Consider what makes up a Java process.
- the JVM (a C program)
- JNI Data
- Java byte codes
- Java data
Notably, they ALL live in the C heap (the JVM Heap is part of the C heap, naturally).
In the Java heap is simply Java byte codes and the Java data. But what is also in the Java heap is "free space".
The typical (i.e. Sun) JVM only grows it Java Heap as necessary, but never shrinks it. Once it reaches its defined maximum (-Xmx512M), it stops growing and deals with whatever is left. When that maximum heap is exhausted, you get the OutOfMemory exception.
What that Xmx512M option DOES NOT do, is limit the overall size of the process. It limits only the Java Heap part of the process.
For example, you could have a contrived Java program that uses 10mb of Java heap, but calls a JNI call that allocates 500MB of C Heap. You can see how your process size is large, even though the Java heap is small. Also, with the new NIO libraries, you can attach memory outside of the heap as well.
The other aspect that you must consider is that the Java GC is typically a "Copying Collector". Which means it takes the "live" data from memory it's collecting, and copies it to a different section of memory. This empty space that is copies to IS NOT PART OF THE HEAP, at least, not in terms of the Xmx parameter. It's, like, "the new Heap", and becomes part of the heap after the copy (the old space is used for the next GC). If you have a 512MB heap, and it's at 510MB, Java is going to copy the live data someplace. The naive thought would be to another large open space (like 500+MB). If all of your data were "live", then it would need a large chunk like that to copy into.
So, you can see that in the most extreme edge case, you need at least double the free memory on your system to handle a specific heap size. At least 1GB for a 512MB heap.
Turns out that not the case in practice, and memory allocation and such is more complicated than that, but you do need a large chunk of free memory to handle the heap copies, and this impacts the overall process size.
Finally, note that the JVM does fun things like mapping in the rt.jar classes in to the VM to ease startup. They're mapped in a read only block, and can be shared across other Java processes. These shared pages will "count" against all Java processes, even though it is really only consuming physical memory once (the magic of virtual memory).
Now as to why your process continues to grow, if you never hit the Java OOM message, that means that your leak is NOT in the Java heap, but that doesn't mean it may not be in something else (the JRE runtime, a 3rd party JNI librariy, a native JDBC driver, etc.).