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This is very similar to this question, but the answers don't really answer this, so I thought I'd ask again:

Sometimes I interact with functions that return variable-length structures; for example, FSCTL_GET_RETRIEVAL_POINTERS in Windows returns a variably-sized RETRIEVAL_POINTERS_BUFFER structure.

Using malloc/free is discouraged in C++, and so I was wondering:
What is the "proper" way to allocate variable-length buffers in standard C++ (i.e. no Boost, etc.)?

vector<char> is type-unsafe (and doesn't guarantee anything about alignment, if I understand correctly), new doesn't work with custom-sized allocations, and I can't think of a good substitute. Any ideas?

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I don't understand what's wrong with having a data member in your struct that is a std::vector<WHATEVER>. – Oliver Charlesworth Sep 14 '11 at 19:44
@Oli: In my struct? It's already defined by Windows, not by me... – Mehrdad Sep 14 '11 at 19:45
"vector<char> is type-unsafe" ... how so? – AJG85 Sep 14 '11 at 19:45
@Mehrdad: Oh, I see. I thought you were just using the Windows thing as an example of how this might be done in C. – Oliver Charlesworth Sep 14 '11 at 19:45
@AJG85: It tells me nothing about the fact that it holds a RETRIEVAL_POINTERS_BUFFER structure, so it's obviously type-unsafe. – Mehrdad Sep 14 '11 at 19:46
up vote 2 down vote accepted

If you like malloc()/free(), you can use

RETRIEVAL_POINTERS_BUFFER* ptr=new char [...appropriate size...];

... do stuff ...

delete[] ptr;

Quotation from the standard regarding alignment (

For arrays of char and unsigned char, the difference between the result of the new-expression and the address returned by the allocation function shall be an integral multiple of the strictest fundamental alignment requirement (3.11) of any object type whose size is no greater than the size of the array being created. [ Note: Because allocation functions are assumed to return pointers to storage that is appropriately aligned for objects of any type with fundamental alignment, this constraint on array allocation overhead permits the common idiom of allocating character arrays into which objects of other types will later be placed. — end note ]

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Ooooh... wow, this is really cool. So the result of new is always properly aligned for primitive types, no matter what type you allocated it as? – Mehrdad Sep 14 '11 at 20:01
Only for new char[n] (or unsigned char). – jpalecek Sep 14 '11 at 20:05
@Mehrdad: Not just primitive types, all types. – GManNickG Sep 14 '11 at 20:08
@Mehrdad: that makes the alignment always properly aligned for all types. A class aligns on the same alignment as it's member with the strictest alignment, eventually that's a primitive type. – Mooing Duck Sep 14 '11 at 20:08
@GMan, Mooing Duck: It can't be all types, because compiler extensions can make alignments of like 64, which it doesn't handle. But yeah, if you disregard that then it works I guess. – Mehrdad Sep 14 '11 at 20:57

I would use std::vector<char> buffer(n). There's really no such thing as a variably sized structure in C++, so you have to fake it; throw type safety out the window.

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But then it's not even guaranteed to be e.g. properly aligned, is it? It seems so much hackier than malloc... – Mehrdad Sep 14 '11 at 19:48
@Mehrdad, I don't know if vector is guaranteed to align its internal buffer but in practice I believe it does on common compilers. You can always use a custom allocator if you need guarantees. – Mark Ransom Sep 14 '11 at 19:51
@Mehrdad You're going to be responsible for alignment regardless. C++11 has more tools to help enforce it, though. – Tom Kerr Sep 14 '11 at 19:51
@TomK: Uhm, what? malloc guarantees that its alignment is correct for any built-in type. vector<char> doesn't. I'm not sure what you mean by being responsible for it regardless... I certainly pay no attention to it when using malloc. – Mehrdad Sep 14 '11 at 19:52
@Mehrdad: It's aligned correctly. Dynamic allocations are guaranteed to be suitably aligned for any type. – GManNickG Sep 14 '11 at 19:56

I don't see any reason why you can't use std::vector<char>:

   std::vector<char> raii(memory_size); 
   char* memory = &raii[0];

  //Now use `memory` wherever you want
  //Maybe, you want to use placement new as:

   A *pA = new (memory) A(/*...*/); //assume memory_size >= sizeof(A);
   pA->~A(); //call the destructor, once done!

}//<--- just remember, memory is deallocated here, automatically!

Alright, I understand your alignment problem. It's not that complicated. You can do this:

A *pA = new (&memory[i]) A();
//choose `i` such that `&memory[i]` is multiple of four, or whatever alignment requires
//read the comments..
share|improve this answer
What are the alignment guarantees? Is the address guaranteed to be aligned correctly? – Mehrdad Sep 14 '11 at 19:51
@Mehrdad: That is the job of placement new, and how you want to use it. – Nawaz Sep 14 '11 at 19:51
@Mehdrad placement new does not allocate it places things in previously allocated memory which the vector does for you. – AJG85 Sep 14 '11 at 20:04
@Nazaz: struct A {int data[3];}; must be aligned on a multiple of sizeof(int), not sizeof(A). If you allocate sizeof(A) bytes, but it doesn't begin on a (for 32 bit machines) byte multiple of four, everything dies. (UB I think) – Mooing Duck Sep 14 '11 at 20:10
@Mehrdad: But if you give it an address that's already aligned there's no issue, which is the case here. – GManNickG Sep 15 '11 at 1:10

You may consider using a memory pool and, in the specific case of the RETRIEVAL_POINTERS_BUFFER structure, allocate pool memory amounts in accordance with its definition:

sizeof(DWORD) + sizeof(LARGE_INTEGER)


ExtentCount * sizeof(Extents)

(I am sure you are more familiar with this data structure than I am -- the above is mostly for future readers of your question).

A memory pool boils down to "allocate a bunch of memory, then allocate that memory in small pieces using your own fast allocator". You can build your own memory pool, but it may be worth looking at Boosts memory pool, which is a pure header (no DLLs!) library. Please note that I have not used the Boost memory pool library, but you did ask about Boost so I thought I'd mention it.

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std::vector<char> is just fine. Typically you can call your low-level c-function with a zero-size argument, so you know how much is needed. Then you solve your alignment problem: just allocate more than you need, and offset the start pointer:

Say you want the buffer aligned to 4 bytes, allocate needed size + 4 and add 4 - ((&my_vect[0] - reinterpret_cast<char*>(0)) & 0x3).

Then call your c-function with the requested size and the offsetted pointer.

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Ok, lets start from the beginning. Ideal way to return variable-length buffer would be:

MyStruct my_func(int a) { MyStruct s; /* magic here */ return s; }

Unfortunately, this does not work since sizeof(MyStruct) is calculated on compile-time. Anything variable-length just do not fit inside a buffer whose size is calculated on compile-time. The thing to notice that this happens with every variable or type supported by c++, since they all support sizeof. C++ has just one thing that can handle runtime sizes of buffers:

MyStruct *ptr = new MyStruct[count];

So anything that is going to solve this problem is necessarily going to use the array version of new. This includes std::vector and other solutions proposed earlier. Notice that tricks like the placement new to a char array has exactly the same problem with sizeof. Variable-length buffers just needs heap and arrays. There is no way around that restriction, if you want to stay within c++. Further it requires more than one object! This is important. You cannot make variable-length object with c++. It's just impossible.

The nearest one to variable-length object that the c++ provides is "jumping from type to type". Each and every object does not need to be of same type, and you can on runtime manipulate objects of different types. But each part and each complete object still supports sizeof and their sizes are determined on compile-time. Only thing left for programmer is to choose which type you use.

So what's our solution to the problem? How do you create variable-length objects? std::string provides the answer. It needs to have more than one character inside and use the array alternative for heap allocation. But this is all handled by the stdlib and programmer do not need to care. Then you'll have a class that manipulates those std::strings. std::string can do it because it's actually 2 separate memory areas. The sizeof(std::string) does return a memory block whose size can be calculated on compile-time. But the actual variable-length data is in separate memory block allocated by the array version of new.

The array version of new has some restrictions on it's own. sizeof(a[0])==sizeof(a[1]) etc. First allocating an array, and then doing placement new for several objects of different types will go around this limitation.

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