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I have Java application, which intensively working with 2D float arrays (float[][] arrays), which actually holding images on black background. Both dimensions are equals (square) and are power of 2 (mostly are 256, 512, 1024), so areas close to borders have zeroes in most cases.

Having sizes equals to power of 2 done for increasing performance (there is some FFT) and decreasing complexity on operations over those arrays like rotation, etc. Recently I faced lack of heap for this application on my machine with 6Gb. By my calculations - memory consumption for this application should be like up to 2-3Gb, while it reaches 4-5Gb (looking in Windows task manager). I used "YourKit" profiler and it shows that those floats arrays indeed takes most memory, however, total rough size for these floats arrays should be like 1.3Gb (well, I know that it's up to JVM to decide how to store data, but I was not expecting 2-3-times difference in memory consumption).

I was trying to compress/decompress data with Snappy compressor on the fly (and memory consumption drops to 3.5Gb), but performance drops several times, which is not very acceptable. Also, I was testing performance when replacing those floats[][] by BufferedImage, but performance was very poor.

So, there is 2 ways left which will work for me to decrease memory consumption: 1) write wrappers for float[][] array in order to save on "zeroes" elements (there are a lot "empty" rows and columns) 2) go away from "power of 2"

Both ways require quite a lot of coding/refactoring, so while I am thinking "to be or not to be" - may be you have better clue on this issue, guys?


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What do the floats represent? Why can't you make them ints instead, for example? – Robin Green Nov 7 '13 at 20:03
I'd pay more careful attention to how the arrays are being used, and whether you're getting any temporaries introduced, which would significantly boost memory usage. There are also some Java classes for sparse arrays that you might want to investigate. – Eric Brown Nov 7 '13 at 20:04
@Arsen how do you store an RGB image in a float[][], I can't help but believe you have a 3rd dimension for the color channels. Show us the actual declaration of such an array and comment on how pixels are stored in it. – Durandal Nov 7 '13 at 21:01
@Arsen So your array is three dimensional? That would easily explain the unexpected memory consumption (java multidimensional arrays are implemented as array of arrays). Since each array has some overhead (about 12 bytes), which for the innermost float[3] amounts to as much memory as the floats stored within consume. That is what your code sample suggests anyway. I specifically asked about an actual declaration of such an array because that would unambigously clear up what memory layout you really use. Playing guessing games doesn't help anyone. Update your question with all relevant details – Durandal Nov 8 '13 at 18:21
@Arsen The problem hotlicks and me too have with your explanation is: You show code that create an array of 3 floats per pixel. You tell us the array is 2D indexed by (x, y). That doesn't fit together at all, agreed? Then you say one float per pixel, in which case it makes even less sense, because of the precision issue hot pointed out. Then you say you need a float for FFT, but a float holding R, G and B together can hardly be suited for FFT processing (precision issue aside) since you would need to split the color channels anyway before processing. Try being less confusing/confused – Durandal Nov 10 '13 at 16:50

An FFT requires a complex array, which is double the size of the real data array, even if you convert from a real array at the input and back to a magnitude array at the end. That may account for 2X of the larger-than-expected memory usage.

A sparse array will not work for an FFT, since the intermediate steps in an FFT will almost always fill the entire complex array.

Many modern high-performance FFT libraries, such as ones based on FFTW, can very efficiently deal with FFT lengths other than just powers-of-2 (any length that is the product of just small primes can be FFT'd quite efficiently). This can save a lot of 2D padding for many sizes.

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true, before making FFT (using JTransfrom, also tried Cuda) - I am converting float[][] array to Re and Im values (so, total array length increased two times), but this done only one time and after computing correlation I am getting absolute and array back reduced to normal size. GC should collect those Re-Im arrays, I have no links on them anywhere. About beneficence of FFT libs, thanks will have in mind – Arsen Nov 7 '13 at 21:36

After more detailed investigation - it appeared that JVM was launching with "UnlockEperimentalFeatures" and "use GC1" flags. As a result - there were a quite a lot of NOT garbage collected "unreachable" BufferedImage rasters (which contains byte[] arrays). When invoking GC from "YourKit" priofiler - those objects removed from heap (this is of course not acceptable way for me, since I was expecting that JVM will manage heap by herself).

I want to say thanks to everybody who put his time helping me. Special thanks to Jim Garrison (it looks like I just postponed memory demand for some time removing flags mentioned above, but when more arrays will came to play - buying more memory will be most easy way to avoid performance penalty.

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