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I have been exploring efficient ways to do image processing in Android and while comparing a simple point operation like YUV to RGB color space conversion of a 8 mega pixel image (8 million pixels) I got following performance difference between Java & Native simple for-loops while running on a certain Android device (arm64-v8a ABI):

Approach Average Verdict
Java 353 ms -
Native standard 76.4 ms 4.62x faster

By simple for-loops I mean both of them were row major for loops (no tiling, no explicit paralellization, no SIMD instructions)

for (int y = 0; y < height; ++y) {
    for (int x = 0; x < width; ++x) {
        // .. yuv to rgb conversion
    }
}

If I understand correctly this is due to the optimisations C++ compiler does for the given CPU architecture. On profiling I observed the C++ code to have good CPU usage while the java code to have much less.

Approach Avg CPU usage
Java ~12%
Native 70%+

This was observed while profiling debug version.

Are there ways to achieve better parallelism (& better throughput) with pure Java code in Android? As in some known APIs or frameworks which allows us to do this easily.

(Please note: the question is strictly about improving performance with Java code and not with alternative frameworks like RenderScript, Vulcan, Halide etc.)

Update 1 - related to Mark Keen's comment

I tried explicitly parallelising the Java code using thread pools & tiling

final int TILES_PER_AXIS = 4;
int tileWidth = width / TILES_PER_AXIS;
int tileHeight = height / TILES_PER_AXIS;
int threadCount = TILES_PER_AXIS * TILES_PER_AXIS;
final ExecutorService executor = Executors.newFixedThreadPool(threadCount);
List<Future<Void>> futures = new ArrayList<>();
int threadCount = TILES_PER_AXIS * TILES_PER_AXIS;

for (int i = 0; i < threadCount; i++) {
    int startY = i / TILES_PER_AXIS * tileHeight;
    int endY = startY + tileHeight;
    int startX = i / TILES_PER_AXIS * tileWidth;
    int endX = startX + tileWidth;
    Future<Void> future = executor.submit(() -> {
        process(startX, endX, startY, endY, ...other data);
        return /* Void */ null;
    });
    futures.add(future);
}

// Wait on all futures
for (Future<?> future : futures) {
    future.get(); // do anything you need, e.g. isDone(), ...
}

And the process(..) function only does the task in the given bounds of (startX, startY) to (endX, endY)

With this I did see both higher CPU usage and performance to a certain limit, but still not satisfied with the CPU usage (& performance with respect to the native code).

Pixel 4A, YUV 420 --> Bitmap, 8MP (3264x2448)

Approach Threads CPU usage Average latency
Direct loops 1 ~12% 353 ms
Parallel 2x2 tiles 4 ~32% 173 ms
Parallel 4x4 tiles 16 ~26% 129.9 ms
Parallel 8x8 tiles 64 ~15% 161.50 ms

Update 2 - improved performance with direct byte[] access.

One key difference between Java code and native code in this case was the java loops were accessing the data using a readonly ByteBuffer while the native code was accessing the underlying data directly. I suppose for loops with direct pointers access are:

  1. Less instructions per iteration
  2. Easier for the compiler to auto-vectorise.

So one way to address this was using fast byte[] copy and doing the conversion using byte[]. This of course not so good hit on java heap. Some performance numbers I saw with this:

Approach Average Verdict
Java (unoptimised} 353 ms
Native (unoptimised) 76.4 ms 4.62x faster
Java byte[] + single threaded 119.5 ms 2.9x faster
Java byte[] + multi threaded 53.8 ms 6.56x faster

And CPU usage:

Approach Avg CPU usage
Java ByteBuffer + single threaded ~12%
Native ~70%+
Java byte[] + multi threaded ~33%+

My write-up on this topic: Faster image processing in Android Java using multi threading (with my limited understanding, but still exploring)

Questions:

  • Can we do better?
  • Is there a easier way to do this way of tiling in Java?
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  • 1
    Supplied code is single threaded. I assume the native c++ implementation must be mutli-threaded based on the cpu usage i.e a 4 core 4 thread cpu in single thread work load could only max 25% (you might be using a 8-core 8-thread CPU to get 12% in the supplied single threaded code), unless your supplied code is identical in both implementations, which makes the results confusing? Making the Java code mutl-threaded will yield far better results, maybe by "tiling" then processing (think Cinebench) sections/chunks on different threads - forking and joining at the end
    – Mark Keen
    Jul 23 at 14:41
  • Thanks for detailed answer. That is likely the root cause, my question is more directed towards some known APIs / frameworks to achieve better parallelism for this kind of operation (just updated the question).
    – Minhaz
    Jul 23 at 14:50
  • 2
    This sort of thing is also exactly the use case for vectorized instructions. Jul 23 at 15:03
  • @chrylis-cautiouslyoptimistic- If I understand correctly Java doesn't expose those lower level details via the public APIs? Also, vectorized instructions should help speedup on single core, for this question I am wondering more from higher parallelization perspective to achieve higher CPU usage for better performance.
    – Minhaz
    Jul 24 at 3:52
  • I did a bit more research and realised that the LLVM compiler used in Android supports auto vectorisation and given that I am compiling the code with -O3 flags - it might be generating SIMD instructions for the simple loops. But, Android started using ART since Android 8.0 and it seems to support Ahead of time compilation with loop optimisations like vectorisation as well. I still don't get both why we get a faster performance with C++ code and cpu usage as high as 70% - is there a concept of running single threaded code over multiple cores or so?
    – Minhaz
    Jul 25 at 6:59

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