I wrote a C program that accepts integer input from the user, that is used as the size of an integer array, and using that value it declares an array of given size, and I am confirming it by checking the size of the array.


#include <stdio.h>
int main(int argc, char const *argv[])
    int n;
    int k[n];
    return 0;

and surprisingly it is correct! The program is able to create the array of required size.
But all static memory allocation is done at compile time, and during compile time the value of n is not known, so how come the compiler is able to allocate memory of required size?

If we can allocate the required memory just like that then what is the use of dynamic allocation using malloc() and calloc()?

  • 1
    Why would you do that, instead of the normal "k = (int *) calloc (n, sizeof (int));"? Just to obfuscate your code?
    – jamesqf
    Sep 24, 2017 at 17:51
  • 30
    @jamesqf How is int k[n]; an obfuscated version of k = (int *) calloc (n, sizeof (int));? I think the former is more readable (if you know VLAs exist).
    – jcai
    Sep 24, 2017 at 19:38
  • 5
    @jamesqf: performance. With n loaded into rsi (ready to be the 2nd arg to printf in the x86-64 SysV ABI), sub rsp, rsi (one simple asm instruction) is much cheaper than a function-call to calloc. Although in this case, k[] itself isn't used, only sizeof(k), so a good compiler won't bother actually reserving stack space before calling printf. Stack memory already hot in L1D cache, and the TLB, so it's a good place for small buffers. It's also extremely cheap to release it, and you can't every get it wrong because the compiler does it for you. Sep 24, 2017 at 23:21
  • 3
    @jamesqf: It doesn't check the size, and it doesn't fail gracefully. It's up to the programmer not to write programs that use a VLA that's too large for the implementations they care about running on. (e.g. 8MB stack size in new user-space threads on Linux x86-64). Generally you segfault if you touch memory below the bottom of the stack and the OS decides that's too much and doesn't grow your stack mapping. It's a bad idea to use a large VLA in a non-leaf function with children that might also use VLAs. Sep 25, 2017 at 12:52
  • 1
    @jamesqf: That sounds like it's a lot worse than new / delete, but with modern OSes that overcommit memory, it's barely any worse. You can allocate much more RAM than the OS has physical RAM + swap space, and touching it all might result in the kernel deciding to kill your process. (Linux calls this the OOM killer). linuxdevcenter.com/pub/a/linux/2006/11/30/…. You can make allocation fail gracefully by setting limits on the amount of virtual memory a process can allocate, though, so malloc will actually return NULL, but this isn't the default. Sep 25, 2017 at 13:02

5 Answers 5


This is not a "static memory allocation". Your array k is a Variable Length Array (VLA), which means that memory for this array is allocated at run time. The size will be determined by the run-time value of n.

The language specification does not dictate any specific allocation mechanism, but in a typical implementation your k will usually end up being a simple int * pointer with the actual memory block being allocated on the stack at run time.

For a VLA sizeof operator is evaluated at run time as well, which is why you obtain the correct value from it in your experiment. Just use %zu (not %ld) to print values of type size_t.

The primary purpose of malloc (and other dynamic memory allocation functions) is to override the scope-based lifetime rules, which apply to local objects. I.e. memory allocated with malloc remains allocated "forever", or until you explicitly deallocate it with free. Memory allocated with malloc does not get automatically deallocated at the end of the block.

VLA, as in your example, does not provide this "scope-defeating" functionality. Your array k still obeys regular scope-based lifetime rules: its lifetime ends at the end of the block. For this reason, in general case, VLA cannot possibly replace malloc and other dynamic memory allocation functions.

But in specific cases when you don't need to "defeat scope" and just use malloc to allocate a run-time sized array, VLA might indeed be seen as a replacement for malloc. Just keep in mind, again, that VLAs are typically allocated on the stack and allocating large chunks of memory on the stack to this day remains a rather questionable programming practice.

  • 6
    @Rahul: C does not support static VLAs. If n is a run-time value, then static int k[n] is not allowed. But even if it were allowed, it wouldn't allocate a new memory block every time. Meanwhile. malloc allocates a new block every time you call it. So, there's no similarity to malloc here even with static. Sep 24, 2017 at 6:26
  • 2
    The wording in "in a typical implementation your k will end up being a simple int * pointer" seems a bit risky. There's plenty of confusion about pointers and arrays out and about as is. Sep 24, 2017 at 6:30
  • 5
    @Rahul: VLA were introduced in C99 standard. Formally, they have been around for about 18 years now. Of course, compiler support took some time. Sep 24, 2017 at 6:31
  • 3
    Well I definitely wouldn't call this an *int * pointer" because there is no such C object here. Sep 24, 2017 at 7:52
  • 2
    @rcgldr: VLA is very similar to alloca and is definitely "inspired" by alloca. However, alloca allocates memory with "function" lifetime: the memory persists until the function exits. I.e. it ignores all block boundaries besides the outermost one - the function body itself. Meanwhile VLA has normal block-based lifetime. In this regard VLA is very different from alloca. It is true that Visual Studio does not support VLA to this day. However, it is worth nothing that since C11 VLA is an optional feature of the language. Sep 25, 2017 at 3:52

In C, the means by which a compiler supports VLAs (variable length arrays) is up to the compiler - it doesn't have to use malloc(), and can (and often does) use what is sometimes called "stack" memory - e.g. using system specific functions like alloca() that are not part of standard C. If it does use stack, the maximum size of an array is typically much smaller than is possible using malloc(), because modern operating systems allow programs a much smaller quota of stack memory.

  • 2
    Modern operating systems (and even old and embedded OS's in some cases) allow user configuration of the stack size
    – M.M
    Sep 24, 2017 at 23:59

Memory for variable length arrays clearly can't be statically allocated. It can however be allocated on the stack. Generally this involves the use of a "frame pointer" to keep track of the location of the functions stack frame in the face of dynamicly determined changes to the stack pointer.

When I try to compile your program it seems that what actually happens is that the variable length array got optimised out. So I modified your code to force the compiler to actually allocate the array.

#include <stdio.h>
int main(int argc, char const *argv[])
    int n;
    int k[n];
    printf("%s %ld",k,sizeof(k));
    return 0;

Godbolt compiling for arm using gcc 6.3 (using arm because I can read arm ASM) compiles this to https://godbolt.org/g/5ZnHfa. (comments mine)

        push    {fp, lr}      ; Save fp and lr on the stack
        add     fp, sp, #4    ; Create a "frame pointer" so we know where
                              ; our stack frame is even after applying a 
                              ; dynamic offset to the stack pointer.
        sub     sp, sp, #8    ; allocate 8 bytes on the stack (8 rather
                              ; than 4 due to ABI alignment
                              ; requirements)
        sub     r1, fp, #8    ; load r1 with a pointer to n
        ldr     r0, .L3       ; load pointer to format string for scanf
                              ; into r0
        bl      scanf         ; call scanf (arguments in r0 and r1)
        ldr     r2, [fp, #-8] ; load r2 with value of n
        ldr     r0, .L3+4     ; load pointer to format string for printf
                              ; into r0
        lsl     r2, r2, #2    ; multiply n by 4
        add     r3, r2, #10   ; add 10 to n*4 (not sure why it used 10,
                              ; 7 would seem sufficient)
        bic     r3, r3, #7    ; and clear the low bits so it is a
                              ; multiple of 8 (stack alignment again) 
        sub     sp, sp, r3    ; actually allocate the dynamic array on
                              ; the stack
        mov     r1, sp        ; store a pointer to the dynamic size array
                              ; in r1
        bl      printf        ; call printf (arguments in r0, r1 and r2)
        mov     r0, #0        ; set r0 to 0
        sub     sp, fp, #4    ; use the frame pointer to restore the
                              ; stack pointer
        pop     {fp, lr}      ; restore fp and lr
        bx      lr            ; return to the caller (return value in r0)
        .word   .LC0
        .word   .LC1
        .ascii  "%d\000"
        .ascii  "%s %ld\000"

The memory for this construct, which is called "variable length array", VLA, is allocated on the stack, in a similar way to alloca. Exactly how this happens depends on exactly which compiler you're using, but essentially it's a case of calculating the size when it is known, and then subtracting [1] the total size from the stack-pointer.

You do need malloc and friends because this allocation "dies" when you leave the function. [And it's not valid in standard C++]

[1] For typical processors that use a stack that "grows towards zero".

  • In C++, as I’m sure you know, you would use std::vector for an array whose size you can determine at runtime, and whose lifetime is the current scope. You can also use std::vector for many other purposes. So there is a close substitute.
    – Davislor
    Sep 24, 2017 at 14:50
  • @Davislor although this wont be on the stack.
    – lalala
    Sep 24, 2017 at 15:28
  • @lalala std::vector allows you to specify the std::allocator it will use. IIRC, although I don’t think the standard ever gives you a guarantee that something uses a stack. But if you really want a std::vector that calls alloca(), you can get one. (You normally wouldn’t, though, because they could be resized.) I’m pretty sure an implementation could even write its C runtime in C++ and implement C VLAs with a C++ std::vector under the hood!
    – Davislor
    Sep 24, 2017 at 16:57
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    @Davislor: std::get_temporary_buffer is nothing like a VLA or alloca in gcc/clang. They try successively smaller new: godbolt.org/g/VTfNzi, following the letter of the standard and trying to allocate something even if it's smaller than requested. You have to free with std::return_temporary_buffer. (OTOH, if a compiler can prove that a pointer doesn't escape, then it could just reserve stack space and make the return_temporary_buffer a no-op. But real compilers don't.) Sep 24, 2017 at 23:58
  • 1
    longjmp is explicitly not required to free VLA storage. This is called out in C11 I assume this is specifically to allow compilers to implement VLAs in the same way they would implement std::vector, or as malloc/free pairs, in situations where stack allocation is difficult.
    – Leushenko
    Sep 25, 2017 at 11:30

When it is said that the compiler allocates memory for variables at compile time, it means that the placement of those variables is decided upon and embedded in the executable code that the compiler generates, not that the compiler is making space for them available while it works. The actual dynamic memory allocation is carried out by the generated program when it runs.

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