Running the code below on Windows 10 / OpenJDK 11.0.4_x64 produces as output used: 197 and expected usage: 200. This means that 200 byte arrays of one million elements take up approx. 200MB RAM. Everything fine.

When I change the byte array allocation in the code from new byte[1000000] to new byte[1048576] (that is, to 1024*1024 elements), it produces as output used: 417 and expected usage: 200. What the heck?

import java.io.IOException;
import java.util.ArrayList;

public class Mem {
    private static Runtime rt = Runtime.getRuntime();
    private static long free() { return rt.maxMemory() - rt.totalMemory() + rt.freeMemory(); }
    public static void main(String[] args) throws InterruptedException, IOException {
        int blocks = 200;
        long initiallyFree = free();
        System.out.println("initially free: " + initiallyFree / 1000000);
        ArrayList<byte[]> data = new ArrayList<>();
        for (int n = 0; n < blocks; n++) { data.add(new byte[1000000]); }
        long remainingFree = free();
        System.out.println("remaining free: " + remainingFree / 1000000);
        System.out.println("used: " + (initiallyFree - remainingFree) / 1000000);
        System.out.println("expected usage: " + blocks);

Looking a bit deeper with visualvm, I see in the first case everything as expected:

byte arrays take up 200mb

In the second case, in addition to the byte arrays, I see the same number of int arrays taking up the same amount of RAM as the byte arrays:

int arrays take up additional 200mb

These int arrays, by the way, do not show that they are referenced, but I can't garbage collect them... (The byte arrays show just fine where they are referenced.)

Any ideas what is happening here?

  • Try changing data from ArrayList<byte[]> to byte[blocks][], and in your for loop: data[i] = new byte[1000000] to eliminate dependencies on the internals of ArrayList
    – jalynn2
    Oct 22, 2019 at 14:43
  • Could it have something to do with the JVM internally using an int[] to emulate a large byte[] for better spatial locality?
    – Jacob G.
    Oct 22, 2019 at 14:50
  • @JacobG. it definitely looks something internal, but there doesn't seem to be any indication in the guide.
    – Kayaman
    Oct 22, 2019 at 15:11
  • Just two observations: 1. If you subtract 16 from 1024*1024 it seems works as expected. 2. The behaviour with a jdk8 seems to be different then what can be observed here.
    – second
    Oct 24, 2019 at 14:42
  • @second Yeah, the magical limit obviously is whether the array takes up 1MB of RAM or not. I assume that if you substract just 1, then the memory is padded for runtime efficiency and/or the management overhead for the array counts to the 1MB... Funny that JDK8 behaves differently!
    – Georg
    Oct 25, 2019 at 13:11

1 Answer 1


What this describes is the out-of-the-box behaviour of the G1 garbage collector which commonly defaults to 1MB "regions" and became a JVM default in Java 9. Running with other GCs enabled gives varying numbers.

any object that is more than half a region size is considered "humongous"... For objects that are just slightly larger than a multiple of the heap region size, this unused space can cause the heap to become fragmented.

I ran java -Xmx300M -XX:+PrintGCDetails and it shows heap is exhausted by humongous regions:

[0.202s][info   ][gc,heap        ] GC(51) Old regions: 1->1
[0.202s][info   ][gc,heap        ] GC(51) Archive regions: 2->2
[0.202s][info   ][gc,heap        ] GC(51) Humongous regions: 296->296
[0.202s][info   ][gc             ] GC(51) Pause Full (G1 Humongous Allocation) 297M->297M(300M) 1.935ms
[0.202s][info   ][gc,cpu         ] GC(51) User=0.01s Sys=0.00s Real=0.00s
Exception in thread "main" java.lang.OutOfMemoryError: Java heap space

We want our 1MiB byte[] to be "less than half the G1 region size" so adding -XX:G1HeapRegionSize=4M gives a functional application:

[0.161s][info   ][gc,heap        ] GC(19) Humongous regions: 0->0
[0.161s][info   ][gc,metaspace   ] GC(19) Metaspace: 320K->320K(1056768K)
[0.161s][info   ][gc             ] GC(19) Pause Full (System.gc()) 274M->204M(300M) 9.702ms
remaining free: 100
used: 209
expected usage: 200

In depth overview of G1: https://www.oracle.com/technical-resources/articles/java/g1gc.html

Crushing detail of G1: https://docs.oracle.com/en/java/javase/13/gctuning/garbage-first-garbage-collector-tuning.html#GUID-2428DA90-B93D-48E6-B336-A849ADF1C552

  • I have same issues with serial GC and with long array that takes 8MB (and was fine with size 1024-1024-2) and changing G1HeapRegionSize did not do anything in my case
    – GotoFinal
    Oct 29, 2019 at 17:04
  • I'm unclear on this. Can you clarify the java invocation used and output of the above code with a long[]
    – drekbour
    Oct 29, 2019 at 18:00
  • @GotoFinal, I don't observe any problem not explained by the above. I tested the code with long[1024*1024] which gives an expected usage of 1600M With G1, varying by -XX:G1HeapRegionSize [1M used: 1887, 2M used: 2097, 4M used: 3358, 8M used: 3358, 16M used: 3363, 32M used: 1682]. With -XX:+UseConcMarkSweepGC used: 1687. With -XX:+UseZGC used: 2105. With -XX:+UseSerialGC used: 1698
    – drekbour
    Oct 29, 2019 at 20:44
  • gist.github.com/c0a4d0c7cfb335ea9401848a6470e816 just code like that, without changing any GC options it will print used: 417 expected usage: 400 but if I will remove that -2 it will change to used: 470 so around 50MB are gone, and 50 * 2 longs is definitely much less than 50MB
    – GotoFinal
    Oct 29, 2019 at 20:57
  • 1
    Same thing. The difference is ~50MB, and you have 50 "humongous" blocks. Here's the GC detail: 1024*1024 -> [0.297s][info ][gc,heap ] GC(18) Humongous regions: 450->450 1024*1024-2 -> [0.292s][info ][gc,heap ] GC(20) Humongous regions: 400->400 It proves those last two longs force G1 to allocate another 1MB region just to store 16 bytes in.
    – drekbour
    Oct 29, 2019 at 22:00

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