According to Section 7.14.1.1 (signals) of the C standard, returning from a SIGSEGV
, SIGILL
, or SIGFPE
signal handler is undefined behavior:
If and when the function returns, if the value of
sig
isSIGFPE
,SIGILL
,SIGSEGV
, or any other implementation-defined value corresponding to a computational exception, the behavior is undefined; otherwise, the program will resume execution at the point it was interrupted.
Furthermore, SIGFPE may not be caught for a significant amount of instructions after the floating-point instruction that creates it.
Noncompliant Code Example
In this noncompliant code example, if the given user input is 0, the division operation sends a SIGFPE
signal to the program.
#include<signal.h> #include<stddef.h> #include<stdlib.h> volatile sig_atomic_t denom; void sighandle(int s){ /* Fix the offending volatile */ if (denom == 0) { denom = 1; } /* Everything is ok */ return; } int main(int argc, char *argv[]){ int result = 0; if (argc < 2) { return 0; } denom = (int)strtol(argv[1], (char **)NULL, 10); signal(SIGFPE,(*sighandle)); result = 100/denom; return 0; }
The noncompliant code example will loop infinitely on input 0 when compiled with GCC 4.3 or GCC 3.4. This illustrates that even when a SIGFPE
handler attempts to fix the error condition while obeying all other rules of signal handling, the program still does not behave as expected.
Compliant Solution
In the compliant solution, the only portably safe way to leave a SIGFPE
, SIGILL
, or SIGSEGV
handler is through abort()
or /_Exit()
. In the case of SIGFPE
, the default handler calls abort()
, so no user-defined handler is actually needed. The handler shown is only for consistency.
#include<signal.h> #include<stddef.h> #include<stdlib.h> volatile sig_atomic_t denom; void sighandle(int s){ /* No recovery */ abort(); } int main(int argc, char *argv[]){ int result = 0; if (argc < 2) { return 0; } denom = (int)strtol(argv[1], (char **)NULL, 10); signal(SIGFPE,(*sighandle)); result = 100/denom; return 0; }
Implementation Details
Some implementations define useful behavior for programs that return from one or more of these signal handlers. For example, Solaris provides the sigfpe()
function specifically to set a SIGFPE
handler that a program may safely return from. Sun also provides platform-specific computational exceptions for the SIGTRAP
, SIGBUS
, and SIGEMT
signals. Finally, GNU libsigsegv takes advantage of the ability to return from a SIGSEGV
handler to implement page-level memory management in user mode.
Risk Assessment
Code that attempts to handle SIGSEGV
, SIGILL
, or SIGFPE
signals is rare. However, code that does rely on handling these signals will usually require a redesign to fix the problem.
Recommendation |
Severity |
Likelihood |
Remediation Cost |
Priority |
Level |
---|---|---|---|---|---|
SIG35-C |
low |
unlikely |
high |
P1 |
L3 |
Related Guidelines
ISO/IEC 9899:1999 7.14.1.1
Bibliography
http://technopark02.blogspot.com/2005/10/handling-sigfpe.html