Sign up ×
Stack Overflow is a community of 4.7 million programmers, just like you, helping each other. Join them; it only takes a minute:

It has never happened to me, and I've programming for years now.

Can someone give me an example of a non-trivial program in which malloc will actually not work?

I'm not talking about memory exhaustion: I'm looking for the simple case when you are allocating just one memory block in a bound size given by the user, lets say an integer, causes malloc to fail.

share|improve this question
Going for the most answers in under 2 minutes prize here :) – Michael Dorgan Feb 1 '12 at 19:05
I don't understand. If you don't have a problem, why are you posting? – Martin James Feb 1 '12 at 19:08
@MichaelDorgan - it might be easy for you, but all my non-trivial apps with malloc problems have been delivered to customers and so I'm not free to post them :) – Martin James Feb 1 '12 at 19:13
Lol - Worked on handheld platforms for so many years that NULL from malloc is quite easy for me to achieve. – Michael Dorgan Feb 1 '12 at 19:15
@Useless - if you leak memory over time, or just fragment it like crazy, no malloc of any size is ever completely safe. – Michael Dorgan Feb 1 '12 at 19:17

10 Answers 10

up vote 12 down vote accepted


Just try to malloc more memory than your system can provide (either by exhausting your address space, or virtual memory - whichever is smaller).


will probably do it. If not, repeat a few times until you run out.

share|improve this answer
thanks that buts thats pretty trivial. I'm talking about the simple case we you allocate just a bouded piece of memory. Can it still fail? see my edit – RanZilber Feb 1 '12 at 19:06
I'm sorry, clearly I should have posted a non-trivial program allocating hundreds of millions of sensible-sized objects for a good reason, which would obviously have exactly the same result. It's unlike to be both readable, concise and non-trivial though! – Useless Feb 1 '12 at 19:13
pah, someone removed the C++ tag after I posted. – Useless Feb 1 '12 at 19:14
SIZE_MAX from stdint.h (I think, originally said limits.h but I think that's wrong) will do the trick in C. – Chris Lutz Feb 1 '12 at 19:16
edited to mirror the tag change - thanks @ChrisLutz – Useless Feb 1 '12 at 19:23

You need to do some work in embedded systems, you'll frequently get NULL returned there :-)

It's much harder to run out of memory in modern massive-address-space-and-backing-store systems but still quite possible in applcations where you process large amounts of data, such as GIS or in-memory databases, or in places where your buggy code results in a memory leak.

But it really doesn't matter whether you've never experienced it before - the standard says it can happen so you should cater for it. I haven't been hit by a car in the last few decades either but that doesn't mean I wander across roads without looking first.

And re your edit:

I'm not talking about memory exhaustion, ...

the very definition of memory exhaustion is malloc not giving you the desired space. It's irrelevant whether that's caused by allocating all available memory, or heap fragmentation meaning you cannot get a contiguous block even though the aggregate of all free blocks in the memory arena is higher, or artificially limiting your address space usage such using the standards-compliant function:

void *malloc (size_t sz) { return NULL; }

The C standard doesn't distinguish between modes of failure, only that it succeeds or fails.

share|improve this answer
The poster asked if there is a case where malloc() returns 0 and memory is NOT exhausted. The case of fragmentation gets a lot more amusing, but it'll take non-trivial code (tuned to a particular allocator) to show the pattern. – Brian Bulkowski Sep 11 '14 at 6:51
Brian, I think that's covered in my answer. Memory exhaustion is defined as malloc not being able to give you what you want. Whether you're truly out of memory totally or whether you asked for 60 bytes and the allocator has one billion 30-bytes chunks that can't be coalesced, doesn't really matter. It's exhaustion in both those cases. In any case, a malloc that returns NULL every tenth time you call it regardless of how much memory it has (written by a true sadist) still complies with the standard. – paxdiablo Sep 11 '14 at 6:56

My first computer was an 8-bit system with 56KB of RAM. malloc() returned NULL all too often.

share|improve this answer
haha, awesome!! – L7ColWinters Feb 1 '12 at 19:06
C-64 with the basic memory mapped to malloc? – Michael Dorgan Feb 1 '12 at 19:21
No, HeathKit H89. – Ferruccio Feb 1 '12 at 19:46

Just check the manual page of malloc.

On success, a pointer to the memory block allocated by the function.
The type of this pointer is always void*, which can be cast to the desired type of data pointer in order to be dereferenceable.
If the function failed to allocate the requested block of memory, a null pointer is returned.

share|improve this answer
This describes the contract but, when can/does it happen? ("...never happened to me ... non-trivial program in which malloc will actually not work? ... when you are allocating just one memory block in a bound size given by the user ... is it still possible that malloc will fail?") – user166390 Feb 1 '12 at 19:13
This is not even an answer. – Koray Tugay Apr 13 at 19:27

Pick any platform, though embedded is probably easier. malloc (or new) a ton of RAM (or leak RAM over time or even fragment it by using naive algorithms). Boom. malloc does return NULL for me on occasion when "bad" things are happening.

In response to your edit. Yes again. Memory fragmentation over time can make it so that even a single allocation of an int can fail. Also keep in mind that malloc doesn't just allocate 4 bytes for an int, but can grab as much space as it wants. It has its own book-keeping stuff and quite often will grab 32-64 bytes minimum.

share|improve this answer
I like this answer because it talks about memory fragmentation and book-keeping. Just because [physical] memory is "there" doesn't mean it is always "available". That is a, malloc can even fail with less data allocated than total memory. (I like the complementing answer about virtual memory and over-committing as well.) – user166390 Feb 1 '12 at 19:22
Are you sure? Can you please see:… – Koray Tugay Apr 13 at 19:25

Unless your memory is already completely reserved (or heavily fragmented), the only way to have malloc() return a NULL-pointer is to request space of size zero:

char *foo = malloc(0);

Citing from the C99 standard, §7.20.3, subsection 1:

If the size of the space requested is zero, the behavior is implementationdefined: either a null pointer is returned, or the behavior is as if the size were some nonzero value, except that the returned pointer shall not be used to access an object.

In other words, malloc(0) may return a NULL-pointer or a valid pointer to zero allocated bytes.

share|improve this answer

Any program at all written in c that needs to dynamically allocate more memory than the OS currently allows.

For fun, if you are using ubuntu type in

 ulimit -v 5000

Any program you run will most likely crash (due to a malloc failure) as you've limited the amount of available memory to any one process to a pithy amount.

share|improve this answer

Since you asked for an example, here's a program that will (eventually) see malloc return NULL:

perror();void*malloc();main(){for(;;)if(!malloc(999)){perror(0);return 0;}}

What? You don't like deliberately obfuscated code? ;) (If it runs for a few minutes and doesn't crash on your machine, kill it, change 999 to a bigger number and try again.)

EDIT: If it doesn't work no matter how big the number is, then what's happening is that your system is saying "Here's some memory!" but so long as you don't try to use it, it doesn't get allocated. In which case:

perror();char*p;void*malloc();main(){for(;;){p=malloc(999);if(p)*p=0;else{perror(0);return 0;}}

Should do the trick. If we can use GCC extentions, I think we can get it even smaller by changing char*p;void*malloc(); to void*p,*malloc(); but if you really wanted to golf you'd be on the Code Golf SE.

share|improve this answer
Although, since the data is not being made "dirty" ... perhaps it's not actually realized in [physical] memory? Not saying that there are infinite resources ... – user166390 Feb 1 '12 at 19:17
@pst - Possibly, but if I add that the code will be too readable. – Chris Lutz Feb 1 '12 at 19:20
The data will be dirty immediately because 999 is smaller than a page. Thus each page will get touched at least once for the bookkeeping structures between allocations. – R.. Feb 1 '12 at 20:04
@R.. - This may be something that merits its own question, if not delving more deeply into the subject of memory management systems, but why don't page-sized allocations need bookkeeping structures? – Chris Lutz Feb 1 '12 at 20:10
@Chris: If the allocation is larger than a page and contains one or more whole pages within the region returned for use by the application, then there's no reason to expect those have been touched. But if you just keep allocating 999 bytes, successive allocations' bookkeeping information will be separated by less than a page and thus you'll end up touching every page that gets allocated. – R.. Feb 1 '12 at 20:24

Yes. Malloc will return NULL when the kernel/system lib are certain that no memory can be allocated.

The reason you typically don't see this on modern machines is that Malloc doesn't really allocate memory, but rather it requests some “virtual address space” be reserved for your program so you might write in it. Kernels such as modern Linux actually over commit, that is they let you allocate more memory than your system can actually provide (swap + RAM) as long as it all fits in the address space of the system (typically 48bits on 64bit platforms, IIRC). Thus on these systems you will probably trigger an OOM killer before you will trigger a return of a NULL pointer. A good example is a 512MB RAM in a 32bit machine: it's trivial to write a C program that will be eaten by the OOM killer because of it trying to malloc all available RAM + swap.

(Overcomitting can be disabled at compile time on Linux, so it depends on the build options whether or not a given Linux kernel will overcommit. However, stock desktop distro kernels do it.)

share|improve this answer
It's disabled at run time not compile time, and most competent admins disable it unless they have a specific reason not to. – R.. Feb 1 '12 at 20:03

On a more-or-less standard system, using a standard one-parameter malloc, there are three possible failure modes (that I can think of):

1) The size of allocation requested is not allowed. Eg, some systems may not allow an allocation > 16M, even if more storage is available.

2) A contiguous free area of the size requested, with default boundary, cannot be located in the heap. There may still be plenty of heap, but just not enough in one piece.

3) The total allocated heap has exceeded some "artificial" limit. Eg, the user may be prohibited from allocation more than 100M, even if there's 200M free and available to the "system" in a single combined heap.

(Of course, you can get combinations of 2 and 3, since some systems allocate non-contiguous blocks of address space to the heap as it grows, placing the "heap size limit" on the total of the blocks.)

Note that some environments support additional malloc parameters such as alignment and pool ID which can add their own twists.

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.