Page History

A signal is a mechanism for transferring control that is typically used to notify a process that an event has occurred. That process can then respond to that the event accordingly. C99 provides  The C Standard provides functions for sending and handling signals within a C program.

Signals are handled by a process Processes handle signals by registering a signal handler using the signal() function, which is specified as

void (*signal(int sig, void (*func)(int)))(int);

This signal handler is conceptually equivalent to

typedef void (*SighandlerTypesighandler_t)(int signum);
extern SighandlerTypesighandler_t signal(
  int signum, SighandlerType 
  sighandler_t handler
);

Signal handlers can be interrupted by signals, including their own. If a signal is not reset before its handler is called, the handler can interrupt its own execution. A handler that always successfully executes its code despite interrupting itself or being interrupted is asynchronousasync-signal-safe.

Some platforms provide the ability to mask signals while a signal handler is being processed. If a signal is masked while its own handler is processed, the handler is non-interruptible noninterruptible and need not be asynchronousasync-signal-safe. However, even when a signal is masked while its own handler is processed, the handler must still avoid invoking async-signal-safe unsafe functions because their execution may be (or have been) interrupted by another signal.

Vulnerabilities can arise if a non-asynchronoussignal handler that is not async-signal-safe signal handler is interrupted with any unmasked signal, including its own, especially if it manipulates globally accessible data.

...

Noncompliant Code Example

This non-compliant noncompliant code example registers a single signal handler to process both SIGUSR1 and SIGUSR2. The variable sig2 should be set to one 1 if one or more SIGUSR1 signals are followed by SIGUSR2. This code , essentially implements implementing a finite state machine within the signal handler.

#include <signal.h>

volatile sig_atomic_t sig1 = 0;
volatile sig_atomic_t sig2 = 0;

void handler(int signum) {
  if (signum == SIGUSR1) {
    sig1 = 1;
  }
  else if (sig1) {
    sig2 = 1;
  }
}

int main(void) {
  if (signal(SIGUSR1, handler); == SIG_ERR) {
    /* Handle error */
  }
  if (signal(SIGUSR2, handler);) == SIG_ERR) {
    /* Handler error */
  }

  while (sig2 == 0) {
    /* doDo nothing or give up CPU for a while */
  }

  /* ... */

  return 0;
}

Unfortunately, there is a race condition occurs in the implementation of handler(). If handler() is called to handle SIGUSR1 and is interrupted to handle SIGUSR2, it is possible that sig2 will not be set.This non-compliant code example also violates SIG31-C. Do not access or modify shared objects in signal handlers.

Compliant Solution (POSIX)

The POSIX sigaction() function assigns handlers to signals in a similar manner to the C99 C signal() function, but it also allows signal masks to be set explicitly. Consequently, sigaction() can be used to prevent a signal handler from interrupting itself.

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

volatile sig_atomic_t sig1 = 0;
volatile sig_atomic_t sig2 = 0;

void handler(int signum) {
  if (signum == SIGUSR1) {
    sig1 = 1;
  }
  else if (sig1) {
    sig2 = 1;
  }
}

int main(void) {
  struct sigaction act;
  act.sa_handler = &handler;
  act.sa_flags = 0;
  if (sigemptyset(&act.sa_mask) != 0) {
    /* handleHandle error */
  }
  if (sigaddset(&act.sa_mask, SIGUSR1)) {
    /* handleHandle error */
  }
  if (sigaddset(&act.sa_mask, SIGUSR2)) {
    /* handleHandle error */
  }

  if (sigaction(SIGUSR1, &act, NULL) != 0) {
    /* handleHandle error */
  }
  if (sigaction(SIGUSR2, &act, NULL) != 0) {
    /* handleHandle error */
  }

  while (sig2 == 0) {
    /* doDo nothing or give up CPU for a while */
  }

  /* ... */

  return 0;
}

POSIX recommends sigaction() and deprecates the use of signal() to register signal handlers. Unfortunately, sigaction() is not defined in C99 and in the C Standard and is consequently not as portable a solution.

Risk Assessment

...

Interrupting a non-interruptible noninterruptible signal handler can result in a variety of vulnerabilities \[ [Zalewski 01|AA. C References#Zalewski 01]\2001].

Recommendation	Severity	Likelihood	Remediation Cost	Priority	Level
SIG00-

A

3 (high)

3 (likely)

1 (high)

C

High

Likely

High

P9

L2

Automated Detection

Related Vulnerabilities

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" (Signal Interruption and Repetition)
\[[ISO/IEC 03|AA. C References#ISO/IEC 03]\] Section 5.2.3, "Signals and interrupts"
\[[Open Group 04|AA. C References#Open Group 04]\] [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]
\[[Zalewski 01|AA. C References#Zalewski 01]\]

Related Guidelines

Bibliography

...

Image Added Image Added Image Added11. Signals (SIG)      11. Signals (SIG)       SIG01-A. Understand implementation-specific details regarding signal handler persistence