According to the C Standard Annex J.2 (133) [ISO/IEC 9899:2024], the behavior of a program is undefined when
the
...
value of
errno
is referred to after a signal occurred other than as the result of calling theabort
...
or
raise
...
function and the corresponding signal handler obtained a
SIG_ERR
return from a call to the
...
Non-Compliant Code Example
signal
function.
A signal handler is allowed to call signal();
if that fails, signal()
returns SIG_ERR
and sets errno
to a positive value. However, if the event that caused a signal was external (not the result of the program calling abort()
or raise()
), the only functions the signal handler may call are _Exit()
or abort()
, or it may call signal()
on the signal currently being handled; if signal()
fails, the value of errno
is indeterminate.
This rule is also a special case of SIG31-C. Do not access shared objects in signal handlers. The object designated by errno
is of static storage duration and is not a volatile sig_atomic_t
. As a result, performing any action that would require errno
to be set would normally cause undefined behavior. The C Standard, 7.14.1.1, paragraph 5, makes a special exception for errno
in this case, allowing errno
to take on an indeterminate value but specifying that there is no other undefined behavior. This special exception makes it possible to call signal()
from within a signal handler without risking undefined behavior, but the handler, and any code executed after the handler returns, must not depend on the value of errno
being meaningful.
Noncompliant Code Example
The handler()
function in this noncompliant code example attempts to restore default handling for the signal indicated by signum
. If the request to set the signal to default If the request to register a signal handler can be honored, the signal()
function returns the value of the signal handler for the most recent successful call to the signal()
function for the specified signal. Otherwise, a value of
SIG_ERR
is returned and a positive value is stored in errno
. Unfortunately, the value of errno
is indeterminate because the handler()
function is called when an external signal is raised, so any attempt to read errno
(for example, by the perror()
function) is undefined behavior:
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#include <signal.h> #include <stdlib.h> #include <string<stdio.h> chartypedef void *err_msg; volatile sig_atomic_t e_flag = 0(*pfv)(int); void handler(int signum) { pfv old_handler = signal(signum, handlerSIG_DFL); if e(old_flaghandler == 1; } int main(voidSIG_ERR) { signalperror("SIGINT, handler"); /* err_msg = (char *)malloc(24);Undefined behavior */ if (err_msg == NULL) { /* handleHandle error condition */ } } int strcpy(err_msg, "No errors yet."); /* main code loop */main(void) { pfv old_handler = signal(SIGINT, handler); if (e_flagold_handler == SIG_ERR) { strcpyperror(err_msg, "SIGINT received.handler"); /* Handle error */ } /* Main code loop */ return 0EXIT_SUCCESS; } |
The call to perror()
from handler()
also violates SIG30-C. Call only asynchronous-safe functions within signal handlers.
Compliant Solution
The This compliant solution does not reference errno
. and does not return from the signal handler if the signal()
call fails:
Code Block | ||||
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#include <signal.h> #include <stdlib.h> #include <string<stdio.h> typedef void (*pfv)(int); char *err_msg; void handler(int signum) { pfv old_handler = signal(signum, handlerSIG_DFL); if (old_handler == SIG_ERR) { /* handle error condition */ abort(); } strcpy(err_msg, "SIGINT encountered."); } int main(void) { pfv old_handler = signal(SIGINT, handler); if (old_handler == SIG_ERR) { perror("SIGINT handler"); /* handleHandle error condition */ } /* Main code loop */ return EXIT_SUCCESS; } |
Noncompliant Code Example (POSIX)
POSIX is less restrictive than C about what applications can do in signal handlers. It has a long list of asynchronous-safe functions that can be called. (See SIG30-C. Call only asynchronous-safe functions within signal handlers.) Many of these functions set errno
on error, which can lead to a signal handler being executed between a call to a failed function and the subsequent inspection of errno
. Consequently, the value inspected is not the one set by that function but the one set by a function call in the signal handler. POSIX applications can avoid this problem by ensuring that signal handlers containing code that might alter errno
; always save the value of errno
on entry and restore it before returning.
The signal handler in this noncompliant code example alters the value of errno
. As a result, it can cause incorrect error handling if executed between a failed function call and the subsequent inspection of errno
:
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#include <signal.h> #include err_msg = (char *)malloc(24); if (err_msg == NULL) <stdlib.h> #include <errno.h> #include <sys/wait.h> void reaper(int signum) { errno = 0; for (;;) { int rc = waitpid(-1, NULL, WNOHANG); if ((0 == rc) || (-1 == rc && EINTR != errno)) { break; } } if (ECHILD != errno) { /* Handle error */ } } int main(void) { struct sigaction act; act.sa_handler = reaper; act.sa_flags = 0; if (sigemptyset(&act.sa_mask) != 0) { /* Handle error */ } if (sigaction(SIGCHLD, &act, NULL) != 0) { /* handleHandle error condition */ } /* ... */ return EXIT_SUCCESS; } |
Compliant Solution (POSIX)
This compliant solution saves and restores the value of errno
in the signal handler:
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| ||||
#include strcpy(err_msg, "No errors yet."); /* main code loop<signal.h> #include <stdlib.h> #include <errno.h> #include <sys/wait.h> void reaper(int signum) { errno_t save_errno = errno; errno = 0; for (;;) { int rc = waitpid(-1, NULL, WNOHANG); if ((0 == rc) || (-1 == rc && EINTR != errno)) { break; } } if (ECHILD != errno) { /* Handle error */ } errno = save_errno; } int main(void) { struct sigaction act; act.sa_handler = reaper; act.sa_flags = 0; if (sigemptyset(&act.sa_mask) != 0) { /* Handle error */ } if (sigaction(SIGCHLD, &act, NULL) != 0) { /* Handle error */ } /* ... */ return 0EXIT_SUCCESS; } |
Risk Assessment
Referencing indeterminate values of errno
is undefined behavior.
Rule | Severity | Likelihood | Remediation Cost | Priority | Level |
---|---|---|---|---|---|
ERR32-C |
1 (low)
1 (unlikely)
3 (low)
P3
Low | Unlikely | Low | P3 | L3 |
Automated Detection
Tool | Version | Checker | Description | ||||||
---|---|---|---|---|---|---|---|---|---|
Astrée |
| chained-errno-function-calls errno-test-after-wrong-call | Supported | ||||||
Axivion Bauhaus Suite |
| CertC-ERR32 | |||||||
Compass/ROSE | Could detect violations of this rule by looking for signal handlers that themselves call | ||||||||
Coverity |
| MISRA C 2012 Rule 22.8 MISRA C 2012 Rule 22.9 MISRA C 2012 Rule 22.10 | Implemented | ||||||
Cppcheck Premium |
| premium-cert-err32-c | Partially implemented | ||||||
Helix QAC |
| C2031 DF4781, DF4782, DF4783 | |||||||
Klocwork |
| MISRA.INCL.SIGNAL.2012 | |||||||
LDRA tool suite |
| 44 S | Enhanced enforcement | ||||||
Parasoft C/C++test |
| CERT_C-ERR32-a | Properly use errno value | ||||||
| CERT C: Rule ERR32-C | Checks for misuse of errno in a signal handler (rule fully covered) | |||||||
RuleChecker |
| chained-errno-function-calls errno-test-after-wrong-call | Supported |
Related Vulnerabilities
Search for vulnerabilities resulting from the violation of this rule on the CERT website.
References
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Related Guidelines
Key here (explains table format and definitions)
Taxonomy | Taxonomy item | Relationship |
---|---|---|
CERT C Secure Coding Standard | SIG30-C. Call only asynchronous-safe functions within signal handlers | Prior to 2018-01-12: CERT: Unspecified Relationship |
CERT C Secure Coding Standard | SIG31-C. Do not access shared objects in signal handlers | Prior to 2018-01-12: CERT: Unspecified Relationship |
Bibliography
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9899:2024] | Subclause 7.14.1.1, |
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"The |
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signal Function" |
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function"ERR31-C. Don't redefine errno 13. Error Handling (ERR) ERR33-C. Only examine the value of errno when it is indicated to be valid by a function's return value