Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I need to manage a memory heap, with the constraint that this memory should only be written to, never read, i.e. the malloc implementation should keep the bookkeeping information separately from the heap it manages, on the normal heap, and should in fact never touch the specific heap it manages. I was hoping to use a tested, optimized, off the shelf solution for that, if one is available. Examples of use include OpenGL VBOs and memory on external units of embedded systems.

I glanced at dlmalloc, and from the documentation, it seems to tag the memory blocks it allocates from both sides with bookkeeping information. Googling didn't do any good either - perhaps i don't have the right keywords to find what i'm looking for.

Clarifications: as a separate heap, i mean what i define to be a heap. I want to tightly use memory with small allocations within one or a small number of pre-allocated blocks. I don't even care if the bookkeeping information (outside the thus managed heap) is larger than the data inside :) Furthermore, the application itself will use stock malloc and heap for its operation, and only use those blocks for special purpose, which boils down to memory regions for speaking to external hardware, where writes from application are the purpose, reads are impossible or expensive. This is not a general malloc question, i was merely hoping to leverage something where a lot of research and testing has gone into.

share|improve this question
/dev/null makes a nice write-only datastore. – Anon. Dec 17 '10 at 0:57
I'm assuming you mean only the heap manager doesn't read the memory. I'm having a hard time seeing much use to a system where the application itself can't read the memory it writes. I'd also be curious as to the need behind this feature - there may be another way. – paxdiablo Dec 17 '10 at 0:59
should in fact never touch the specific heap it manages - how does it manage then? – detly Dec 17 '10 at 1:01
So you want that a memory corruption won't affect the bookkeping data? How about *(int*)rand() = rand()? Unless it's completely in kernel, you can never be sure. And how about the very good better dead than crippled principle? – ruslik Dec 17 '10 at 1:08
@detly: He means keeping the metadata separate from the allocatable memory blocks. – Clifford Dec 17 '10 at 9:30

and should in fact never touch the specific heap it manages.

What if it does not manage the heap? See this malloc function utilizing a particular implementation that neither manages the [heap] area (cf. /proc/$$/maps), nor stores its metadata in adressable memory, and yet, gives your program unique adressable memory.

void *mymalloc(size_t len)
        void *x = mmap(NULL, len, PROT_READ | PROT_WRITE, MAP_PRIVATE | MAP_ANONYMOUS, -1, 0);
        return (x == (void *)-1) ? NULL : x;

And now for the killer revelation: glibc uses exactly that for sufficiently large allocations.

share|improve this answer
glibc does not (and cannot) use that method for large allocations, because your method throws away the size of the mapping. Thus it's impossible to later free it. glibc stores the size at the beginning of the map and returns a pointer to memory just beyond the size. – R.. Dec 17 '10 at 3:24

It's not a ready to use library, but the resource management code in the Linux kernel does exactly this to manage resources such as PCI address space.

share|improve this answer

Here's a very simple malloc implementation that never writes bookkeeping information to the heap it manages:

void *malloc(size_t n) { return sbrk(n); }
void free(void *p) { }
void *realloc(void *p, size_t n }
    void *q = malloc(n);
    if (q) memcpy(q, p, n);
    return q;

If you'd like some more realistic ideas, one simple solution is to choose a smallest unit of memory for allocation (8 or 16 bytes might be reasonable) and divide the managed heap into units of this size, then store which ones are free in a bitmap (e.g. one bit per 16 bytes, for 1/128, <1% overhead). Searching for free space is then O(n), but you can think of ways to improve it with multi-scale maps perhaps.

Another idea is to use the same principles as dlmalloc, but instead of storing data in the free chunks, perform a hash on a chunk's address to get its bookkeeping information from a hash bin. One big problem with any method like this that doesn't store information in the actual heap, though, is that freeing memory can paradoxically increase the amount of memory in use (due to the need to allocate new bookkeeping structures).

share|improve this answer
i would be a bit uncomfortable with the realloc. if the malloc fails, your allocation doesn't have the requested extra space. – EvilTeach Aug 17 '12 at 0:18
If the malloc fails, it returns a null pointer. – R.. Aug 17 '12 at 1:11
ya i'm blind. thanks. – EvilTeach Aug 17 '12 at 1:16

An implementation would probably be fairly simple to implement. One disadvantage of not storing the metatdata with the allocated block is that the performance of free() is likley to be slower and non-deterministic. But since malloc() already has that problem, perhaps that is not really an issue.

A simple deterministic solution is to implement a fixed-block memory allocator, where fixed size blocks are allocated from the conventional heap and a pointer to each block is placed on a queue or linked list. To allocate a block you simply take a pointer from the free-block queue/list, and to free it you place the pointer back on the free-block list.

share|improve this answer
Oh sure, simple to implement! Hard to get perfect, and i'm sure someone did that before me, and looking at 30 years of malloc history of research, implementation and testing, i was hoping to fish there. – 3yE Dec 19 '10 at 14:30

Does the manager need to have the same semantics as malloc/free? Things would be greatly simplified if you could have your allocate function return a pointer to a structure which would in turn point to the actual memory; the deallocate function would accept a pointer to the structure, rather than a pointer to the memory.

Beyond that, the allocation method will be greatly influenced by your usage patterns. What can be said about the sizes of allocations, and the pattern of allocating and freeing memory blocks?

share|improve this answer

Just use the Buddy System.

share|improve this answer
While this link may answer the question, it is better to include the essential parts of the answer here and provide the link for reference. Link-only answers can become invalid if the linked page changes. – Rostyslav Dzinko Aug 16 '12 at 19:58

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.