a string can result in buffer overflows and other undefined behavior.when passed to wcslen()
:
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#include <stdlib.h>
#include <wchar.h>
wchar_t *cur_msg = NULL;
size_t cur_msg_size = 1024;
size_t cur_msg_len = 0;
void lessen_memory_usage(void) {
wchar_t *temp;
size_t temp_size;
/* ... */
if (cur_msg != NULL) {
temp_size = cur_msg_size / 2 + 1;
temp = realloc(cur_msg, temp_size * sizeof(wchar_t));
/* temp and cur_msg may no longer be null-terminated */
if (temp == NULL) {
/* Handle error */
}
cur_msg = temp;
/* Properly null-terminate cur_msg */
cur_msg[temp_size - 1] = L'\0';
cur_msg_size = temp_size;
cur_msg_len = wcslen(cur_msg);
}
} |
Noncompliant Code Example (strncpy()
)
While Although the strncpy()
function takes a string as input, it does not guarantee that the resulting value is still null-terminated. In the following noncompliant code example, 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 character sequence to strlen()
results in is undefined behavior:.
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#include <string.h> enum { NTBSSTR_SIZE = 32 }; size_t func(const char *source) { char ntbsc_str[NTBSSTR_SIZE]; size_t ret = 0; if (source) { ntbsc_str[sizeof(ntbsc_str) - 1] = '\0'; strncpy(ntbsc_str, source, sizeof(ntbsc_str)); ret return= strlen(ntbs); } |
Compliant Solution (Truncation)
The correct solution depends on the programmer's intent. If the intent is to truncate a string, this solution can be used:
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#include <string.h> enum { NTBS_SIZE = 32 }; size_t func(const char *source)c_str); } else { char ntbs[NTBS_SIZE]; strncpy(ntbs, source, sizeof(ntbs) - 1); ntbs[sizeof(ntbs) - 1] = '\0'; /* Handle null pointer */ } return strlen( ntbs)ret; } |
Compliant Solution (
...
Truncation)
If the This compliant solution is correct if the programmer's intent is to copy without truncation, this example copies the data and guarantees that the resulting array is null-terminated. If the string cannot be copied, it is handled as an error condition.truncate the string:
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#include <string.h> enum { NTBSSTR_SIZE = 32 }; size_t func(const char *source) { char ntbsc_str[NTBSSTR_SIZE]; size_t ret = 0; if (source) { if (strlen(source) < sizeof(ntbs)) {strncpy(c_str, source, sizeof(c_str) - 1); strcpy(ntbs, source); } else {c_str[sizeof(c_str) - 1] = '\0'; ret /* Handle string-too-large */ }= strlen(c_str); } else { /* Handle null pointer */ } return strlen(ntbs)ret; } |
Compliant Solution (Truncation, strncpy_s())
The C Standard,
...
Annex K
...
strncpy_s()
function can also be used to copy with truncation. The 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.
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#define __STDC_WANT_LIB_EXT1__ 1 #include <string.h> enum { NTBSSTR_SIZE = 32 }; size_t func(const char *source) { char ac_str[NTBSSTR_SIZE]; size_t ret = 0; if (source) { errno_t err = strncpy_s(a c_str, sizeof(a)c_str), source, strnlen(source, 5sizeof(c_str)) ); if (err != 0) { /* Handle error */ } } else { /* Handle nullret pointer */ } 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 strings. As a result, if realloc()
is called to decrease the memory allocated for a string, the null-termination character may be truncated.
This noncompliant code example fails to ensure that cur_msg
is properly null-terminated:
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#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= strnlen(c_str, sizeof(c_str)); temp = realloc(cur_msg, temp_size);} } if (temp == NULL) else { /* Handle null errorpointer */ } cur_msg = temp; cur_msg_size = temp_size; fputs(stderr, cur_msg); } } |
Because realloc()
does not guarantee that the character sequence 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()
)
return ret;
}
|
Compliant Solution (Copy without Truncation)
If the programmer's intent is to copy without truncation, this compliant solution copies the data and guarantees that the resulting array is null-terminated. If the string cannot be copied, it is handled as an error condition.In this compliant solution, the lessen_memory_usage()
function ensures that the resulting string is always properly null-terminated:
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#include <stdlib<string.h> char *cur_msgenum { STR_SIZE = 32 NULL}; size_t cur_msg_size = 1024; void lessen_memory_usage(voidfunc(const char *source) { char *tempc_str[STR_SIZE]; size_t temp_size ret = 0; if (cur_msg != NULLsource) { temp_size = cur_msg_size / 2 + 1;if (strnlen(source, sizeof(c_str)) < sizeof(c_str)) { temp = reallocstrcpy(curc_msgstr, temp_sizesource); if (tempret == NULL) strlen(c_str); } else { /* Handle errorstring-too-large */ } } cur_msg = temp; cur_msg_size = temp_size; else { /* EnsureHandle stringnull ispointer null-terminated */ } cur_msg[cur_msg_size - 1] = '\0'; } fputs(stderr, cur_msg); }return ret; } |
Note that this code is not bulletproof. It gracefully handles the case where source
is NULL, when it is a valid string, and when source
is not null-terminated, but at least the first 32 bytes are valid. However, in cases where source
is not NULL, but points to invalid memory, or any of the first 32 bytes are invalid memory, the first call to strnlen()
will access this invalid memory, and the resulting behavior is undefined. Unfortunately, standard C provides no way to prevent or even detect this condition without some external knowledge about the memory source
points to.
Risk Assessment
Failure to properly null-terminate a character sequence that is passed to a library function that expects a string 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 | ||||||
---|---|---|---|---|---|---|---|---|---|
Astrée |
| Supported Astrée supports the implementation of library stubs to fully verify this guideline. | |||||||
Axivion Bauhaus Suite |
| CertC-STR32 | Partially implemented: can detect some violation of the rule | ||||||
CodeSonar |
| MISC.MEM.NTERM.CSTRING | Unterminated C String | ||||||
Compass/ROSE |
Can detect some violations of this rule | |||
Coverity |
| STRING_NULL | Fully |
implemented | |||||||||
Helix QAC |
| DF2835, DF2836, DF2839 | |||||||
Klocwork |
| NNTS.MIGHT |
.MUST | ||||||||
LDRA tool suite |
| 404 S, 600 S |
Fully implemented
Partially implemented | |||||||||
Parasoft C/C++test |
| CERT_C-STR32-a | Avoid overflow due to reading a not zero terminated string | ||||||
Polyspace Bug Finder |
| Checks for:
Rule partially covered. | |||||||
PVS-Studio |
| V692 | |||||||
TrustInSoft Analyzer |
| match format and arguments | Partially verified. |
Related Vulnerabilities
Search for vulnerabilities resulting from the violation of this rule on the CERT website.
Related Guidelines
Key here (explains table format and definitions)
Taxonomy | Taxonomy item | Relationship |
---|
ISO/IEC TR 24772:2013 | String Termination [CMJ] | Prior to 2018-01-12: CERT: Unspecified Relationship |
ISO/IEC TS 17961:2013 | Passing a non-null-terminated character sequence to a library function that expects a string [strmod] |
Prior to 2018-01-12: CERT: Unspecified Relationship | |
CWE 2.11 | CWE-119, |
CWE-170, Improper null termination
Improper Restriction of Operations within the Bounds of a Memory Buffer | 2017-05-18: CERT: Rule subset of CWE | |
CWE 2.11 | CWE-123, Write-what-where Condition | 2017-06-12: CERT: Partial overlap |
CWE 2.11 | CWE-125, Out-of-bounds Read | 2017-05-18: CERT: Rule subset of CWE |
CWE 2.11 | CWE-170, Improper Null Termination | 2017-06-13: CERT: Exact |
CERT-CWE Mapping Notes
Key here for mapping notes
CWE-119 and STR32-C
Independent( ARR30-C, ARR38-C, ARR32-C, INT30-C, INT31-C, EXP39-C, EXP33-C, FIO37-C) STR31-C = Subset( Union( ARR30-C, ARR38-C)) STR32-C = Subset( ARR38-C)
CWE-119 = Union( STR32-C, list) where list =
- Out-of-bounds reads or writes that do not involve non-null-terminated byte strings.
CWE-125 and STR32-C
Independent( ARR30-C, ARR38-C, EXP39-C, INT30-C) STR31-C = Subset( Union( ARR30-C, ARR38-C)) STR32-C = Subset( ARR38-C)
CWE-125 = Union( STR32-C, list) where list =
- Out-of-bounds reads that do not involve non-null-terminated byte strings.
CWE-123 and STR32-C
Independent(ARR30-C, ARR38-C) STR31-C = Subset( Union( ARR30-C, ARR38-C)) STR32-C = Subset( ARR38-C)
Intersection( CWE-123, STR32-C) =
- Buffer overflow from passing a non-null-terminated byte string to a standard C library copying function that expects null termination, and that overwrites an (unrelated) pointer
STR32-C - CWE-123 =
- Buffer overflow from passing a non-null-terminated byte string to a standard C library copying function that expects null termination, but it does not overwrite an (unrelated) pointer
CWE-123 – STR31-C =
- Arbitrary writes that do not involve standard C library copying functions, such as strcpy()
Bibliography
[Seacord 2013] | Chapter 2, "Strings" |
[Viega 2005] | Section 5.2.14, "Miscalculated NULL Termination" |
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