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I need to programmatically find out exactly how much memory a given Java Object is occupying including the memory occupied by the objects that it is referencing.

I can generate a memory heap dump and analyse the results using a tool. However it takes a considerable amount of time to generate a heap dump and for such a tool to read the dump to generate reports. Given the fact that I will probably need to do this several times, my work would be a lot more agile if I could throw in some code in my project that would give me this value "runtime".

How could I best achieve this?

ps: Specifically I have a collection of objects of type javax.xml.transform.Templates

marked as duplicate by Ciro Santilli 新疆改造中心 六四事件 法轮功, Roddy of the Frozen Peas, DNA java May 3 '15 at 17:46

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  • You can investigate your object graph during runtime by using reflection. – flybywire Apr 16 '09 at 17:57
  • What about the overhead on instances? This may also differ depending on the runtime and system (think x64...). – Lucero Apr 16 '09 at 18:01
  • I wouldnt call that an exact dupe. – Inisheer Apr 16 '09 at 18:10
  • Well, not exactly a dupe, as the original question failed to provide an answer usable in this context... – Varkhan Apr 16 '09 at 18:11
  • It provided several. – erickson Apr 16 '09 at 18:46
up vote 11 down vote accepted

You will need to use reflection for that. The resulting piece of code is too complicated for me to post here (although it will soon be available as part of a GPL toolkit I am building), but the main idea is:

  • An object header uses 8 bytes (for class pointer and reference count)
  • Each primitive field uses 1, 2, 4 or 8 bytes depending on the actual type
  • Each object reference (i.e. non-primitive) field uses 4 bytes (the reference, plus whatever the referenced object uses)

You need to treat arrays separately (8 bytes of header, 4 bytes of length field, 4*length bytes of table, plus whatever the objects inside are using). You need to process other types of objects iterating through the fields (and it's parents fields) using reflection.

You also need to keep a set of "seen" objects during the recursion, so as not to count multiple times objects referenced in several places.

  • 2
    For what it's worth, object header uses at least that much, but I think older JVMs use more. That's easy (enough) to verify, too, by simple test code (create a million objects, gc, sleep a bit, check out free memory -- not theoretically guaranteed to work, in practice does). – StaxMan Apr 16 '09 at 18:11
  • 2
    Also: 4 bytes is for 32-bit references. For 64-bit systems 8 bytes I think. – StaxMan Apr 16 '09 at 18:12
  • 1
    Maybe 64-bit VMs use compressed pointers... that would make sense. – Varkhan Apr 16 '09 at 18:18
  • 1
    Isn't it possible for different JVMs to be slightly different on some of this? – matt b Apr 16 '09 at 18:24
  • 1
    Yes, I think it is entirely possible. Which is why any such implementation is going to be a (hopefully good enough) approximate. – Varkhan Apr 16 '09 at 18:28

Looks like there is already a utility for doing this called Classmexer.

I haven't tried it myself, but I would go that route before I rolled my own.

  • 1
    +1 for the link. – Radu Murzea Apr 16 '12 at 13:01

A good generic solution is to use heap size delta. This involves minimal effort and is re-usable between any type of object / object graph. By instantiating and destroying your objects many times and garbage collecting in between, and then taking the average, you avoid compiler and JVM optimizations that alter results and get a fairly accurate result. If you need an EXACT answer down to the byte then this may not be the solution for you, but for all practical applications that I know of (profiling, memory requirement calcualtions) it works extremely well. The code below will do just that.

    public class Sizeof {
      public static void main(String[] args)
          throws Exception {
        // "warm up" all classes/methods that we are going to use:
        runGC();
        usedMemory();

        // array to keep strong references to allocated objects:
        final int count = 10000; // 10000 or so is enough for small ojects
        Object[] objects = new Object[count];

        long heap1 = 0;

        // allocate count+1 objects, discard the first one:
        for (int i = -1; i < count; ++i) {
          Object object;

    //// INSTANTIATE YOUR DATA HERE AND ASSIGN IT TO 'object':


          object=YOUR OBJECT;
    ////end your code here
          if (i >= 0) {
            objects[i] = object;
          }
          else {
            object = null; // discard the "warmup" object
            runGC();
            heap1 = usedMemory(); // take a "before" heap snapshot
          }
        }

        runGC();
        long heap2 = usedMemory(); // take an "after" heap snapshot:

        final int size = Math.round(((float)(heap2 - heap1)) / count);
        System.out.println("'before' heap: " + heap1 +
                           ", 'after' heap: " + heap2);
        System.out.println("heap delta: " + (heap2 - heap1) +
                           ", {" + objects[0].getClass() + "} size = " + size + " bytes");
      }

      // a helper method for creating Strings of desired length
      // and avoiding getting tricked by String interning:
      public static String createString(final int length) {
        final char[] result = new char[length];
        for (int i = 0; i < length; ++i) {
          result[i] = (char)i;
        }

        return new String(result);
      }

      // this is our way of requesting garbage collection to be run:
      // [how aggressive it is depends on the JVM to a large degree, but
      // it is almost always better than a single Runtime.gc() call]
      private static void runGC()
          throws Exception {
        // for whatever reason it helps to call Runtime.gc()
        // using several method calls:
        for (int r = 0; r < 4; ++r) {
          _runGC();
        }
      }

      private static void _runGC()
          throws Exception {
        long usedMem1 = usedMemory(), usedMem2 = Long.MAX_VALUE;

        for (int i = 0; (usedMem1 < usedMem2) && (i < 1000); ++i) {
          s_runtime.runFinalization();
          s_runtime.gc();
          Thread.currentThread().yield();

          usedMem2 = usedMem1;
          usedMem1 = usedMemory();
        }
      }

      private static long usedMemory() {
        return s_runtime.totalMemory() - s_runtime.freeMemory();
      }

      private static final Runtime s_runtime = Runtime.getRuntime();

    } // end of class
  • 1
    This is flawed by virtue of the fact that the gc() and runFinalization() methods are not deterministic. I.e.: they are only hints to the runtime to do those actions. It's perfectly legal for a runtime to ignore them. – Edward Q. Bridges Apr 16 '09 at 19:50
  • 1
    it is not flawed - they will be ignored sometimes as you say which is why the large number of iterations and averaging of results. – Peter Apr 16 '09 at 20:24
  • 1
    You could have at least credited the source of this code, even if you've tweaked it a bit: javaworld.com/javaworld/javatips/jw-javatip130.html – wolfcastle Oct 21 '10 at 3:02
  • This is not a good solution to the question, which is "How to programmatically determine how much memory a given Java object uses". – Matt Quigley Jan 20 '12 at 2:26

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