Note: All the answers so far, even the accepted one, seem to answer the question by saying that Runtime.getRuntime().freeMemory(); gives you the amount of memory which may be allocated until an out-of-memory error occurs. However: this is wrong.
The approximate amount of memory which may be allocated until an out-of-memory error occurs, i.e., the free memory is likely
long presumableFreeMemory = Runtime.getRuntime().maxMemory() - allocatedMemory;
long allocatedMemory = (Runtime.getRuntime().totalMemory()-Runtime.getRuntime().freeMemory());
If you launch the JVM via an -mx parameter (or -Xmx) you specify the maximum amount available to the JVM.
Runtime.getRuntime().maxMemory() will give you this amount. From this amount of system memory the JVM will allocate memory in chunks, say for example blocks of 64 mb. At start, the JVM will only allocate such a chunk from the system and not the full amount.
Runtime.getRuntime().totalMemory() gives the total memory allocated from the system, while
Runtime.getRuntime().freeMemory() gives you the free memory within the total memory allocated.
long definitelyFreeMemory = Runtime.getRuntime().freeMemory();
is the free memory already reserved by the JVM, but it is likely just a small amount. And you will likely get
presumableFreeMemory. Of course, you may get an out-of-memory exception even if you tried to allocate an amount smaller than
presumableFreeMemory. This may happen if the JVM does not get the next memory chunk from the system. However, on most systems this will never happen and the system will rather start swapping - a situation you like to avoid. W.r.t. to the original question: if -mx is set to a reasonable value, then
presumableFreeMemory is a good indicator for the free memory.