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I am loading many textures into an (Open GL) app (hundreds of megabytes uncompressed in memory) so I use LRU cache and discard them when needed. In Android the Open GL textures are allocated in the native heap, so I can use all the available memory.

The problems are that...

ActivityManager activityManager = (ActivityManager)VhbApplication.getInstance().getSystemService(Context.ACTIVITY_SERVICE);
ActivityManager.MemoryInfo memoryInfo = new ActivityManager.MemoryInfo();

the availMem reports weird number on some devices: Galaxy tab 10.1 with 3.2 - 160MiB and system shows 300MiB free, Acer Iconia Tab A200 with 4.0.3 reports the same value for free memory as the system ~400MiB. The second problem is that on that Acer I get out of memory errors (not in the form of OutOfMemoryError that can be caught as an exception. then it just hits a SIGSEGV) even when allocating textures of size less than 200MiB. Not always, but if the app runs long enough that some textures are deleted from the cache and new ones are loaded, then the app can crash.

So I cannot set the cache size in a very robust way. Those random OOM crashes are only with the Acer. My other devices like Galaxy tab 10.1, Nexus 7 and even Galaxy note (the 5") I do get these random crashes. I properly delete the Open GL textures.

Is there some limit that Acer put into their Androids that limits not only the VM memory size, but also native heap allocation? Or is it a buggy Open GL driver? That Acer an Galaxy tab use almost the same Tegra 2 GPU.

How can I robustly set the cache size? And I need at least 100MiB. Or any other way to robustly allocate 100-200 MiB of textures into an Android Open GL application?

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1 Answer 1

One thing to note is that an out of memory error on a system is not necessarily a "you exhausted all the available memory" error. It's a "we can't find a contiguous section of pages that fits the size you requested" error.

So it's very conceivable when you're working anywhere even close towards the peak of your system's memory capacity to run into an OOM error when trying to allocate a single 100-megabyte block, for example, while at the same time succeeding to allocate a hundred 1-megabyte blocks. Fragmentation doesn't reduce available memory but it does place a cap on the availability of large, contiguous blocks of memory.

It's also worth noting that GPU APIs tend to play by different, lower-level rules than CPU. So if it's the GPU side that's failing to allocate textures, it's not necessarily going to throw exceptions. If you're using OGL/es, handling errors often means sprinkling glGetError calls throughout your code in critical areas. The segfault you're getting in some cases is probably not due to a failure to allocate the texture, but trying to use it after the allocation failed without checking for that condition.

Yet this is all in the realm of robust recovery from out of memory errors, not preventing them outright. In your case, I'm assuming your main goal is to prevent them from happening all together.


Assuming this is not the result of any leaks, then one strategy to avoid this problem is to pre-allocate your memory (or at least the bulky parts) and maintain a pool that you use and reuse. This can mitigate the fragmentation that can result from allocating and deallocating some, but not all, smaller blocks repeatedly.

So you can potentially pre-allocate and reuse the memory on the GPU for things like VBOs and textures (even reusing the same texture object and writing new images to ones you mark as free on demand).

This can be a bit difficult to manage but can help considerably to avoid these kinds of issues as well as sometimes even boosting performance. It can be a very useful strategy for mission-critical software with a foreseeable upper bound on memory use that can't afford to run into memory issues in the middle of execution.

Split the Big Data

Another strategy is to simply dice up the big, contiguous blocks of data into smaller blocks. You can still use the same amount of memory provided it's available, but we're simply dividing the data into smaller blocks to avoid those OOM problems resulting from fragmentation.

When you have single, seamless textures that span 200 MiB while targeting Android, that sounds to me like a potential problem waiting to happen. While the higher end of the devices can boast very powerful hardware, the lowest end of the spectrum can be a lot more constrained. Some of these devices apparently also have VRAM for fast access, it's just that the limited amount of VRAM means that things will be constantly swapped in and out of system memory (making it non-dedicated, highly volatile, and a very temporary storage area like hardware registers while the dedicated area will be system memory). In such cases, you might actually be looking at tighter constraints on the size of your GPU resources if they cannot be used directly from system memory (I'm not sure what the case is here when it comes to information that is applicable to all Android devices).

This info might help add some comfort in exchange for the extra work required to split apart the texture data.

If you go this route, you can always split a single, seamless texture into multiple. It will require multiple passes to render it all, but it doesn't necessarily involve more processing and can actually boost performance when you're working with smaller VBOs and textures rendering segments of a mesh instead of the whole thing at once due to the improved locality.

The easiest way to do this is to simply have your artists create the 3D objects in more segments. For example, a character mesh might store its texture for the character's face/head/hair with a separate texture image and coordinates from the rest of its body. You then render the character in two passes: one for its head and another for its body.

By doing things like this, you can reduce the texture sizes from one giant texture to multiple smaller ones that can fit on lower-end devices without paying for it with so many texture context switches that it starts to become an overhead. A harder way is to split that data apart yourself on the fly automatically, but it's doable.

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This was a long time ago, so from memory: The project uses 256x256 textures only in 8888 encoding (no compressions or 565 allowed becuase of grayscale parts). So every texture uses 256KiB and they are decoded via a shared Bitmap. These squares together form one big image with resolution up to 30k x 30k. They are loaded/discarded on demand, no memory leaks and probably very small memory fragmentation. It was robably a bug in the Acer OGL driver, as it was the only device with this issue. – shelll May 28 at 7:20
Oh, so your data was already broken up into 256KiB tiles? If so, my bad, I thought you were trying to allocate single 200MiB textures in one go. – Ike May 28 at 8:19

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