Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I recently came across this article which provided a nice intro to memory mapped files and how it can be shared between two processes. Here is the code for a process that reads in the file:

import java.io.File;
import java.io.FileNotFoundException;
import java.io.IOException;
import java.io.RandomAccessFile;
import java.nio.MappedByteBuffer;
import java.nio.channels.FileChannel;

public class MemoryMapReader {

 /**
  * @param args
  * @throws IOException 
  * @throws FileNotFoundException 
  * @throws InterruptedException 
  */
 public static void main(String[] args) throws FileNotFoundException, IOException, InterruptedException {

  FileChannel fc = new RandomAccessFile(new File("c:/tmp/mapped.txt"), "rw").getChannel();

  long bufferSize=8*1000;
  MappedByteBuffer mem = fc.map(FileChannel.MapMode.READ_ONLY, 0, bufferSize);
  long oldSize=fc.size();

  long currentPos = 0;
  long xx=currentPos;

  long startTime = System.currentTimeMillis();
  long lastValue=-1;
  for(;;)
  {

   while(mem.hasRemaining())
   {
    lastValue=mem.getLong();
    currentPos +=8;
   }
   if(currentPos < oldSize)
   {

    xx = xx + mem.position();
    mem = fc.map(FileChannel.MapMode.READ_ONLY,xx, bufferSize);
    continue;   
   }
   else
   {
     long end = System.currentTimeMillis();
     long tot = end-startTime;
     System.out.println(String.format("Last Value Read %s , Time(ms) %s ",lastValue, tot));
     System.out.println("Waiting for message");
     while(true)
     {
      long newSize=fc.size();
      if(newSize>oldSize)
      {
       oldSize = newSize;
       xx = xx + mem.position();
       mem = fc.map(FileChannel.MapMode.READ_ONLY,xx , oldSize-xx);
       System.out.println("Got some data");
       break;
      }
     }   
   }

  }

 }

}

I have, however, a few comments/questions regarding that approach:

If we execute the reader only on an empty file, i.e run

  long bufferSize=8*1000;
  MappedByteBuffer mem = fc.map(FileChannel.MapMode.READ_ONLY, 0, bufferSize);
  long oldSize=fc.size();

This will allocate 8000 bytes which will now extend the file. The buffer that this returns has a limit of 8000 and a position of 0, therefore, the reader can proceed and read empty data. After this happens, the reader will stop, as currentPos == oldSize.

Supposedly now the writer comes in (code is omitted as most of it is straightforward and can be referenced from the website) - it uses the same buffer size, so it will write first 8000 bytes, then allocate another 8000, extending the file. Now, if we suppose this process pauses at this point, and we go back to the reader, then the reader sees the new size of the file and allocates the remainder (so from position 8000 until 1600) and starts reading again, reading in another garbage...

I am a bit confused whether there is a why to synchronize those two operations. As far as I see it, any call to map might extend the file with really an empty buffer (filled with zeros) or the writer might have just extended the file, but has not written anything into it yet...

share|improve this question
    
Anytime I see "write" and "shared data", I think synchronization will be needed. –  duffymo Mar 3 at 17:39
    
I don't know what you mean by 'whether there is a why to synchronize', but opening lots of memory mapped files, or the same one multiple times, is a very bad idea anyway, for garbage collection reasons, as there is no well-defined time that the memory concerned can be released. And there's no particular advantage to mapping in tiny quantities like 8k: you may as well just use buffered streams, which have that much buffering by default, and none of this malarkey about what to do when the file is extended. Mapped files are best when used on a very small number, such as one, of very large files. –  EJP Mar 3 at 22:02
    
OK, got it - open one large file. Still, this is the mean for IPC, so I want to know how that can be achieved i..e one process writes, the other one reads, but in a way that we know the other process actually wrote sth before we read from it. This is the synchronization I am talking about –  Bober02 Mar 4 at 10:24
    
It is a file not a pipe. Using mmap() alone will not allow you to synchronize. The sample code does (ugly) busy polling. –  eckes May 26 at 20:07
add comment

2 Answers 2

up vote 1 down vote accepted

There are several ways.

  1. Let the writer acquire an exclusive Lock on the region that has not been written yet. Release the lock when everything has been written. This is compatible to every other application running on that system but it requires the reader to be smart enough to retry on failed reads unless you combine it with one of the other methods

  2. Use another communication channel, e.g. a pipe or a socket or a file’s metadata channel to let the writer tell the reader about the finished write.

  3. Write at a position in the file a special marker (being part of the protocol) telling about the written data, e.g.

    MappedByteBuffer bb;
    …
    // write your data
    
    bb.force();// ensure completion of all writes
    bb.put(specialPosition, specialMarkerValue);
    bb.force();// ensure visibility of the marker
    
share|improve this answer
    
By lock you mean a FileLock on the channel? –  Bober02 Mar 4 at 14:22
    
Yes, I mean FileLock. –  Holger Mar 4 at 14:25
add comment

I do a lot of work with memory-mapped files for interprocess communication. I would not recommend Holger's #1 or #2, but his #3 is what I do. But a key point is perhaps that I only ever work with a single writer - things get more complicated if you have multiple writers.

The start of the file is a header section with whatever header variables you need, most importantly a pointer to the end of the written data. The writer should always update this header variable after writing a piece of data, and the reader should never read beyond this variable. A thing called "cache coherency" that all mainstream CPU's have will guarantee that the reader will see memory writes in the same sequence they are written, so the reader will never read uninitialised memory if you follow these rules. (An exception is where the reader and writers are on different servers - cache coherency doesn't work there. Don't try to implement shared memory across different servers!)

There is no limit to how frequently you can update the end-of-file pointer - it's all in memory and there won't be any i/o involved, so you can update it each record or each message you write.

ByteBuffer has versions of 'getInt()' and 'putInt()' methods which take an absolute byte offset, so that's what I use for reading & writing the end-of-file marker...I never use the relative versions when working with memory-mapped files.

There's no way you should use the file size or yet another interprocess method to communicate the end-of-file marker and no need or benefit when you already have shared memory.

share|improve this answer
    
+1. You could state how you prevent two writers from trying to extend the file at the same place at the same time. I've also seen the header used to implement the locks themselves. –  EJP Apr 12 at 0:48
    
Store order will be respected on x86, but not any other "mainstream" CPU. Also your compiler/JVM may be allowed to re-order your stores (if they're not volatile or ordered.) –  Eloff May 29 at 22:52
    
Store order will be respected on all mainstream compilers. It's called "cache coherency". There were some experimental CPU's developed that don't respect "cache coherency" but they never became mainstream. I've used this technique for many years on a great many computers, Windows and Unix. –  Tim Cooper May 31 at 3:10
    
Remember we're not storing POJO's in the shared memory, we're using 'getInt()' etc. methods, and everything here is implicitly volatile. –  Tim Cooper May 31 at 3:23
add comment

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.