# Why does a BufferedImage require so much memory beyond the size of its data array?

I'm trying to determine how much heap any given TYPE_INT_ARGB BufferedImage will use so that, for a program which is doing some image processing, I can set a reasonable max heap based on the size of image we feed it.

I wrote the following program as a test, which I then used to determine the least maximum heap under which it would run without an OutOfMemoryError:

import java.awt.image.BufferedImage;

public class Test {
public static void main(String[] args) {
final int w = Integer.parseInt(args[0]);
final int h = Integer.parseInt(args[1]);

final BufferedImage img =
new BufferedImage(w, h, BufferedImage.TYPE_INT_ARGB);

System.out.println((4*w*h) >> 20);
}
}

(The printed value is the expected size of the int[] in which the BufferedImage's pixel data is stored.) What I expected to find was that the required max heap is something like x + c, where x is the size of the data array and c is a constant consisting of the sizes of the classes which are loaded, the BufferedImage object, etc. This is what I found instead (all values are in MB):

4*w*h   min max heap
-----   ------------
5          -
10         15
20         31
40         61
80        121
160        241

1.5x is a good fit for the observations. (Note that I found no minimum for the 5MB image.) I don't understand what I'm seeing. What are these extra bytes?

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Might be a noob question but why 4*w*h? –  Sagar V Oct 4 '10 at 11:24
w*h is the number of pixels. In a TYPE_INT_ARGB image, each pixel is stored in an int, which should be 4 bytes. So 4*w*h ought to be the number of bytes the int[] uses for storing its data. –  uckelman Oct 4 '10 at 11:28

There seem to be a bug in Oracle's VM introduced somewhere between 1.6.0_16 and 1.6.0_20. You can even reduce the problem to allocating an int array, as the problem is not only related to BufferedImage.

With 1.6.0_16, I need at least 413 MB heap to allocate an int array with 100,000,000 elements, which seem reasonable. With 1.6.0_20, the same operation requires at least 573 MB heap space, although only appr 400,000,000 bytes are actually used after allocating the array.

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The difference is rather big, but not huge. Maybe they added some extra internal book-keeping to arrays or something. Should not be too hard to find out, the source is still free right? –  Prof. Falken Oct 4 '10 at 12:45

On further investigation, the problem appears to be that the Old Generation in the heap is not able to expand sufficiently to accommodate the image's data array, despite that there is enough free memory in the heap at large.

For further details about how to expand the Old Generation, see this question.

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