Google's C++ style guide says "We do not use exceptions". The style does not mention STL with respect to usage of exception. Since STL allocators can fail, how do they handle exceptions thrown by containers?

  1. If they use STL, how is the caller informed of allocation failures? STL methods like push_back() or map operator[] do not return any status codes.
  2. If they do not use STL, what container implementation do they use?
  • 8
    Before I came in and yelled until I got my way, the shop I work at had the same silly convention. We just ignored reality. My bet is that this is also what google does. Mar 3, 2011 at 17:42
  • 15
    Google has pretty archaic standards. Guess they hire a lot of students and only can afford a small number of C++ wizards. Mar 3, 2011 at 17:56
  • 7
    No need to assert NULL pointers. Just crash and burn. Rule of Repair: Repair what you can — but when you must fail, fail noisily and as soon as possible. Mar 3, 2011 at 18:15
  • 21
    @Maxim: that's why you need to assert null pointers, to follow that advice. If you don't assert, there's a risk that your code might fail to crash and burn, because "undefined behavior" does not mean "segfault immediately". Admittedly a small risk, but consider for example theregister.co.uk/2009/07/17/linux_kernel_exploit Mar 3, 2011 at 18:30
  • 12
    @Maxim: "Mapping a page at 0 address is asking for trouble." - quite, and attackers generally are asking for trouble when they maliciously pull some such stunt. That's just an example, though. If you act as though you're guaranteed to get a segfault from accessing a null pointer, eventually the compiler will surprise you (or someone else like you) by not guaranteeing that. Undefined behavior can travel back in time to make demons fly out of your nose as soon as the program starts. Either fail as soon as possible, or else don't, but don't expect to fail and then not fail. Mar 3, 2011 at 22:20

8 Answers 8


They say that they don't use exceptions, not that nobody should use them. If you look at the rationale they also write:

Because most existing C++ code at Google is not prepared to deal with exceptions, it is comparatively difficult to adopt new code that generates exceptions.

The usual legacy problem. :-(

  • 5
    And the question is how they deal with the consequences of that decision for the STL container interfaces, not how anybody else does ;-) Mar 3, 2011 at 17:36
  • 5
    Not just a legacy problem. Writing exception-safe code is not trivial and no tool exists (that I know of) that helps the developers here too. So, even new codes are prone to exception dangers.
    – kirakun
    Mar 3, 2011 at 17:37
  • 3
    The question is not "is their decision reasonable, or shoudl everybody follow their decision". No, no, and no. The question is, is it possible to use stl containers and abide by this rule.
    – Andrei
    Mar 3, 2011 at 18:54
  • 4
    Let's be fair. Of their 6 reasons against exceptions, only one is related to legacy. Five others "cons" do not have anything to do with legacy.
    – Andrei
    Mar 5, 2011 at 5:43
  • 12
    There are cons with their method as well, like having to all an Init() function for the objects. What if you forget one call? How do you do it for temporary objects? Don't use that? Do you have an empty Init() function for all classes, or do you add one just when you discover you need one? Then how do you find all places where you need to add an Init() call? They say that exceptions forces you to use RAII, and that is supposed to be hard. If you don't use exceptions, you must check return codes or object validity all over the place. That is even harder to get right.
    – Bo Persson
    Mar 5, 2011 at 8:21

We simply don't handle exceptions thrown by containers, at least in application-level code.

I've been an engineer at Google Search working in C++ since 2008. We do use STL containers often. I cannot personally recall a single major failure or bug that was ever traced back to something like vector::push_back() or map::operator[] failing, where we said "oh man, we have to rewrite this code because the allocation could fail" or "dang, if only we used exceptions, this could have been avoided." Does a process ever run out of memory? Yes, but this is usually a simple mistake (e.g., someone added a large new data file to the program and forgot to increase the RAM allocation) or a catastrophic failure where there's no good way to recover and proceed. Our system already manages and restarts jobs automatically to be robust to machines with faulty disks, cosmic rays, etc., and this is really no different.

So as far as I can tell, there is no problem here.

  • 2
    @Hinata Hyuga: Thanks for the suggestions, but I agree with Loki Astari; my answer relies entirely on my personal experience at Google, which, I believe, is a valid source when answering a Stack Overflow question. I have taken some of your suggestions for grammar though. Thanks, both!
    – hoffmanj
    Mar 22, 2013 at 18:01
  • As I said in my answer below, it’s quite unlikely that you’ll see allocator exceptions anyway on modern systems when using the standard allocator. You might conceivably with some kind of custom allocator, but otherwise it really isn’t worth worrying about.
    – al45tair
    Sep 16, 2013 at 7:07
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    @hoffmanj I've seen some code using streams where the underlying stream entered a failed state and the code was silently failing. Checking the state of the stream after every insertion (ala WinAPI) would be obnoxious. Granted, the style guide forbids the use of streams for non-logging purposes (as an aside, does that include stringstream?). I suppose my question is, if you're interacting with an STL construct that doesn't have a great interface for error conditions other than exceptions, do you just ban them outright? Aug 6, 2015 at 18:27

I'm pretty sure that they mean they do not use exceptions in their code. If you check out their cpplint script, it does check to ensure you are including the correct headers for STL containers (like vector, list, etc).

  • 1
    Homm so do they wrap every single call to stl method into catch(...) ?
    – Andrei
    Mar 3, 2011 at 17:36
  • 3
    Mark, if you mean "they do not throw exceptions in ther code, but they allow the code they call to throwexceptions", this interpretation is wrong. CLick on small triangle to the left of the rule. From explanations, it becomes clear that they do not want exceptions thrown from underlying code, too.
    – Andrei
    Mar 3, 2011 at 18:56
  • 4
    As stated in the "Exceptions to the Rules" section "You may diverge from the rules when dealing with code that does not conform to this style guide." certainly STL was not designed with Google conventions in mind.
    – Ismael
    Mar 4, 2011 at 15:07

You can’t handle allocation failures anyway on modern operating systems; as a performance optimization, they typically over-commit memory. For instance, if you call malloc() and ask for a really huge chunk of memory on Linux, it will succeed even if the memory required to back it actually isn’t there. It’s only when you access it that the kernel actually tries to allocate pages to back it, and at that point it’s too late to tell you that the allocation failed anyway.


  1. Except in special cases, don’t worry about allocation failures. If the machine runs out of memory, that’s a catastrophic failure from which you can’t reliably recover.

  2. Nevertheless, it’s good practice to catch unhandled exceptions and log the e.what() output, then re-throw, since that may be more informative than a backtrace, and typical C++ library implementations don’t do that automatically for you.

  3. The whole huge thread above about how you can’t rely on crashing when you run out of memory is complete and utter rubbish. The C(++) standard may not guarantee it, but on modern systems crashing is the only thing you can rely on if you run out of memory. In particular, you can’t rely on getting a NULL or indeed any other indication from your allocator, up to and include a C++ exception.

  4. If you find yourself on an embedded system where page zero is accessible, I strongly suggest you fix that by mapping an inaccessible page at that location. Human beings cannot be relied upon to check for NULL pointers everywhere, but you can fix that by mapping a page once rather than trying to correct every possible (past, present and future) location at which someone might have missed a NULL.

I will qualify the above by saying that it’s possible you’re using some kind of custom allocator, or that you’re on a system that doesn’t over-commit (embedded systems without swap are one example of that, but not the only example). In that case, maybe you can handle out-of-memory conditions gracefully, on your system. But in general in the 21st century I’m afraid you are unlikely to get the chance; the first you’ll know that your system is out of memory is when things start crashing.

  • 1
    (1) The machine running OOM is different from the process running OOM, at least for the (majority) of processes that are still 32bit: due to address space fragmentation, you will start to hit allocation failures for large blocks sooner rather than later. (As we experience repeatedly on Windows.)
    – Martin Ba
    Sep 16, 2013 at 7:37
  • 1
    (2) If you want to crash (i.e., core dump) the process for unhandled exceptions and later analyze the crash dump, it may be better to not catch the exception (and rethrow) as catching them will unwind the stack, either leading to more errors or at least obfuscating the rash dump.
    – Martin Ba
    Sep 16, 2013 at 7:43
  • 1
    And, correct me, last time I checked, Windows didn't overcommit. So that leaves quite a large chunk of the installation base to consider, doesn't it?
    – Martin Ba
    Sep 16, 2013 at 7:45
  • @MartinBa Surprised to hear that you have address space fragmentation issues. That’s quite an unusual problem for most 32-bit programs (those that are most susceptible would have gone 64-bit already where possible).
    – al45tair
    Sep 17, 2013 at 10:40
  • @MartinBa I’m not so sure Windows doesn’t ever overcommit. I recall, on Win2K?, accidentally allocating more memory than could possibly have been available and having it succeed then crash later.
    – al45tair
    Sep 17, 2013 at 10:41

I have found that Google mentions this explicitly about STL and exceptions (emphasis is mine):

Although you should not use exceptions in your own code, they are used extensively in the ATL and some STLs, including the one that comes with Visual C++. When using the ATL, you should define _ATL_NO_EXCEPTIONS to disable exceptions. You should investigate whether you can also disable exceptions in your STL, but if not, it is OK to turn on exceptions in the compiler. (Note that this is only to get the STL to compile. You should still not write exception handling code yourself.)

I don't like such decisions (lucky that I am not working for Google), but they are quite clear about their behaviour and intentions.


Stl itself is directly only throwing in case of memory allocation failure. But usually a real world application can fail for a variety of reasons, memory allocation failure just one of them. On 32 bit systems memory allocation failure is not something which should be ignored, as it can occur. So the entire discussion above that memory allocation failure is not going to happen is kind of pointless. Even assuming this, one would have to write ones code using two step initialization. And C++ exception handling predates 64 bit architectures by a long time. I'm not certain how far I should go in dignifying the negative professionalism shown here by google and only answer the question asked. I remember some paper from IBM in around 1997 stating how well some people at IBM understood & appreciated the implications of C++ Exception Handling. Ok professionalism is not necessary an indicator of success. So giving up exception handling is not only a problem if one uses STL. It is a problem if one uses C++ as such. It means giving up on

  • constructor failure
  • being able to use member objects and base class objects as arguments for any of the following base/member class constructors ( without any testing). It is no wonder that people used two step construction before C++ exception handling existed.
  • giving up on hierarchical & rich error messages in an environment which allows for code to be provided by customers or third parties and throw errors, which the original writer of the calling code could not possible have foreseen when writing the calling code and could have provided space for in his return error code range.
  • avoids such hacks as returning a pointer to a static memory object to message allocation failure which the authors of FlexLm did
  • being able to use a memory allocator returning addresses into a memory mapped sparse file. In this case allocation failure happens when one accesses the memory in question.(ok currently this works only on windows but apple forced the gnu team to provide the necessary functionality in the G++ compiler. Some more pressure from Linux g++ developer will be necessary to provide the this functionality also for them) (oops -- this even applies to STL)
  • being able to leave this C style coding behind us (ignoring return values) and having to use a debugger with debug executable to find out what is failing in a non trivial environment with child processes and shared libraries provided by third parties or doing remote execution
  • being able to return rich error information to the caller without just dumping everything to stderr

There is only one possibility to handle allocation failure under assumptions outlined in the question:

  • that allocator force application exit on allocation failure. In particular, this requires the cusror allocator.

Index-out-of-bound exceptions are less interesting in this context, because application can ensure they won't happen using pre-checks.


Late to the party here although I didn't see any comparisons between C++ exception handling at Google and exception handling in Go. Specifically, Go only has error handling via a built-in error type. The linked Golang blog post explicitly concludes

Proper error handling is an essential requirement of good software. By employing the techniques described in this post you should be able to write more reliable and succinct Go code.

The creation of Golang certainly took considerations of best practices from working with C++ into account. The underlying intuition is that less can be more. I haven't worked at Google but do find their use of C++ and creation of Golang to be potentially suggestive of underlying best practices at the company.

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