Question

Is it ever acceptable to have a memory leak in your C or C++ application?

What if you allocate some memory and use it until the very last line of code in your application (for example, a global object's deconstructor)? As long as the memory consumption doesn't grow over time, is it OK to trust the OS to free your memory for you when your application terminates (on Windows, Mac, and Linux)? Would you even consider this a real memory leak if the memory was being used continuously until it was freed by the OS.

What if a third party library forced this situation on you? Would refuse to use that third party library no matter how great it otherwise might be?

I only see one practical disadvantage, and that is that these benign leaks will show up with memory leak detection tools as false positives.

Answer 1

Its perfectly acceptable to omit freeing memory on the last line of the program since freeing it would have no effect on anything since the program never needs memory again.

Answer 2

Splitting hairs perhaps: what if your app is running on UNIX and can become a zombie? In this case the memory does not get reclaimed by the OS. So I say you really should de-allocate the memory before the program exits.

Answer 3

No, they are not O.K., but I've implemented a few allocators, memory dumpers, and leak detectors, and have found that as a pragmatic matter it's convenient to allow one to mark such an allocation as "Not a Leak as far as the Leak Report is concerned"...

This helps make the leak report more useful... and not crowded with "dynamic allocation at static scope not free'd by program exit"

Answer 4

Is it ok for you to go to a mates house, have a hell of a party and leave without cleaning up?

Answer 5

If your code has any memory leaks, even known "acceptable" leaks, then you will have an annoying time using any memory leak tools to find your "real" leaks. Just like leaving "acceptable" compiler warnings makes finding new, "real" warnings more difficult.

Answer 6

If you are using it up until the tail of your main(), it is simply not a leak (assuming a protected memory system, of course!).

In fact, freeing objects at process shutdown is the absolute worst thing you could do... the OS has to page back in every page you have ever created. Close file handles, database connections, sure, but freeing memory is just dumb.

Answer 7

While most answers concentrate on real memory leaks (which are not OK ever, because they are a sign of sloppy coding), this part of the question appears more interesting to me:

What if you allocate some memory and use it until the very last line of code in your application (for example, a global object's deconstructor)? As long as the memory consumption doesn't grow over time, is it OK to trust the OS to free your memory for you when your application terminates (on Windows, Mac, and Linux)? Would you even consider this a real memory leak if the memory was being used continuously until it was freed by the OS.

If the associated memory is used, you cannot free it before the program ends. Whether the free is done by the program exit or by the OS does not matter. As long as this is documented, so that change don't introduce real memory leaks, and as long as there is no C++ destructor or C cleanup function involved in the picture. A not-closed file might be revealed through a leaked FILE object, but a missing fclose() might also cause the buffer not to be flushed.

So, back to the original case, it is IMHO perfectly OK in itself, so much that Valgrind, one of the most powerful leak detectors, will treat such leaks only if requested. On Valgrind, when you overwrite a pointer without freeing it beforehand, it gets considered as a memory leak, because it is more likely to happen again and to cause the heap to grow endlessly.

Then, there are not nfreed memory blocks which are still reachable. One could make sure to free all of them at the exit, but that is just a waste of time in itself. The point is if they could be freed before. Lowering memory consumption is useful in any case.

Answer 8

The best practice is to always free what you allocate, especially if writing something that is designed to run during the entire uptime of a system, even when cleaning up prior to exiting.

Its a very simple rule .. programming with the intention of having no leaks makes new leaks easy to spot. Would you sell someone a car that you made knowing that it sputtered gas on the ground ever time it was turned off? :)

A few if () free() calls in a cleanup function are cheap, why not use them?

Answer 9

Only in one instance: The program is going to shoot itself due to an unrecoverable error.

Answer 10

When an application shuts down, it can be argued that it is best to not free memory.

In theory, the OS should release the resources used by the application, but there is always some resources that are exceptions to this rule. So beware.

The good with just exiting the application:

1. The OS gets one chunk to free instead of many many small chunks. This means shutdown is much much faster. Especially on Windows with it's slow memory management.

The bad with just exiting is actually two points:

1. It is easy to forget to release resources that the OS does not track or that the OS might wait a bit with releasing. One example is TCP sockets.
2. Memory tracking software will report everything not freed at exit as leaks.

Because of this, you might want to have two modes of shutdown, one quick and dirty for end users and one slow and thorough for developers. Just make sure to test both :)

Answer 11

No, you should not have leaks that the OS will clean for you. The reason (not mentioned in the answers above as far as I could check) is that you never know when your main() will be re-used as a function/module in another program. If your main() gets to be a frequently-called function in another persons' software - this software will have a memory leak that eats memory over time.

KIV

Answer 12

As long as your memory utilization doesn't increase over time, it depends. If you're doing lots of complex synchronization in server software, say starting background threads that block on system calls, doing clean shutdown may be too complex to justify. In this situation the alternatives may be:

1. Your library that doesn't clean up its memory until the process exits.
2. You write an extra 500 lines of code and add another mutex and condition variable to your class so that it can shut down cleanly from your tests – but this code is never used in production, where the server only terminates by crashing.

Answer 13

It really depends upon the usage of the object that creating the memory leak. If you are creating the object so many times in the life time of the application that is using the object, then it is bad to use that way. Because so much memory leak will be there. On the other hand if we have a single instance of object without consuming the memory and leaking only in terms of small amount then it is not a problem.

Memory leak is a problem when the leak increases when the application is running.

Answer 14

As a general rule, if you've got memory leaks that you feel you can't avoid, then you need to think harder about object ownership.

But to your question, my answer in a nutshell is In production code, yes. During development, no. This might seem backwards, but here's my reasoning:

In the situation you describe, where the memory is held until the end of the program, it's perfectly okay to not release it. Once your process exits, the OS will clean up anyway. In fact, it might make the user's experience better: In a game I've worked on, the programmers thought it would be cleaner to free all the memory before exiting, causing the shutdown of the program to take up to half a minute! A quick change that just called exit() instead made the process disappear immediately, and put the user back to the desktop where he wanted to be.

However, you're right about the debugging tools: They'll throw a fit, and all the false positives might make finding your real memory leaks a pain. And because of that, always write debugging code that frees the memory, and disable it when you ship.

Answer 15

Many people seem to be under the impression that once you free memory, it's instantly returned to the operating system and can be used by other programs.

This isn't true. Operating systems commonly manage memory in 4KiB pages. malloc and other sorts of memory management get pages from the OS and sub-manage them as they see fit. It's quite likely that free() will not return pages to the operating system, under the assumption that your program will malloc more memory later.

I'm not saying that free() never returns memory to the operating system. It can happen, particularly if you are freeing large stretches of memory. But there's no guarantee.

The important fact: If you don't free memory that you no longer need, further mallocs are guaranteed to consume even more memory. But if you free first, malloc might re-use the freed memory instead.

What does this mean in practice? It means that if you know your program isn't going to require any more memory from now on (for instance it's in the cleanup phase), freeing memory is not so important. However if the program might allocate more memory later, you should avoid memory leaks - particularly ones that can occur repeatedly.

Also see this comment for more details about why freeing memory just before termination is bad.

A commenter didn't seem to understand that calling free() does not automatically allow other programs to use the freed memory. But that's the entire point of this answer!

So, to convince people, I will demonstrate an example where free() does very little good. To make the math easy to follow, I will pretend that the OS manages memory in 4000 byte pages.

Suppose you allocate ten thousand 100-byte blocks (for simplicity I'll ignore the extra memory that would be required to manage these allocations). This consumes 1MB, or 250 pages. If you then free 9000 of these blocks at random, you're left with just 1000 blocks - but they're scattered all over the place. Statistically, about 5 of the pages will be empty. The other 245 will each have at least one allocated block in them. That amounts to 980KB of memory, that cannot possibly be reclaimed by the operating system - even though you now only have 100KB allocated!

On the other hand, you can now malloc() 9000 more blocks without increasing the amount of memory your program is tying up.

Even when free() could technically return memory to the OS, it may not do so. free() needs to achieve a balance between operating quickly and saving memory. And besides, a program that has already allocated a lot of memory and then freed it is likely to do so again. A web server needs to handle request after request after request - it makes sense to keep some "slack" memory available so you don't need to ask the OS for memory all the time.

Answer 16

I believe the answer is no, never allow a memory leak, and I have a few reasons which I haven't seen explicitly stated. There are great technical answers here but I think the real answer hinges on more social/human reasons.

(First, note that as others mentioned, a true leak is when your program, at any point, loses track of memory resources that it has allocated. In C, this happens when you malloc() to a pointer and let that pointer leave scope without doing a free() first.)

The important crux of your decision here is habit. When you code in a language that uses pointers, you're going to use pointers a lot. And pointers are dangerous; they're the easiest way to add all manner of severe problems to your code.

When you're coding, sometimes you're going to be on the ball and sometimes you're going to be tired or mad or worried. During those somewhat distracted times, you're coding more on autopilot. The autopilot effect doesn't differentiate between one-off code and a module in a larger project. During those times, the habits you establish are what will end up in your code base.

So no, never allow memory leaks for the same reason that you should still check your blind spots when changing lanes even if you're the only car on the road at the moment. During times when your active brain is distracted, good habits are all that can save you from disastrous missteps.

Beyond the "habit" issue, pointers are complex and often require a lot of brain power to track mentally. It's best to not "muddy the water" when it comes to your usage of pointers, especially when you're new to programming.

There's a more social aspect too. By proper use of malloc() and free(), anyone who looks at your code will be at ease; you're managing your resources. If you don't, however, they'll immediately suspect a problem.

Maybe you've worked out that the memory leak doesn't hurt anything in this context, but every maintainer of your code will have to work that out in his head too when he reads that piece of code. By using free() you remove the need to even consider the issue.

Finally, programming is writing a mental model of a process to an unambiguous language so that a person and a computer can perfectly understand said process. A vital part of good programming practice is never introducing unnecessary ambiguity.

Smart programming is flexible and generic. Bad programming is ambiguous.

Answer 17

Let's get our definitions correct, first. A memory leak is when memory is dynamically allocated, eg with malloc(), and all references to the memory are lost without the corresponding free. An easy way to make one is like this:

#define BLK ((size_t)1024)
while(1){
    void * vp = malloc(BLK);
}

Note that every time around the while(1) loop, 1024 (+overhead) bytes are allocated, and the new address assigned to vp; there's no remaining pointer to the previous malloc'ed blocks. This program is guaranteed to run until the heap runs out, and there's no way to recover any of the malloc'ed memory. Memory is "leaking" out of the heap, never to be seen again.

What you're describing, though, sound like

int main(){
    void * vp = malloc(LOTS);
    // Go do something useful
    return 0;
}

You allocate the memory, work with it until the program terminates. This is not a memory leak; it doesn't impair the program, and all the memory will be scavenged up automagically when the program terminates.

Generally, you should avoid memory leaks. First, because like altitude above you and fuel back at the hangar, memory that has leaked and can't be recovered is useless; second, it's a lot easier to code correctly, not leaking memory, at the start than it is to find a memory leak later.

Answer 18

It looks like your definition of "memory leak" is "memory that I don't clean up myself." All modern OSes will free it on program exit. However, since this is a C++ question, you can simply wrap the memory in question inside an appropriate std::auto_ptr which will call delete when it goes out of scope.

Answer 19

Generally a memory leak in a stand alone application is not fatal, as it gets cleaned up when the program exits.

What do you do for Server programs that are designed so they don't exit?

If you are the kind of programmer that does not design and implement code where the resources are allocated and released correctly, then I don't want anything to do with you or your code. If you don't care to clean up your leaked memory, what about your locks? Do you leave them hanging out there too? Do you leave little turds of temporary files laying around in various directories?

Leak that memory and let the program clean it up? No. Absolutely not. It's a bad habit, that leads to bugs, bugs, and more bugs.

Clean up after yourself. Yo momma don't work here no more.

Answer 20

This was already discussed ad nauseam. Bottom line is that a memory leak is a bug and must be fixed. If a third party library leaks memory, it makes one wonder what else is wrong with it, no? If you were building a car, would you use an engine that is occasionally leaking oil? After all, somebody else made the engine, so it's not your fault and you can't fix it, right?

Answer 21

If you allocate a bunch of heap at the beginning of your program, and you don't free it when you exit, that is not a memory leak per se. A memory leak is when your program loops over a section of code, and that code allocates heap and then "loses track" of it without freeing it.

In fact, there is no need to make calls to free() or delete right before you exit. When the process exits, all of its memory is reclaimed by the OS (this is certainly the case with POSIX. On other OSes – particularly embedded ones – YMMV).

The only caution I'd have with not freeing the memory at exit time is that if you ever refactor your program so that it, for example, becomes a service that waits for input, does whatever your program does, then loops around to wait for another service call, then what you've coded can turn into a memory leak.

Answer 22

I can count on one hand the number of "benign" leaks that I've seen over time.

So the answer is a very qualified yes.

An example. If you have a singleton resource that needs a buffer to store a circular queue or deque but doesn't know how big the buffer will need to be and can't afford the overhead of locking or every reader, then allocating an exponentially doubling buffer but not freeing the old ones will leak a bounded amount of memory per queue/deque. The benefit for these is they speed up every access dramatically and can change the asymptotics of multiprocessor solutions by never risking contention for a lock.

I've seen this approach used to great benefit for things with very clearly fixed counts such as per-CPU work-stealing deques, and to a much lesser degree in the buffer used to hold the singleton /proc/self/maps state in Hans Boehm's conservative garbage collector for C/C++, which is used to detect the root sets, etc.

While technically a leak, both of these cases are bounded in size and in the growable circular work stealing deque case there is a huge performance win in exchange for a bounded factor of 2 increase in the memory usage for the queues.

Answer 23

Even if you are sure that your 'known' memory leak will not cause havoc, don't do it. At best, it will pave a way for you to make a similar and probably more critical mistake at a different time and place.

For me, asking this is like questioning "Can I break the red light at 3 AM in the morning when no one is around?". Well sure, it may not cause any trouble at that time but it will provide a lever for you to do the same in rush hour!

Answer 24

In this sort of question context is everything. Personally I can't stand leaks, and in my code I go to great lengths to fix them if they crop up, but it is not always worth it to fix a leak, and when people are paying me by the hour I have on occasion told them it was not worth my fee for me to fix a leak in their code. Let me give you an example:

I was triaging a project, doing some perf work and fixing a lot of bugs. There was a leak during the applications initialization that I tracked down, and fully understood. Fixing it properly would have required a day or so refactoring a piece of otherwise functional code. I could have done something hacky (like stuffing the value into a global and grabbing it some point I know it was no longer in use to free), but that would have just caused more confusion to the next guy who had to touch the code.

Personally I would not have written the code that way in the first place, but most of us don't get to always work on pristine well designed codebases, and sometimes you have to look at these things pragmatically. The amount of time it would have taken me to fix that 150 byte leak could instead be spent making algorithmic improvements that shaved off megabytes of ram.

Ultimately, I decided that leaking 150 bytes for an app that used around a gig of ram and ran on a dedicated machine was not worth fixing it, so I wrote a comment saying that it was leaked, what needed to be changed in order to fix it, and why it was not worth it at the time.

Answer 25

I totally agree with JohnMcG, and just want to add that I have myself had problems to discover real, potentially serious memory leaks in time, just because it have been accepted to have the benign ones. When these have grown to be so many over time, it becomes more and more difficult to detect the serious ones in the flood of the benign ones.

So at least for your fellow programmers sake (and also for yourself in the future), please try to eleminate them as soon as possible.

Answer 26

No.

As professionals, the question we should not be asking ourselves the question, "Is it ever OK to do this?" but rather "Is there ever a good reason to do this?" And "hunting down that memory leak is a pain" isn't a good reason.

I like to keep things simple. And the simple rule is that my program should have no memory leaks.

That makes my life simple, too. If I detect a memory leak, I eliminate it, rather than run through some elaborate decision tree structure to determine whether it's an "acceptable" memory leak.

It's similar to compiler warnings – will the warning be fatal to my particular application? Maybe not.

But it's ultimately a matter of professional discipline. Tolerating compiler warnings and tolerating memory leaks is a bad habit that will ultimately bite me in the rear.

To take things to an extreme, would it ever be acceptable for a surgeon to leave some piece of operating equipment inside a patient?

Although it is possible that a circumstance could arise where the cost/risk of removing that piece of equipment exceeds the cost/risk of leaving it in, and there could be circumstances where it was harmless, if I saw this question posed on SurgeonOverflow.com and saw any answer other than "no," it would seriously undermine my confidence in the medical profession.

–

If a third party library forced this situation me, it would lead me to seriously suspect the overall quality of the library in question. It would be as if I test drove a car and found a couple loose washers and nuts in one of the cupholders – it may not be a big deal in itself, but it betrays a lack of commitment to quality, so I would consider alternatives.

Answer 27

Historically, it did matter on some operating systems under some edge cases. These edge cases could exist in the future.

Here's an example, on SunOS in the Sun 3 era, there was an issue if a process used exec (or more traditionally fork and then exec), the subsequent new process would inherit the same memory footprint as the parent and it could not be shrunk. If a parent process allocated 1/2 gig of memory and didn't free it before calling exec, the child process would start using that same 1/2 gig (even though it wasn't allocated). This behavior was best exhibited by SunTools (their default windowing system), which was a memory hog. Every app that it spawned was created via fork/exec and inherited SunTools footprint, quickly filling up swap space.

Answer 28

I agree with vfilby – it depends. In Windows, we treat memory leaks as relatively serous bugs. But, it very much depends on the component.

For example, memory leaks are not very serious for components that run rarely, and for limited periods of time. These components run, do theire work, then exit. When they exit all their memory is freed implicitly.

However, memory leaks in services or other long run components (like the shell) are very serious. The reason is that these bugs 'steal' memory over time. The only way to recover this is to restart the components. Most people don't know how to restart a service or the shell – so if their system performance suffers, they just reboot.

So, if you have a leak – evaluate its impact two ways

1. To your software and your user's experience.
2. To the system (and the user) in terms of being frugal with system resources.

Foredecker :)

Answer 29

I think in your situation the answer may be that it's okay. But you definitely need to document that the memory leak is a conscious decision. You don't want a maintenance programmer to come along, slap your code inside a function, and call it a million times. So if you make the decision that a leak is okay you need to document it (IN BIG LETTERS) for whoever may have to work on the program in the future.

If this is a third party library you may be trapped. But definitely document that this leak occurs.

But basically if the memory leak is a known quantity like a 512 KB buffer or something then it is a non issue. If the memory leak keeps growing like every time you call a library call your memory increases by 512KB and is not freed, then you may have a problem. If you document it and control the number of times the call is executed it may be manageable. But then you really need documentation because while 512 isn't much, 512 over a million calls is a lot.

Also you need to check your operating system documentation. If this was an embedded device there may be operating systems that don't free all the memory from a program that exits. I'm not sure, maybe this isn't true. But it is worth looking into.

Answer 30

You have to first realize that there's a big difference between a perceived memory leak and an actual memory leak. Very frequently analysis tools will report many red herrings, and label something as having been leaked (memory or resources such as handles etc) where it actually isn't. Often times this is due to the analysis tool's architecture. For example, certain analysis tools will report run time objects as memory leaks because it never sees those object freed. But the deallocation occurs in the runtime's shutdown code, which the analysis tool might not be able to see.

With that said, there will still be times when you will have actual memory leaks that are either very difficult to find or very difficult to fix. So now the question becomes is it ever OK to leave them in the code?

The ideal answer is, "no, never." A more pragmatic answer may be "no, almost never." Very often in real life you have limited number of resources and time to resolve and endless list of tasks. When one of the tasks is eliminating memory leaks, the law of diminishing returns very often comes in to play. You could eliminate say 98% of all memory leaks in an application in a week, but the remaining 2% might take months. In some cases it might even be impossible to eliminate certain leaks because of the application's architecture without a major refactoring of code. You have to weigh the costs and benefits of eliminating the remaining 2%.