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In one C++ open source project, I see this.

struct SomeClass {
  ...
  size_t data_length;
  char data[1];
  ...
}

What are the advantages of doing so rather than using a pointer?

struct SomeClass {
  ...
  size_t data_length;
  char* data;
  ...
}

The only thing I can think of is with the size 1 array version, users aren't expected to see NULL. Is there anything else?

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7  
This has a lot of potential benefits over a pointer, but none that I can think of over a plain char. –  larsmans Jun 17 '11 at 18:47
    
Maybe a duplicate of stackoverflow.com/questions/1704407/…? –  Yet Another Geek Jun 17 '11 at 18:47
7  
That is the ISO C90 idiom for a variable length structure. You are right insofar as a pointer would do the same, but this one allows for a more comfortable access. In ISO C99 you would use empty brackets instead. A one-element array is valid for C++ too, I'm not sure whether that is true for empty brackets as well (though gcc does support it anyway). –  Damon Jun 17 '11 at 18:47
    
@larsman: The benefit is if the memory allocation is larger than sizeof(SomeClass), so you can use data as an array of a size larger than 1. –  Mike Seymour Jun 17 '11 at 18:49
    
@Mike: I'm aware of that. It's hardly a benefit. –  larsmans Jun 17 '11 at 18:51

6 Answers 6

up vote 27 down vote accepted

With this, you don't have to allocate the memory elsewhere and make the pointer point to that.

  • No extra memory management
  • Accesses to the memory will hit the memory cache (much) more likely

The trick is to allocate more memory than sizeof (SomeClass), and make a SomeClass* point to it. Then the initial memory will be used by your SomeClass object, and the remaining memory can be used by the data. That is, you can say p->data[0] but also p->data[1] and so on up until you hit the end of memory you allocated.

Points can be made that this use results in undefined behavior though, because you declared your array to only have one element, but access it as if it contained more. But real compilers do allow this with the expected meaning because C++ has no alternative syntax to formulate these means (C99 has, it's called "flexible array member" there).

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@larsmans: Because not all C compilers allow zero-sized arrays. (C89 did not, I believe. gcc probably does) –  Ben Zotto Jun 17 '11 at 18:50
    
@larsmans because declaring an array of size zero is not allowed - char x[0]; is invalid to say in C++ and C, it requires a diagnostic message (error / warning message). –  Johannes Schaub - litb Jun 17 '11 at 18:50
5  
If the OP's code example is to be believed, then I don't think this answer is correct. He has "..." after the char data[1], implying that there are more fields following. –  Oliver Charlesworth Jun 17 '11 at 18:53
    
Ah, so there can only be one of this array in a class and it has to be at the end too right? The ... following is not exactly more fields, they're just inline function definitions. I didn't think that was relevant. Sorry I wasn't clear. –  Russell Jun 17 '11 at 18:55
    
@Oli that's a good point I didn't notice. Though if you take into account the questioner wasn't aware of the special meaning, he also wasn't aware that this only makes sense for the last member of the struct, so he may just have inserted the "..." at both ends to keep it symmetric. –  Johannes Schaub - litb Jun 17 '11 at 18:57

This is usually a quick(and dirty?) way of avoiding multiple memory allocations and deallocations, though it's more C stylish than C++.

That is, instead of this:

struct SomeClass *foo = malloc(sizeof *foo);
foo->data = malloc(data_len);
memcpy(foo->data,data,data_len);

....
free(foo->data);
free(foo);

You do something like this:

struct SomeClass *foo = malloc(sizeof *foo + data_len);
memcpy(foo->data,data,data_len);

...
free(foo);

In addition to saving (de)allocation calls, this can also save a bit of memory as there's no space for a pointer and you could even use space that otherwise could have been struct padding.

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Usually you see this as the final member of a structure. Then whoever mallocs the structure, will allocate all the data bytes consecutively in memory as one block to "follow" the structure.

So if you need 16 bytes of data, you'd allocate an instance like this:

SomeClass * pObj = malloc(sizeof(SomeClass) + (16 - 1));

Then you can access the data as if it were an array:

pObj->data[12] = 0xAB;

And you can free all the stuff with one call, of course, as well.

The data member is a single-item array by convention because older C compilers (and apparently the current C++ standard) doesn't allow a zero-sized array. Nice further discussion here: http://gcc.gnu.org/onlinedocs/gcc/Zero-Length.html

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This is called (even in the C standard's index) the struct hack. –  larsmans Jun 17 '11 at 18:49

They are semantically different in your example.

char data[1] is a valid array of char with one uninitialized element allocated on the stack. You could write data[0] = 'w' and your program would be correct.

char* data; simply declares a pointer that is invalid until initialized to point to a valid address.

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I'm not sure how this was ignored. A pointer and a character are not the same thing. –  Jay Jun 17 '11 at 19:32
  1. The structure can be simply allocated as a single block of memory instead of multiple allocations that must be freed.

  2. It actually uses less memory because it doesn't need to store the pointer itself.

  3. There may also be performance advantages with caching due to the memory being contiguous.

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The idea behind this particular thing is that the rest of data fits in memory directly after the struct. Of course, you could just do that anyway.

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