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I was trying to look at the behavior of the new allocator and why it doesn't place data contiguously.

My code:

struct ci {
    char c;
    int i;

template <typename T>
void memTest()
    T * pLast = new T();
    for(int i = 0; i < 20; ++i) {
         T * pNew = new T();
         cout << (pNew - pLast) << " ";
         pLast = pNew;

So I ran this with char, int, ci. Most allocations were a fixed length from the last, sometimes there were odd jumps from one available block to another.

sizeof(char) : 1
Average Jump: 64 bytes

sizeof(int): 4
Average Jump: 16

sizeof(ci): 8 (int has to be placed on a 4 byte align)
Average Jump: 9

Can anyone explain why the allocator is fragmenting memory like this? Also why is the jump for char so much larger then ints and a structure that contains both an int and char.

share|improve this question
I should have added the behavior is very different between debug and release mode. I'd assume the extra space in debug mode is for debug purposes... – Jason T. Apr 27 '10 at 20:31
I don't reckon it's worth making any assumptions about the general purpose allocator - it will vary from mode to mode, from platform to platform. I don't mean to discourage you at all - if you have this interest in how things work under the hood you should definitely keep digging! (upvoted your question accordingly) – Matt Curtis Apr 27 '10 at 21:05
up vote 8 down vote accepted

There are two issues:

  • most allocators store some additional data prior to the start of the block (typically block size and a couple of pointers)

  • there are usually alignment requirements, e.g. Linux typically allocates to at least an 8 byte boundary, OS X allocates to at least a 16 byte boundary

So you'll nearly always get some kind of gap between successive allocations.

Of course you should never rely on any specific behaviour for something like this, where the implementation is free to do as it pleases.

share|improve this answer
I wasn't planning on relying on a specific behavior. Just trying to understand where the fragmentation comes from, so I know why I would want to do a giant block allocation and dole out memory myself if I had a memory constraint. – Jason T. Apr 27 '10 at 20:35
@tamulji: yes, there are sometimes cases where you want to use a single large allocation and parcel it out yourself. Two cases that come to mind are (i) when you have a lot of very small allocations, and (ii) for things like image processing where you want your image to be a T ** but you also want the rows to be contiguous. – Paul R Apr 27 '10 at 20:46
Also in tight memory situations, or for very fast allocations/deallocations if you know a lot about your allocation patterns and lifetimes - if you have specific requirements you can always do better than the general purpose allocator, the trade-off is the gp allocator is just there and easy to use. – Matt Curtis Apr 27 '10 at 21:10

Your code contains a bug, to know distance of pointers cast them to (char *), otherwise the deltas are in sizeof(T).

share|improve this answer
Yeah I realized this after posting. Still shows the fragmentation. – Jason T. Apr 27 '10 at 20:31
Or cast to an integer type like ptrdiff_t or intptr_t prior to taking the difference. – Void Apr 27 '10 at 20:34
It seems consistent to me. int and char allocations are 64 bytes apart. structs "ci" are 72 bytes apart. You don't say on which OS you're running, but it seems the allocator is putting blocks one behind the other. – plodoc Apr 27 '10 at 20:49

In general, you cannot depend on particular memory placement. The memory allocator's internal bookkeeping data and alignment requirements can both affect the placement of blocks. There is no requirement for blocks to be allocated contiguously.

Further, some systems will give you even "stranger" behavior. Many modern Linux systems have heap randomization enabled, where newly-allocated virtual memory pages are placed at random addresses to make certain types of security vulnerability exploits more difficult. With virtual memory, disparate allocated block addresses do not necessarily mean that the physical memory is fragmented, as there is no requirement for the virtual address space to be dense.

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This isn't fragmentation, it's just rounding up the size of your allocation to a round block size.

In general programming you should not pay attention to the pattern of memory addresses returned by general purpose allocators like new. When you do care about allocation behaviour you should always use a special purpose allocator (boost::pool, something you write yourself, etc.)

The exception is if you are studying allocators, in which case you could do worse than pick up your copy of K&R for a simple allocator which might help you understand how new gets its memory.

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As others have already said, basically you have no control over how the memory management system works. If you allocate many singular objects, that might result in fragmentation, and there's nothing you can do against this.

However, if you need your objects to be in contiguous order in memory, you can write your own memory allocator that operates on top of malloc() or new. One way to control fragmentation is to allocate a larger block of memory and to then construct your actual singular objects inside this block using placement new (link to the C++ FAQ Lite).

(This works of course because a call to malloc() or new T[] is guaranteed to return a contiguous block of memory. One singular allocated object cannot be fragmented; fragmentation can only results with several allocated objects.)

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For small allocation, boost has a very simple allocator I've used called boost::simple_segregated_storage

It creates a copy of slists of free and used blocks, all the same size. As long as you only allocate to its set block size, you get no external fragmentation (though you can get some internal fragmentation if your block size is bigger than the requested size.) It also runs O(1) if you use it in this manner. Great for small allocation the likes of which are common with template programming.

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