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I wish to make a large int array that very nearly fills all of the memory available to the JVM. Take this code, for instance:

    final int numBuffers = (int) ((runtime.freeMemory() - 200000L) / (BUFFER_SIZE));
    System.out.println(runtime.freeMemory());
    System.out.println(numBuffers*(BUFFER_SIZE/4)*4);
    buffers = new int[numBuffers*(BUFFER_SIZE / 4)];

When run with a heap size of 10M, this throws an OutOfMemoryException, despite the output from the printlns being:

9487176
9273344

I realise the array is going to have some overheads, but not 200k, surely? Why does java fail to allocate memory for something it claims to have enough space for? I have to set that constant that is subtracted to something around 4M before Java will run this (By which time the printlns are looking more like: 9487176 5472256 )

Even more bewilderingly, if I replace buffers with a 2D array:

buffers = new int[numBuffers][BUFFER_SIZE / 4];

Then it runs without complaint using the 200k subtraction shown above - even though the amount of integers being stored is the same in both arrays (And wouldn't the overheads on a 2D array be larger than that of a 1D array, since it's got all those references to other arrays to store).

Any ideas?

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Is BUFFER_SIZE set to the size of the heap? –  jschoen Aug 3 '12 at 17:17
    
No, it is set to 16384 in this case. –  Chris Kitching Aug 3 '12 at 17:20
    
So that is how much memory you want left to work with after filling the array? –  jschoen Aug 3 '12 at 17:22
    
Perhaps java fails to allocate a block of contiguous memory of the required size for the array, and so fails - but in the 2D array case it can put the smaller arrays into a number of different, smaller contiguous sections and is thus fine? I wasn't aware memory fragmentation was a thing in Java. –  Chris Kitching Aug 3 '12 at 17:23
    
Ah, no, my explanation wasn't entirely clear - the numBuffers value divides the free memory up into segments of size BUFFER_SIZE for use in the 2D array scenario. I am not understanding why a 1D array of the same dimensions cannot be allocated instead. –  Chris Kitching Aug 3 '12 at 17:24

3 Answers 3

up vote 3 down vote accepted

The VM will divide the heap memory into different areas (mainly for the garbage collector), so you will run out of memory when you attempt to allocate a single object of nearly the entire heap size.

Also, some memory will already have been used up by the JRE. 200k is nothing with todays memory sizes, and 10M heap is almost unrealistically small for most applications.

The actual overhead of an array is relatively small, on a 32bit VM its 12 bytes IIRC (plus what gets wasted if the size is less than the minimal granularity, which is AFAIK 8 bytes). So in the worst case you have something like 19 bytes overhead per array.

Note that Java has no 2D (multi-dimensional) arrays, it implements this internally as an array of arrays.

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This makes some sense - is there any way to work around this (At least to some extent) to get me my giant array? –  Chris Kitching Aug 3 '12 at 17:27
    
Larger heap obviously :) You can play with the garbage collectors settings on the command line. This allows some control over the size of the 'generations'. It can probably be tuned to allow allocations to very near the maximum heap size, but may impact performance of the GC. –  Durandal Aug 3 '12 at 17:29
    
Since my app is going to do virtually nothing except play with this one single array, GC performance isn't a big issue. –  Chris Kitching Aug 3 '12 at 17:39

In the 2D case, you are allocating more, smaller objects. The memory manager is objecting to the single large object taking up most of the heap. Why this is objectionable is a detail of the garbage collection scheme-- it's probably because something like it can move the smaller objects between generations and the heap won't accomodate moving the single large object around.

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This might be due to memory fragmentation and the JVM's inability to allocate an array of that size given the current heap.

Imagine your heap is 10 x long:

xxxxxxxxxx 

Then, you allocate an object 0 somehere. This makes you're heap look like:

xxxxxxx0xx

Now, you can no longer allocate those 10 x spaces. You can not even allocate 8 xs, despite the fact that available memory is 9 xs.

The fact is that an array of arrays does not suffer from the same problem because it's not contiguous.

EDIT: Please note that the above is a very simplistic view of the problem. When in need of space in the heap, Java's garbage collector will try to collect as much memory as it can and, if really, really necessary, try to compact the heap. However, some objects might not be movable or collectible, creating heap fragmentation and putting you in the above situation.

There are also many other factors that you have to consider, some of which include: memory leaks either in the VM (not very likely) or your application (also not likely for a simple scenario), unreliability of using Runtime.freeMemory() (the GC might run right after the call and the available free memory could change), implementation details of each particular JVM, etc.

The point is, as a rule of thumb, don't always expect to have the full amount of Runtime.freeMemory() available to your application.

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Java is and has been able to relocate objects on the heap since at least Java5. Please don't spread FUD. –  Durandal Aug 3 '12 at 17:27
    
@Durandal -- Java can relocate SOME objects. Large objects are a special case. –  Hot Licks Aug 3 '12 at 17:37
    
@Durandal - Along with heap compacting there's also object pinning, which prevents the GC from moving or collecting some objects freely. That leads to memory fragmentation. The answer very simplistic just to get the message across. –  lsoliveira Aug 3 '12 at 17:39
    
@Isoliviera: Admitted, there are scenarios where an object may not be moved. But your answer completely ignores that objects normally are movable by the GC and that in turn makes it look like objects are never movable. –  Durandal Aug 3 '12 at 17:56
    
@HotLicks: I can't find any source for 'large objects are never moved'. Do you have a link? –  Durandal Aug 3 '12 at 17:57

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