A couple of years ago I was taught, that in real-time applications such as Embedded Systems or (Non-Linux-)Kernel-development C++-Exceptions are undesirable. (Maybe that lesson was from before gcc-2.95). But I also know, that Exception Handling has become better.

So, are C++-Exceptions in the context of real-time applications in practice

  • totally unwanted?
  • even to be switched off via via compiler-switch?
  • or very carefully usable?
  • or handled so well now, that one can use them almost freely, with a couple of things in mind?
  • Does C++11 change anything w.r.t. this?

Update: Does exception handling really require RTTI to be enabled (as one answerer suggested)? Are there dynamic casts involved, or similar?

  • 7
    @Chris What issues c++ has in these environments? I am using c++ for an embedded system and is great. Mar 10, 2011 at 8:58
  • 2
    @RedX: C++ is just fine in a real-time environment (unless the real-time requirements are truly extreme), as long as you're careful about what you do in the time-critical sections (as you must be in any language). The only things that really happen "behind the curtains" are constructors, destructors, and overloaded operators, and it's easy enough to tame these by just not doing anything weird in performance-critical classes. Mar 10, 2011 at 9:36
  • 2
    error handling via exceptions means its impossible to prove code coverage. Kernel (Rather than 'merely' embedded or realtime) development requires code placement - c++'s implicitly generated code structures can't be explicitly placed. Kernel development again has situations where hardware exceptions MUST NOT be thrown, so sw exceptions implemented on hw exceptions is out. embedded development also has memory conditions where the c++ memory model is inconvenient. Mar 10, 2011 at 10:22
  • 1
    @Steve: to some extent, although personally my code looks very little like C. The important thing is to understand everything that happens on the critical path; avoiding too much implicit behaviour helps that understanding, and makes it easier to find bottlenecks by inspection. The biggest issue is to make sure there's no heap allocation/deallocation, and only use classes that are very clear about when that happens. Mar 10, 2011 at 10:39
  • 2
    @Lundin: This is getting a bit off-topic, and I'm not about to spend money to discover why MISRA think C++ needs restricting to a subset, or what that subset might be. But I do disagree with your alleged choice between adhering to a coding standard and working in chaos. Coding guidelines can be useful (at the level of, e.g. "prefer RAII to manual resource management", not "put this brace here, not here"), but they are no substitute for an understanding of the language and problem domain, and a desire to produce clean, maintainable code. These to me are the hallmarks of a professional. Mar 10, 2011 at 18:08

7 Answers 7


Exceptions are now well-handled, and the strategies used to implement them make them in fact faster than testing return code, because their cost (in terms of speed) is virtually null, as long as you do not throw any.

However they do cost: in code-size. Exceptions usually work hand in hand with RTTI, and unfortunately RTTI is unlike any other C++ feature, in that you either activate or deactivate it for the whole project, and once activated it will generated supplementary code for any class that happens to have a virtual method, thus defying the "you don't pay for what you don't use mindset".

Also, it does require supplementary code for its handling.

Therefore the cost of exceptions should be measured not in terms of speed, but in terms of code growth.


From @Space_C0wb0y: This blog article gives a small overview, and introduces two widespread methods for implementing exceptions Jumps and Zero-Cost. As the name implies, good compilers now use the Zero-Cost mechanism.

The Wikipedia article on Exception Handling talk about the two mechanisms used. The Zero-Cost mechanism is the Table-Driven one.


From @Vlad Lazarenko whose blog I had referenced above, the presence of exception thrown might prevent a compiler from inlining and optimizing code in registers.

  • 2
    I know of the two typical ways to "set up" for a potentional Exception (roughly): I think, One needs space, the other time during run-time. Even if no exception is thrown.
    – towi
    Mar 10, 2011 at 9:00
  • 1
    @VJo: you're wrong :) It's the old way of doing things, but now compilers use another strategy which make exception propagation slower but doesn't introduce overhead in the case no exception is thrown. I'll shamelessly steal @Space_C0wb0y link to add some reference. Mar 10, 2011 at 9:04
  • 1
    @Matthieu It is not possible not to have at least minimal overhead. The only way to check what really happen is to compile an example into assembly code. Mar 10, 2011 at 9:11
  • 2
    @VJo: The Table-Driven approach is based on the Program Counter (en.wikipedia.org/wiki/Program_counter), though it's technically an overhead, it's already paid for without exceptions anyway. When an exception is thrown, the value of the counter is looked-up in the Tables to find the appropriate handler. So you don't have to setup anything (at runtime) however the tables do consume space (though readonly and precomputed during compilation). Mar 10, 2011 at 9:17
  • 1
    @VJo: This article db.usenix.org/events/wiess2000/full_papers/dinechin/… in 2.2 details the inner working of the Table Driven approach, then sums up the disadvantages. I haven't read the rest yet though :) Mar 10, 2011 at 9:24

Answer just to the update:

Does exception handling really require RTTI to be enabled

Exception-handling actually requires something more powerful than RTTI and dynamic cast in one respect. Consider the following code:

try {
} catch (const int &i) {
} catch (const std::logic_error &e) {}

So, when the function in the other TU throws, it's going to look up the stack (either check all levels immediately, or check one level at a time during stack unwinding, that's up to the implementation) for a catch clause that matches the object being thrown.

To perform this match, it might not need the aspect of RTTI that stores the type in each object, since the type of a thrown exception is the static type of the throw expression. But it does need to compare types in an instanceof way, and it needs to do this at runtime, because some_function_in_another_TU could be called from anywhere, with any type of catch on the stack. Unlike dynamic_cast, it needs to perform this runtime instanceof check on types which have no virtual member functions, and for that matter types which are not class types. That last part doesn't add difficulty, because non-class types have no hierarchy, and so all that's needed is type equality, but you still need type identifiers that can be compared at runtime.

So, if you enable exceptions then you need the part of RTTI that does type comparisons, like dynamic_cast's type comparisons but covering more types. You don't necessarily need the part of RTTI that stores the data used to perform this comparison in each class's vtable, where it's reachable from the object -- the data could instead only be encoded at the point of each throw expression and each catch clause. But I doubt that's a significant saving, since typeid objects aren't exactly massive, they contain a name that's often needed anyway in a symbol table, plus some implementation-defined data to describe the type hierarchy. So probably you might as well have all of RTTI by that point.

  • Thanks, thats a very deep explanation. I will ponder that. Although, I will have to brush up upon dynamic_cast not needing RTTI and so on. I will let that settle and sort it out: What typeid() does, what dynamic_cast does, and what is stored in the vtable, and when and how static type matching is done. And whether thats what is needed for exceptions.
    – towi
    Mar 10, 2011 at 14:10
  • "To perform this match, it might not need the aspect of RTTI that stores the type in each object" IOW, you don't need typeid (object), but you do need typeid (type).
    – curiousguy
    Dec 7, 2011 at 3:56

The problem with exceptions is not necessarily the speed (which may differ greatly, depending on the implementation), but it's what they actually do.

In the real-time world, when you have a time constraint on an operation, you need to know exactly what your code does. Exceptions provide shortcuts that may influence the overall run time of your code (exception handler may not fit into the real-time constraint, or due to an exception you might not return the query response at all, for example).

If you mean "real-time" as in fact "embedded", then the code size, as mentioned, becomes an issue. Embedded code may not necessarily be real-time, but it can have size constraint (and often does).

Also, embedded systems are often designed to run forever, in an infinite event loop. Exception may take you somewhere out of that loop, and also corrupt your memory and data (because of the stack unwinding) - again, depends on what you do with them, and how the compiler actually implements it.

So better safe than sorry: don't use exceptions. If you can sustain occasional system failures, if you're running in a separate task than can be easily restarted, if you're not really real-time, just pretend to be - then you probably can give it a try. If you're writing software for a heart-pacer - I would prefer to check return codes.

  • 6
    I do not agree on "Exceptions may corrupt your memory and data". One can write correct code with and without exceptions -- different styles. Therefore I dont think that "better safe then sorry" is the answer I am looking for. But goot point about code size. Thx.
    – towi
    Mar 13, 2011 at 16:08
  • If you're worried about timing, isn't an exception just another execution path that you would need to test? Granted, it may be harder to know what mysterious stuff is going on "under the hood" with C++ exceptions, compared to the alternative of testing return codes. Mar 14, 2011 at 1:15
  • 4
    "Exception may take you somewhere out of that loop, and also corrupt your memory and data (because of the stack unwinding)" then obviously you are not using exceptions correctly. Do you have a sound argument?
    – curiousguy
    Dec 7, 2011 at 3:54
  • 1
    I too disagree on "Exceptions may corrupt your memory and data". If you can afford to terminate the program on error, then that is what you should do when performance is critical. If you cannot afford that (for example because you are writing a library), then you have two choices, return an error code, or throw an exception. Here the error code approach will be far more prone to data corruption due to bugs in the code that checks the error codes. Nov 3, 2012 at 23:02

C++ exceptions still aren't supported by every realtime environment in a way that makes them acceptable everywhere.

In the particular example of video games (which have a soft 16.6ms deadline for every frame), the leading compilers implement C++ exceptions in such a way that simply turning on exception handling in your program will significantly slow it down and increase code size, regardless of whether you actually throw exceptions or not. Given that both performance and memory are critical on a game console, that's a dealbreaker: the PS3's SPU units, for example, have 256kb of memory for both code and data!

On top of this, throwing exceptions is still quite slow (measure it if you don't believe me) and can cause heap deallocations which are also undesirable in cases where you haven't got microseconds to spare.

The one... er... exception I have seen to this rule is cases where the exception might get thrown once per app run -- not once per frame, but literally once. In that case, structured exception handling is an acceptable way to catch stability data from the OS when a game crashes and relay it back to the developer.

  • 1
    Throwing exceptions every frame (or with similar frequency in other domains) is bad in any case. Mar 10, 2011 at 11:12
  • @Andy T: Indeed, but I've seen developers that did it anyway in a shipped product. The product failed due to poor performance, and their studio went out of business.
    – Crashworks
    Mar 10, 2011 at 12:04
  • "throwing exceptions is still quite slow (measure it if you don't believe me) and can cause heap deallocations which are also undesirable in cases where you haven't got microseconds to spare" Why do you throw an exception?
    – curiousguy
    Dec 7, 2011 at 3:53
  • C++-exceptions have a zero overhead when not being thrown and the implementation uses table-driven exceptions. Sep 3, 2019 at 7:26

The implementation of the exception mechanism is usually very slow when an exception is thrown, otherwise the costs of using them is almost none. In my opinion exceptions are very useful if you use them correctly.

In RT applications, exceptions should be thrown only when something goes bad and the program has to stop and fix the issue (and possible wait for the user interaction). Under such circumstances, it takes longer to fix the issue.

Exceptions provide hidden path of reporting an error. They make the code more shorter and more readable, therefore easier maintenance.

  • slow ? As far as I know they are faster than unlikely tests, with a cost virtually null as long as they are not thrown. Mar 10, 2011 at 8:46
  • 2
    Checkout this blog. It provides a good explanation of the tradeoffs of exceptions, and explains that in some scenarios they can even make code faster. Mar 10, 2011 at 8:49
  • @Matthieu @Space Slow when an exception is thrown. Implementation using exceptions do not slow down execution. Well, just a bit (to provide try/catch context), but the alternative (with if's) is slower when an exception is not thrown. Mar 10, 2011 at 8:52
  • I agree, when an exception is thrown it's slower than an if, by an order of magnitude in fact. However there is no context setting any longer now with the Zero-Cost mechanism, it's free (as in beer) as long as no exception is thrown. Mar 10, 2011 at 9:08

Typical implementations of C++ exception handling were still not ideal, and might cause the entire language implementation almost unusable for some embedded targets with extremely limited resources, even if the user code is not explicitly using these features. This is referred as "zero overhead principle violation" by recent WG21 papers, see N4049 and N4234 for details. In such environments, exception handling does not work as expected (consuming reasonable system resources) whether the application is real-time or not.

However, there should be real-time applications in embedded environments which can afford these overhead, e.g. a video player in a handheld device.

Exception handling should always be used carefully. Throwing and catching exceptions per frame in a real-time application for any platforms (not only for embedded environments) is a bad design/implementation and not acceptable in general.


There are generally 3 or 4 constraints in embedded / realtime development - especially when that implies kernel mode development

  • at various points - usually while handling hardware exceptions - operations MUST NOT throw more hardware exceptions. c++'s implicit data structures (vtables) and code (default constructors & operators & other implicitly generated code to support the c++ exception mechanisim) are not placeable, and cannot as a result be guaranteed to be placed in non paged memory when executed in this context.

  • Code quality - c++ code in general can hide a lot of complexity in statements that look trivial making code difficult to visually audit for errors. exceptions decouple handling from location, making proving code coverage of tests difficult.

  • C++ exposes a very simple memory model: new allocates from an infinite free store, until you run out, and it throws an exception. In memory constrained devices, more efficient code can be written that makes explicit use of fixed size blocks of memory. C+'s implicit allocations on almost any operation make it impossible to audit memory use. Also, most c++ heaps exhibit the disturbing property that there is no computable upper limit on how long a memory allocation can take - which again makes it difficult to prove the response time of algorithms on realtime devices where fixed upper limits are desirable.

  • 3
    The third point is completely wrong - you can override operator new() at class or namespace scope to allocate memory in any way you like. Or avoid new where it's not appropriate, and use your own allocator instead. Mar 10, 2011 at 11:03
  • 2
    "implicit allocations on almost any operation" - your C++ code doesn't look like my C++ code. Of course you have to understand when copies take place, but in C the rule is, "if you don't call a function, you know what's going on". In C++ written to even the most basic standards appropriate for real-time work, the rule is "if you don't call a function or use a type that holds dynamically allocated resources, you know what's going on". It's not that hard to record and recognise what types allocate memory, and even to use a naming scheme to highlight it. Then don't copy them in critical context Mar 10, 2011 at 11:52
  • 1
    @VJo and Steve: ideomatic c++ code makes use of the STL for generic programming. This means none of the operators are as simple as they look. You can create super complex stuff in C, but C++ is super complex "out the box". And I maintain that if you arn't using STL/generic programming techniques, then you are rather wasting your time with c++ anyway. Mar 10, 2011 at 12:02
  • 3
    So the question becomes, "can you write C++ in such a way that you know whether your code allocates memory or not?" With good knowledge of C++, and a bit of care, yes you can. For the specific case of memory allocation it's not really any harder than keeping a record of what exception guarantees your various operations offer. For other things banned in critical context, it may be a bit more difficult, more akin to e.g. keeping track of what you can safely do in a signal handler in C. If "idiomatic C++" means "create a vector in every function", then OK, you can't do that. Mar 10, 2011 at 14:22
  • 1
    Chris: You're lumping two very different things together when you say "STL/generic programming techniques". There are very definitely useful ways to use C++ for generic programming that don't involve the STL. More specifically, I would say that STL is "idiomatic C++" for a certain kind of application, which is generally not kernel programming, and C++ is useful beyond that range of applications. (Are exceptions useful beyond that range? I don't know -- but that's what the question is about.) Mar 10, 2011 at 16:59

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge that you have read and understand our privacy policy and code of conduct.

Not the answer you're looking for? Browse other questions tagged or ask your own question.