I was trying to figure out how much memory I can malloc to maximum extent on my machine (1 Gb RAM 160 Gb HD Windows platform).

I read that the maximum memory malloc can allocate is limited to physical memory (on heap).

Also when a program exceeds consumption of memory to a certain level, the computer stops working because other applications do not get enough memory that they require.

So to confirm, I wrote a small program in C:

int main(){  
    int *p;
        p=(int *)malloc(4);

I was hoping that there would be a time when memory allocation would fail and the loop would break, but my computer hung as it was an infinite loop.

I waited for about an hour and finally I had to force shut down my computer.

Some questions:

  • Does malloc allocate memory from HD also?
  • What was the reason for above behaviour?
  • Why didn't loop break at any point of time?
  • Why wasn't there any allocation failure?

I read that the maximum memory malloc can allocate is limited to physical memory (on heap).

Wrong: most computers/OSs support virtual memory, backed by disk space.

Some questions: does malloc allocate memory from HDD also?

malloc asks the OS, which in turn may well use some disk space.

What was the reason for above behavior? Why didn't the loop break at any time?

Why wasn't there any allocation failure?

You just asked for too little at a time: the loop would have broken eventually (well after your machine slowed to a crawl due to the large excess of virtual vs physical memory and the consequent super-frequent disk access, an issue known as "thrashing") but it exhausted your patience well before then. Try getting e.g. a megabyte at a time instead.

When a program exceeds consumption of memory to a certain level, the computer stops working because other applications do not get enough memory that they require.

A total stop is unlikely, but when an operation that normally would take a few microseconds ends up taking (e.g.) tens of milliseconds, those four orders of magnitude may certainly make it feel as if the computer had basically stopped, and what would normally take a minute could take a week.

  • Thanx for the info about malloc allocating Disk space. I suspected that, but in many article there was no mention of disk space and was written that malloc alllocates on heap and physical memory. :)
    – Vikas
    May 9 '10 at 17:21
  • @Richie I also suppose that Alex meant 'thrashing' there.
    – Vikas
    May 9 '10 at 17:22
  • @Richie and @Vikas, oops, yes, edited to fix the typo, thanks!-) May 9 '10 at 19:50
  • your memory size is 1GB doesnt mean that malloc will go all the way there. It really depends upon the amount of memory your OS assigns to your process. Which by looking at the code in this case will be very low. From there on it goes on to allocate memory on your virtual memory.
    – Laz
    May 30 '10 at 15:03
  • 3
    Actually on some platforms malloc might succeed even though the requested size exceeds RAM+swap size. On linux for example asking for memory means to map /dev/zero which in turn means just mark up pages as being zero - unless you change the content it doesn't have to consume much memory or swap space.
    – skyking
    Jul 31 '15 at 14:00

I know this thread is old, but for anyone willing to give it a try oneself, use this code snipped

#include <stdlib.h>

int main() {
int *p;
while(1) {
    int inc=1024*1024*sizeof(char);
    p=(int*) calloc(1,inc);
    if(!p) break;


$ gcc memtest.c
$ ./a.out

upon running, this code fills up ones RAM until killed by the kernel. Using calloc instead of malloc to prevent "lazy evaluation". Ideas taken from this thread: Malloc Memory Questions

This code quickly filled my RAM (4Gb) and then in about 2 minutes my 20Gb swap partition before it died. 64bit Linux of course.

  • 2
    I just tried the same program on a machine with 192Gb memory/4Gb swap. Within a minute it consumed up to 175Gb, then the swap was slowly filled. When there were only 24kb of swap left, it got killed.
    – Sebastian
    Jan 22 '13 at 7:59
  • 1
    What you call "lazy evaluation" presumably allows the kernel to use a zero page for each page of allocated but unwritten memory. Compression (especially for swap) and even deduplication (as currently done by some hypervisors) may reduce actual memory required. Of course, malloc has storage overhead, page tables add overhead, the program has non-heap memory, the OS uses memory, etc. Mar 17 '14 at 14:06
  • 1
    A good calloc(3) implementation doesn't touch the pages after it gets them from mmap(2), because they're already zeroed. The reason this actually eventually triggers the OOM killer is that malloc's extra bookkeeping info uses memory. If you strace it, you'll see mmap(NULL, 1052672, PROT_READ|PROT_WRITE, MAP_PRIVATE|MAP_ANONYMOUS, -1, 0) = 0x7f4fc4d14000. The allocation size, 1052672, is 1MiB + 4096, and that extra page is presumably what glibc's malloc actually dirties. e.g. on my desktop with 5GiB of physical memory, I can calloc 16GiB (in 1MiB chunks) without disk activity. Jun 6 '16 at 17:29
  • The untouched virtual pages are all still mapped to the same physical zeroed page. Jun 6 '16 at 17:30

/proc/sys/vm/overcommit_memory controls the maximum on Linux

On Ubuntu 19.04 for example, we can easily see that malloc is implemented with mmap(MAP_ANONYMOUS by using strace.

Then man proc then describes how /proc/sys/vm/overcommit_memory controls the maximum allocation:

This file contains the kernel virtual memory accounting mode. Values are:

  • 0: heuristic overcommit (this is the default)
  • 1: always overcommit, never check
  • 2: always check, never overcommit

In mode 0, calls of mmap(2) with MAP_NORESERVE are not checked, and the default check is very weak, leading to the risk of getting a process "OOM-killed".

In mode 1, the kernel pretends there is always enough memory, until memory actually runs out. One use case for this mode is scientific computing applications that em‐ ploy large sparse arrays. In Linux kernel versions before 2.6.0, any nonzero value implies mode 1.

In mode 2 (available since Linux 2.6), the total virtual address space that can be allocated (CommitLimit in /proc/meminfo) is calculated as

CommitLimit = (total_RAM - total_huge_TLB) * overcommit_ratio / 100 + total_swap


  • total_RAM is the total amount of RAM on the system;
  • total_huge_TLB is the amount of memory set aside for huge pages;
  • overcommit_ratio is the value in /proc/sys/vm/overcommit_ratio; and
  • total_swap is the amount of swap space.

For example, on a system with 16GB of physical RAM, 16GB of swap, no space dedicated to huge pages, and an overcommit_ratio of 50, this formula yields a Com‐ mitLimit of 24GB.

Since Linux 3.14, if the value in /proc/sys/vm/overcommit_kbytes is nonzero, then CommitLimit is instead calculated as:

CommitLimit = overcommit_kbytes + total_swap

See also the description of /proc/sys/vm/admiin_reserve_kbytes and /proc/sys/vm/user_reserve_kbytes.

Documentation/vm/overcommit-accounting.rst in the 5.2.1 kernel tree also gives some information, although lol a bit less:

The Linux kernel supports the following overcommit handling modes

  • 0 Heuristic overcommit handling. Obvious overcommits of address space are refused. Used for a typical system. It ensures a seriously wild allocation fails while allowing overcommit to reduce swap usage. root is allowed to allocate slightly more memory in this mode. This is the default.

  • 1 Always overcommit. Appropriate for some scientific applications. Classic example is code using sparse arrays and just relying on the virtual memory consisting almost entirely of zero pages.

  • 2 Don't overcommit. The total address space commit for the system is not permitted to exceed swap + a configurable amount (default is 50%) of physical RAM. Depending on the amount you use, in most situations this means a process will not be killed while accessing pages but will receive errors on memory allocation as appropriate.

    Useful for applications that want to guarantee their memory allocations will be available in the future without having to initialize every page.

Minimal experiment

We can easily see the maximum allowed value with:


#define _GNU_SOURCE
#include <stdio.h>
#include <stdlib.h>
#include <sys/mman.h>
#include <string.h>
#include <unistd.h>

int main(int argc, char **argv) {
    char *chars;
    size_t nbytes;

    /* Decide how many ints to allocate. */
    if (argc < 2) {
        nbytes = 2;
    } else {
        nbytes = strtoull(argv[1], NULL, 0);

    /* Allocate the bytes. */
    chars = mmap(

    /* This can happen for example if we ask for too much memory. */
    if (chars == MAP_FAILED) {

    /* Free the allocated memory. */
    munmap(chars, nbytes);

    return EXIT_SUCCESS;

GitHub upstream.

Compile and run to allocate 1GiB and 1TiB:

gcc -ggdb3 -O0 -std=c99 -Wall -Wextra -pedantic -o main.out main.c
./main.out 0x40000000
./main.out 0x10000000000

We can then play around with the allocation value to see what the system allows.

I can't find a precise documentation for 0 (the default), but on my 32GiB RAM machine it does not allow the 1TiB allocation:

mmap: Cannot allocate memory

If I enable unlimited overcommit however:

echo 1 | sudo tee /proc/sys/vm/overcommit_memory

then the 1TiB allocation works fine.

Mode 2 is well documented, but I'm lazy to carry out precise calculations to verify it. But I will just point out that in practice we are allowed to allocate about:

overcommit_ratio / 100

of total RAM, and overcommit_ratio is 50 by default, so we can allocate about half of total RAM.

VSZ vs RSS and the out-of-memory killer

So far, we have just allocated virtual memory.

However, at some point of course, if you use enough of those pages, Linux will have to start killing some processes.

I have illustrated that in detail at: What is RSS and VSZ in Linux memory management


Try this

#include <stdlib.h>
#include <stdio.h>

main() {
    int Mb = 0;
    while (malloc(1<<20)) ++Mb;
    printf("Allocated %d Mb total\n", Mb);

Include stdlib and stdio for it.
This extract is taken from deep c secrets.

  • Darn... with a swap of like 100Gb you're going to wait quite a bit of time before you get your result. And better not have anything else running on your computer at that time! May 7 '14 at 21:03
  • 2
    On Linux, with the default virtual memory settings, your program will eventually be killed (with SIGKILL), rather than have malloc actually return NULL. Jun 6 '16 at 17:33
  • 2
    Like others have noted, this won't work as expected. (I guess someone needs to write Deep 'Deep C Secrets' Secrets). It will be killed rather than returning a null pointer. It also may well use swap or even disk-backed space depending on your system. And if your system uses memory overcommit together with lazy evaluation of allocated memory, it can easily appear to support tens of thousands of gigabytes, etc., before triggering the OS logic that says to kill the process for out-of-memory reasons.
    – ely
    Jan 28 '18 at 19:17

malloc does its own memory management, managing small memory blocks itself, but ultimately it uses the Win32 Heap functions to allocate memory. You can think of malloc as a "memory reseller".

The windows memory subsystem comprises physical memory (RAM) and virtual memory (HD). When physical memory becomes scarce, some of the pages can be copied from physical memory to virtual memory on the hard drive. Windows does this transparently.

By default, Virtual Memory is enabled and will consume the available space on the HD. So, your test will continue running until it has either allocated the full amount of virtual memory for the process (2GB on 32-bit windows) or filled the hard disk.


As per C90 standard guarantees that you can get at least one object 32 kBytes in size, and this may be static, dynamic, or automatic memory. C99 guarantees at least 64 kBytes. For any higher limit, refer your compiler's documentation.

Also, malloc's argument is a size_t and the range of that type is [0,SIZE_MAX], so the maximum you can request is SIZE_MAX, which value varies upon implementation and is defined in <limits.h>.


I don't actually know why that failed, but one thing to note is that `malloc(4)" may not actually give you 4 bytes, so this technique is not really an accurate way to find your maximum heap size.

I found this out from my question here.

For instance, when you declare 4 bytes of memory, the space directly before your memory could contain the integer 4, as an indication to the kernel of how much memory you asked for.

  • indeed, malloc usually give a multiple of 16 bytes. There is two reasons. One is that standard says malloc should return a pointer compatible with any data alignment. Thus addresses separated by less than 16 bytes coulnd't be returned. The other reason is that freed blocks usually store some data used for internal memory management and a block too short - say 4 bytes - couldn't store it.
    – kriss
    May 9 '10 at 16:47
  • @kriss [i] freed blocks usually store some data used for internal memory management and a block too short - say 4 bytes - couldn't store it.[/i] Can you mention what kind of data?
    – Vikas
    May 9 '10 at 17:24

when first time you allocate any size to *p, every next time you leave that memory to be unreferenced. That means

at a time your program is allocating memory of 4 bytes only

. then how can you thing you have used entire RAM, that's why SWAP device( temporary space on HDD) is out of discussion. I know an memory management algorithm in which when no one program is referencing to memory block, that block is eligible to allocate for programs memory request. That's why you are just keeping busy to RAM Driver and that's why it can't give chance to service other programs. Also this a dangling reference problem.

Ans : You can at most allocate the memory of your RAM size. Because no program has access to swap device.

I hope your all questions has got satisfactory answers.

  • 3
    That's simply incorrect. I tried to run 8Gb allocations in a loop, it managed to run for 16382 allocations, thats 128Tb - I don't have that much RAM at least. In fact not even that much swap (see my comment to the accepted answer).
    – skyking
    Jul 31 '15 at 14:45
  • Because of compressed memory maybe?
    – JustinCB
    Jun 1 '17 at 16:58
  • "you leave that memory to be unreferenced" there is no reference counting in place here. The memory is not released despite not having anything point to it.
    – olivecoder
    May 3 '19 at 7:50

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