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This is a poll of sorts about common concurrency problems in Java. An example might be the classic deadlock or race condition or perhaps EDT threading bugs in Swing. I'm interested both in a breadth of possible issues but also in what issues are most common. So, please leave one specific answer of a Java concurrency bug per comment and vote up if you see one you've encountered.

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closed as not constructive by Bill the Lizard Oct 2 '11 at 1:00

As it currently stands, this question is not a good fit for our Q&A format. We expect answers to be supported by facts, references, or expertise, but this question will likely solicit debate, arguments, polling, or extended discussion. If you feel that this question can be improved and possibly reopened, visit the help center for guidance.If this question can be reworded to fit the rules in the help center, please edit the question.

4  
Why is this closed? This is useful both for other programmers begging concurrency in Java, and to have an idea of what classes of concurrency defects are being observed the most by other Java developers. –  L̲̳o̲̳̳n̲̳̳g̲̳̳p̲̳o̲̳̳k̲̳̳e̲̳̳ Mar 31 '13 at 1:56
1  
I guess the community disagrees as this article's getting 100+ views/day! I've found it very useful as I'm involved with the development of a static analysis tool specifically designed to fix concurrency issues contemplateltd.com/threadsafe. Having a bank of commonly encountered concurrency problems has been great for testing and improving ThreadSafe. –  Craig Manson Mar 4 at 16:35

49 Answers 49

up vote 84 down vote accepted

The most common concurrency problem I've seen, is not realizing that a field written by one thread is not guaranteed to be seen by a different thread. A common application of this:

class MyThread extends Thread {
  private boolean stop = false;

  public void run() {
    while(!stop) {
      doSomeWork();
    }
  }

  public void setStop() {
    this.stop = true;
  }
}

As long as stop is not volatile or setStop and run are not synchronized this is not guaranteed to work. This mistake is especially devilish as in 99.999% it won't matter in practice as the reader thread will eventually see the change - but we don't know how soon he saw it.

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8  
A great solution to this is to make the stop instance variable an AtomicBoolean. It solves all the problems of the non-volatile, while shielding you from the JMM issues. –  Kirk Wylie Jan 20 '09 at 23:59
27  
It's worse than 'for several minutes' -- you might NEVER see it. Under the Memory Model, the JVM is allowed to optimize while(!stop) into while(true) and then you're hosed. This may only happen on some VMs, only in server mode, only when the JVM recompiles after x iterations of the loop, etc. Ouch! –  Cowan Feb 11 '09 at 6:15
2  
Why would you want to use AtomicBoolean over volatile boolean? I'm developing for version 1.4+, so are there any pitfalls with just declaring volatile? –  Pool Mar 29 '09 at 23:26
2  
Nick, I think it's because atomic CAS is usually even faster than volatile. If you're developing for 1.4 your only safe option IMHO is to use synchronized as volatile in 1.4 hasn't got the strong memory barrier guarantees as it has in Java 5. –  Kutzi Apr 5 '09 at 13:04
4  
@Thomas: that's because of the Java memory model. You should read about it, if you want to know it in detail (Java Concurrency in Practice by Brian Goetz explains it good e.g.). In short: unless you use memory synchronization keywords/constructs (like volatile, synchronized, AtomicXyz, but also when a Thread is finished) one Thread has NO guarantee whatsoever to see the changes made to any field done by a different thread –  Kutzi Aug 24 '10 at 14:03

My #1 most painful concurrency problem ever occurred when two different open source libraries did something like this:

private static final String LOCK = "LOCK";  // use matching strings 
                                            // in two different libraries

public doSomestuff() {
   synchronized(LOCK) {
       this.work();
   }
}

At first glance, this looks like a pretty trivial synchronization example. However; because Strings are interned in Java, the literal string "LOCK" turns out to be the same instance of java.lang.String (even though they are declared completely disparately from each other.) The result is obviously bad.

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35  
This is one of the reasons why I prefer private static final Object LOCK = new Object(); –  Andrzej Doyle Jan 21 '09 at 9:59
7  
I love it - oh, this is nasty :) –  Thorbjørn Ravn Andersen Jan 21 '09 at 16:40
5  
That's a good one for Java Puzzlers 2. –  Dov Wasserman Jan 29 '09 at 18:30
10  
Actually...it really makes me want the compiler to refuse to allow you to synchronize on a String. Given String interning, there is no case where that would be a "good thing(tm)". –  Jared Feb 4 '09 at 15:30
3  
@Jared: "until the string is interned" makes no sense. Strings don't magically "become" interned. String.intern() returns a different object, unless you already have the canonical instance of the specified String. Also, all literal strings and string-valued constant expressions are interned. Always. See the docs for String.intern() and §3.10.5 of the JLS. –  Laurence Gonsalves Aug 6 '09 at 4:21

One classic problem is changing the object you're synchronizing on while synchronizing on it:

synchronized(foo) {
  foo = ...
}

Other concurrent threads are then synchronizing on a different object and this block does not provide the mutual exclusion you expect.

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14  
There is an IDEA inspection for this called "Synchronization on non-final field unlikely to have useful semantics". Very nice. –  Jen S. Jan 20 '09 at 16:28
8  
Ha...now that's a tortured description. "unlikely to have useful semantics" could better be described as "most likely broken". :) –  Alex Miller Jan 20 '09 at 16:45

A common problem is using classes like Calendar and SimpleDateFormat from multiple threads (often by caching them in a static variable) without synchronization. These classes are not thread-safe so multi-threaded access will ultimately cause strange problems with inconsistent state.

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Double-Checked Locking. By and large.

The paradigm, which I started learning the problems of when I was working at BEA, is that people will check a singleton in the following way:

public Class MySingleton {
  private static MySingleton s_instance;
  public static MySingleton getInstance() {
    if(s_instance == null) {
      synchronized(MySingleton.class) { s_instance = new MySingleton(); }
    }
    return s_instance;
  }
}

This never works, because another thread might have gotten into the synchronized block and s_instance is no longer null. So the natural change is then to make it:

  public static MySingleton getInstance() {
    if(s_instance == null) {
      synchronized(MySingleton.class) {
        if(s_instance == null) s_instance = new MySingleton();
      }
    }
    return s_instance;
  }

That doesn't work either, because the Java Memory Model doesn't support it. You need to declare s_instance as volatile to make it work, and even then it only works on Java 5.

People that aren't familiar with the intricacies of the Java Memory Model mess this up all the time.

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4  
The enum singleton pattern solves all of these problems (see Josh Bloch's comments on this). The knowledge of its existence should be more widespread among Java programmers. –  Robin Jan 21 '09 at 8:59
1  
This is what I use for Lazy initialization of Singleton classes. Also no synchronization required as this is guaranteed by java implicitly. class Foo { static class Holder { static Foo foo = new Foo(); } static Foo getInstance() { return Holder.foo; } } –  Irfan Zulfiqar Mar 27 '09 at 11:17

Though probably not exactly what you are asking for, the most frequent concurrency-related problem I've encountered (probably because it comes up in normal single-threaded code) is a

java.util.ConcurrentModificationException

caused by things like:

List<String> list = new ArrayList<String>(Arrays.asList("a", "b", "c"));
for (String string : list) { list.remove(string); }
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Not properly synchronizing on objects returned by Collections.synchronizedXXX(), especially during iteration or multiple operations:

Map<String, String> map = Collections.synchronizedMap(new HashMap<String, String>());

...

if(!map.containsKey("foo"))
    map.put("foo", "bar");

That's wrong. It should be:

synchronized(map) {
    if(!map.containsKey("foo"))
        map.put("foo", "bar");
}

Or with a ConcurrentMap implementation:

map.putIfAbsent("foo", "bar");
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3  
Or better, use a ConcurrentHashMap and putIfAbsent. –  Tom Hawtin - tackline Jan 20 '09 at 16:43

The most common bug we see where I work is programmers perform long operations, like server calls, on the EDT, locking up the GUI for a few seconds and making the app unresponsive.

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Forgetting to wait() (or Condition.await()) in a loop, checking that the waiting condition is actually true. Without this, you run into bugs from spurious wait() wakeups. Canonical usage should be:

 synchronized (obj) {
     while (<condition does not hold>) {
         obj.wait();
     }
     // do stuff based on condition being true
 }
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Another common bug is poor exception handling. When a background thread throws an exception, if you don't handle it properly, you might not see the stack trace at all. Or perhaps your background task stops running and never starts again because you failed to handle the exception.

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2  
Could you post links to any articles or references that explain this in greater detail? –  Abhijeet Kashnia Nov 1 '10 at 12:19

It can be easy to think synchronized collections grant you more protection than they actually do, and forget to hold the lock between calls. If have seen this mistake a few times:

 List<String> l = Collections.synchronizedList(new ArrayList<String>());
 String[] s = l.toArray(new String[l.size()]);

For example, in the second line above, the toArray and size() methods are both thread safe in their own right, but the size() is evaluated separately from the toArray(), and the lock on the List is not held between these two calls. If you run this code with another thread concurrently removing items from the list, sooner or later you will end up with a new String[] returned which is larger than required to hold all the elements in the list, and has null values in the tail. It is easy to think that because the two method calls to the List occur in a single line of code this is somehow an atomic operation, but it is not.

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2  
good example. I think I'd chalk this up more generally as "composition of atomic operations is not atomic". (See volatile field++ for another simple example) –  Alex Miller Jan 21 '09 at 18:40

Until I took a class with Brian Goetz I didn't realize that the non-synchronized getter of a private field mutated through a synchronized setter is never guaranteed to return the updated value. Only when a variable is protected by synchronized block on both reads AND writes will you get the guarantee of the latest value of the variable.

public class SomeClass{
    private Integer thing = 1;

    public synchronized void setThing(Integer thing)
        this.thing = thing;
    }

    /**
     * This may return 1 forever and ever no matter what is set
     * because the read is not synched
     */
    public Integer getThing(){
        return thing;  
    }
}
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3  
In the later JVM's (1.5 and forward, I think), the use of volatile will fix that as well. –  James Schek Jan 27 '09 at 23:18
2  
Not necessarily. volatile gives you the latest value so it prevents the returning of 1 forever, but it does not provide locking. Its close, but not quite the same. –  John Russell Mar 5 '09 at 21:29

Thinking you are writing single-threaded code, but using mutable statics (including singletons). Obviously they will be shared between threads. This happens surprisingly often.

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1  
Yes, indeed! Mutable statics break thread confinement. Surprisingly, I never found anything about this pitfall in either JCiP or CPJ. –  Julien Chastang Jan 20 '09 at 17:43

Arbitrary method calls should not be made from within synchronized blocks.

Dave Ray touched on this in his first answer, and in fact I also encountered a deadlock also having to do with invoking methods on listeners from within a synchronized method. I think the more general lesson is that method calls should not be made "into the wild" from within a synchronized block - you have no idea if the call will be long-running, result in deadlock, or whatever.

In this case, and usually in general, the solution was to reduce the scope of the synchronized block to just protect a critical private section of code.

Also, since we were now accessing the Collection of listeners outside of a synchronized block, we changed it to be a copy-on-write Collection. Or we could have simply made a defensive copy of the Collection. The point being, there are usually alternatives to safely access a Collection of unknown objects.

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My biggest problem has always been deadlocks, especially caused by listeners that are fired with a lock held. In these cases, it's really easy to get inverted locking between two threads. In my case, between a simulation running in one thread and a visualization of the simulation running in the UI thread.

EDIT: Moved second part to separate answer.

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I believe in the future the main problem with Java will be the (lack of) visibility guarantees for constructors. For example, if you create the following class

class MyClass {
    public int a = 1;
}

and then just read the value MyClass.a from another thread, MyClass.a could be either 0 or 1, depending on the JavaVM's implementation and mood. Today the chances for 'a' being 1 are very high. But on future NUMA machines this may be different. Many people are not aware of this and believe that they don't need to care about multi-threading during the initialization phase.

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2  
This is only a problem, if the reference of the freshly created instance is in use already before the constructor has returned/finished. For instance the class registers itself during construction in a public pool and other threads start to access it. –  ReneS Mar 12 '09 at 2:59
2  
MyClass.a indicates static access, and 'a' is not a static member of MyClass. Other than that, it's as 'ReneS' states, this is only a problem if a reference to the uncompleted object is leaked, like adding 'this' to some external map in the constructor, for instance. –  Markus Jevring Jan 25 '11 at 7:54

The most recent Concurrency-related bug I ran into was an object that in its constructor created an ExecutorService, but when the object was no longer referenced, it had never shutdown the ExecutorService. Thus, over a period of weeks, thousands of threads leaked, eventually causing the system to crash. (Technically, it didn't crash, but it did stop functioning properly, while continuing to run.)

Technically, I suppose this isn't a concurrency problem, but it's a problem relating to use of the java.util.concurrency libraries.

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Starting a thread within the constructor of a class is problematic. If the class is extended, the thread can be started before subclass' constructor is executed.

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Unbalanced synchronization, particularly against Maps seems to be a fairly common problem. Many people believe that synchronizing on puts to a Map (not a ConcurrentMap, but say a HashMap) and not synchronizing on gets is sufficient. This however can lead to an infinite loop during re-hash.

The same problem (partial synchronization) can occur anywhere you have shared state with reads and writes however.

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I encountered a concurrency problem with Servlets, when there are mutable fields which will be setted by each request. But there is only one servlet-instance for all request, so this worked perfectly in a single user environment but when more than one user requested the servlet unpredictable results occured.

public class MyServlet implements Servlet{
    private Object something;

    public void service(ServletRequest request, ServletResponse response)
        throws ServletException, IOException{
        this.something = request.getAttribute("something");
        doSomething();
    }

    private void doSomething(){
        this.something ...
    }
}
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Mutable classes in shared data structures

Thread1:
    Person p = new Person("John");
    sharedMap.put("Key", p);
    assert(p.getName().equals("John");  // sometimes passes, sometimes fails

Thread2:
    Person p = sharedMap.get("Key");
    p.setName("Alfonso");

When this happens, the code is far more complex that this simplified example. Replicating, finding and fixing the bug is hard. Perhaps it could be avoided if we could mark certain classes as immutable and certain data structures as only holding immutable objects.

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Synchronizing on a string literal or constant defined by a string literal is (potentially) a problem as the string literal is interned and will be shared by anyone else in the JVM using the same string literal. I know this problem has come up in application servers and other "container" scenarios.

Example:

private static final String SOMETHING = "foo";

synchronized(SOMETHING) {
   //
}

In this case, anyone using the string "foo" to lock on is sharing the same lock.

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Not exactly a bug but, the worst sin is providing a library you intend other people to use, but not stating which classes/methods are thread-safe and which ones must only be called from a single thread etc.

More people should make use of the concurrency annotations (e.g. @ThreadSafe, @GuardedBy etc) described in Goetz's book.

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Multiple objects that are lock protected but are commonly accessed in succession. We've run into a couple of cases where the locks are obtained by different code in different orders, resulting in deadlock.

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Using a local "new Object()" as mutex.

synchronized (new Object())
{
    System.out.println("sdfs");
}

This is useless.

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2  
This is probably useless, but the act of synchronizing at all does some interesting things... Certainly creating a new Object every time is a complete waste. –  TREE Jan 22 '09 at 15:59
3  
It's not useless. It's memory barrier without a lock. –  David Roussel May 4 '11 at 14:41
1  
@David: the only problem - jvm could optimize it by removing such lock at all –  yetanothercoder May 11 '11 at 10:15

Another common 'concurrency' issue is to use synchronized code when it is not necessary at all. For example I still see programmers using StringBuffer or even java.util.Vector (as method local variables).

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1  
This is not a problem, but unnecessary, because it tells the JVM sync the data against the global memory and therefore might run badly on multi-cpus even so, nobody uses the synchronization block in a concurrent fashion. –  ReneS Mar 12 '09 at 3:01

The dumbest mistake I frequently make is forgetting to synchronize before calling notify() or wait() on an object.

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4  
Unlike most concurrency problems, isn't this one easy to find? At least you get an IllegalMonitorStateException here... –  Outlaw Programmer Jan 26 '09 at 19:21

Not realising that the this in an inner class is not the this of the outer class. Typically in an anonymous inner class that implements Runnable. The root problem is that because synchronisation is part of all Objects there is effectively no static type checking. I've seen this at least twice on usenet, and it also appears in Brian Goetz'z Java Concurrency in Practice.

BGGA closures don't suffer from this as there is no this for the closure (this references the outer class). If you use non-this objects as locks then it gets around this problem and others.

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Use of a global object such as a static variable for locking.

This leads to very bad performance because of contention.

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Not realising the java.awt.EventQueue.invokeAndWait acts as if it holds a lock (exclusive access to the Event Dispatch Thread, EDT). The great thing about deadlocks is that even if that happens rarely you can grab a stack trace with jstack or the like. I've seen this in a number of widely used programs (a fix to a problem I have only seen occur once in Netbeans should be included in the next release).

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