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Call only asynchronous-safe functions within signal handlers. For strictly conforming programs, only the C standard library functions abort(), _Exit(), quick_exit(), and signal() can be safely called from within a signal handler. 

The C Standard, Wiki MarkupAccording to Section 7.14.1.1 of the C Rationale \[, paragraph 5 [ISO/IEC 03|AA. C References#ISO/IEC 03]\]:

When a signal occurs, the normal flow of control of a program is interrupted. If a signal occurs that is being trapped by a signal handler, that handler is invoked. When it is finished, execution continues at the point at which the signal occurred. This arrangement can cause problems if the signal handler invokes a library function that was being executed at the time of the signal.

Similarly, Section 7.14.1 paragraph 5 of C99 \[[ISO/IEC 9899:1999|AA. C References#ISO/IEC 9899-1999]\] states that if the signal occurs other than as the result of calling the {{abort}} or {{raise}} function, the behavior is [undefined|BB. Definitions#undefined behavior] if:

...the signal handler calls any function in the standard library other than the abort function, the _Exit function, or the signal function with the first argument equal to the signal number corresponding to the signal that caused the invocation of the handler.

Many systems define an implementation-specific list of asynchronous safe functions. In general, I/O functions are not safe to invoke inside signal handlers. Check your system's asynchronous-safe functions before using them in signal handlers.

Non-Compliant Code Example

In this non-compliant code example, the program allocates a string on the heap, and uses it to log messages in a loop. The program also registers the signal handler int_handler() to handle the terminal interrupt signal SIGINT. The int_handler() function logs the last message, calls free(), and exits.

9899:2024], states that if the signal occurs other than as the result of calling the abort() or raise() function, the behavior is undefined if

If the signal occurs other than as the result of calling the abort or raise function, the behavior is undefined if the signal handler refers to any object with static or thread storage duration that is not a lock-free atomic object and that is not declared with the constexpr storage-class specifier other than by assigning a value to an object declared as volatile sig_atomic_t, or the signal handler calls any function in the standard library other than

—  the abort function,

—  the _Exit function,

—  the quick_exit function,

—  the functions in <stdatomic.h> (except where explicitly stated otherwise) when the atomic arguments are lock-free,

—  the atomic_is_lock_free function with any atomic argument, or

—  the signal function with the first argument equal to the signal number corresponding to the signal that caused the invocation of the handler. Furthermore, if such a call to the signal function results in a SIG_ERR return, the object designated by errno has an indeterminate representation.294)

Implementations may define a list of additional asynchronous-safe functions. These functions can also be called within a signal handler. This restriction applies to library functions as well as application-defined functions.

According to the C Rationale, 7.14.1.1 [C99 Rationale 2003],

When a signal occurs, the normal flow of control of a program is interrupted. If a signal occurs that is being trapped by a signal handler, that handler is invoked. When it is finished, execution continues at the point at which the signal occurred. This arrangement can cause problems if the signal handler invokes a library function that was being executed at the time of the signal.

In general, it is not safe to invoke I/O functions from within signal handlers. Programmers should ensure a function is included in the list of an implementation's asynchronous-safe functions for all implementations the code will run on before using them in signal handlers.

Noncompliant Code Example

In this noncompliant example, the C standard library functions fputs() and free() are called from the signal handler via the function log_message(). Neither function is asynchronous-safe.

#include <signal.h>
#include <stdio.h>
#include <stdlib.h>

enum { MAXLINE = 1024 };
char *info = NULL;

void log_message(void) {
  fputs(info, stderr);
}

void handler(int signum) {
  log_message(

#include <signal.h>
#include <stdio.h>
#include <stdlib.h>

enum { MAXLINE = 1024 };
char *info = NULL;

void log_message(void) {
  fprintf(stderr, info);
}

void handler(int signum) {
  log_message();
  free(info);
  info = NULL;
}

int main(void) {
  if (signal(SIGINT, handler);
  info == (char*)malloc(MAXLINE);SIG_ERR) {
  if   /* Handle error */
  }
  info = (char *)malloc(MAXLINE);
  if (info == NULL) {
    /* Handle Error */
  }

  while (1) {
    /* mainMain loop program code */

    log_message();

    /* moreMore program code */
  }
  return 0;
}

Compliant Solution

This program has four potential problems. The first is that the Signal handlers should be as concise as possible—ideally by unconditionally setting a flag and returning. This compliant solution sets a flag of type volatile sig_atomic_t and returns; the log_message() function calls fprintf(), which is an unsafe function to call from within a signal handler, because the handler might have been called when global data (such as stderr) was in an inconsistent state. In general, standard I/O is never safe to invoke within a signal handler.

The second problem is that the {{free()}} function is also not \[[asynchronous-safe|AA. C References#asynchronous-safe]\], and its invocation from within a signal handler is also a violation of this rule. If an interrupt signal is received during the {{free()}} call in {{main()}}, the heap may be corrupted.

The third problem is if SIGINT occurs after the call to free(), resulting in the memory referenced by info being freed twice. This is a violation of MEM31-C. Free dynamically allocated memory exactly once and SIG31-C. Do not access or modify shared objects in signal handlers.

The fourth and final problem is that the signal handler reads the variable info, which is not declared to be of type volatile sig_atomic_t. This is a violation of SIG31-C. Do not access or modify shared objects in signal handlers.

Implementation Details

POSIX

The following table from the the Open Group Base Specifications \[[Open Group 04|AA. C References#Open Group 04]\] defines a set of functions that are asynchronous-signal-safe. Applications may consequently invoke them, without restriction, from signal-catching functions.

All functions not in this table are considered to be unsafe with respect to signals. In the presence of signals, all functions defined by IEEE standard 1003.1-2001 behave as defined when called from or interrupted by a signal-catching function, with a single exception: when a signal interrupts an unsafe function and the signal-catching function calls an unsafe function, the behavior is undefined.

Note that while raise() is on the list of asynchronous-safe functions, it is specifically covered by SIG33-C. Do not recursively invoke the raise() function.

OpenBSD

The OpenBSD signal() man page identifies functions that are asynchronous-signal safe. Applications may consequently invoke them, without restriction, from signal-catching functions.

The OpenBSD signal() man page list a few additional functions that are asynchronous-safe in OpenBSD but "probably not on other systems" including: snprintf(), vsnprintf(), and syslog_r() (but only when the syslog_data struct is initialized as a local variable).

Compliant Solution

Signal handlers should be as concise as possible, ideally unconditionally setting a flag and returning. They may also call the _Exit() function. Finally, they may call functions listed above as asynchronous-safe.

This example code achieves compliance with this rule by moving the final log message and call to free() outside the signal handler.

#include <signal.h>
#include <stdio.h>
#include <stdlib.h>

enum { MAXLINE = 1024 };
volatile sig_atomic_t eflag = 0;
char *info = NULL;

void log_message(void) {
  fprintf(stderr, info);
}

void handler(int signum) {
  eflag = 1;
}

int main(void) {
  signal(SIGINT, handler);
  info = (char*)malloc(MAXLINE);
  if (info == NULL) {
    /* Handle Error */
  }

  while (!eflag) {
    /* main loop program code */

    log_message();

    /* more program code */
  }

  log_message();
  free(info);
  info = NULL;

  return 0;
}

Risk Assessment

Invoking functions that are not asynchronous-safe from within a signal handler may result in privilege escalation and other attacks.

Automated Detection

Compass/ROSE can detect violations of the rule for single-file programs.

Related Vulnerabilities

For an overview of some software vulnerabilities, see Zalewski's paper on understanding, exploiting, and preventing signal-handling related vulnerabilities \[[Zalewski 01|AA. C References#Zalewski 01]\]. [VU #834865|http://www.kb.cert.org/vuls/id/834865] describes a vulnerability resulting from a violation of this rule.

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

References

\[[Dowd 06|AA. C References#Dowd 06]\] Chapter 13, "Synchronization and State"
\[[ISO/IEC 03|AA. C References#ISO/IEC 03]\] Section 5.2.3, "Signals and interrupts"
\[[ISO/IEC 9899:1999|AA. C References#ISO/IEC 9899-1999]\] Section 7.14, "Signal handling <signal.h>"
\[[Open Group 04|AA. C References#Open Group 04]\] [longjmp|http://www.opengroup.org/onlinepubs/000095399/functions/longjmp.html]
\[[OpenBSD|AA. C References#OpenBSD]\] [{{signal()}} Man Page|http://www.openbsd.org/cgi-bin/man.cgi?query=signal]
\[[Zalewski 01|AA. C References#Zalewski 01]\]

and free() functions are called directly from main():

#include <signal.h>
#include <stdio.h>
#include <stdlib.h>

enum { MAXLINE = 1024 };
volatile sig_atomic_t eflag = 0;
char *info = NULL;

void log_message(void) {
  fputs(info, stderr);
}

void handler(int signum) {
  eflag = 1;
}

int main(void) {
  if (signal(SIGINT, handler) == SIG_ERR) {
    /* Handle error */
  }
  info = (char *)malloc(MAXLINE);
  if (info == NULL) {
    /* Handle error */
  }

  while (!eflag) {
    /* Main loop program code */

    log_message();

    /* More program code */
  }

  log_message();
  free(info);
  info = NULL;

  return 0;
}

Noncompliant Code Example (longjmp())

Invoking the longjmp() function from within a signal handler can lead to undefined behavior if it results in the invocation of any non-asynchronous-safe functions. Consequently, neither longjmp() nor the POSIX siglongjmp() functions should ever be called from within a signal handler.

This noncompliant code example is similar to a vulnerability in an old version of Sendmail [VU #834865]. The intent is to execute code in a main() loop, which also logs some data. Upon receiving a SIGINT, the program transfers out of the loop, logs the error, and terminates.

However, an attacker can exploit this noncompliant code example by generating a SIGINT just before the second if statement in log_message(). The result is that longjmp() transfers control back to main(), where log_message() is called again. However, the first if statement would not be executed this time (because buf is not set to NULL as a result of the interrupt), and the program would write to the invalid memory location referenced by buf0.

#include <setjmp.h>
#include <signal.h>
#include <stdlib.h>

enum { MAXLINE = 1024 };
static jmp_buf env;

void handler(int signum) {
  longjmp(env, 1);
}

void log_message(char *info1, char *info2) {
  static char *buf = NULL;
  static size_t bufsize;
  char buf0[MAXLINE];

  if (buf == NULL) {
    buf = buf0;
    bufsize = sizeof(buf0);
  }

  /*
   * Try to fit a message into buf, else reallocate
   * it on the heap and then log the message.
   */

  /* Program is vulnerable if SIGINT is raised here */

  if (buf == buf0) {
    buf = NULL;
  }
}

int main(void) {
  if (signal(SIGINT, handler) == SIG_ERR) {
    /* Handle error */
  }
  char *info1;
  char *info2;

  /* info1 and info2 are set by user input here */

  if (setjmp(env) == 0) {
    while (1) {
      /* Main loop program code */
      log_message(info1, info2);
      /* More program code */
    }
  } else {
    log_message(info1, info2);
  }

  return 0;
}

Compliant Solution

In this compliant solution, the call to longjmp() is removed; the signal handler sets an error flag instead:

#include <signal.h>
#include <stdlib.h>

enum { MAXLINE = 1024 };
volatile sig_atomic_t eflag = 0;

void handler(int signum) {
  eflag = 1;
}

void log_message(char *info1, char *info2) {
  static char *buf = NULL;
  static size_t bufsize;
  char buf0[MAXLINE];

  if (buf == NULL) {
    buf = buf0;
    bufsize = sizeof(buf0);
  }

  /*
   * Try to fit a message into buf, else reallocate
   * it on the heap and then log the message.
   */
  if (buf == buf0) {
    buf = NULL;
  }
}

int main(void) {
  if (signal(SIGINT, handler) == SIG_ERR) {
    /* Handle error */
  }
  char *info1;
  char *info2;

  /* info1 and info2 are set by user input here */

  while (!eflag) {
    /* Main loop program code */
    log_message(info1, info2);
    /* More program code */
  }

  log_message(info1, info2);

  return 0;
}

Noncompliant Code Example (raise())

In this noncompliant code example, the int_handler() function is used to carry out tasks specific to SIGINT and then raises SIGTERM. However, there is a nested call to the raise() function, which is undefined behavior.

#include <signal.h>
#include <stdlib.h>
 
void term_handler(int signum) {
  /* SIGTERM handler */
}
 
void int_handler(int signum) {
  /* SIGINT handler */
  if (raise(SIGTERM) != 0) {
    /* Handle error */
  }
}
 
int main(void) {
  if (signal(SIGTERM, term_handler) == SIG_ERR) {
    /* Handle error */
  }
  if (signal(SIGINT, int_handler) == SIG_ERR) {
    /* Handle error */
  }
 
  /* Program code */
  if (raise(SIGINT) != 0) {
    /* Handle error */
  }
  /* More code */
 
  return EXIT_SUCCESS;
}

Compliant Solution

In this compliant solution, int_handler() invokes term_handler() instead of raising SIGTERM: 

#include <signal.h>
#include <stdlib.h>
 
void term_handler(int signum) {
  /* SIGTERM handler */
}
 
void int_handler(int signum) {
  /* SIGINT handler */
  /* Pass control to the SIGTERM handler */
  term_handler(SIGTERM);
}
 
int main(void) {
  if (signal(SIGTERM, term_handler) == SIG_ERR) {
    /* Handle error */
  }
  if (signal(SIGINT, int_handler) == SIG_ERR) {
    /* Handle error */
  }
 
  /* Program code */
  if (raise(SIGINT) != 0) {
    /* Handle error */
  }
  /* More code */
 
  return EXIT_SUCCESS;
}

Implementation Details

POSIX

The following table from the POSIX standard [IEEE Std 1003.1:2013] defines a set of functions that are asynchronous-signal-safe. Applications may invoke these functions, without restriction, from a signal handler.

All functions not listed in this table are considered to be unsafe with respect to signals. In the presence of signals, all POSIX functions behave as defined when called from or interrupted by a signal handler, with a single exception: when a signal interrupts an unsafe function and the signal handler calls an unsafe function, the behavior is undefined.

The C Standard, 7.14.1.1, paragraph 4 [ISO/IEC 9899:2011], states

If the signal occurs as the result of calling the abort or raise function, the signal handler shall not call the raise function.

However, in the description of signal(), POSIX [IEEE Std 1003.1:2013] states

This restriction does not apply to POSIX applications, as POSIX.1-2008 requires raise() to be async-signal-safe.

See also undefined behavior 131. 

OpenBSD

The OpenBSD signal() manual page lists a few additional functions that are asynchronous-safe in OpenBSD but "probably not on other systems" [OpenBSD], including snprintf(), vsnprintf(), and syslog_r() but only when the syslog_data struct is initialized as a local variable.

Risk Assessment

Invoking functions that are not asynchronous-safe from within a signal handler is undefined behavior.

Automated Detection

Related Vulnerabilities

For an overview of software vulnerabilities resulting from improper signal handling, see Michal Zalewski's paper "Delivering Signals for Fun and Profit" [Zalewski 2001].

CERT Vulnerability Note VU #834865, "Sendmail signal I/O race condition," describes a vulnerability resulting from a violation of this rule. Another notable case where using the longjmp() function in a signal handler caused a serious vulnerability is wu-ftpd 2.4 [Greenman 1997]. The effective user ID is set to 0 in one signal handler. If a second signal interrupts the first, a call is made to longjmp(), returning the program to the main thread but without lowering the user's privileges. These escalated privileges can be used for further exploitation.

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

Related Guidelines

Key here (explains table format and definitions)

Bibliography

...

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adjust column widthsSIG02-A. Avoid using signals to implement normal functionality      11. Signals (SIG)       SIG31-C. Do not access or modify shared objects in signal handlers