74

There is a method called foo that sometimes returns the following error:

terminate called after throwing an instance of 'std::bad_alloc'
  what():  std::bad_alloc
Abort

Is there a way that I can use a try-catch block to stop this error from terminating my program (all I want to do is return -1)?

If so, what is the syntax for it?

How else can I deal with bad_alloc in C++?

4
  • 5
    Did you try to code a try ... catch statement? Which one?? Feb 26, 2012 at 20:15
  • 1
    I've never seen a bad_alloc exception. I imagine I'd have to allocate an incorrect amount of resources. What are you doing to cause that to happen?
    – Peter Wood
    Feb 26, 2012 at 20:25
  • 3
    Can you be more specific and more precise? What do you mean with "there is", "sometimes", "all I want to do"... Catching exceptions is technically easy, but in most cases it's a bad idea to do so without understanding its semantics.
    – Wolf
    May 16, 2014 at 14:33
  • 1
    Also the title is not consistent with your problem description.
    – Wolf
    May 16, 2014 at 14:39

7 Answers 7

102

In general you cannot, and should not try, to respond to this error. bad_alloc indicates that a resource cannot be allocated because not enough memory is available. In most scenarios your program cannot hope to cope with that, and terminating soon is the only meaningful behaviour.

Worse, modern operating systems often over-allocate: on such systems, malloc and new can return a valid pointer even if there is not enough free memory left – std::bad_alloc will never be thrown, or is at least not a reliable sign of memory exhaustion. Instead, attempts to access the allocated memory will then result in a segmentation fault, which is not catchable (you can handle the segmentation fault signal, but you cannot resume the program afterwards).

The only thing you could do when catching std::bad_alloc is to perhaps log the error, and try to ensure a safe program termination by freeing outstanding resources (but this is done automatically in the normal course of stack unwinding after the error gets thrown if the program uses RAII appropriately).

In certain cases, the program may attempt to free some memory and try again, or use secondary memory (= disk) instead of RAM but these opportunities only exist in very specific scenarios with strict conditions:

  1. The application must ensure that it runs on a system that does not overcommit memory, i.e. it signals failure upon allocation rather than later.
  2. The application must be able to free memory immediately, without any further accidental allocations in the meantime.

It’s exceedingly rare that applications have control over point 1 — userspace applications never do, it’s a system-wide setting that requires root permissions to change.1

OK, so let’s assume you’ve fixed point 1. What you can now do is for instance use a LRU cache for some of your data (probably some particularly large business objects that can be regenerated or reloaded on demand). Next, you need to put the actual logic that may fail into a function that supports retry — in other words, if it gets aborted, you can just relaunch it:

lru_cache<widget> widget_cache;

double perform_operation(int widget_id) {
    std::optional<widget> maybe_widget = widget_cache.find_by_id(widget_id);
    if (not maybe_widget) {
        maybe_widget = widget_cache.store(widget_id, load_widget_from_disk(widget_id));
    }
    return maybe_widget->frobnicate();
}

…

for (int num_attempts = 0; num_attempts < MAX_NUM_ATTEMPTS; ++num_attempts) {
    try {
        return perform_operation(widget_id);
    } catch (std::bad_alloc const&) {
        if (widget_cache.empty()) throw; // memory error elsewhere.
        widget_cache.remove_oldest();
    }
}

// Handle too many failed attempts here.

But even here, using std::set_new_handler instead of handling std::bad_alloc provides the same benefit and would be much simpler.


1 If you’re creating an application that does control point 1, and you’re reading this answer, please shoot me an email, I’m genuinely curious about your circumstances.

26
  • 23
    @KonradRudolph, may be a bit too much saying "cannot and should not try" to respond to this error. What if that program is in a sensitive host (nuclear plant, robot, mars rover) where it is unacceptable to just get yourself killed by the exception? What if you could actually handle it? An even simpler example is a game that is loading objects. If there is not enough memory, it could try reloading with lower quality meshes, or decrease the number of particles, or show cubes for whatever object that is missing etc.
    – Shahbaz
    Apr 15, 2013 at 13:33
  • 4
    @DavidHammen, that's true. Actually it would probably be written in C anyway, since many features of C++ are too high level for system programming and less controllable than in C. I meant to say that: saying "most often you can do nothing against bad_alloc, so you might as well get killed" is ok, but saying "you should never check for bad_alloc" is too much. You can't possibly imagine every use case. For some, maybe checking for bad_alloc is actually useful.
    – Shahbaz
    May 15, 2014 at 14:12
  • 12
    @SHahbaz, One can always take the route Matlab used to take. Suppose a user inadvertently asks for almost all of virtual memory. Knowing the machine size, Matlab thought "I can do that! But these things must be done delicately!" It didn't go for all that memory at once. It instead went piece by piece. On getting a failure it went into a busy loop and retried, again and again. When some other process quit, Matlab gobbled that memory, ASAP. Eventually, there was nothing left but the Matlab beast, with no way to kill it other than reboot. It's not a good idea to catch allocation failures. May 15, 2014 at 15:23
  • 3
    @KonradRudolph: "You won’t get meaningful diagnostics from this anyway, since most modern systems never fail a malloc, they just mark nonexistent memory as reserved." - just a thought, but perhaps this comment should be edited into the answer itself, as it's a crucial insight in to why attempts to handle bad_alloc may be useless or unreliable.... May 16, 2014 at 0:55
  • 3
    "most modern systems never fail a malloc" - that's simply not true. Malloc and new can definitely fail on Windows, which is still the most widespread OS in 2015. Unfortunately supporting 32 bit applications is also still important for most vendors, and running out of virtual address space, or having memory fragmentation are common issues. (Btw. new can also fail with 64 bit applications on Windows.)
    – darklon
    Jan 15, 2015 at 12:13
42

What is the C++ Standard specified behavior of new in c++?

The usual notion is that if new operator cannot allocate dynamic memory of the requested size, then it should throw an exception of type std::bad_alloc.
However, something more happens even before a bad_alloc exception is thrown:

C++03 Section 3.7.4.1.3: says

An allocation function that fails to allocate storage can invoke the currently installed new_handler(18.4.2.2), if any. [Note: A program-supplied allocation function can obtain the address of the currently installed new_handler using the set_new_handler function (18.4.2.3).] If an allocation function declared with an empty exception-specification (15.4), throw(), fails to allocate storage, it shall return a null pointer. Any other allocation function that fails to allocate storage shall only indicate failure by throw-ing an exception of class std::bad_alloc (18.4.2.1) or a class derived from std::bad_alloc.

Consider the following code sample:

#include <iostream>
#include <cstdlib>

// function to call if operator new can't allocate enough memory or error arises
void outOfMemHandler()
{
    std::cerr << "Unable to satisfy request for memory\n";

    std::abort();
}

int main()
{
    //set the new_handler
    std::set_new_handler(outOfMemHandler);

    //Request huge memory size, that will cause ::operator new to fail
    int *pBigDataArray = new int[100000000L];

    return 0;
}

In the above example, operator new (most likely) will be unable to allocate space for 100,000,000 integers, and the function outOfMemHandler() will be called, and the program will abort after issuing an error message.

As seen here the default behavior of new operator when unable to fulfill a memory request, is to call the new-handler function repeatedly until it can find enough memory or there is no more new handlers. In the above example, unless we call std::abort(), outOfMemHandler() would be called repeatedly. Therefore, the handler should either ensure that the next allocation succeeds, or register another handler, or register no handler, or not return (i.e. terminate the program). If there is no new handler and the allocation fails, the operator will throw an exception.

What is the new_handler and set_new_handler?

new_handler is a typedef for a pointer to a function that takes and returns nothing, and set_new_handler is a function that takes and returns a new_handler.

Something like:

typedef void (*new_handler)();
new_handler set_new_handler(new_handler p) throw();

set_new_handler's parameter is a pointer to the function operator new should call if it can't allocate the requested memory. Its return value is a pointer to the previously registered handler function, or null if there was no previous handler.

How to handle out of memory conditions in C++?

Given the behavior of newa well designed user program should handle out of memory conditions by providing a proper new_handlerwhich does one of the following:

Make more memory available: This may allow the next memory allocation attempt inside operator new's loop to succeed. One way to implement this is to allocate a large block of memory at program start-up, then release it for use in the program the first time the new-handler is invoked.

Install a different new-handler: If the current new-handler can't make any more memory available, and of there is another new-handler that can, then the current new-handler can install the other new-handler in its place (by calling set_new_handler). The next time operator new calls the new-handler function, it will get the one most recently installed.

(A variation on this theme is for a new-handler to modify its own behavior, so the next time it's invoked, it does something different. One way to achieve this is to have the new-handler modify static, namespace-specific, or global data that affects the new-handler's behavior.)

Uninstall the new-handler: This is done by passing a null pointer to set_new_handler. With no new-handler installed, operator new will throw an exception ((convertible to) std::bad_alloc) when memory allocation is unsuccessful.

Throw an exception convertible to std::bad_alloc. Such exceptions are not be caught by operator new, but will propagate to the site originating the request for memory.

Not return: By calling abort or exit.

4
  • 6
    This does not directly answer the exact Q asked, (Konrad's answer already answers it quite well) But this answer provides a insight on less commonly known means of handling out of memory conditions in c++ before a bad_allocis thrown.
    – Alok Save
    Feb 27, 2012 at 3:46
  • this permits to setup your own error handler and display if needed a stack backtrace and thus locate enough precisely where is the problem.
    – sancelot
    Jul 2, 2014 at 14:14
  • That doesn't work for me, the program still doesn't get my call catched and freeze instead (arch linux) if the swap is disabled
    – Ingo Mi
    Feb 25, 2020 at 22:29
  • @IngoMi you could take a look at Chapter 8 (Customizing new and delete) of Effective C++ by Scott Meyers to see whether your implementation is correct.
    – Hari
    Mar 16, 2023 at 12:22
41

You can catch it like any other exception:

try {
  foo();
}
catch (const std::bad_alloc&) {
  return -1;
}

Quite what you can usefully do from this point is up to you, but it's definitely feasible technically.

0
9

I would not suggest this, since bad_alloc means you are out of memory. It would be best to just give up instead of attempting to recover. However here is is the solution you are asking for:

try {
    foo();
} catch ( const std::bad_alloc& e ) {
    return -1;
}
4
  • 2
    @Wolf: the question explicitly says "to stop this error from terminating my program (all I want to do is return -1)" - it may or may not be useful as discussed in Konrad's answer, but this is what's been requested (unlike your answer's exit()). May 16, 2014 at 0:50
  • @TonyD Yes, you're right, and he explicitly states that he doesn't suggest it. Today I would not downvote this. My technical problem is now that that I cannot change this premature decision any more, because it happened too long ago.
    – Wolf
    May 16, 2014 at 12:59
  • SamMiller do you think it's possible to improve your answer so that it can compete with Flexo's ...I'd really like to (at least) undownvote it ;)
    – Wolf
    May 16, 2014 at 13:05
  • I already made a suggestion ...which was accepted :)
    – Wolf
    May 19, 2014 at 7:57
5

I may suggest a more simple (and even faster) solution for this. new operator would return null if memory could not be allocated.

int fv() {
    T* p = new (std::nothrow) T[1000000];
    if (!p) return -1;
    do_something(p);
    delete p;
    return 0;
}

I hope this could help!

3

Of course you can catch a bad_alloc, but I think the better question is how you can stop a bad_alloc from happening in the first place.

Generally, bad_alloc means that something went wrong in an allocation of memory - for example when you are out of memory. If your program is 32-bit, then this already happens when you try to allocate >4 GB. This happened to me once when I copied a C-string to a QString. The C-string wasn't '\0'-terminated which caused the strlen function to return a value in the billions. So then it attempted to allocate several GB of RAM, which caused the bad_alloc.

I have also seen bad_alloc when I accidentally accessed an uninitialized variable in the initializer-list of a constructor. I had a class foo with a member T bar. In the constructor I wanted to initialize the member with a value from a parameter:

foo::foo(T baz) // <-- mistyped: baz instead of bar
: bar(bar)
{
}

Because I had mistyped the parameter, the constructor initialized bar with itself (so it read an uninitialized value!) instead of the parameter.

valgrind can be very helpful with such errors!

1
  • 2
    You could allocate two buffers of size 3 GB each. That would blow your address-space.
    – Algoman
    Jul 19, 2021 at 8:28
1

Let your foo program exit in a controlled way:

#include <stdlib.h>     /* exit, EXIT_FAILURE */

try {
    foo();
} catch (const std::bad_alloc&) {
    exit(EXIT_FAILURE);
}

Then write a shell program that calls the actual program. Since the address spaces are separated, the state of your shell program is always well-defined.

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