After invoking longjmp(), non-volatile-qualified local objects should not be accessed if their values could have changed since the invocation of setjmp(). Their value in this case is considered indeterminate, and accessing them is undefined behavior.

Now my question is why volatile works in this situation? Wouldn't change in that volatile variable still fail the longjmp? For example, how longjmp will work correctly in the example given below? When the code get backs to setjmp after longjmp, wouldn't the value of local_var be 2 instead of 1?

void some_function()
  volatile int local_var = 1;

  setjmp( buf );
  local_var = 2;
  longjmp( buf, 1 );

setjmp and longjmp clobber registers. If a variable is stored in a register, its value gets lost after a longjmp.

Conversely, if it's declared as volatile, then every time it gets written to, it gets stored back to memory, and every time it gets read from, it gets read back from memory every time. This hurts performance, because the compiler has to do more memory accesses instead of using a register, but it makes the variable's usage safe in the face of longjmping.

  • 2
    Is there any way I can reduce the performance overhead due to volatile, while still have accurate execution? How much volatile would impact the optimization? Nov 3 '11 at 15:09
  • 6
    Well you could add some extra code to only make it volatile across the call to setjmp. Something like: int x; /* do stuff */ volatile int save_x = x; if(setjmp(buf)) { x = save_x; /* do stuff */ }. This maximizes performance before and after setjmp by using non-volatile variables, but ensures safety by using a volatile variable across the call. Nov 3 '11 at 15:14
  • Cool man, that is indeed a nice trick! But I can see that compiler wouldn't try to use registers for arrays, so in case of arrays volatile would not make such difference, right? Nov 3 '11 at 15:23

The crux is in the optimization in this scenario: The optimizer would naturally expect that a call to a function like setjmp() does not change any local variables, and optimize away read accesses to the variable. Example:

int foo;
foo = 5;
if ( setjmp(buf) != 2 ) {
   if ( foo != 5 ) { optimize_me(); longjmp(buf, 2); }
   foo = 6;
   longjmp( buf, 1 );
   return 1;
return 0;

An optimizer can optimize away the optimize_me line because foo has been written in line 2, does not need to be read in line 4 and can be assumed to be 5. Additionally, the assignment in line 5 can be removed because foo would be never read again if longjmp was a normal C functon. However, setjmp() and longjmp() disturb the code flow in a way the optimizer cannot account for, breaking this scheme. The correct result of this code would be a termination; with the line optimized away, we have an endless loop.

  • 1
    Actually modern C compilers do need to know that setjmp is a special case, since there are, in general, optimizations where the change of flow caused by setjmp could badly corrupt things, and these need to be avoided. Back in K&R days, setjmp did not need special handling, and didn't get any, and so the caveat about locals applied. Since that caveat is already there and (should be!) understood - and of course, setjmp use is pretty rare - there is no incentive for modern compilers to go to any extra lengths to fix the 'clobber' issue -- it would still be in the language.
    – greggo
    Nov 4 '16 at 15:40

The most common reason for problems in the absence of a 'volatile' qualifier is that compilers will often place local variables into registers. These registers will almost certainly be used for other things between the setjmp and longjmp. The most practical way to ensure that the use of these registers for other purposes won't cause the variables to hold the wrong values after the longjmp is to cache the values of those registers in the jmp_buf. This works, but has the side effect that there is no way for the compiler to update the contents of the jmp_buf to reflect changes made to the variables after the registers are cached.

If that were the only problem, the result of accessing local variables not declared volatile would be indeterminate, but not Undefined Behavior. There's a problem even with memory variables, though, which thiton alludes to: even if a local variable happens to be allocated on the stack, a compiler would be free to overwrite that variable with something else any time it determines that its value is no longer needed. For example, a compiler could identify that some variables are never 'live' when a routine calls other routines, place those variables shallowest in its stack frame, and pop them before calling other routines. In such a scenario, even though the variables existed in memory when setjmp() is called, that memory might have been reused for something else like holding return address. As such, after the longjmp() is performed, the memory would be considered uninitialized.

Adding a 'volatile' qualifier to a variable's definition causes storage to be reserved exclusively for the use of that variable, for as long as it is within scope. No matter what happens between the setjmp and longjmp, provided control has not left the scope where the variable was declared, nothing is allowed to use that location for any other purpose.

  • How much would this impact the performance. Can't we do something like tell the compiler to use a register for a variable as it pleases but flush it to a memory area representing that variable at some point, so that when we call longjmp, the variable value is there. Nov 3 '11 at 15:17
  • @MetallicPriest: Fair question. There are at least two distinctly different levels of volatile semantics one might need, one of which could have a significantly higher performance penalty than the other. My guess would be that compilers would use the definition that allows the fewest optimizations; if efficiency in using those variables matters, I would suggest declaring both volatile and non-volatile variables, and copying the volatile one to the non-volatile one after the setjmp, and only writing to the volatile one in cases where one cares about the longjmp() seeing it.
    – supercat
    Nov 3 '11 at 15:40
  • Say if we push all the registers in a stack before calling each function, would the problem still remain? I mean in that case, even if the local variables are accessed through registers, they would be pushed in the stack and later popped. isn't it? And secondly, say even if don't use push them, setjmp would have the registers saved them in a buffer anyway, so on returning why wouldn't we have the right value of the variables? I mean it should be the value which was when setjmp was called. isn't it? Nov 3 '11 at 16:20
  • @MetallicPriest: Normally, longjmp() will be called from within a function that is in turn called by the function which performed the setjmp(). In some cases, however, it could be called by an asynchronous signal handler. In such a scenario, if there isn't an up-to-date copy of the variable kept on the stack, there would likely be no way for longjmp() to determine what the correct value of the variable should be. If a routine that does a setjmp() passes the jmp_buf to some other routine, the compiler would have no way of knowing whether that routine might create a signal handler.
    – supercat
    Nov 3 '11 at 16:27
  • The performance impact is likely to be pretty minor compared to the cost of calling setjmp - let alone the cost of calling another function which calls longjmp.
    – greggo
    Nov 4 '16 at 15:22

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