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According to Linux programmers manual:

brk() and sbrk() change the location of the program break, which defines the end of the process's data segment.

What does the data segment mean over here? Is it just the data segment or data, BSS, and heap combined?

According to wiki:

Sometimes the data, BSS, and heap areas are collectively referred to as the "data segment".

I see no reason for changing the size of just the data segment. If it is data, BSS and heap collectively then it makes sense as heap will get more space.

Which brings me to my second question. In all the articles I read so far, author says that heap grows upward and stack grows downward. But what they do not explain is that what happens when heap occupies all the space between heap and stack?

enter image description here

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So what do you do when you're out of space ? you swap to HDD. When you have used space, you release it for other kind of information. – Igoris Azanovas Aug 8 '11 at 21:01
@Igoris: You're confusing physical memory (which you can swap to disk as needed, using virtual memory) and address space. When you fill up your address space, no amount of swapping will give you back those addresses in the middle. – Daniel Pryden Aug 8 '11 at 21:21
Just as a reminder, the brk() system call is more useful in assembly language than in C. In C, malloc() should be used instead of brk() for any data-allocation purposes -- but this does not invalidate the proposed question in any way. – Alek Aug 9 '11 at 0:58
@Brian: The heap is a complex data structure for handling regions of varying sizes and alignments, free pool, etc. Thread stacks are always contiguous (in virtual address space) sequences of complete pages. In most OSes, there's a page allocator underlying stacks, heap, and memory-mapped files. – Ben Voigt Aug 23 '11 at 19:49
@Brian: Who said there's any "Stack" being manipulated by brk() and sbrk()? The stacks are managed by the page allocator, at a much lower level. – Ben Voigt Aug 23 '11 at 20:58
up vote 122 down vote accepted

I see a lot of partial answers but no complete answer. Here's that picture you posted again:

simplified image of virtual memory layout

The "break"--the address manipulated by brk and sbrk--is the dotted line at the top of the heap. The documentation you've read describes this as the end of the "data segment" because in traditional (pre-shared-libraries, pre-mmap) Unix the data segment was continuous with the heap; before program start, the kernel would load the "text" and "data" blocks into RAM starting at address zero (actually a little above address zero, so that the NULL pointer genuinely didn't point to anything) and set the break address to the end of the data segment. The first call to malloc would then use sbrk to move the break up and create the heap in between the top of the data segment and the new, higher break address, as shown in the diagram, and subsequent use of malloc would use it to make the heap bigger as necessary.

Meantime, the stack starts at the top of memory and grows down. The stack doesn't need explicit system calls to make it bigger; either it starts off with as much RAM allocated to it as it can ever have (this was the traditional approach) or there is a region of reserved addresses below the stack, to which the kernel automatically allocates RAM when it notices an attempt to write there (this is the modern approach). Either way, there may or may not be a "guard" region at the bottom of the address space that can be used for stack. If this region exists (all modern systems do this) it is permanently unmapped; if either the stack or the heap tries to grow into it, you get a segmentation fault. Traditionally, though, the kernel made no attempt to enforce a boundary; the stack could grow into the heap, or the heap could grow into the stack, and either way they would scribble over each other's data and the program would crash. If you were very lucky it would crash immediately.

I'm not sure where the number 512GB in this diagram comes from. It implies a 64-bit virtual address space, which is inconsistent with the very simple memory map you have there. A real 64-bit address space looks more like this:

less simplified address space

This is not remotely to scale, and it shouldn't be interpreted as exactly how any given OS does stuff (after I drew it I discovered that Linux actually puts the executable much closer to address zero than I thought it did, and the shared libraries at surprisingly high addresses). The black regions of this diagram are unmapped -- any access causes an immediate segfault -- and they are gigantic relative to the gray areas. The light-gray regions are the program and its shared libraries (there can be dozens of shared libraries); each has an independent text and data segment (and "bss" segment, which also contains global data but is initialized to all-bits-zero rather than taking up space in the executable or library on disk). The heap is no longer necessarily continous with the executable's data segment -- I drew it that way, but it looks like Linux, at least, doesn't do that. The stack is no longer pegged to the top of the virtual address space, and the distance between the heap and the stack is so enormous that you don't have to worry about crossing it.

The break is still the upper limit of the heap. However, what I didn't show is that there could be dozens of independent allocations of memory off there in the black somewhere, made with mmap instead of brk. (The OS will try to keep these far away from the brk area so they don't collide.)

share|improve this answer
+1 for a detailed explanation. Do you know if malloc still relies on brk or if it is using mmap to be able to "give back" separate memory blocks? – Anders Abel Aug 9 '11 at 6:08
It depends on the specific implementation, but IIUC a lot of current mallocs use the brk area for small allocations and individual mmaps for large (say, >128K) allocations. See, for instance, the discussion of MMAP_THRESHOLD in the Linux malloc(3) manpage. – zwol Aug 9 '11 at 15:26
Indeed a good explanation. But as you said that Stack no longer sits at the top of the Virtual address space. Is this true for only 64 bit address space or it is true even for 32 bit address space. And if stack sits at the top of the address space, where does anonymous memory maps happen? Is it at the top of the virtual address space just before stack. – nik Aug 9 '11 at 15:28
@Nikhil: it's complicated. Most 32-bit systems put the stack at the very top of the user-mode address space, which is often only the lower 2 or 3G of the full address space (the remaining space is reserved for the kernel). I can't presently think of one that didn't but I don't know 'em all. Most 64-bit CPUs don't actually let you use the entire 64-bit space; the high 10 to 16 bits of the address have to be all-zero or all-one. The stack is generally placed near the top of the usable low addresses. I can't give you a rule for mmap; it's extremely OS-dependent. – zwol Aug 9 '11 at 16:47
Actually, 512GB implies a 39-bit user address space -- possibly half of a 40-bit address space with the upper half reserved for the kernel. – Chris Dodd Aug 3 '13 at 4:23

You can use brk and sbrk yourself to avoid the "malloc overhead" everyone's always complaining about. But you can't easily use this method in conjuction with malloc so it's only appropriate when you don't have to free anything. Because you can't. Also, you should avoid any library calls which may use malloc internally. Ie. strlen is probably safe, but fopen probably isn't.

Call sbrk just like you would call malloc. It returns a pointer to the current break and increments the break by that amount.

void *myallocate(int n){
    return sbrk(n);

While you can't free individual allocations (because there's no malloc-overhead, remember), you can free the entire space by calling brk with the value returned by the first call to sbrk, thus rewinding the brk.

void *memorypool;
void initmemorypool(void){
    memorypool = sbrk(0);
void resetmemorypool(void){

You could even stack these regions, discarding the most recent region by rewinding the break to the region's start.

One more thing ...

sbrk is also useful in code golf because it's 2 characters shorter than malloc.

share|improve this answer
-1 because: malloc/free most certainly can (and do) give memory back to the OS. They might not always do it when you want them to, but that's a matter of the heuristics being imperfectly tuned for your use case. More importantly, it is unsafe to call sbrk with a nonzero argument in any program that might ever call malloc -- and almost all C library functions are allowed to call malloc internally. The only ones that definitely won't are the async-signal-safe functions. – zwol Aug 3 '13 at 1:39
And by "it is unsafe", I mean "your program will crash." – zwol Aug 3 '13 at 1:39
I've edited to remove the returning memory boast, and mentioned the danger of library functions internally using malloc. – luser droog Aug 3 '13 at 2:14
If you want to do fancy memory allocation, either base it oon top of malloc, or on top of mmap. Don't touch brk and sbrk, they are relics from the past that do more harm than good (even the manpages tell you to stay clear of them!) – Eloff Jan 18 '14 at 23:03
Agreed. For real world use, they're a no-no. But I just wrote a program yesterday which uses them. code-golf, of course. – luser droog Jan 18 '14 at 23:44

There is a special designated anonymous private memory mapping (traditionally located just beyond the data/bss, but modern Linux will actually adjust the location with ASLR). In principle it's no better than any other mapping you could create with mmap, but Linux has some optimizations that make it possible to expand the end of this mapping (using the brk syscall) upwards with reduced locking cost relative to what mmap or mremap would incur. This makes it attractive for malloc implementations to use when implementing the main heap.

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You meant possible to expand the end of this mapping upward, yes? – zwol Aug 9 '11 at 0:35
Yes, fixed. Sorry about that! – R.. Aug 9 '11 at 0:47

Minimal runnable example

What does brk( ) system call do?

Asks the kernel to let you you read and write to a contiguous chunk of memory called the heap.

If you don't ask him, it might segfault you.

Without brk:

#define _GNU_SOURCE
#include <unistd.h>

int main(void) {
    /* Get the first address beyond the end of the heap. */
    void *b = sbrk(0);
    int *p = (int *)b;
    /* Segfault because it is outside of the heap. */
    *p = 1;
    return 0;

With brk:

#define _GNU_SOURCE
#include <assert.h>
#include <unistd.h>

int main(void) {
    void *b = sbrk(0);
    int *p = (int *)b;

    /* Move it 2 ints forward */
    brk(p + 2);

    /* Use the ints. */
    *p = 1;
    *(p + 1) = 2;
    assert(*p == 1);
    assert(*(p + 1) == 2);

    /* Deallocate back. */

    return 0;

See also:

man brk

It used to be POSIX, but was removed in POSIX 2001, thus the need for _GNU_SOURCE to access the glibc wrapper.

Internally, the kernel decides if the process can have that much memory, and earmarks memory pages for that usage.

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Since p is a pointer to type int, shouldn't this have been brk(p + 2); ? – Johan Boule yesterday
@JohanBoule you are right, fixed. – Ciro Santilli 巴拿馬文件 六四事件 法轮功 yesterday

I can answer your second question. Malloc will fail and return a null pointer. That's why you always check for a null pointer when dynamically allocating memory.

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then what's the use of brk and sbrk? – nik Aug 8 '11 at 21:17
@NikhilRathod: malloc() will use brk() and/or sbrk() under the hood -- and you can, too, if you want to implement your own customized version of malloc(). – Daniel Pryden Aug 8 '11 at 21:19
@Daniel Pryden: how can brk and sbrk work on heap when it is between stack and data segment as shown in the diagram above. for this to work heap should be in the end. Am I right? – nik Aug 8 '11 at 21:27
@Brian: Daniel said that the OS manages the stack segment, not the stack pointer ... very different things. The point is that there is no sbrk/brk syscall for the stack segment -- Linux automatically allocates pages upon attempts to write to the end of the stack segment. – Jim Balter Aug 8 '11 at 23:45
And Brian, you only answered half of half of the question. The other half is what happens if you attempt to push onto the stack when no space is available ... you get a segmentation fault. – Jim Balter Aug 8 '11 at 23:49

The heap is placed last in the program's data segment. brk() is used to change (expand) the size of the heap. When the heap cannot grow any more any malloc call will fail.

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So you are saying that all of the diagrams in the internet, like the one in my question are wrong. If possible can you please point me to a correct diagram. – nik Aug 8 '11 at 21:20
@Nikkhil Keep in mind that the top of that diagram is the end of the memory. The top of the stack moves downward on the diagram as the stack grows. The top of the heap moves upward on the diagram as it is expanded. – Brian Gordon Aug 8 '11 at 21:28

The data segment is the portion of memory that holds all your static data, read in from the executable at launch and usually zero-filled.

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It also holds uninitialized static data (not present in the executable) which may be garbage. – luser droog Aug 9 '11 at 6:16
Uninitialized static data (.bss) is initialized to all-bits-zero by the OS before program start; this is actually guaranteed by the C standard. Some embedded systems might not bother, I suppose (I've never seen one, but I don't work all that embedded) – zwol Aug 9 '11 at 16:50
@zwol: Linux has a compile-time option to not zero pages returned by mmap, but I'd assume the .bss would still be zeroed. BSS space is probably the most compact way to express the fact that a program wants some zerod arrays. – Peter Cordes Oct 1 '15 at 12:06
@PeterCordes What the C standard says is that global variables declared with no initializer are treated as-if initialized to zero. A C implementation that puts such variables in .bss and doesn't zero .bss would therefore be nonconforming. But nothing forces a C implementation to use .bss at all or even have such a thing. – zwol Oct 1 '15 at 17:12
@PeterCordes Also, the line between the "C implementation" and the program can be very fuzzy, e.g. there's usually a small chunk of code from the implementation, statically linked into each executable, that runs before main; that code could zero out the .bss area rather than having the kernel do it, and that would still be conforming. – zwol Oct 1 '15 at 17:16

malloc uses brk system call to allocate memory.


int main(void){

char *a = malloc(10); 
return 0;

run this simple program with strace, it will call brk system.

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  1. The system call that handles memory allocation is sbrk(2). It increases or decreases the address space of the process by a specified number of bytes.

  2. The memory allocation function, malloc(3), implements one particular type of allocation. malloc() function, which will probably use the sbrk() system call.

The system call sbrk(2) in the kernel allocates an additional chunk of space on behalf of the process. The malloc() library function manages this space from user level.

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