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  • Here I have Java and C code that tries to do an Atomic increment operation using CAS.
  • To increment an long variable from 0 to 500,000,000.
  • C : Time taken : 7300ms
  • Java : Time Taken : 2083ms
  • Can any one double check these results? Because I just can't believe them.
  • Thanks

Java code:

import java.util.concurrent.TimeUnit;
import java.util.concurrent.atomic.AtomicLong;

public class SmallerCASTest {

    public static void main(String[] args){
        final long MAX = 500l * 1000l * 1000l;
        final AtomicLong counter = new AtomicLong(0);

        long start = System.nanoTime();
        while (true) {
            if (counter.incrementAndGet() >= MAX) {
                break;
            }
        }

        long casTime = TimeUnit.NANOSECONDS.toMillis(System.nanoTime() - start);
        System.out.println("Time Taken=" + casTime + "ms");
    }

}

C code:

#include <stdio.h>
#include <stdlib.h>
#include <time.h>
#define NITER 500000000


int main (){
   long val = 0;     
   clock_t starttime = clock ();
    while (val < NITER){
      while (1){
        long current = val;
        long next = current+1;
        if ( __sync_bool_compare_and_swap (&val, current, next))
            break;
      }
     } 
   clock_t castime = (clock()-starttime)/ (CLOCKS_PER_SEC / 1000);
   printf ("Time taken : %d ",castime);
}

run.sh

#!/bin/bash

gcc -O3 test.c -o test.o
echo -e "\nC"
./test.o
javac SmallerCASTest.java
echo -e "\nJava"
java SmallerCASTest

Other details:

System : Linux XXXXXXXXX #1 SMP Thu Mar 22 08:00:08 UTC 2012 x86_64 x86_64 x86_64 GNU/Linux

gcc --version:
 gcc (GCC) 4.4.6 20110731 (Red Hat 4.4.6-3)

java -version: 
java version "1.6.0_31"
Java(TM) SE Runtime Environment (build 1.6.0_31-b04)
Java HotSpot(TM) 64-Bit Server VM (build 20.6-b01, mixed mode)
share|improve this question
10  
You could get better results in Java by warming up the JVM before measuring. And it is conceivable that because your code is single threaded, the JVM optimises the need for synchronization away, effectively incrementing a long variable. It might even determine that the incremented variable is never used, and optimise the whole loop away... etc... –  assylias Oct 9 '12 at 11:50
    
JVM isn't that smart, yet. –  irreputable Oct 9 '12 at 17:36
2  
can someone reproduce the number for the java example? on my machine the java example takes 7500ms –  irreputable Oct 9 '12 at 20:38
    
On my machine (Xeon X3450), the java version takes ~4700 ms, the C version ~4600 ms, a C version using __sync_add_and_fetch() ~3800 ms. –  janneb Oct 10 '12 at 13:17
    
@janneb, by any chance are you using mac? what os, version of java and c, also you using openJDK or sunJDK. I have found that on mac both programs perform the same. Also results are different with OpenJDK. I am specifically interested in sunJdk, on linux it tends to outperform C. –  Jigar Oct 12 '12 at 10:08
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3 Answers

You are comparing apples with oranges as I am sure you expected. The java version is a true CAS with retry on failure while the C version is using what I'd call in java a synchronized form.

See this question for more details.

See this answer to that question for supporting narrative where it says A full memory barrier is created when this function is invoked, i.e. in java terms, this is a synchronized call.

Try using _compare_and_swap in the same way AtomicLong uses its java equivalent, i.e. spin on the function until the value changes to what you want it to be.

Added:

I cannot find a definitive C++ equivalent of a java AtomicLong but that does not mean there isn't one. Essentially, an AtomicLong can be changed by any thread at any time and just one of them succeeds. However, the change will be consistent, i.e. the change will be the result of the change by one or other of the threads, it will not be a combination of the two. If thread A attempts to change the value to 0xffff0000 (or the equivalent 64bit number) while thread B attempts a change to 0x0000ffff (ditto) the result will be either of the two values, more specifically it will not be 0x00000000 or 0xffffffff (unless of course a third thread gets involved).

Essentially, an AtomicLong has no synchronisation at all other than this.

share|improve this answer
    
As I understand, are you trying to say that the __sync_** is creating a memory barrier, and compiler is unable to optimize code around it, hence the slowdown? If so, is there some alternative in GCC, that I could use achieve equivalent results as java? (the _compare_and_swap link you provided is pointing to some "XL C for AIX, V12.1" compiler, which I don't think I can use.) –  Jigar Oct 9 '12 at 13:11
    
Not a C++ guru - sorry. I don't know of an equivalent, perhaps someone else will suggest one. –  OldCurmudgeon Oct 9 '12 at 13:23
    
... but this may be a good start. It looks like just using a volatile may be an effective equivalent. Actually - don't go there, just use a volatile. –  OldCurmudgeon Oct 9 '12 at 13:28
2  
@OldCurmudgeon "just use a volatile" -- no, not for C or C++. semantics/guarantees in Java vs C or C++ are different. don't go there :) –  justin Oct 9 '12 at 14:52
1  
@OldCurmudgeon C++ (and C) execute using sequential consistency. e.g. the compiler and/or the hardware are free to reorder instructions so long as they happen "as-if" they were not reordered. accesses and reads/writes to memory are by default unfettered, may be reordered, interrupted, etc. the exact implementation of an atomic operation varies by architecture. atomicity under the latest C++ and C memory models is in effect a guarantee that an atomic operation on a memory region cannot be interrupted (e.g. context switch) or that the region may not accessed from another thread at the same time. –  justin Oct 9 '12 at 16:03
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EDIT Indeed, java seems to implement incrementAndGet using a CAS operation, as you point out.

My testing seems to suggest that the C and Java versions have roughly equivalent performance (which makes sense, as the time consuming part is the atomic rather than any optimization of the rest that the java or C compilers manage to do).

So on my machine (Xeon X3450), the java version takes ~4700 ms, the C version ~4600 ms, a C version using __sync_add_and_fetch() ~3800 ms (suggesting that java could be improved here instead of implementing all the atomic operations on top of CAS).

java version is


java version "1.6.0_24"
OpenJDK Runtime Environment (IcedTea6 1.11.4) (6b24-1.11.4-1ubuntu0.10.04.1)
OpenJDK 64-Bit Server VM (build 20.0-b12, mixed mode)

GCC is 4.4.3, x86_64.

OS is Ubuntu 10.04 x86_64.

So I can only conclude that something seems fishy in your tests.

share|improve this answer
2  
Don't think so, check the source of incrementAndGet. pastebin.com/Cu8Q7aVy –  Jigar Oct 9 '12 at 11:58
    
Nopes, nothing's proven fishy yet. As you said, you are using OpenJDK, try sunJDK, then we can talk about my tests being fishy. Regardless, thanks for running these tests, I'll remove my downvote now. –  Jigar Oct 12 '12 at 10:40
    
@Jigar: Well, I do think it's quite fishy if sunjdk can do "lock cmpxchg" a factor of 3 times faster than C or openjdk. It would be interesting to see the asm generated (is that possible in java somehow?). –  janneb Oct 12 '12 at 11:02
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Because Java is awesome?

The java version takes 4ns for each loop. That is about right. An uncontended CAS is actually a CPU local operation, it should be very fast. (edit: probably not 4ns fast!)

Java achieves that speed by aggressive runtime optimization, the code is inlined and becomes just a couple of machine instructions, i.e. as fast as one can hand-code in assembly.

If the gcc version couldn't inline the function call, that's a big overhead per loop.

share|improve this answer
2  
There's no function call in the GCC version, __sync_bool_compare_and_swap is a compiler builtin which on x86_64 is expanded into "lock cmpxchgq". –  janneb Oct 9 '12 at 20:18
    
then there shouldn't be much difference. I just ran OP's java example and it takes 7500ms on my machine. I don't believe OP's machine can be that faster than mine, so he probably screwed up his test numbers. –  irreputable Oct 9 '12 at 20:37
    
I can assure you that I have not screwed up any numbers. I have ran these types of tests multiple times, with more than one-pair of eyes to review. I was running these tests, with multiple threads, and multiple counters. We were shocked with the results, hence we wrote a minimal test that highlights my discovery. Also we are using amazon's EC2 standard-medium instance to run these tests. aws.amazon.com/ec2/instance-types .Results differ with, mac and openJDK. But I am interested only in SunJdk on linux. –  Jigar Oct 12 '12 at 10:32
    
@Jigar ask experts: altair.cs.oswego.edu/mailman/listinfo/concurrency-interest –  irreputable Oct 12 '12 at 14:41
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