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Just curious, what actually happens if I define a zero-length array int array[0]; in code? GCC doesn't complain at all.

Sample Program

#include <stdio.h>

int main() {
    int arr[0];
    return 0;


I'm actually trying to figure out if zero-length arrays initialised this way, instead of being pointed at like the variable length in Darhazer's comments, are optimised out or not.

This is because I have to release some code out into the wild, so I'm trying to figure out if I have to handle cases where the SIZE is defined as 0, which happens in some code with a statically defined int array[SIZE];

I was actually surprised that GCC does not complain, which led to my question. From the answers I've received, I believe the lack of a warning is largely due to supporting old code which has not been updated with the new [] syntax.

Because I was mainly wondering about the error, I am tagging Lundin's answer as correct (Nawaz's was first, but it wasn't as complete) -- the others were pointing out its actual use for tail-padded structures, while relevant, isn't exactly what I was looking for.

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@AlexanderCorwin: Unfortunately in C++, with undefined behavior, non-standard extensions, and other anomalies, trying something out yourself is often not a path to knowledge. –  Benjamin Lindley Mar 15 '12 at 15:19
stackoverflow.com/a/4288868/797303 - this as well –  Darhazer Mar 15 '12 at 15:19
@JustinKirk I just got trapped by that too by testing and seing it worked. And due to the criticism I received in my post, I learnt that testing and seing it working does not mean it is valid and legal. So a self test is not valid sometimes. –  StormByte Mar 15 '12 at 15:39
@JustinKirk, see Matthieu's answer for an example of where you would use it. It also might come in handy in a template where the array size is a template parameter. The example in the question is obviously out of context. –  Mark Ransom Mar 15 '12 at 15:49
What is "C/C++"? These are two separate languages –  Lightness Races in Orbit Mar 15 '12 at 21:32

6 Answers 6

up vote 52 down vote accepted

An array cannot have zero size.

ISO 9899:2011

If the expression is a constant expression, it shall have a value greater than zero.

The above text is true both for a plain array (§1) and a VLA (§5). This is normative text in the C standard. A compiler is not allowed to implement it differently.

gcc -std=c99 -pedantic gives a warning for this.

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"it must actually give an error" - the distinction between "warnings" and "errors" isn't recognized in the standard (it only mentions "diagnostics"), and the only situation where compilation must stop [i.e. the real-world difference between warning and error] is on encountering an #error directive. –  Random832 Mar 15 '12 at 16:06
FYI, as a general rule, the (C or C++) standards only state what compilers must allow, but not what they must disallow. In some cases, they will state that the compiler should issue a "diagnostic" but that's about as specific as they get. The rest is left to the compiler vendor. EDIT: What Random832 said too. –  mcmcc Mar 15 '12 at 16:09
@Lundin "A compiler isn't allowed to build a binary containing zero-length arrays." The standard says absolutely nothing of the sort. It only says that it must generate at least one diagnostic message when given source code containing an array with a zero-length constant expression for its size. The only circumstance under which the standard forbids a compiler to build a binary is if it encounters an #error preprocessor directive. –  Random832 Mar 16 '12 at 12:45
@Lundin Generating a binary for all correct cases satisfies #1, and generating or not generating one for incorrect cases would not affect it. Printing a warning is sufficient for #3. This behavior has no relevance to #2, since the standard does not define the behavior of this source code. –  Random832 Mar 16 '12 at 14:06
@Lundin: The point is that your statement is mistaken; conforming compilers are allowed to build a binary containing a zero-length arrays, as long as a diagnostic is issued. –  Keith Thompson Mar 24 '12 at 7:29

In Standard C and C++, zero-size array is not allowed..

If you're using GCC, compile it with -pedantic option. It will give warning, saying:

zero.c:3:6: warning: ISO C forbids zero-size array 'a' [-pedantic]

In case of C++, it gives similar warning.

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In Visual C++ 2010: error C2466: cannot allocate an array of constant size 0 –  Mark Ransom Mar 15 '12 at 15:17
-Werror simply turns all warnings into errors, that doesn't fix the incorrect behavior of the GCC compiler. –  Lundin Mar 15 '12 at 15:42
C++ Builder 2009 also correctly gives an error: [BCC32 Error] test.c(3): E2021 Array must have at least one element –  Lundin Mar 15 '12 at 15:43
Apparently zero-sized arrays will be allowed in C++11. –  Almo Mar 15 '12 at 15:50
A zero-sized array is not quite the same thing as a zero-sized std::array. (Aside: I recall but can't find the source that VLAs were considered and explicitly rejected from being in C++.) –  user79758 Mar 15 '12 at 17:17

Normally, it is not allowed.

However it's been current practice in C to use flexible arrays.

C99, §16: As a special case, the last element of a structure with more than one named member may have an incomplete array type; this is called a flexible array member.


struct Array {
  size_t size;
  int content[];

The idea is that you would then allocate it so:

void foo(size_t x) {
  Array* array = malloc(sizeof(size_t) + x * sizeof(int));

  array->size = x;
  for (size_t i = 0; i != x; ++i) {
    array->content[i] = 0;

You might also use it statically (gcc extension):

Array a = { 3, { 1, 2, 3 } };

This is also known as tail-padded structures (this term predates the publication of the C99 Standard) or struct hack (thanks to Joe Wreschnig for pointing it out).

However this syntax was standardized (and the effects guaranteed) only lately in C99. Before a constant size was necessary.

  • 1 was the portable way to go, though it was rather strange
  • 0 was better at indicating intent, but not legal as far as the Standard was concerned and supported as an extension by some compilers (including gcc)

The tail padding practice, however, relies on the fact that storage is available (careful malloc) so is not suited to stack usage in general.

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+1: good answer, comprehensively covering just about the only use case I can think of for a zero length array –  Paul R Mar 15 '12 at 15:28
@Lundin: I have not seen any VLA here, all the sizes are known at compile time. The flexible array term comes from gcc.gnu.org/onlinedocs/gcc-4.1.2/gcc/Zero-Length.html and doe qualify int content[]; here as far as I understand. Since I am not too savvy on C terms of the art... could you confirm whether my reasoning seems correct ? –  Matthieu M. Mar 15 '12 at 16:03
@MatthieuM.: C99, §16: As a special case, the last element of a structure with more than one named member may have an incomplete array type; this is called a flexible array member. –  Christoph Mar 15 '12 at 16:10
@Christoph: Thanks a lot, I will steal this if you don't mind ;) –  Matthieu M. Mar 15 '12 at 16:20
This idiom is also known by the name "struct hack", and I've met more people familiar with that name than "tail-padded structure" (never heard it before except maybe as a generic reference to padding a struct for future ABI compatibility) or "flexible array member" which I first heard in C99. –  user79758 Mar 15 '12 at 17:04

It's totally illegal, and always has been, but a lot of compilers neglect to signal the error. I'm not sure why you want to do this. The one use I know of is to trigger a compile time error from a boolean:

char someCondition[ condition ];

If condition is a false, then I get a compile time error. Because compilers do allow this, however, I've taken to using:

char someCondition[ 2 * condition - 1 ];

This gives a size of either 1 or -1, and I've never found a compiler which would accept a size of -1.

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This is an interesting hack to use it for. –  Alex Koay Mar 15 '12 at 15:49
It's a common trick in metaprogramming, I think. I wouldn't be surprised if the implementations of STATIC_ASSERT used it. –  James Kanze Mar 15 '12 at 16:02

I'll add that there is a whole page of the online documentation of gcc on this argument.

Some quotes:

Zero-length arrays are allowed in GNU C.

In ISO C90, you would have to give contents a length of 1


GCC versions before 3.0 allowed zero-length arrays to be statically initialized, as if they were flexible arrays. In addition to those cases that were useful, it also allowed initializations in situations that would corrupt later data

so you could

int arr[0] = { 1 };

and boom :-)

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Zero-size array declarations within structs would be useful if they were allowed, and if the semantics were such that (1) they would force alignment but otherwise not allocate any space, and (2) indexing the array would be considered defined behavior in the case where the resulting pointer would be within the same block of memory as the struct. Such behavior was never permitted by any C standard, but some older compilers allowed it before it became standard for compilers to allow incomplete array declarations with empty brackets.

The struct hack, as commonly implemented using an array of size 1, is dodgy and I don't think there's any requirement that compilers refrain from breaking it. For example, I would expect that if a compiler sees int a[1], it would be within its rights to regard a[i] as a[0]. If someone tries to work around the alignment issues of the struct hack via something like

typedef struct {
  uint32_t size;
  uint8_t data[4];  // Use four, to avoid having padding throw off the size of the struct

a compiler might get clever and assume the array size really is four:

; As written
  foo = myStruct->data[i];
; As interpreted (assuming little-endian hardware)
  foo = ((*(uint32_t*)myStruct->data) >> (i << 3)) & 0xFF;

Such an optimization might be reasonable, especially if myStruct->data could be loaded into a register in the same operation as myStruct->size. I know nothing in the standard that would forbid such optimization, though of course it would break any code which might expect to access stuff beyond the fourth element.

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