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From the question:

Is it good programming practice to use setjmp and longjmp in C?

Two of the comments left said:

"You can't throw an exception in a signal handler, but you can do a longjmp safely -- as long as you know what you are doing. – Dietrich Epp Aug 31 at 19:57 @Dietrich: +1 to your comment. This is a little-known and completely-under-appreciated fact. There are a number of problems that cannot be solved (nasty race conditions) without using longjmp out of signal handlers. Asynchronous interruption of blocking syscalls is the classic example."

I was under the impression that signal handlers were called by the kernel when it encountered an exceptional condition (e.g. divide by 0). Also, that they're only called if you specifically register them.

This would seem to imply (to me) that they aren't called through your normal code.

Moving on with that thought... setjmp and longjmp as I understand them are for collapsing up the stack to a previous point and state. I don't understand how you can collapse up a stack when a signal handler is called since its called from the Kernel as a one-off circumstance rather than from your own code. What's the next thing up the stack from a signal handler!?

6 Answers 6

24

The way the kernel "calls" a signal handler is by interrupting the thread, saving the signal mask and processor state in a ucontext_t structure on the stack just beyond (below, on grows-down implementations) the interrupted code's stack pointer, and restarting execution at the address of the signal handler. The kernel does not need to keep track of any "this process is in a signal handler" state; that's entirely a consequence of the new call frame that was created.

If the interrupted thread was in the middle of a system call, the kernel will back out of the kernelspace code and adjust the return address to repeat the system call (if SA_RESTART is set for the signal and the system call is a restartable one) or put EINTR in the return code (if not restartable).

It should be noted that longjmp is async-signal-unsafe. This means it invokes undefined behavior if you call it from a signal handler if the signal interrupted another async-signal-unsafe function. But as long as the interrupted code is not using library functions, or only using library functions that are marked async-signal-safe, it's legal to call longjmp from a signal handler.

Finally, my answer is based on POSIX since the question is tagged unix. If the question were just about pure C, I suspect the answer is somewhat different, but signals are rather useless without POSIX anyway...

15

longjmp does not perform normal stack unwinding. Instead, the stack pointer is simply restored from the context saved by setjmp.

Here is an illustration on how this can bite you with non-async-safe critical parts in your code. It is advisable to e.g. mask the offending signal during critical code.

1
  • Can you name an implementation of longjmp that does not perform stack unwinding? The libc implementation sure doesn't, but C++ is free to substitute an implementation that does, and that's what happens on a number of popular platforms.
    – zneak
    Jun 15, 2017 at 23:28
1

worth reading this: http://man7.org/linux/man-pages/man2/sigreturn.2.html in regard to how Linux handles signal handler invocation, and in this case how it manages signal handler exit, my reading of this suggests that executing a longjmp() from a signal handler (resulting in no call of sigreturn()) might be at best "undefined"... also have to take into account on which thread (and thus user stack) the setjmp() was called, and on which thread (and thus user stack) longjmp() in subsequently called also!

1

This doesn't answer the question of whether or not it is "good" to do this, but this is how to do it. In my application, I have a complicated interaction between custom hardware, huge page, shared memory, NUMA lock memory, etc, and it is possible to have memory that seems to be decently allocated but when you touch it (write in this case), it throws a BUS error or SEGV fault in the middle of the application. I wanted to come up with a way of testing memory addresses to make sure that the shared memory wasn't node locked to a node that didn't have enough memory, so that the program would fail early with graceful error messages. So these signal handlers are ONLY used for this one piece of code (a small memcpy of 5 bytes) and not used to rescue the app while it is in use. I think it is safe here.

Apologies if this is not "correct". Please comment and I'll fix it up. I cobbled it together based on hints and some sample code that didn't work.

#include <stdio.h>
#include <signal.h>
#include <setjmp.h>
#include <unistd.h>
#include <stdlib.h>
#include <string.h>

sigjmp_buf  JumpBuffer;

void handler(int);

int count = 0;

int main(void)
{
    struct sigaction sa;
    sa.sa_handler = handler;
    sigemptyset(&(sa.sa_mask));
    sigaddset(&(sa.sa_mask), SIGSEGV);
    sigaction(SIGSEGV, &sa, NULL);

    while (1) {
        int r = sigsetjmp(JumpBuffer,1);
        if (r == 0) {
            printf("Ready for memcpy, count=%d\n",count);
            usleep(1000000);
            char buffer[10];
#if 1
            char* dst = buffer; // this won't do bad
#else
            char* dst = nullptr; // this will cause a segfault
#endif
            memcpy(dst,"12345",5); // trigger seg fault here
            longjmp(JumpBuffer,2);
        }
        else if (r == 1)
        {
            printf("SEGV. count %d\n",count);
        }
        else if (r == 2)
        {
            printf("No segv. count %d\n",count);
        }
    }
    return 0;
}

void handler(int  sig)
{
    count++;
    siglongjmp(JumpBuffer, 1);
}

References

0

In most systems a signal handler has it's own stack, separate from the main stack. That's why you could longjmp out of a handler. I think it's not a wise thing to do though.

5
  • 3
    It does not have its own stack unless you use sigaltstack. It merely grows on top of the stack of the interrupted code. Any stack memory beyond (below, on common grows-down implementations) the stack pointer is considered unused, so the kernel is free to clobber it (with the necessary arguments for the signal handler and return address to the main program) and adjust the stack pointer for the signal handler code to run. Sep 7, 2011 at 13:52
  • 1
    In that case it's even safer to use a longjmp if you're sure that the handler was called after setjmp.
    – cyco130
    Sep 7, 2011 at 13:58
  • It's always impossible to use longjmp without a valid jmp_buf created by setjmp... Sep 7, 2011 at 14:00
  • @R.. I think the intended meaning of "after" here was "lower down the call stack", not the conventional time-wise meaning. (So "before" would be, for example, a jmp_buf variable declared in main, with a pointer to it passed down to some subroutine which in turn calls setjmp to set another local jmp_buf, but then memcpys the contents from that jmp_buf into the original jmp_buf, and then later in main, a call to longjmp with that original jmp_buf.) I think that's technically undefined behavior, but that's the impression of intended meaning I get here.
    – mtraceur
    Feb 15, 2019 at 21:08
  • Correction: That is definitely undefined behavior, I just wasn't able to verify that within the duration of the comment edit window.
    – mtraceur
    Feb 15, 2019 at 21:14
-3

You can't use longjmp to get out of a signal handler.

The reason for this is that setjmp only saves the resources (process registers) etc. that the calling-convention specifies that should be saved over a plain function call.

When an interrupt occurs, the function being interrupted may have a much larger state, and it will not be restored correctly by longjmp.

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  • 2
    That's not relevant. The same is true whenever you longjmp, regardless of whether it's from a signal handler or not. It's true that the signal mask won't be restored when you longjmp out of a signal handler (you can use sigsetjmp and siglongjmp if you want it to be restored) but this might even be desirable, and it's always possible to save and restore it yourself too if needed. Sep 7, 2011 at 13:57
  • Think of this from the point of view of a compiler. It can do any kind of optimization, like caching the value of a global variable, as long as it is saved back whenever the value could be used again. One assumption that the compiler makes is that a longjmp only can occur is at function calls. If an asynchronous signal occurs and control is passed back using longjmp, this assumption is broken. Hence, you can't use longjmp to return control from a signal handler. (Btw, I've spent the majority of my profession career writing C compilers...) Sep 7, 2011 at 14:24
  • I agree you can't rely on the consistency of data that was being modified in the interrupted code, just like you can't rely on the consistency of that data from within the signal handler context. This is not very relevant however if the interrupted code was only modifying automatic storage objects and possibly kernel-level resources (e.g. calling async-signal-safe functions like sigprocmask, read, etc.). Sep 7, 2011 at 14:36
  • Whatever the interrupt routine does is irrelevant. The fact is that if normal code would be interrupted and control restored using longjmp, then the normal function and normal global data could end up in an inconsistent state. Sep 7, 2011 at 14:46
  • If global data is not being modified, it could not end up in an inconsistent state. 5.1.2.3 also specifies the behavior for volatile global data with signals; at most one value (between sequence points) may be inconsistent, and if the implementation does not have padding bits (or if you're only using character types), there is no possibility of a trap representation and thus no danger. It also allows implementations (or higher-level standards like POSIX) to make further guarantees. Sep 7, 2011 at 14:54

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