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When I'm looking the Linux kernel code, found the below code:

   struct thread_info {
    struct task_struct  *task;
    struct exec_domain  *exec_domain;
    unsigned long       flags;
    __u32           status;
    __u32           cpu;
    int         preempt_count;
    mm_segment_t        addr_limit;
    struct restart_block    restart_block;
    void __user     *sysenter_return;
    unsigned long           previous_esp;
    __u8            supervisor_stack[0];
};

Notice that the last variable "supervisor_stack", it is a zero length array, what is the usage of it? Thanks in advance!

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marked as duplicate by Shahbaz, Patrick B., Book Of Zeus, Kent Fredric, Pigueiras Nov 16 '13 at 22:02

This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.

    
I think think that means zero length array, I think it means it is getting or retrieving the first value of the array. –  Ryan Fung Jul 31 '12 at 5:58

4 Answers 4

up vote 12 down vote accepted

It's the pre-C99 version of a flexible array member, offered by gcc as an extension.

The C99 way is to define the flexible array member with empty brackets,

__u8  supervisor_stack[];

It's used to store data whose amount is not constant contiguous to the struct. Memory is allocated in the form

struct foo *ptr = malloc(sizeof *ptr + whatever_is_needed);

In paragraph 18 of 6.7.2.1, the standard (draft N1570) describes them:

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. In most situations, the flexible array member is ignored. In particular, the size of the structure is as if the flexible array member were omitted except that it may have more trailing padding than the omission would imply. However, when a . (or ->) operator has a left operand that is (a pointer to) a structure with a flexible array member and the right operand names that member, it behaves as if that member were replaced with the longest array (with the same element type) that would not make the structure larger than the object being accessed; the offset of the array shall remain that of the flexible array member, even if this would differ from that of the replacement array. If this array would have no elements, it behaves as if it had one element but the behavior is undefined if any attempt is made to access that element or to generate a pointer one past it.

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This is an excellent question. Zero-length arrays, also known as flexible arrays, are used to implement variable-length arrays, primarily in structures.

That's a little confusing, so let's look at an example. Say you wanted a structure to represent an email:

struct email {

time_t send_date;

int flags;

int length;

char body[EMAIL_BODY_MAX];

};

Yes, we're missing a lot of fields. This is just an example; bear with me.

This structure has a problem: Each structure consumes those

EMAIL_BODY_MAX

bytes, even if you have a one-word email. Unfortunately email size is highly variable: Some emails are but a single word while others are many paragraphs. Not only do we often end up wasting most of those

EMAIL_BODY_MAX

bytes, but we have to make the constant large, too. Worse, there really isn't a limit on email body length, so we'd prefer not to impose one.

Zero-length arrays solve this:

struct email {

time_t send_date;

int flags;

int length;

char body[];

};

If you allocated this structure the usual way, you'd see body doesn't consume any memory:

struct email *email = malloc (sizeof (struct email));

Here, body is zero-length. You can't legally access any memory at body

. In fact, on Linux/x86-32 this structure is just 12 bytes in length, the size of the first three fields.

But that isn't how you'd allocate these. Instead, you'd do this:

/* we have an email of email_length bytes ... */

struct email *email = malloc (sizeof (struct email) + email_length);

email->length = email_length;

Voila. We now have a structure with an extra length bytes on the end. You can access body as if it were the length-byte array body[length]

. If length were, say, 16, then body would be 16 bytes in length and our total structure would be 28 bytes. Thus, you can look at zero-length arrays as a pointer whose contents are inlined at itself.

An astute reader is now asking, Why not just return a pointer to an email body of dynamic length? If doing so is possible, that is absolutely preferred. Indeed, zero-length arrays are useful only in cases where you have a large structure, which contains a field of dynamic length, and you need to share that structure across program or even computer boundaries. For example, I used a zero-length array in the Linux kernel's implementation of inotify. It was actually the first zero-length array I had ever seen!

struct inotify_event {

int wd;

uint32_t mask;

uint32_t cookie;

uint32_t len;

char name[];

};

This structure represents an inotify event, which is an action such as was written to and a target filename such as

/home/rlove/wolf.txt

. You can see the problem: How big should I have made name

? Filenames can be any size. Worse, filesystems vary in their maximum filename length (

PATH_MAX isn't a limit, just a lazy man's constant). Now, if I was only returning the filename, I could have simply returned a dynamically-allocated char *

. But I had to return this giant structure. Moreover, I was implementing a system call, so I couldn't allocate pointers inside of the structure, since they wouldn't point at memory in the user's address space. My options were limited. A zero-length array was a perfect solution.

An inotify user would receive this structure via a read() call on an inotify file descriptor. The structure is effectively variable in length. The user would read the len parameter to find the size of name and thus the total size of the structure they just read. The length field is effectively require; otherwise the users of structures with zero-length arrays won't know the size of the variable-length array and thus the structure itself.

Bonus discussion: In this case, len needn't be equal to strlen ( name )

. Inotify lets you read multiple structures at once. This means I needed to pad the end of name out so that the sizeof (inotify_event) would properly align multiple structures if stored in an array. Consequently len is usually larger than the filename as there is a handful of extra nul bytes, padding out the structure such that the next struct inotify_event is itself correctly aligned.

Note: The type name [] syntax is C99. GCC implemented zero-length arrays years prior to C99; the syntax was type name [0]

. The two are equivalent, but you should prefer the empty array operator as it is now standardized.

Source

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This answer is exactly the same as Robert Love on Quora. –  David Andreoletti May 17 at 15:01
    
I had saved the answer on my local machine for future read. Can you please give the link here so that I can update the reference in answer? –  Aashish May 19 at 7:06
    
Click on Quora in my comment. –  David Andreoletti May 19 at 8:44
    
Here you go: quora.com/C-programming-language/… –  David Andreoletti May 19 at 14:07
    
Thanks :) Updated –  Aashish May 19 at 20:15

It's a common C hack to declare what can be called a variable length-array (where you define the size at allocation time

Example:

struct line {
   int length;
   char contents[0];
 };

 struct line *thisline = (struct line *)
   malloc (sizeof (struct line) + this_length);
 thisline->length = this_length;

This way you have a structure definition of your data, which also stores the array length for obvious convecience purposes, but you're not constrained by the fixed size that is usually associated with a struct

Example taken from here (also more info in there)

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