Collecting bits and pieces of information (which is surprisingly difficult, since the official documentation is quite bad), I've determined...
There are generally two reasons this may happen, both related to fragmentation of free space (ie, free space existing in small pieces such that a large object cannot be allocated). First, the garbage collector might not do compaction, which is to say it does not defragment the memory. Even a collector that does compaction may not do it perfectly well. Second, the garbage collector typically splits the memory area into regions that it reserves for different kinds of objects, and it may not think to take free memory from the region that has it to give to the region that needs it.
The CMS garbage collector does not do compaction, while the others (the serial, parallel, parallelold, and G1) do. The default collector in Java 8 is ParallelOld.
All garbage collectors split memory into regions, and, AFAIK, all of them are too lazy to try very hard to prevent an OOM error. The command line option
-XX:+PrintGCDetails is very helpful for some of the collectors in showing the sizes of the regions and how much free space they have.
It is possible to experiment with different garbage collectors and tuning options. Regarding my question, the
G1 collector (enabled with the JVM flag
-XX:+UseG1GC) solved the issue I was having. However, this was basically down to chance (in other situations, it OOMs more quickly). Some of the collectors (the serial, cms, and G1) have extensive tuning options for selecting the sizes of the various regions, to enable you to waste time in futilely trying to solve the problem.
Ultimately, the real solutions are rather unpleasant. First, is to install more RAM. Second, is to use smaller arrays. Third, is to use
ByteBuffer.allocateDirect. Direct byte buffers (and their int/float/double wrappers) are array-like objects with array-like performance that are allocated on the OS's native heap. The OS heap uses the CPU's virtual memory hardware and is free from fragmentation issues and can even effectively use the disk's swap space (allowing you to allocate more memory than available RAM). A big drawback, however, is that the JVM doesn't really know when direct buffers should be deallocated, making this option more desirable for long-lived objects. The final, possibly best, and certainly most unpleasant option is to allocate and deallocate memory natively using JNI calls, and use it in Java by wrapping it in a