What is the difference between xmalloc() and malloc() for memory allocation?
Is there any pro of using xmalloc()?

  • 2
    malloc() exists in standard C. xmalloc() doesn't. Where is this xmalloc() function defined? Sep 28, 2011 at 22:16
  • 4
    Where did you see this xmalloc? And the main difference between the two is that malloc is part of the C standard and xmalloc isn't
    – Praetorian
    Sep 28, 2011 at 22:16
  • Here's an example of xmalloc in use: github.com/kanwei/algorithms/blob/…
    – film42
    Apr 22, 2015 at 17:54
  • then @KeithThompson should we use malloc and not xmalloc() ? if yes tell why?
    – simon
    Mar 11, 2020 at 18:05
  • @simon See the accepted answer. I have nothing to add to it. Mar 11, 2020 at 18:40

6 Answers 6


xmalloc() is a non-standard function that has the motto succeed or die. If it fails to allocate memory, it will terminate your program and print an error message to stderr.

The allocation itself is no different; only the behaviour in the case that no memory could be allocated is different.

Use malloc(), since it's more friendly and standard.

  • 1
    Learned something new. Thanks! I'd just explain xmalloc and leave it at that. Or perhaps say, use whatever makes sense to your situation. For instance if I'm writing a program for a specific OS and it's not mission-critical that I don't mind losing data in OOM, xmalloc makes sense.
    – legends2k
    Dec 27, 2021 at 9:38

xmalloc is not part of the standard library. It's usually the name of a very harmful function for lazy programmers that's common in lots of GNU software, which calls abort if malloc fails. Depending on the program/library, it might also convert malloc(0) into malloc(1) to ensure that xmalloc(0) returns a unique pointer.

In any case, aborting on malloc failure is very very bad behavior, especially for library code. One of the most infamous examples is GMP (the GNU multiprecision arithmetic library), which aborts the calling program whenever it runs out of memory for a computation.

Correct library-level code should always handle allocation failures by backing out whatever partially-completed operation it was in the middle of and returning an error code to the caller. The calling program can then decide what to do, which will likely involve saving critical data.

  • 8
    Of course, saving critical data and pretty much anything else which the calling program may want to do also requires allocating memory pages (even if you don't actually do allocate yourself, library functions need to do so). I don't think it's very likely that you can recover in any case. May 19, 2014 at 9:20
  • 6
    If it does then you're doing it wrong. There's no legitimate need for serialization to use any new allocations. May 19, 2014 at 11:37
  • 47
    Calling developers that use xmalloc() 'lazy programmers' is unfair. Detecting allocation errors is not always possible. Isn't it a waste of time and money to bloat your code base with checks on the return value of malloc() if your target OS is one where malloc() (essentially) never fails due to overcommit being enabled? Coding an in-house level editor for a game as though it were an air traffic control system just drives up the cost with no real benefit. Outside of safety-critical systems, it's okay to be 'lazy' sometimes, IMHO.
    – evadeflow
    Jun 13, 2014 at 22:41
  • 12
    @evadeflow: Tell that to the person who loses their document due to accidentally opening a second document that's too large to fit in memory (happened just yesterday to someone who doesn't believe me on this issue). Jun 13, 2014 at 23:23
  • 12
    @evadeflow: That's a valid approach at the application level, but not at the library level. It's not reasonable for a library (e.g. glib) to assume the calling application does not have any non-journaled data it doesn't care about losing. And if a library is going to behave this way, it should document that requirement prominently rather than hiding it in the documentation for the allocation functions. Of course they won't do that, because nobody would knowingly use a library documented as such; to get people to use such a low-quality library you have to hide the issue. Jun 16, 2014 at 17:04

As others have mentioned, it's true that xmalloc is very often implemented as a wrapper function that invokes the OS-supplied malloc and blindly calls abort or exit if it fails. However, many projects contain an xmalloc function that tries to save application state before exiting (see, for example, neovim).

Personally, I think of xmalloc as a kind of project-specific extended malloc rather than an exiting malloc. Though I don't recall ever seeing a version that didn't wind up calling abort or exit, some of them do a lot more than that.

So the answer to the question "What's the difference between xmalloc and malloc is: it depends. xmalloc is a non-standard, project-specific function, so it could do anything at all. The only way to know for sure is to read the code.


xmalloc is part of libiberty

https://gcc.gnu.org/onlinedocs/libiberty/index.html which is a GNU utils library.

malloc is ANSI C.

xmalloc is often included in-source in many important GNU projects, including GCC and Binutils, both of which use it a lot. But it is also possible to build it as a dynamic library to use in your programs. E.g. Ubuntu has the libiberty-dev package.

xmalloc is documented at: https://gcc.gnu.org/onlinedocs/libiberty/Functions.html and on GCC 5.2.0 it is implemented on libiberty/xmalloc.c

xmalloc (size_t size)
  PTR newmem;

  if (size == 0)
    size = 1;
  newmem = malloc (size);
  if (!newmem)
    xmalloc_failed (size);

  return (newmem);

xmalloc_failed (size_t size)
#ifdef HAVE_SBRK
  extern char **environ;
  size_t allocated;

  if (first_break != NULL)
    allocated = (char *) sbrk (0) - first_break;
    allocated = (char *) sbrk (0) - (char *) &environ;
  fprintf (stderr,
       "\n%s%sout of memory allocating %lu bytes after a total of %lu bytes\n",
       name, *name ? ": " : "",
       (unsigned long) size, (unsigned long) allocated);
#else /* HAVE_SBRK */
  fprintf (stderr,
       "\n%s%sout of memory allocating %lu bytes\n",
       name, *name ? ": " : "",
       (unsigned long) size);
#endif /* HAVE_SBRK */
  xexit (1);

/* This variable is set by xatexit if it is called.  This way, xmalloc
   doesn't drag xatexit into the link.  */
void (*_xexit_cleanup) (void);

xexit (int code)
  if (_xexit_cleanup != NULL)
    (*_xexit_cleanup) ();
  exit (code);

Which as others mentioned, is pretty straightforward:

  • try malloc
  • if it fails
    • print error messages
    • call exit
  • why the f are they not using __builtin_expect here? with that code, it will do an extra jmp every time it succeeds... it should be the other way around (do an extra jmp every time it fails)
    – hanshenrik
    May 12, 2018 at 8:48
  • @hanshenrik if you benchmark it and notice a difference, describe me the setup and I'll mention at: stackoverflow.com/questions/7346929/… :-) May 12, 2018 at 9:13
  • 1
    unfortunately, benchmarking it is difficult because of the size of the branch predictor of modern CPUs. to see a difference, you'll probably need to do so much in between each invocation of xmalloc that the branch predictor has forgotten which branch was taken the last time.. =/
    – hanshenrik
    May 12, 2018 at 9:25
  • @hanshenrik I know :-) And then it won't be measurable most likely. May 12, 2018 at 9:27

an primitive example of xmalloc.c in K&R C

#include <stdio.h>
extern char *malloc ();
void *
xmalloc (size)
    unsigned size;
  void *new_mem = (void *) malloc (size);
  if (new_mem == NULL)    
      fprintf (stderr, "fatal: memory exhausted (xmalloc of %u bytes).\n", size);
      exit (-1);
  return new_mem;

then in your code header (early) you put

#define malloc(m) xmalloc(m)

to silently rewrite the source before compilation. (you can see the rewritten code by invoking the C preprocessor directly and saving the output. )

if crashing your program is not what you want you can do something different

  • Use a garbage collector
  • redesign your code to be less of a memory hog
  • have error checking code in your program to handle an Out of Memory or other allocation error gracefully.

Users don't enjoy losing their data to a built-in crash command in their program.

  • 1
    @MilesRout: it's K&R C - very old stuff.
    – orlp
    Feb 4, 2013 at 20:25
  • +1, but garbage collection and C probably don't go very well together.
    – thb
    Dec 13, 2016 at 14:17
  • 2
    @thb In specialized applications it could be nice. Sure, it won't work for everything but there are things where it works nicely. ALSO... Well, garbage collection in a language's runtime is garbage collection in C as the runtime itself is written in C. Apr 3, 2019 at 16:29

I have seen xmalloc while working on IBM AIX. xmalloc is a kernel service provided by AIX.

Nothing can explain a function better than the function's man page in my opinion. So I am pasting the below details from the man page

Purpose: Allocates memory.


caddr_t xmalloc ( size, align, heap)


size: Specifies the number of bytes to allocate.

align: Specifies the alignment characteristics for the allocated memory.

heap : Specifies the address of the heap from which the memory is to be allocated.


The xmalloc kernel service allocates an area of memory out of the heap specified by the heap parameter. This area is the number of bytes in length specified by the size parameter and is aligned on the byte boundary specified by the align parameter. The align parameter is actually the log base 2 of the desired address boundary. For example, an align value of 4 requests that the allocated area be aligned on a 2^4 (16) byte boundary.

There are multiple heaps provided by the kernel for use by kernel extensions. Two primary kernel heaps are kernel_heap and pinned_heap. Kernel extensions should use the kernel_heap value when allocating memory that is not pinned, and should use the pinned_heap value when allocating memory that should always be pinned or pinned for long periods of time. When allocating from the pinned_heap heap, the xmalloc kernel service will pin the memory before a successful return. The pin and unpin kernel services should be used to pin and unpin memory from the kernel_heap heap when the memory should only be pinned for a limited amount of time. Memory from the kernel_heap heap must be unpinned before freeing it. Memory from the pinned_heap heap should not be unpinned.

If one is interested in knowing more about this function can visit the following link: IBM AIX Support

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