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.

The Java language spec defines semantics of final fields in section 17.5:

The usage model for final fields is a simple one. Set the final fields for an object in that object's constructor. Do not write a reference to the object being constructed in a place where another thread can see it before the object's constructor is finished. If this is followed, then when the object is seen by another thread, that thread will always see the correctly constructed version of that object's final fields. It will also see versions of any object or array referenced by those final fields that are at least as up-to-date as the final fields are.

My question is - does the 'up-to-date' guarantee extend to the contents of nested arrays, and nested objects?

In a nutshell: If one thread assigns a mutable object graph to a final field in an object, and the object graph is never updated, can all threads safely read that object graph via the final field?

An example scenario:

  1. Thread A constructs a HashMap of ArrayLists, then assigns the HashMap to final field 'myFinal' in an instance of class 'MyClass'
  2. Thread B sees a (non-synchronized) reference to the MyClass instance and reads 'myFinal', and accesses and reads the contents of one of the ArrayLists

In this scenario, are the members of the ArrayList as seen by Thread B guaranteed to be at least as up to date as they were when MyClass's constructor completed?

I'm looking for clarification of the semantics of the Java Memory Model and language spec, rather than alternative solutions like synchronization. My dream answer would be a yes or no, with a reference to the relevant text.

Updates:

  • I'm interested in the semantics of Java 1.5 and above, i.e. with the updated Java Memory Model introduced via JSR 133. The 'up-to-date' guarantee on final fields was introduced in this update.
share|improve this question

2 Answers 2

up vote 3 down vote accepted

In this scenario, are the members of the ArrayList as seen by Thread B guaranteed to be at least as up to date as they were when MyClass's constructor completed?

Yes, they are.

A thread is required to read memory when it encounters reference for the first time. Because hash map is constructed, all entries in it are brand new, then the references to objects are up-to-date to what they were when the constructor has finished.

After that initial encounter, the usual visibility rules apply. So, when other thread changes non-final field in the final references, the other thread may not see that change, but it still will see the reference that came out of constructor.

In reality, it means that if you do not modify final hash-map after the constructor, its contents are constants for all threads.

EDIT

I knew that I've seen this guarantee somewhere before.

Here is a paragraph of interest from this article that describes JSR 133

Initialization safety

The new JMM also seeks to provide a new guarantee of initialization safety -- that as long as an object is properly constructed (meaning that a reference to the object is not published before the constructor has completed), then all threads will see the values for its final fields that were set in its constructor, regardless of whether or not synchronization is used to pass the reference from one thread to another. Further, any variables that can be reached through a final field of a properly constructed object, such as fields of an object referenced by a final field, are also guaranteed to be visible to other threads as well. This means that if a final field contains a reference to, say, a LinkedList, in addition to the correct value of the reference being visible to other threads, also the contents of that LinkedList at construction time would be visible to other threads without synchronization. The result is a significant strengthening of the meaning of final -- that final fields can be safely accessed without synchronization, and that compilers can assume that final fields will not change and can therefore optimize away multiple fetches.

share|improve this answer
    
The things I'm worried about are stale references to objects in the ArrayLists, and compiler reorderings, e.g. making an ArrayList instance available in the HashMap before the ArrayList is fully initialized. I'm keen to know what ordering guarantees are offered when assigning a mutable object graph to a final field. –  mattbh May 14 '10 at 0:20
    
@mattbh. If mutable object had existed before the constructor call, then the usual visibility constraints apply, but the final reference seen by all threads will point to the same object. Though, in absence of synchronization, each thread may see it a little different. –  Alexander Pogrebnyak May 14 '10 at 1:12
    
@Alexander. Thanks for your answer. Is there anything in the specs which prevents the compiler from making the references to those inner objects available before their (non-final) fields are initialised? The compiler is free to do this normally for non-final fields. The FinalFieldExample class in section 17.5 of the Java spec illustrates how this reordering is allowed to happen. –  mattbh May 15 '10 at 13:03
    
@mattbh. If you don't shoot yourself in the foot by sharing the half constructed objects with other threads ( say by passing this inside constructor or initializer ), then nobody, but your calling thread will see the updates to non-final fields. In the context of the same thread it sees the most up-to-date value of the field. The FinalFieldExample shows what troubles may beset you after you exit the constructor and start calling unsynchronized methods and change state of the non-final fields. If, on the other hand, you never change them after the constructor, they will remain constant. –  Alexander Pogrebnyak May 15 '10 at 13:20
    
@Alexander: The FinalFieldExample is showing something more insidious than that -- a case where fields are initialised once in the constructor, then left unchanged, but where another thread sees the reference to the object, and sees values in that object as they were before the constructor completed. That's what I'm worried about here: references to objects being made visible before the post-constructor state is made visible. –  mattbh May 17 '10 at 23:49

If the constructor is written like this, you should have no issue:

public class MyClass {
    public final Map myFinal;
    public MyClass () {
        Map localMap = new HashMap();
        localMap.put("key", new ArrayList());
        this.myFinal = localMap;
    }
}

This is because the map is fully initialized before it's assigned to the public reference. Once the constructor completes, the final Map will be up-to-date.

share|improve this answer
    
What if the ArrayList is populated with arbitrary mutable values? Are their contents guaranteed to be visible (and up to date) from other threads? –  mattbh May 14 '10 at 2:39
    
yes, anything that's done before the assignment of the final variable, is visible to other threads. –  irreputable May 14 '10 at 17:07
    
@mattbh: if the members of the arraylist are initialized before the map is assigned to this.myFinal, then they will be up-to-date and not visible prior to the assignment (in my example above). However, if elements are assigned to the list after the constructor is called then all bets are off and the answer is "it depends." –  eqbridges May 15 '10 at 4:12
    
@irreputable: not quite -- in my example above there's a case where localMap is not visible to other threads prior to the assignment. please clarify. thanks! –  eqbridges May 15 '10 at 4:13
    
@eqbridges Thanks, do you have a reference in the Java spec or similar that I could look at which confirms the 'yes' answer? Section 17.5.1 seems to define things formally, but I can't quite parse the parts about the dereference chain and memory chain. –  mattbh May 15 '10 at 13:14

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.