I came across this article discussing why the double-check locking paradigm is broken in Java. Is the paradigm valid for .NET (in particular, C#), if variables are declared volatile?


Implementing the Singleton Pattern in C# talks about this problem in the third version.

It says:

Making the instance variable volatile can make it work, as would explicit memory barrier calls, although in the latter case even experts can't agree exactly which barriers are required. I tend to try to avoid situations where experts don't agree what's right and what's wrong!

The author seems to imply that double locking is less likely to work than other strategies and thus should not be used.


Double-checking locking now works in Java as well as C# (the Java memory model changed and this is one of the effects). However, you have to get it exactly right. If you mess things up even slightly, you may well end up losing the thread safety.

As other answers have stated, if you're implementing the singleton pattern there are much better ways to do it. Personally, if I'm in a situation where I have to choose between double-checked locking and "lock every time" code I'd go for locking every time until I'd got real evidence that it was causing a bottleneck. When it comes to threading, a simple and obviously-correct pattern is worth a lot.

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    @Jon: Article from the question states that volatile helps for JDK5+. What about .NET? Was volatile enough to implement a proper double-check locking on .NET 1.1? (for example, what about the example "Third version - attempted thread-safety using double-check locking" in your article: is it technically 'fixed' when volatile put on instance static field?) – IgorK Mar 24 '10 at 10:49
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    @IgorK: Yes, I believe it works when the variable is marked as volatile. – Jon Skeet Mar 24 '10 at 11:12
  • @Jon: OK, thank you. At least for singletons we have better solutions indeed. – IgorK Mar 24 '10 at 11:26
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    @Myster: I would personally just take out the lock always - particularly if you're doing other slow things, which make the cost of the lock insignificant. – Jon Skeet Feb 18 '11 at 6:22
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    @Myster: By "take out the lock" I meant "acquire the lock". I see that it was ambiguous :) Yes, remove the outer check. – Jon Skeet Feb 20 '11 at 22:48

.NET 4.0 has a new type: Lazy<T> that takes away any concern about getting the pattern wrong. It's part of the new Task Parallel Library.

See the MSDN Parallel Computing Dev Center: http://msdn.microsoft.com/en-us/concurrency/default.aspx

BTW, there's a backport (I believe it is unsupported) for .NET 3.5 SP1 available here.


Note than in Java (and most likely in .Net as well), double-checked locking for singleton initialization is completely unnecessary as well as broken. Since classes are not initialized until they're first used, the desired lazy initialization is already achieved by this;

private static Singleton instance = new Singleton();

Unless your Singleton class contains stuff like constants that may be accessed before a Singleton instance is first used, this is all you need to do.


I don't get why all people says that the double-check locking is bad pattern, but don't adapt the code to make it work correctly. In my opinion, this below code should work just fine.

If someone could tell me if this code suffer from the problem mentionned in Cameron's article, please do.

public sealed class Singleton {
    static Singleton instance = null;
    static readonly object padlock = new object();

    Singleton() {

    public static Singleton Instance {
        get {
            if (instance != null) {
                return instance;

            lock (padlock) {
                if (instance != null) {
                    return instance;

                tempInstance = new Singleton();

                // initialize the object with data

                instance = tempInstance;
            return instance;
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    The reason people say it's bad is because it is incredibly easy to get wrong. I think your code needs a volatile on the instance member. (whether code works is, at least in this case, not a matter of opinion but a matter of fact. I think the fact is that it does not work, but I might be wrong on this). – erikkallen Apr 14 '15 at 13:07
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    @erikkallen There is no need for volatile in .NET. Don't forget that .NET has stronger memory model than Java, that is what confuses people a lot. The lock statement in C# (Monitor.Enter(), Monitor.Exit()) implicitely creates full memory fence (albahari.com/threading/part4.aspx). The only excuse to use volatile in C# by some is because then the double-checked locking looks the same in Java and in C# so it doesn't confuse people. My opinion is to use Lazy<T> (msdn.microsoft.com/en-us/library/dd997286(v=vs.110).aspx) – Tiny Jul 15 '15 at 8:11
  • Correct me if I'm mistaken but the issue is that you cannot guarantee the ordering of instructions inside the lock. So the instance = tempInstance assignment could be done before the instance is finished initializing, making a second call that sees a non-null value outside the lock (that's not finished initializing) unsafe. – Austin Salgat Sep 16 '18 at 17:57
  • @Salgat, IMO the compiler optimization is smart enough to create the object before assigning it so the problem you describe is very unlikely to happen, but to be more bulletproof, maybe adding a Thread.MemoryBarrier() before the assignment would do the trick. – M.Parent Sep 17 '18 at 14:29
  • The concern is not about instruction ordering in the compiled code, but the x86 CPU reordering instructions in the instruction pipeline; but you are right, a memory barrier would prevent that from occurring before initialization is complete. – Austin Salgat Sep 17 '18 at 16:08

I've gotten double-checked locking to work by using a boolean (i.e. using a primitive to avoid the lazy initialisation):

The singleton using boolean does not work. The order of operations as seen between different threads is not guaranteed unless you go through a memory barrier. In other words, as seen from a second thread, created = true may be executed before instance= new Singleton();


I don't quite understand why there are a bunch of implementation patterns on double-checked locking (apparently to work around compiler idiosyncrasies in various languages). The Wikipedia article on this topic shows the naive method and the possible ways to solve the problem, but none are as simple as this (in C#):

public class Foo
  static Foo _singleton = null;
  static object _singletonLock = new object();

  public static Foo Singleton
      if ( _singleton == null )
        lock ( _singletonLock )
          if ( _singleton == null )
            Foo foo = new Foo();

            // Do possibly lengthy initialization,
            // but make sure the initialization
            // chain doesn't invoke Foo.Singleton.

            // _singleton remains null until
            // object construction is done.
            _singleton = foo;
      return _singleton;

In Java, you'd use synchronized() instead of lock(), but it's basically the same idea. If there's the possible inconsistency of when the singleton field gets assigned, then why not just use a locally scoped variable first and then assign the singleton field at the last possible moment before exiting the critical section? Am I missing something?

There's the argument by @michael-borgwardt that in C# and Java the static field only gets initialized once on first use, but that behavior is language specific. And I've used this pattern frequently for lazy initialization of a collection property (e.g. user.Sessions).

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    The error in the analysis is this: “ _singleton remains null until object construction is done.” The compiler is free to rearrange this whole line above foo.Initialize(), or even optimize out the foo variable altogether. Even if a compiler is dumb, the CPU is smart, and may execute some memory stores done inside foo.Initialize() after the assignment _singleton = foo. The article linked to from the original post also explains other reasons this code does not do what you may think it does. – kkm Apr 19 '16 at 17:27

I've gotten double-checked locking to work by using a boolean (i.e. using a primitive to avoid the lazy initialisation):

private static Singleton instance;
private static boolean created;
public static Singleton getInstance() {
    if (!created) {
        synchronized (Singleton.class) {
            if (!created) {
                instance = new Singleton();
                created = true;
    return instance;
  • The problem with double checked locking is that the instance could be non-null but still not initialized. Hence a thread outside of the synchronized block could pass the initial (unsynchronized) null check even though the object has not yet been initialized. The code above gets around this by checking the boolean instead. When created=true is hit we know the instance has been initialized so there is no way a thread outside the synchronized block can get an uninitialized instance. – Jono Jan 15 '13 at 15:36

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