I allocated a very large byte array for threads to read and write bytes in the array. Write operation is to assign the new byte directly to the value in the array like byte[i] = byte2;

I can ensured that there will be no conflict for those operation (same section in the byte array will not write by 2 different threads. when a section in reading, no write operation will perform by other threads). My concern is will the modification to array been instantly available to other threads. I know there might be memory fence, which other threads may still read the old values in the array.

If the problem exists, how to avoid? will volatile byte[] store; works in this circumstance?


will the modification to array been instantly available to other threads.

not without a write fence for the writer and a read fence for the reader.

I know there might be memory fence, which other threads may still read the old values in the array.

You will need to use one of those for the reader and writer (not one per byte, one per operation)

will volatile byte[] store; works in this circumstance?

It won't do what you want, though it will slow down your application. When you do

store[i] = b;

This added a read fence as you are reading the store reference to the byte[].

The best solution is to use Unsafe to have complete control over these read write operations. See the code for AtomicIntegerArray.

However, without going down that road you can do a dummy operation like this which is not as efficient/elegant, but a lot simpler to implement.

private final AtomicBoolean fence = new AtomicBoolean();

public void readFence() {

public void writeFence() {

For this to work, you must do a writeFence() after all writes, and a readFence() before all reads.

If you are going down the more low level route you might find using off heap memory an advantage. Off heap memory can store very large (TBs) amounts of data without impacting the GC.

  • Why will volatile not work in his case? It will make sure all threads always have the proper vaule, no? Nvm, I found this: stackoverflow.com/questions/2236184/… – Christophe De Troyer Feb 5 '16 at 13:30
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    @ChristopheDeTroyer correct, all threads will read the right value of the byte[] reference using a read fence. There is no write fence and the contents of the byte[] might no be visible. volatile like final only applies to the reference to the array, not operations on the array. e.g. final bytes[] store = { .. } you can change the contents. You could do a dummy store = store; to trigger a write fence, but I find this more hacky than what proposed. The other downside is there is a memory barrier on every operation which can slow down the copies by an order of magnitude. – Peter Lawrey Feb 5 '16 at 13:33
  • Thank you, I think I can find my answer in the AtomicIntegerArray. I still don't understand what is the fence in your example do to the store to make the write fence. – Shisoft Feb 5 '16 at 13:37
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    I know that you know, but I think it'd still be interesting to mention the old "assign volatile array to itself" trick. That's still the only portable way (what with unsafe being an implementation detail theoretically) if you don't want to use the AtomicArray classes. – Voo Feb 5 '16 at 17:21
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    I have already migrate my application to use unsafe for backend store. It seems more easy to use than my byte array solution since it has internal encoder and decoder for primary types and able to break the 2G size limit. – Shisoft Feb 6 '16 at 18:21

You can use SynchronizedList for this Example

byte[] c = new byte[];
List list = Collections.synchronizedList(Arrays.asList(c));

It will be thread-safely

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    You have to replace the entire byte[] each time for this to work. It wouldn't work for portions of a byte[]. – Peter Lawrey Feb 5 '16 at 13:30
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    Actually, I don't want to do any copy on the byte array – Shisoft Feb 5 '16 at 13:32

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