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When do we use AtomicReference. Is it needed to create objects in all multithreaded programs. Can you provide a simple example where AtomicReference should be used.

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3 Answers 3

up vote 69 down vote accepted

Atomic reference should be used in a setting where you need to do simple atomic (i.e., thread safe, non-trivial) operations on a reference, for which monitor-based synchronization is not appropriate. Suppose you want to check to see if a specific field only if the state of the object remains as you last checked:

AtomicReference<Object> cache = new AtomicReference<Object>();

Object cachedValue = new Object();
cache.set(cachedValue);

//... time passes ...
Object cachedValueToUpdate = cache.get();
//... do some work to transform cachedValueToUpdate into a new version
Object newValue = someFunctionOfOld(cachedValueToUpdate);
boolean success = cache.compareAndSet(cachedValue,cachedValueToUpdate);

Because of the atomic reference semantics, you can do this even if the cache object is shared amongst threads, without using synchronized. In general, you're better off using synchronizers or the java.util.concurrent framework rather than bare Atomic* unless you know what you're doing.

Two excellent dead-tree references which will introduce you to this topic: Herlihy's excellent Art of Multiprocessor Programming and Java Concurrency in Practice.

Note that (I don't know if this has always been true) reference assignment (i.e., =) is itself atomic (updating primitive 64-bit types(long/double) may not be atomic; but updating a reference is always atomic, even if it's 64 bit) without explicitly using an Atomic*. See the JLS 3ed, Section 17.7,

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8  
Correct me if I'm wrong, but it seems like the key to needing this is because you need to do a "compareAndSet". If all I needed to do was set I wouldn't need the AtomicObject at all because of reference updates themselves being atomic? –  sMoZely Jan 20 '13 at 21:46
    
Is it safe to do cache.compareAndSet(cachedValue, someFunctionOfOld(cachedValueToUpdate))? I.e. inline the computation? –  kaqqao Dec 10 '13 at 12:07
2  
@veggen Function arguments in Java are evaluated before function itself, so inlining makes no difference in this case. Yes, it is safe. –  Dmitry Feb 19 '14 at 12:54
5  
@sMoZely That is correct, but if you're not using AtomicReference you should mark the variable volatile because while the runtime guarantees that reference assignment is atomic, the compiler may perform optimizations under the assumption that the variable was not being modified by other threads. –  kbolino Mar 14 '14 at 17:51
    
@kbolino only if you change your AtomicReference field (cache in the code above) to a different AtomicReference. If you keep the same one, like in the answer, you shouldn't need volatile –  Brad Cupit Mar 25 '14 at 21:54

An atomic reference is ideal to use when you need to share and change an immutable object between multiple threads. That is a super dense statement so I will break it down a bit.

First, an immutable object is an object that is effectively not changed after construction. Frequently and immutable object's methods return new instances of that same object. Some examples include the wrapper classes of Long and Double, as well as String, just to name a few. (According to Programming Concurrency on the JVM immutable objects are a critical part of modern concurrency).

Next, why AtomicReference is better than a volatile object for sharing that shared value. A simple code example will show the difference.

volatile String sharedValue;
static final Object lock=new Object();
void modifyString(){
  synchronized(lock){
    sharedValue=sharedValue+"something to add";
  }
}
void useStringExample(){
  System.out.println(sharedValue)
}

Every time you want to modify the string referenced by that volatile field based on its current value, you first need to obtain a lock on that object. This prevents some other thread from coming in during the meantime and changing the value in the middle of the new string concatenation. Then when your thread resumes, you clobber the work of the other thread. But honestly that code will work, it looks clean, and it would make most people happy.

Slight problem. It is slow. Especially if there is a lot of contention of that lock Object. Thats because most locks require an OS system call, and your thread will block and be context switched out of the CPU to make way for other processes.

The other option is to use an AtomicRefrence.

public static AtomicReference<String> shared = new AtomicReference<>();
String init="Inital Value";
shared.set(init);
//now we will modify that value
String prevValue=shared.get();
String newValue=shared.get()+"lets add something";
boolean worked=shared.compareAndSet(prevValue,newValue);

Now why is this better? Honestly that code is a little less clean than before. But there is something really important that happens under the hood in AtomicRefrence, and that is compare and swap. It is a single CPU instruction, not an OS call, that makes the switch happen. That is a single instruction on the CPU. And because there are no locks, there is no context switch in the case where the lock gets exercised which saves even more time!

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3  
Your two examples behave differently. You'd have to loop on worked to get the same semantics. –  CurtainDog Oct 13 '14 at 20:32
    
I think you should initialize the value inside the AtomicReference constructor, otherwise another thread may still see the value null before you call shared.set. (Unless shared.set is run in a static initializer.) –  Henno Vermeulen May 20 at 9:35

Here is a use case for AtomicReference:

Consider this class that acts as a number range, and uses individual AtmomicInteger variables to maintain lower and upper number bounds.

public class NumberRange {
    // INVARIANT: lower <= upper
    private final AtomicInteger lower = new AtomicInteger(0);
    private final AtomicInteger upper = new AtomicInteger(0);

    public void setLower(int i) {
        // Warning -- unsafe check-then-act
        if (i > upper.get())
            throw new IllegalArgumentException(
                    "can't set lower to " + i + " > upper");
        lower.set(i);
    }

    public void setUpper(int i) {
        // Warning -- unsafe check-then-act
        if (i < lower.get())
            throw new IllegalArgumentException(
                    "can't set upper to " + i + " < lower");
        upper.set(i);
    }

    public boolean isInRange(int i) {
        return (i >= lower.get() && i <= upper.get());
    }
}

Both setLower and setUpper are check-then-act sequences, but they do not use sufficient locking to make them atomic. If the number range holds (0, 10), and one thread calls setLower(5) while another thread calls setUpper(4), with some unlucky timing both will pass the checks in the setters and both modifications will be applied. The result is that the range now holds (5, 4)an invalid state. So while the underlying AtomicIntegers are thread-safe, the composite class is not. This can be fixed by using a AtomicReference instead of using individual AtomicIntegers for upper and lower bounds.

public class CasNumberRange {
    //Immutable
    private static class IntPair {
        final int lower;  // Invariant: lower <= upper
        final int upper;
        ...
    }
    private final AtomicReference<IntPair> values =
        new AtomicReference<IntPair>(new IntPair(0, 0));

    public int getLower() { return values.get().lower; }
    public int getUpper() { return values.get().upper; }

    public void setLower(int i) {
        while (true) {
            IntPair oldv = values.get();
            if (i > oldv.upper)
                throw new IllegalArgumentException(
                   "Can't set lower to " + i + " > upper");
            IntPair newv = new IntPair(i, oldv.upper);
            if (values.compareAndSet(oldv, newv))
                return;
        }
    }
    // similarly for setUpper
}
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