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Another question made me wonder if the seqlock can be efficiently implemented with a volatile version counter in Java.

Here's a prototypical implementation, for the case there will only ever be a single writer thread:

class Seqlock {
  private volatile long version = 0;
  private final byte[] data = new byte[10];

  void write(byte[] newData) {
    version++;  // 1
    System.arraycopy(newData, 0, data, 0, data.length);  // 2
    version++;  // 3
  }

  byte[] read() {
    long v1, v2;
    byte[] ret = new byte[data.length];
    do {
      v1 = version; // 4
      System.arraycopy(data, 0, ret, 0, data.length);  // 5
      v2 = version; // 6
    } while (v1 != v2 || (v1 & 1) == 1);
  }
}

The basic idea is to increment the version number before and after writing, and for readers to check they got a "consistent" read by verifying that the version numbers were the same and even, as odd indicates a "write in progress".

There are all sorts of happens-before relationships between the key actions in the writer thread and readers threads since version is volatile.

I can't, however, see what prevents the write at (2) from moving up above (1) and thus cause a reader to see a write in progress.

For example, the following synchronization order of volatile reads and writes, using the labels in the comments next to each line (showing also the data reads and writes which are not volatile and thus not part of the synchronization order, indented):

1a (version is now 1)
  2a (not part of the synchronization order)
3 (version is now 2)
4 (read version == 2, happens before 3)
  5 (not part of the synchronization order)
6 (read version == 2, happens before 4 and hence 3)
1b (second write, version is now 3)
  2b (not part of the synchronization order)

ISTM that there is no happens-before between 5 (the read of the data) and 2b (the second write of the data, so it is possible for 2b to occur before the read and wrong data to be read.

If that's true, does declaring write() as synchronized help?

share|improve this question
    
i can answer the last question easily: declaring the write synchronized is meaningless if read is not synchronized. as for whether or not volatile works on its own, i'm still pondering that one. – jtahlborn Feb 7 '13 at 4:29
1  
may not be what you are looking for, but you can solve this problem very simply in java (with the same guarantees) using a simple volatile reference to a byte[] which is assigned in the write() method. – jtahlborn Feb 7 '13 at 4:38
    
I cannot understand your "synchronization order". How many threads do you have there? In the fourth line, what exactly do you mean by 4 (read version == 2, happens before 3)? What is happening first? I'd suggest that you draw a "table", each column is a thread, each line is "an instant". – Bruno Reis Feb 7 '13 at 5:38
    
Also, have you actually compared the performance of this with a similar class using a trivial synchronized {} block? The JVM is very, very good at handling synchronized blocks, in that it will have almost no impact in performance if the lock is not acquired (compared to a volatile read/write pair), and if it is acquired, then it will happily spin the thread a little bit before actually giving up and stopping the thread (ie, it will loop, something similar to what your code is doing, but without the extra work of pointlessly calling System.arraycopy and discarding the result) – Bruno Reis Feb 7 '13 at 5:44
    
Assuming you have multiple readers, they may suffer in performance with a synchronized block. In this case, compare your code with a locking version that uses ReentrantReadWriteLock instead of synchronized. – Bruno Reis Feb 7 '13 at 5:47
up vote 2 down vote accepted

In java you can implement a shared buffer (or other object) very simply:

public class SharedBuffer {

  private volatile byte[] _buf;

  public void write(byte[] buf) {
    _buf = buf;
  }

  public byte[] read() {
    // maybe copy here if you are worried about passing out the internal reference
    return _buf;
  }
}

obviously, this is not a "seqlock".

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