In theory, you run the risk of having your program
terminate if you ever have two unhandled exceptions at the same time. This is, however, a rather rare situation.
- Throwing during the preparation of the exception: fine (though you won't get the exception you expected)
- Throwing during the copy of the exception (often elided, avoidable): crash
- Throwing during the unwinding: crash
- Throwing during the handling of the exception (
catch): fine (after all, rethrowing a different exception is common)
So, the avoidable risk here is if the copy constructor of your exception might happen to throw. It is trivial to elude the issue by moving the state off to a
shared_ptr contained within the exception. It makes copies a bit "special" (since they share their state with the original) but if it's documented properly it should not cause any grief.
The greater risk is during stack unwinding. It only occurs if a destructor throws, though.
Personally, the exceptions I use contain:
- an error code (for the API to display/encode properly, all error messages are mapped to a code, it helps in Chinese/Korean/Japanese, really)
- a log message, with some details (ID/name of the item that cause the issue, original error when translating another exception, whatever helps!)
- the function/file/line at which the exception was thrown
- the time at which the exception thrown
- additional notes (appended "on the fly" during stack unwinding)
- a complete backtrace (using Linux specific functions)
The only controversial point here is the on the fly bit, since it might effectively crash. On the other hand, I work on servers so crashes are easily (and urgently) fixed and for the last 5 years I was careful enough not to cause a crash (this way ;)).
Note that this scheme is obviously only available if you use exceptions sparsely. If you routinely throw a dozen exceptions per task, the performance might be unnacceptable. On the other hand, the Zero Cost model used by major compilers already harshly penalize the exceptional path so...