Thinking in particular of C++ on Windows using a recent Visual Studio C++ compiler, I am wondering about the heap implementation:

Assuming that I'm using the release compiler, and I'm not concerned with memory fragmentation/packing issues, is there a memory overhead associated with allocating memory on the heap? If so, roughly how many bytes per allocation might this be? Would it be larger in 64-bit code than 32-bit?

I don't really know a lot about modern heap implementations, but am wondering whether there are markers written into the heap with each allocation, or whether some kind of table is maintained (like a file allocation table).

On a related point (because I'm primarily thinking about standard-library features like 'map'), does the Microsoft standard-library implementation ever use its own allocator (for things like tree nodes) in order to optimize heap usage?

  • 2
    Typically when you allocate arrays, some bytes are stored at the beginning with the size allocated for future deletes. For large allocations, the overhead is close to none. If you allocate, say, 4 bytes at a time, it can very well double the memory. Apr 8 '13 at 14:09

Yes, absolutely.

Every block of memory allocated will have a constant overhead of a "header", as well as a small variable part (typically at the end). Exactly how much that is depends on the exact C runtime library used. In the past, I've experimentally found it to be around 32-64 bytes per allocation. The variable part is to cope with alignment - each block of memory will be aligned to some nice even 2^n base-address - typically 8 or 16 bytes.

I'm not familiar with how the internal design of std::map or similar works, but I very much doubt they have special optimisations there.

You can quite easily test the overhead by:

char *a, *b;

a = new char;
b = new char;

ptrdiff_t diff = a - b;

cout << "a=" << a << " b=" << b << " diff=" << diff;

[Note to the pedants, which is probably most of the regulars here, the above a-b expression invokes undefined behaviour, since subtracting the address of one piece of allocated and the address of another, is undefined behaviour. This is to cope with machines that don't have linear memory addresses, e.g. segmented memory or "different types of data is stored in locations based on their type". The above should definitely work on any x86-based OS that doesn't use a segmented memory model with multiple data segments in for the heap - which means it works for Windows and Linux in 32- and 64-bit mode for sure].

You may want to run it with varying types - just bear in mind that the diff is in "number of the type, so if you make it int *a, *b will be in "four bytes units". You could make a reinterpret_cast<char*>(a) - reinterpret_cast<char *>(b);

[diff may be negative, and if you run this in a loop (without deleting a and b), you may find sudden jumps where one large section of memory is exhausted, and the runtime library allocated another large block]

  • I've added a comment to that effect. If you have a suggestion for a better way to determine the distance between two independent allocations, feel free to suggets. Apr 8 '13 at 14:32
  • No no, I wasn't implying that, just pointing something out. For proving stuff like this, sometimes you resort to UB, no problem there :) Apr 8 '13 at 14:35
  • Ah, edited my comment while you were providing an answer to the original comment. Sorry for any other readers... ;) Apr 8 '13 at 14:37
  • Thanks @Mats. I hadn't considered a heap allocator to be so predictable that in most cases the difference between successive (equal sized) allocations gives a reliable indication of memory overhead. I might give that a try.
    – Coder_Dan
    Apr 8 '13 at 15:03
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    As long as you don't run it in multiple threads, or have call some function that allocates on the heap in between your calls to new, it should be fine. Of course, this applies to a heap that uses one large chunk of memory to provide different allocations... It is possible to have allocators that don't do that. Also, if by the time you get to this code, you've already done a bunch of alloc/free calls to the underlying heap, it may reuse memory blocks that come from those calls to free them - which may of course be out of order. Apr 8 '13 at 15:05

Visual C++ embeds control information (links/sizes and possibly some checksums) near the boundaries of allocated buffers. That also helps to catch some buffer overflows during memory allocation and deallocation.

On top of that you should remember that malloc() needs to return pointers suitably aligned for all fundamental types (char, int, long long, double, void*, void(*)()) and that alignment is typically of the size of the largest type, so it could be 8 or even 16 bytes. If you allocate a single byte, 7 to 15 bytes can be lost to alignment only. I'm not sure if operator new has the same behavior, but it may very well be the case.

This should give you an idea. The precise memory waste can only be determined from the documentation (if any) or testing. The language standard does not define it in any terms.


Yes. All practical dynamic memory allocators have a minimal granularity1. For example, if the granularity is 16 bytes and you request only 1 byte, the whole 16 bytes is allocated nonetheless. If you ask for 17 bytes, a block whose size is 32 bytes is allocated etc...

There is also a (related) issue of alignment.2

Quite a few allocators seem to be a combination of a size map and free lists - they split potential allocation sizes to "buckets" and keep a separate free list for each of them. Take a look at Doug Lea's malloc. There are many other allocation techniques with various tradeoffs but that goes beyond the scope here...

1 Typically 8 or 16 bytes. If the allocator uses a free list then it must encode two pointers inside every free slot, so a free slot cannot be smaller than 8 bytes (on 32-bit) or 16 byte (on 16-bit). For example, if allocator tried to split a 8-byte slot to satisfy a 4-byte request, the remaining 4 bytes would not have enough room to encode the free list pointers.

2 For example, if the long long on your platform is 8 bytes, then even if the allocator's internal data structures can handle blocks smaller than that, actually allocating the smaller block might push the next 8-byte allocation to an unaligned memory address.

  • Thanks for the information & malloc link, @Branko, that appears to be a very good basic introduction to heap management design.
    – Coder_Dan
    Apr 9 '13 at 8:06

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