From C++11 standard (15.1.p4):

The memory for the exception object is allocated in an unspecified way, except as noted in

What if allocation fails -- will it throw std::bad_alloc instead? Call std::terminate? Unspecified?

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    FWIW, the size of the exception object can be quite big, and if you try to allocate something too big, it appears that std::terminate is called. Whether this is the specified behavior in the standard I'm unsure. – Justin Aug 4 '17 at 3:56
  • In a less extreme example, not involving a stack overflow, I would expect a bad_alloc. Also, some compilers preallocate space for a "reasonable" amount of exceptions. – Bo Persson Aug 4 '17 at 8:46
  • @BoPersson Expectations are irrelevant -- does standard specify what is going to happen? Look like an omission that needs to be fixed – C.M. Aug 4 '17 at 16:22
  • The Itanium ABI specifies that __cxa_allocate_exception calls terminate if it cannot allocate memory. – T.C. Aug 4 '17 at 16:58
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    @T.C. If this behavior is OK from standard POV then it is impossible to write reliable C++ code. I can't find anything that forbids or allows std::teminate() in this case. – C.M. Aug 5 '17 at 1:19

(providing my own answer... I'll wait for few days and if there are no problems with it -- I'll mark it as accepted)

I spent some time investigating this and here is what I unearthed:

  • C++ standard does not specify what is going to happen in this case
  • Clang and GCC seem to use C++ Itanium ABI

Itanimum ABI suggests to use heap for exceptions:

Storage is needed for exceptions being thrown. This storage must persist while stack is being unwound, since it will be used by the handler, and must be thread-safe. Exception object storage will therefore normally be allocated in the heap


Memory will be allocated by the __cxa_allocate_exception runtime library routine.

So, yeah... throwing an exception will likely involve locking mutexes and searching for a free memory block. :-(

It also mentions this:

If __cxa_allocate_exception cannot allocate an exception object under these constraints, it calls terminate()

Yep... in GCC and Clang "throw myX();" can kill your app and you can't do a thing about it (maybe writing your own __cxa_allocate_exception can help -- but it certainly won't be portable)

It gets even better:

3.4.1 Allocating the Exception Object

Memory for an exception object will be allocated by the __cxa_allocate_exception runtime library routine, with general requirements as described in Section 2.4.2. If normal allocation fails, then it will attempt to allocate one of the emergency buffers, described in Section 3.3.1, under the following constraints:

  • The exception object size, including headers, is under 1KB.
  • The current thread does not already hold four buffers.
  • There are fewer than 16 other threads holding buffers, or this thread will wait until one of the others releases its buffers before acquiring one.

Yep, your program can simply hang! Granted chance of this are small -- you'd need to exhaust memory and your threads need to use up all 16 emergency buffers and enter wait for another thread that should generate an exception. But if you do things with std::current_exception (like chaining exception and passing them between threads) -- it is not so improbable.


This is a deficiency in C++ standard -- you can't write 100% reliable programs (that use exceptions). Text book example is a server that accepts connections from clients and executes submitted tasks. Obvious approach to handle problems would be to throw an exception, which will unwind everything and close connection -- all other clients won't be affected and server will continue to operate (even under low memory conditions). Alas, such server is impossible to write in C++.

You can claim that modern systems (i.e. Linux) will kill such server before we reach this situation anyway. But (1) it is not an argument; (2) memory manager can be set to overcommit; (3) OOM killer won't be triggered for 32-bit app running on 64bit hardware with enough memory (or if app artificially limited memory allocation).

On personal note I am quite pissed about this discovery -- for many years I claimed that my code handles out-of-memory gracefully. Turns out I lied to my clients. :-( Might as well start intercepting memory allocation, call std::terminate and treat all related functions as noexcept -- this will certainly make my life easier (coding-wise). No wonder they still use Ada to programs rockets.

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    Unfortunately, use of Ada didn't help the Ariane 5 rocket when an uncaught exception turned the system off. – Bo Persson Aug 15 '17 at 14:49
  • @BoPersson This is because they had a bug in the code. Point of that rant was that with C++ even a 100% correct code can still crash. – C.M. Aug 15 '17 at 16:20
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    About the last few paragraphs... You are claiming the implementation detail of Itanium ABI is a deficiency in the standard. I would say it is a deficiency in the implementation. – André Oct 15 '17 at 9:05
  • @André afaik standard allows any behaviour in this situation -- therefore Itanium ABI is fine. But since any behavior means unusable for practical purposes -- I consider it a deficiency in C++ standard. – C.M. Oct 15 '17 at 18:22
  • I think C++ runtime might be allowed to allocate exception object on stack and copy it during stack unwinding once per each catch block. Standard does not allow exception copy constructor to throw anyway, so such implementation should be reliable. – StaceyGirl Oct 16 '17 at 2:02

[intro.compliance]/2 Although this International Standard states only requirements on C++ implementations, those requirements are often easier to understand if they are phrased as requirements on programs, parts of programs, or execution of programs. Such requirements have the following meaning:

(2.1) — If a program contains no violations of the rules in this International Standard, a conforming implementation shall, within its resource limits, accept and correctly execute that program.

Emphasis mine. Basically, the standard envisions failure to allocate dynamic memory (and prescribes behavior in this case), but not any other kind of memory; and doesn't prescribe in any way what the implementation should do when its resource limits are reached.

Another example is running out of stack due to a too-deep recursion. Nowhere does the standard say how deep a recursion is allowed. The resulting stack overflow is the implementation exercising its "within resource limits" right-to-fail.

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    I could easily see and control how deep my stack will be. I have no good way to estimate how much of "invisible exception heap" have been used in my program -- libraries can accumulate exception objects (via std::exception_ptr). Each thread can accumulate a few. No good way to estimate usage of this "invisible heap" just by looking at my code. Imho, it is not OK to terminate in this case -- standard needs to be updated to provide better guarantees. – C.M. Aug 5 '17 at 18:47
  • Comparing OOM to stack overflow seems to be a common mistake. The difference is that stack usage does not depend on the size of input data (unless recursive algorithms are used), but heap usage usually does depend on it. – StaceyGirl Oct 16 '17 at 2:08
  • @C.M.: If you don't know what your libraries do (in terms of accumulating exception objects) I don't see how you can know how much stack space they will need either. – MikeMB Mar 6 '18 at 19:09
  • @MikeMB I didn't imply that I have no knowledge of libraries code. Point was that there is "no good way to estimate how much of 'invisible exception heap' have been used in my program". E.g. I can "pin" exceptions with "std::current_exception" and accumulate them somewhere. On the other hand stack usage can be figured out by looking at the code (well... unless you use implementation-specific stuff like alloca()/etc, or unless your recursion depth depends on input data). – C.M. Mar 7 '18 at 2:26
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    @C.M. By the same token, you can estimate how much of "invisible exception heap" is used by your program (well ... unless you use std::current_exception to pin exceptions and accumulate them somewhere). Avoid doing that, just like you avoid recursion whose depth depends on input data. I'm not sure why you consider one bad practice as OK to hand-wave away, while another as sky-is-falling horrible. The bad use of std::current_exception is much less common than the bad use of recursion, in my experience; in fact, I don't think I've ever seen anyone use std::current_exception in real code. – Igor Tandetnik Mar 7 '18 at 3:26

Current answer already describes what GCC does. I have checked MSVC behavior - it allocates exception on the stack, so allocation does not depend on the heap. This makes stack overflow is possible (exception object can be big), but stack overflow handling is not covered by standard C++.

I used this short program to examine what happens during exception throw:

#include <iostream>

class A {
    A() { std::cout << "A::A() at " << static_cast<void *>(this) << std::endl; }
    A(const A &) { std::cout << "A::A(const A &) at " << static_cast<void *>(this) << std::endl; }
    A(A &&) { std::cout << "A::A(A &&) at " << static_cast<void *>(this) << std::endl; }
    ~A() { std::cout << "A::~A() at " << static_cast<void *>(this) << std::endl; }
    A &operator=(const A &) = delete;
    A &operator=(A &&) = delete;

int main()
    try {
        try {
            try {
                A a;
                throw a;
            } catch (const A &ex) {
        } catch (const A &ex) {
    } catch (const A &ex) {

When build with GCC output clearly shows that exception thrown is being allocated far from stack:

A::A() at 0x22cad7
A::A(A &&) at 0x600020510
A::~A() at 0x22cad7
A::~A() at 0x600020510

When build with MSVC output shows that exception is allocated nearby on the stack:

A::A() at 000000000018F4E4
A::A(A &&) at 000000000018F624
A::~A() at 000000000018F4E4
A::~A() at 000000000018F624

Additional examination with debugger shows that catch handlers and destructors are executed on the top of the stack, so stack consumption grows with each catch block starting with the first throw and until std::uncaught_exceptions() becomes 0.

Such behavior means that correct out of memory handling requires you to prove there is enough stack space for the program to execute exception handlers and all destructors on the way.

To prove the same with GCC it seems that you will need to prove there no more than four nested exceptions and exceptions have size less than 1KiB (this includes header). Additionally if some thread has more than four nested exceptions, you also need to prove there is no deadlock caused by emergency buffer allocation.

  • So MSVC followes what is said in the c++ standard! – Oliv Oct 16 '17 at 6:31
  • According to your answer it looks like GCC is just non-conforming in this regard. As much as I hate MSVC and its runtime, it wins here over GCC. – StaceyGirl Oct 16 '17 at 6:34
  • I also use GCC on Linux, and I have abandoned to use MSVC because there are too much nonconformties: too much work to make a code compile on MSVC, too much work to maintain it and too many bugs in the executable that just come from MSVC bugs! This is the first case were I see MSVC do a better job than GCC. I hope MSVC will go into the party soon, I know they are working on it. GCC seems to benefit of competition. – Oliv Oct 16 '17 at 6:43
  • @Ivan -- question was about C++ standard, not particular implementation. I know MSVC uses stack for exceptions and this makes it immune to this problem, but because of that now it is very hard (or impossible) to estimate how much stack space my program needs -- which means if my guess is wrong, result is the same as with GCC (crash). Btw, both GCC and MSVC conform to standard here – C.M. Oct 17 '17 at 2:12
  • @Ivan Your answer provides good MSVC-specific info. If you update it a bit -- I'll mark it too. In particular these points need some improvement: (1) it is not really expected -- turns out standard allows it to be "dependent on compiler"; (2) allocation can fail -- just failure is different (running out of stack); (3) not only catch-handlers, but dtors also executed on top of the stack; (4) MSVC does conform standard here – C.M. Oct 17 '17 at 2:49

Actualy it is specified that if allocation for the exception object fails, bad_alloc should be thrown and implementation could also call the new handler.

This is what is actualy specified in the c++ standard section (§ you site [basic.stc.dynamic.allocation]:

An allocation function that fails to allocate storage can invoke the currently installed new-handler function (, if any. [ Note: A program-supplied allocation function can obtain the address of the currently installed new_handler using the std::get_new_handler function ( — end note ] If an allocation function that has a non-throwing exception specification (18.4) fails to allocate storage, it shall return a null pointer. Any other allocation function that fails to allocate storage shall indicate failure only by throwing an exception (18.1) of a type that would match a handler (18.3) of type std::bad_alloc (

Then this recalled in [except.terminate]

In some situations exception handling must be abandoned for less subtle error handling techniques. [ Note: These situations are: — (1.1) when the exception handling mechanism, after completing the initialization of the exception object but before activation of a handler for the exception (18.1)*

So the itanium ABI does not follow the c++ standard specification, since it can block or call terminate if the program fails to allocate memory for the exception object.

  • first paragraph of states that "An allocation function shall be a class member function or a global function;" -- don't see how it applies to throw-expression, there is nothing in text that requires throw-expression to use allocation function from – C.M. Oct 15 '17 at 18:33
  • 18.5.1.p(1-1) has nothing to do with my question either – C.M. Oct 15 '17 at 18:34
  • @C.M. The y changed the numbering of sections in the new standard. -> I have put a link to the section you cite in your question... Yes it does apply to your question (you cite it yourself!). So the good practice when you cite the standard is not to use the section number, but the section name is [basic.stc.dynamic.allocation]. – Oliv Oct 16 '17 at 6:12
  • @C.M. Compiler must followes the fundamental rules describe in [intro.execution], it must execute what is asked and continue execution (there are progress guarentees). For exemple in [expr.add] it is not stated that "1+1" can cause the program termination or the program to block. The fact it is not stated does not mean that a compiler could is allowed to block or allowed to terminate because of it executes 1+1. The same applies to a throw expression!! – Oliv Oct 16 '17 at 6:28
  • @C.M. It seems your are not the first to ask this question so they have recalled in [except.terminate] what can cause a program termination, and object exception allocation is explicitly excluded from the set of operation that can cause terminate. – Oliv Oct 16 '17 at 6:28

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