Most people say never throw an exception out of a destructor - doing so results in undefined behavior. Stroustrup makes the point that "the vector destructor explicitly invokes the destructor for every element. This implies that if an element destructor throws, the vector destruction fails... There is really no good way to protect against exceptions thrown from destructors, so the library makes no guarantees if an element destructor throws" (from Appendix E3.2).

This article seems to say otherwise - that throwing destructors are more or less okay.

So my question is this - if throwing from a destructor results in undefined behavior, how do you handle errors that occur during a destructor?

If an error occurs during a cleanup operation, do you just ignore it? If it is an error that can potentially be handled up the stack but not right in the destructor, doesn't it make sense to throw an exception out of the destructor?

Obviously these kinds of errors are rare, but possible.

  • 47
    "Two exceptions at once" is a stock answer but it's not the REAL reason. The real reason is that an exception should be thrown if and only if a function's postconditions cannot be met. The postcondition of a destructor is that the object no longer exists. This can't not happen. Any failure-prone end-of-life operation must therefore be called as a separate method before the object goes out of scope (sensible functions normally only have one success path anyway).
    – spraff
    Aug 30, 2011 at 10:13
  • 41
    @spraff: Are you aware that what you said implies "throw away RAII"?
    – Kos
    Oct 26, 2011 at 13:30
  • 21
    @spraff: having to call "a separate method before the object goes out of scope" (as you wrote) actually throws away RAII! Code using such objects will have to ensure that such a method will be called before the destructor is called.. Finally, this idea does not help at all.
    – Frunsi
    Aug 8, 2012 at 2:00
  • 14
    @Frunsi no, because this problem stems from the fact that the destructor is trying to do something beyond the mere releasing of resources. It's tempting to say "i always want to end up doing XYZ" and thinking this is an argument for putting such logic in the destructor. No, don't be lazy, write xyz() and keep the destructor clean of non-RAII logic.
    – spraff
    Aug 11, 2012 at 21:11
  • 7
    @Frunsi For example, committing something to file isn't necessarily OK to do in the destructor of a class representing a transaction. If the commit failed, it's too late to handle it when all the code that was involved in the transaction has gone out of scope. The destructor should discard the transaction unless a commit() method is called. Aug 21, 2013 at 9:44

17 Answers 17


Throwing an exception out of a destructor is dangerous.
If another exception is already propagating the application will terminate.

#include <iostream>

class Bad
        // Added the noexcept(false) so the code keeps its original meaning.
        // Post C++11 destructors are by default `noexcept(true)` and
        // this will (by default) call terminate if an exception is
        // escapes the destructor.
        // But this example is designed to show that terminate is called
        // if two exceptions are propagating at the same time.
        ~Bad() noexcept(false)
            throw 1;
class Bad2
            throw 1;

int main(int argc, char* argv[])
        Bad   bad;
        std::cout << "Print This\n";

        if (argc > 3)
            Bad   bad; // This destructor will throw an exception that escapes (see above)
            throw 2;   // But having two exceptions propagating at the
                       // same time causes terminate to be called.
            Bad2  bad; // The exception in this destructor will
                       // cause terminate to be called.
        std::cout << "Never print this\n";


This basically boils down to:

Anything dangerous (i.e. that could throw an exception) should be done via public methods (not necessarily directly). The user of your class can then potentially handle these situations by using the public methods and catching any potential exceptions.

The destructor will then finish off the object by calling these methods (if the user did not do so explicitly), but any exceptions throw are caught and dropped (after attempting to fix the problem).

So in effect you pass the responsibility onto the user. If the user is in a position to correct exceptions they will manually call the appropriate functions and processes any errors. If the user of the object is not worried (as the object will be destroyed) then the destructor is left to take care of business.

An example:


The close() method can potentially throw an exception. The destructor calls close() if the file has been opened but makes sure that any exceptions do not propagate out of the destructor.

So if the user of a file object wants to do special handling for problems associated to closing the file they will manually call close() and handle any exceptions. If on the other hand they do not care then the destructor will be left to handle the situation.

Scott Myers has an excellent article about the subject in his book "Effective C++"


Apparently also in "More Effective C++"
Item 11: Prevent exceptions from leaving destructors

  • 7
    "Unless you don't mind potentially terminating the application you should probably swallow the error." - this should probably be the exception (pardon the pun) rather than the rule - that is, to fail fast. Sep 24, 2008 at 22:05
  • 17
    I disagree. Terminating the program stops the stack unwind. No more destructor will be called. Any resources opened will be left open. I think swallowing the exception would be the prefered option. Sep 24, 2008 at 22:15
  • 24
    The OS acan clean up resources it is the owner off. Memory, FileHandles etc. What about complex resources: DB connections. That uplink to the ISS you opened (is it automatically going to send the close connections)? I am sure NASA would want you to close the connection cleanly! Oct 3, 2008 at 18:02
  • 8
    If an application is going to "fail fast" by aborting, it shouldn't be throwing exceptions in the first place. If it is going to fail by passing control back up the stack, it should not do so in a way that may cause the program to be aborted. One or the other, don't pick both.
    – Tom
    Dec 13, 2008 at 22:06
  • 6
    @LokiAstari The transport protocol you are using to communicate with a spacecraft can't handle a dropped connection? Ok...
    – doug65536
    Feb 9, 2014 at 15:41

Throwing out of a destructor can result in a crash, because this destructor might be called as part of "Stack unwinding". Stack unwinding is a procedure which takes place when an exception is thrown. In this procedure, all the objects that were pushed into the stack since the "try" and until the exception was thrown, will be terminated -> their destructors will be called. And during this procedure, another exception throw is not allowed, because it's not possible to handle two exceptions at a time, thus, this will provoke a call to abort(), the program will crash and the control will return to the OS.

  • 1
    can you please elaborate how abort() got called in the above situation. Means the control of execution was still with the C++ compiler Jan 24, 2014 at 6:00
  • 2
    @Krishna_Oza: Quite simple: whenever an error is thrown, the code that raises an error checks some bit that indicates that the runtime system is in the process of stack unwinding (i.e., handling some other throw but not having found a catch block for it yet) in which case std::terminate (not abort) is called instead of raising a (new) exception (or continuing the stack unwinding). Jun 6, 2016 at 9:04

We have to differentiate here instead of blindly following general advice for specific cases.

Note that the following ignores the issue of containers of objects and what to do in the face of multiple d'tors of objects inside containers. (And it can be ignored partially, as some objects are just no good fit to put into a container.)

The whole problem becomes easier to think about when we split classes in two types. A class dtor can have two different responsibilities:

  • (R) release semantics (aka free that memory)
  • (C) commit semantics (aka flush file to disk)

If we view the question this way, then I think that it can be argued that (R) semantics should never cause an exception from a dtor as there is a) nothing we can do about it and b) many free-resource operations do not even provide for error checking, e.g. void free(void* p);.

Objects with (C) semantics, like a file object that needs to successfully flush it's data or a ("scope guarded") database connection that does a commit in the dtor are of a different kind: We can do something about the error (on the application level) and we really should not continue as if nothing happened.

If we follow the RAII route and allow for objects that have (C) semantics in their d'tors I think we then also have to allow for the odd case where such d'tors can throw. It follows that you should not put such objects into containers and it also follows that the program can still terminate() if a commit-dtor throws while another exception is active.

With regard to error handling (Commit / Rollback semantics) and exceptions, there is a good talk by one Andrei Alexandrescu: Error Handling in C++ / Declarative Control Flow (held at NDC 2014)

In the details, he explains how the Folly library implements an UncaughtExceptionCounter for their ScopeGuard tooling.

(I should note that others also had similar ideas.)

While the talk doesn't focus on throwing from a d'tor, it shows a tool that can be used today to get rid of the problems with when to throw from a d'tor.

In the future, there may be a std feature for this, see N3614, and a discussion about it.

Upd '17: The C++17 std feature for this is std::uncaught_exceptions afaikt. I'll quickly quote the cppref article:


An example where int-returning uncaught_exceptions is used is ... ... first creates a guard object and records the number of uncaught exceptions in its constructor. The output is performed by the guard object's destructor unless foo() throws (in which case the number of uncaught exceptions in the destructor is greater than what the constructor observed)

  • 6
    Highly agree. And adding one more semantic (Ro) rollback semantics. Used commonly in scope guard. Like the case in my project where I defined a ON_SCOPE_EXIT macro. The case about rollback semantics is that anything meaningful could happen here. So we really shouldn't ignore the failure.
    – Weipeng
    Aug 23, 2013 at 6:55
  • 1
    @MartinBa: I think you missed the point of my comment, which is surprising since I was agreeing with your notion that (R) and (C) are different. I was trying to say that a dtor is inherently a tool for (R) and finally is inherently a tool for (C). If you don't see why: consider why it's legitimate to throw exceptions on top of each other in finally blocks, and why the same is not for destructors. (In some sense, it's a data vs. control thing. Destructors are for releasing data, finally is for releasing control. They are different; it's unfortunate that C++ ties them together.)
    – user541686
    Dec 1, 2015 at 11:18
  • 1
    @Mehrdad : Getting too long here. If you want, you can build up your arguments here: programmers.stackexchange.com/questions/304067/… . Thanks.
    – Martin Ba
    Dec 2, 2015 at 9:29
  • 1
    Disagree about the rationale for (R) semantics: "(R) semantics should never cause an exception from a dtor as there is a) nothing we can do about it and b) many free-resource operations do not even provide for error checking." About (b): For free ops which can't fail/don't report errors, this question doesn't come up. It comes up when these ops do report errors. In such cases, there are lots of things one can do about it - but, of course, not within the destructor, which has very little context. And...
    – einpoklum
    Dec 11, 2021 at 18:36
  • 1
    ... And when you need to tell outside code that there was a problem which you can't handle yourself, throwing an exception is how you do it (especially when you cant return an error status).
    – einpoklum
    Dec 11, 2021 at 18:37

The real question to ask yourself about throwing from a destructor is "What can the caller do with this?" Is there actually anything useful you can do with the exception, that would offset the dangers created by throwing from a destructor?

If I destroy a Foo object, and the Foo destructor tosses out an exception, what I can reasonably do with it? I can log it, or I can ignore it. That's all. I can't "fix" it, because the Foo object is already gone. Best case, I log the exception and continue as if nothing happened (or terminate the program). Is that really worth potentially causing undefined behavior by throwing from a destructor?

  • 15
    Just noticed ... throwing from a dtor is never Undefined Behaviour. Sure, it might call terminate(), but that is very well specified behaviour.
    – Martin Ba
    Dec 25, 2013 at 20:09
  • 4
    std::ofstream's destructor flushes and then closes the file. A disk full error could occur while flushing, which you can absolutely do something useful with: show the user an error dialog saying the disk is out of free space.
    – Andy
    Feb 20, 2018 at 9:13
  • 1
    First of all, logging is already enough to merit throwing an exception (had it not been for the difficulty of stack-unwinding destruction). Logging errors can be critically important, but the destructed object cannot, in general, know how to log errors. Additionally, there may be other things which need to / should be done after such an error, e.g. also releasing other resources or perhaps re-establishing a state in which such errors would no longer occur (e.g. a network connection). So, bottom line: The caller can do lots.
    – einpoklum
    Dec 11, 2021 at 18:40
  • @Andy also it is a common strategy to flush to a copy of sensitive file and then move said modified file onto the original. You can probably imagine how you can lose data just because you went ahead and ignored fsync error, which lead to you moving a broken file onto the original. Even a hard termination of a program the moment fsync failed would've been safer than simply losing everything. But you can make a backup beforehand... Which will fail too if you don't make sure fsync succeeded. You should never ignore these kinds of errors unless what you're doing isn't very important.
    – user11877195
    Mar 10, 2022 at 13:13

Its dangerous, but it also doesn't make sense from a readability/code understandability standpoint.

What you have to ask is in this situation

int foo()
   Object o;
   // As foo exits, o's destructor is called

What should catch the exception? Should the caller of foo? Or should foo handle it? Why should the caller of foo care about some object internal to foo? There might be a way the language defines this to make sense, but its going to be unreadable and difficult to understand.

More importantly, where does the memory for Object go? Where does the memory the object owned go? Is it still allocated (ostensibly because the destructor failed)? Consider also the object was in stack space, so its obviously gone regardless.

Then consider this case

class Object
   Object2 obj2;
   Object3* obj3;
   virtual ~Object()
       // What should happen when this fails? How would I actually destroy this?
       delete obj3;

       // obj 2 fails to destruct when it goes out of scope, now what!?!?
       // should the exception propogate? 

When the delete of obj3 fails, how do I actually delete in a way that is guaranteed to not fail? Its my memory dammit!

Now consider in the first code snippet Object goes away automatically because its on the stack while Object3 is on the heap. Since the pointer to Object3 is gone, you're kind of SOL. You have a memory leak.

Now one safe way to do things is the following

class Socket
    virtual ~Socket()
      catch (...) 
          // Why did close fail? make sure it *really* does close here


Also see this FAQ

  • Resurrecting this answer, re: the first example, about int foo(), you can use a function-try-block to wrap the entire function foo in a try-catch block, including catching destructors, if you cared to do so. Still not the preferred approach, but it is a thing.
    – tyree731
    Apr 15, 2019 at 13:59
  • "What should catch the exception? Should the caller of foo?" Yes; or it could let it propagate up. "Why should the caller of foo care about some object internal to foo?" The caller of foo does know about the internal object, it will know that foo() threw an exception, somehow.
    – einpoklum
    Dec 11, 2021 at 18:42
  • "Why should the caller of foo care about some object internal to foo?" you're right, they shouldn't, but as responsible C++ programmer I assume that they will, they always do, you can tell them whatever you want, they don't care. Hyrum's Law. C++'s terrible design can be blamed on this.
    – user11877195
    Mar 10, 2022 at 13:22

From the ISO draft for C++ (ISO/IEC JTC 1/SC 22 N 4411)

So destructors should generally catch exceptions and not let them propagate out of the destructor.

3 The process of calling destructors for automatic objects constructed on the path from a try block to a throw- expression is called “stack unwinding.” [ Note: If a destructor called during stack unwinding exits with an exception, std::terminate is called (15.5.1). So destructors should generally catch exceptions and not let them propagate out of the destructor. — end note ]

  • 1
    Did not answer the question - the OP is already aware of this.
    – Arafangion
    May 12, 2009 at 9:19
  • 3
    @Arafangion I doubt that he was aware of this (std::terminate being called) as the accepted answer made exactly the same point.
    – lothar
    May 12, 2009 at 15:10
  • @Arafangion as in some answers here some people mentioned that abort() being called; Or is it that the std::terminate in turns calls the abort() function. Jan 24, 2014 at 7:12

I am in the group that considers that the "scoped guard" pattern throwing in the destructor is useful in many situations - particularly for unit tests. However, be aware that in C++11, throwing in a destructor results in a call to std::terminate since destructors are implicitly annotated with noexcept.

Andrzej Krzemieński has a great post on the topic of destructors that throw:

He points out that C++11 has a mechanism to override the default noexcept for destructors:

In C++11, a destructor is implicitly specified as noexcept. Even if you add no specification and define your destructor like this:

  class MyType {
        public: ~MyType() { throw Exception(); }            // ...

The compiler will still invisibly add specification noexcept to your destructor. And this means that the moment your destructor throws an exception, std::terminate will be called, even if there was no double-exception situation. If you are really determined to allow your destructors to throw, you will have to specify this explicitly; you have three options:

  • Explicitly specify your destructor as noexcept(false),
  • Inherit your class from another one that already specifies its destructor as noexcept(false).
  • Put a non-static data member in your class that already specifies its destructor as noexcept(false).

Finally, if you do decide to throw in the destructor, you should always be aware of the risk of a double-exception (throwing while the stack is being unwind because of an exception). This would cause a call to std::terminate and it is rarely what you want. To avoid this behaviour, you can simply check if there is already an exception before throwing a new one using std::uncaught_exception().


Your destructor might be executing inside a chain of other destructors. Throwing an exception that is not caught by your immediate caller can leave multiple objects in an inconsistent state, thus causing even more problems then ignoring the error in the cleanup operation.


Everyone else has explained why throwing destructors are terrible... what can you do about it? If you're doing an operation that may fail, create a separate public method that performs cleanup and can throw arbitrary exceptions. In most cases, users will ignore that. If users want to monitor the success/failure of the cleanup, they can simply call the explicit cleanup routine.

For example:

class TempFile {
    TempFile(); // throws if the file couldn't be created
    ~TempFile() throw(); // does nothing if close() was already called; never throws
    void close(); // throws if the file couldn't be deleted (e.g. file is open by another process)
    // the rest of the class omitted...
  • I am looking for a solution but they are trying to explain what happened and why. Just want to make it clear is the close function get called inside the destructor?
    – Jason Liu
    Nov 15, 2019 at 6:53
  • 1
    @JasonLiu no, close is in fact completely separate from destructor and has very little to absolutely no coupling. It is pretty much a switch that causes certain part of code that throws to be ran prematurely. In destructor, you check if it already ran, for example, if it's a file, you skip closing it, it's already closed in some predictable state. But this pretty much throws away the only real thing C++ has over C... RAII. And you write twice as much code. You can see this in fstream class, if you don't close file manually, destructor closes it and ignores all errors.
    – user11877195
    Mar 10, 2022 at 13:28

As an addition to the main answers, which are good, comprehensive and accurate, I would like to comment about the article you reference - the one that says "throwing exceptions in destructors is not so bad".

The article takes the line "what are the alternatives to throwing exceptions", and lists some problems with each of the alternatives. Having done so it concludes that because we can't find a problem-free alternative we should keep throwing exceptions.

The trouble is is that none of the problems it lists with the alternatives are anywhere near as bad as the exception behaviour, which, let's remember, is "undefined behaviour of your program". Some of the author's objections include "aesthetically ugly" and "encourage bad style". Now which would you rather have? A program with bad style, or one which exhibited undefined behaviour?

  • 3
    Not undefined behaviour, but rather immediate termination. Jun 6, 2016 at 9:10
  • The standard says 'undefined behaviour'. That behaviour is frequently termination but it isn't always. Jun 6, 2016 at 11:35
  • 1
    No, read [except.terminate] in Exception handling->Special functions (which is 15.5.1 in my copy of the standard, but its numbering is probably outdated). Jun 6, 2016 at 15:06
  • @MarcvanLeeuwen thank you for that point, I found myself in a spot where I could easily prevent double throw in some part of a code and it would've been a lot cleaner if I simply moved the throw into the destructor considering different kinds of usage patterns of that particular class don't make sense anyway, but didn't because it's "bad practice". Wish people experimented with this concept a bit more, because there are cases where losing 15 minutes of work due to an unexpected termination feels a lot better than I don't know, whole disk being destroyed because I forgot to call some function.
    – user11877195
    Mar 10, 2022 at 13:36

Q: So my question is this - if throwing from a destructor results in undefined behavior, how do you handle errors that occur during a destructor?

A: There are several options:

  1. Let the exceptions flow out of your destructor, regardless of what's going on elsewhere. And in doing so be aware (or even fearful) that std::terminate may follow.

  2. Never let exception flow out of your destructor. May be write to a log, some big red bad text if you can.

  3. my fave : If std::uncaught_exception returns false, let you exceptions flow out. If it returns true, then fall back to the logging approach.

But is it good to throw in d'tors?

I agree with most of the above that throwing is best avoided in destructor, where it can be. But sometimes you're best off accepting it can happen, and handle it well. I'd choose 3 above.

There are a few odd cases where its actually a great idea to throw from a destructor. Like the "must check" error code. This is a value type which is returned from a function. If the caller reads/checks the contained error code, the returned value destructs silently. But, if the returned error code has not been read by the time the return values goes out of scope, it will throw some exception, from its destructor.

  • 5
    Your fave is something I tried recently, and it turns out you should not do it. gotw.ca/gotw/047.htm
    – GManNickG
    Mar 18, 2010 at 15:03
  • I can't believe an answer actually answering OP's question is ranked so low. +1.
    – einpoklum
    Dec 11, 2021 at 19:00
  • @einpoklum and everything else is so vague too, "you shouldn't throw in destructor, but I'm not going to provide a proper solution"... I'm not sure anymore whether this is cargo cultism or simply people who have no idea trying to answer the question by improvising...
    – user11877195
    Mar 10, 2022 at 13:50

So my question is this - if throwing from a destructor results in undefined behavior, how do you handle errors that occur during a destructor?

The main problem is this: you can't fail to fail. What does it mean to fail to fail, after all? If committing a transaction to a database fails, and it fails to fail (fails to rollback), what happens to the integrity of our data?

Since destructors are invoked for both normal and exceptional (fail) paths, they themselves cannot fail or else we're "failing to fail".

This is a conceptually difficult problem but often the solution is to just find a way to make sure that failing cannot fail. For example, a database might write changes prior to committing to an external data structure or file. If the transaction fails, then the file/data structure can be tossed away. All it has to then ensure is that committing the changes from that external structure/file an atomic transaction that can't fail.

The pragmatic solution is perhaps just make sure that the chances of failing on failure are astronomically improbable, since making things impossible to fail to fail can be almost impossible in some cases.

The most proper solution to me is to write your non-cleanup logic in a way such that the cleanup logic can't fail. For example, if you're tempted to create a new data structure in order to clean up an existing data structure, then perhaps you might seek to create that auxiliary structure in advance so that we no longer have to create it inside a destructor.

This is all much easier said than done, admittedly, but it's the only really proper way I see to go about it. Sometimes I think there should be an ability to write separate destructor logic for normal execution paths away from exceptional ones, since sometimes destructors feel a little bit like they have double the responsibilities by trying to handle both (an example is scope guards which require explicit dismissal; they wouldn't require this if they could differentiate exceptional destruction paths from non-exceptional ones).

Still the ultimate problem is that we can't fail to fail, and it's a hard conceptual design problem to solve perfectly in all cases. It does get easier if you don't get too wrapped up in complex control structures with tons of teeny objects interacting with each other, and instead model your designs in a slightly bulkier fashion (example: particle system with a destructor to destroy the entire particle system, not a separate non-trivial destructor per particle). When you model your designs at this kind of coarser level, you have less non-trivial destructors to deal with, and can also often afford whatever memory/processing overhead is required to make sure your destructors cannot fail.

And that's one of the easiest solutions naturally is to use destructors less often. In the particle example above, perhaps upon destroying/removing a particle, some things should be done that could fail for whatever reason. In that case, instead of invoking such logic through the particle's dtor which could be executed in an exceptional path, you could instead have it all done by the particle system when it removes a particle. Removing a particle might always be done during a non-exceptional path. If the system is destroyed, maybe it can just purge all particles and not bother with that individual particle removal logic which can fail, while the logic that can fail is only executed during the particle system's normal execution when it's removing one or more particles.

There are often solutions like that which crop up if you avoid dealing with lots of teeny objects with non-trivial destructors. Where you can get tangled up in a mess where it seems almost impossible to be exception-safety is when you do get tangled up in lots of teeny objects that all have non-trivial dtors.

It would help a lot if nothrow/noexcept actually translated into a compiler error if anything which specifies it (including virtual functions which should inherit the noexcept specification of its base class) attempted to invoke anything that could throw. This way we'd be able to catch all this stuff at compile-time if we actually write a destructor inadvertently which could throw.

  • 2
    Destruction is failure now?
    – curiousguy
    Jan 15, 2019 at 0:16
  • 2
    I think he means that destructors are called during a failure, to cleanup that failure. So if a destructor is called during an active exception, then it is failing to cleanup from a previous failure. Mar 17, 2019 at 0:41
  • @user2445507 complete nonsense. Destructors are small part of the program, the last thing they should be aware of is other destructors, or whether they were called because object gracefully fell out of scope or because stack was unwound prematurely... And that's why the program is terminated if you throw during stack unwinding, precisely because of the fact that they are not aware, should not be.
    – user11877195
    Mar 10, 2022 at 13:45

Throwing an exception out of a destructor never causes undefined behaviour.

The problem of throwing exceptions out a destructor is that destructors of successfully created objects which scopes are leaving while handling an uncaught exception (it is after an exception object is created and until completion of a handler of the exception activation), are called by exception handling mechanism; and, If such additional exception from the destructor called while processing the uncaught exception interrupts handling the uncaught exception, it will cause calling std::terminate (the other case when std::exception is called is that an exception is not handled by any handler but this is as for any other function, regardless of whether or not it was a destructor).

If handling an uncaught exception in progress, your code never knows whether the additional exception will be caught or will archive an uncaught exception handling mechanism, so never know definitely whether it is safe to throw or not.

Though, it is possible to know that handling an uncaught exception is in progress ( https://en.cppreference.com/w/cpp/error/uncaught_exception), so you are able to overkill by checking the condition and throw only if it is not the case (it will not throw in some cases when it would be safe).

But in practice such separating into two possible behaviours is not useful - it just does not help you to make a well-designed program.

If you throw out of destructors ignoring whether or not an uncaught exception handling is in progress, in order to avoid possible calling std::terminate, you must guarantee that all exceptions thrown during lifetime of an object that may throw an exception from their destructor are caught before beginning of destruction of the object. It is quite limited usage; you hardly can use all classes which would be reasonably allowed to throw out of their destructor in this way; and a combination of allowing such exceptions only for some classes with such restricted usage of these classes impede making a well-designed program, too.


Set an alarm event. Typically alarm events are better form of notifying failure while cleaning up objects


Unlike constructors, where throwing exceptions can be a useful way to indicate that object creation succeeded, exceptions should not be thrown in destructors.

The problem occurs when an exception is thrown from a destructor during the stack unwinding process. If that happens, the compiler is put in a situation where it doesn’t know whether to continue the stack unwinding process or handle the new exception. The end result is that your program will be terminated immediately.

Consequently, the best course of action is just to abstain from using exceptions in destructors altogether. Write a message to a log file instead.

  • 3
    Writing a message to the log file can cause an exception.
    – Konard
    Jul 23, 2019 at 16:25
  • @Konard and throwing in destructor can't... I am still looking for a real explanation why everyone is so against this, because so far in every scenario where I considered doing this, it actually makes sense to me.
    – user11877195
    Mar 10, 2022 at 13:53
  • @Sahsahae I think that if you use try and catch around log operation in destructor it should be ok.
    – Konard
    Mar 10, 2022 at 16:10
  • @Konard but the issue is that if it throws you can't log it or do anything, it's useless, just like the logging (and then just ignoring the error) itself. Exceptions are exceptional, but control flow nonetheless, and ignoring it only leads to bugs, some of which aren't recoverable from even if you read the logs and noticed the issue, such as corrupted files or databases...
    – user11877195
    Mar 10, 2022 at 16:12

I currently follow the policy (that so many are saying) that classes shouldn't actively throw exceptions from their destructors but should instead provide a public "close" method to perform the operation that could fail...

...but I do believe destructors for container-type classes, like a vector, should not mask exceptions thrown from classes they contain. In this case, I actually use a "free/close" method that calls itself recursively. Yes, I said recursively. There's a method to this madness. Exception propagation relies on there being a stack: If a single exception occurs, then both the remaining destructors will still run and the pending exception will propagate once the routine returns, which is great. If multiple exceptions occur, then (depending on the compiler) either that first exception will propagate or the program will terminate, which is okay. If so many exceptions occur that the recursion overflows the stack then something is seriously wrong, and someone's going to find out about it, which is also okay. Personally, I err on the side of errors blowing up rather than being hidden, secret, and insidious.

The point is that the container remains neutral, and it's up to the contained classes to decide whether they behave or misbehave with regard to throwing exceptions from their destructors.


Martin Ba (above) is on the right track- you architect differently for RELEASE and COMMIT logic.

For Release:

You should eat any errors. You're freeing memory, closing connections, etc. Nobody else in the system should ever SEE those things again, and you're handing back resources to the OS. If it looks like you need real error handling here, its likely a consequence of design flaws in your object model.

For Commit:

This is where you want the same kind of RAII wrapper objects that things like std::lock_guard are providing for mutexes. With those you don't put the commit logic in the dtor AT ALL. You have a dedicated API for it, then wrapper objects that will RAII commit it in THEIR dtors and handle the errors there. Remember, you can CATCH exceptions in a destructor just fine; its issuing them that's deadly. This also lets you implement policy and different error handling just by building a different wrapper (e.g. std::unique_lock vs. std::lock_guard), and ensures you won't forget to call the commit logic- which is the only half-way decent justification for putting it in a dtor in the 1st place.

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