The class at the bottom is an implementation of fast, thread safe, "lock free", lazy initializer.

I say "lock free", although it isn't completely; It uses a lock until it is initialized, and then replaces the call to get the data with one that doesn't use the lock. (Similar to a double checked lock with a volatile member; and from performance tests I get v. similar results.)

My question is; is this a good/safe thing to do?

(After I had written this I noticed that the .net 4.0 has a LazyInit<T> which performs the same operations and more, but in a very highly contrived example that I created my implementation was slightly faster :-) )

NB Class has been modified to include Value member, and volatile on the _get

class ThreadSafeInitializer<TOutput>
    where TOutput : class
    readonly object _sync = new object();
    TOutput _output;
    private volatile Func<TOutput> _get;

    public TOutput Value { get { return _get(); } }

    public ThreadSafeInitializer(Func<TOutput> create)
        _get = () =>
            lock (_sync)
                if (_output == null)
                    _output = create();
                    _get = () => _output; // replace the Get method, so no longer need to lock
                return _output;
  • +1, A very clever example of what not to do ;) – Sep 24 '09 at 1:19
  • Well I think that's a bit harsh; although as I acknowledged having unknown code called from a lock is a bad thing to do, it is, as Sam notes below, what ships with the .net 4.0 framework... – Paul Westcott Sep 24 '09 at 20:51
up vote 1 down vote accepted

Make the Get member volatile, so that you are sure to call the current version. With that modification it's safe as far as I can tell.

  • Do you need to make it volatile? It doesn't matter if you have the replaced Get, or the old one (it just has the lock hit). Just let it flush through whatever caches over time...? – Paul Westcott Sep 24 '09 at 0:43
  • For non-volatile fields, optimization techniques that reorder instructions can lead to unexpected and unpredictable results in multi-threaded programs that access fields without synchronization such as that provided by the lock-statement (Section 8.12) – Sam Saffron Sep 24 '09 at 0:47
  • Get is accessed outside of the lock statement ... – Sam Saffron Sep 24 '09 at 0:48
  • Indeed, but the choice for the compiler it is one or the other, it doesn't matter which one is called, so it's free to reorder statements however it likes. But, in my highly contrived example, it doesn't change performance at all. – Paul Westcott Sep 24 '09 at 1:02

As Guffa said, you want to add volatile on Get to make this safe

However I found the implementation a bit tricky to follow. I think its trying to be a bit too fancy for its own good.

So something along these lines is easier to follow:

class Lazy<T> {

    readonly object sync = new object();
    Func<T> init;
    T result;
    volatile bool initialized;

    public Lazy(Func<T> func) {
        this.init = func;

    public T Value {
        get {

            if(initialized) return result;

            lock (sync) {
                if (!initialized) {
                    result = this.init();
                    initialized = true;
            return result;

Minor advantages:

  • Less fancy
  • No performance hit of invoking the Func
  • Lock only acquired on initialization.
  • Accessing Value via obj.Value is a bit more intuitive than obj.Get()
  • BTW, there is a Lazy<T> structure included in .NET 4.0 – Thomas Levesque Sep 24 '09 at 0:12
  • But, with the functional world coming of age, is it really that "fancy" or is it just a little bit different from what people are used to? (and from a performance perspective, yours performs worse [in my highly contrived example]) – Paul Westcott Sep 24 '09 at 0:53
  • +1 for readability but see my response below as to the whole idea. – Sep 24 '09 at 1:52
  • This code simulates LazyInitMode.EnsureSingleExecution, this will ship in the framework in V4.0 , you could introduce a defensive timeout if you want to ensure deadlocks never ever happen, but keep in mind the framework version has no timeout built in. – Sam Saffron Sep 24 '09 at 2:51

I write this code a lot:

private SomeThing _myThing = null;
public SomeThing MyThing 
{ get { return _myThing != null ? _myThing : _myThing = GetSomeThing(); } }

Lazy loads just fine and is very readable. My point? the lack of lock(object) is not accidental. Lazy loading properties with locks would be asking for trouble IMO.

Use of the lock statement should be tightly controlled and both Paul and Sam stand hereby accused of calling code they didn't write while holding a lock. Maybe that's no big deal, maybe it deadlocks your program. And your doing this from inside an innocent-looking property get so that you might save a few milliseconds?

My guess is that if you can safely load it twice without catastrophic results that would be better. Then in the rare event that two threads access the same property at the same time then two instances are loaded... Depends on what your loading if that is really a bad thing, I bet most times it doesn't matter that each thread gets a different instance. If it does matter I would recommend performing the needed locks at construction and don't bother with lazy loading. Likely since the constructor can only happen on one thread you won't need a lock at all.

  • +1 Accusation acknowledged sheepishly :-) – Paul Westcott Sep 24 '09 at 1:59
  • +1 for a pragmatic, sensible approach. :) – Greg D Sep 24 '09 at 2:02
  • The lock is unavoidable if you want to simulate LazyInitMode.EnsureSingleExecution , which ships in the framework (in v4.0). If you are happy with AllowMultipleExecution, go with it. Its not about saving time, some initilization code may result in bigger issues if called concurrently – Sam Saffron Sep 24 '09 at 2:52
  • What if it initializes to null? – Sam Saffron Sep 24 '09 at 2:55
  • LOL, yea I've had the null return get me before. I couldn't figure out why it kept calling the load method. When I found out I fixed the bug in the load method :) – Sep 24 '09 at 3:40

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