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I would like to use singleton pattern in a multithreaded program. Double-checked locking method seems suitable for its efficiency, however this method is broken and not easy to get right.

I write the following code hoping that it works as an alternative to the double-checked locking. Is it a correct implementation of a thread-safe singleton pattern?

static bool created = false;
static Instance *instance = 0;

Instance *GetInstance() {
    if (!created) {
        Lock lock;    // acquire a lock, parameters are omitted for simplicity
        if (!instance) {
            instance = new Instance;
        } else {
            created = true;
    return instance;

The first call will create Instance. The second call will set created to true. And finally, all other calls will return a well initialized instance.

share|improve this question
Why not simply use Instance* GetInstance() { static Instance instance; return &instance; } – kennytm Jan 30 '12 at 8:00
Has anyone told you yet that singletons are evil? The complexity people end up introducing just to create one with any semblance of thread safety is only part of the problem. – cHao Jan 30 '12 at 8:08
Whole singleton principle is broken, not only this implementation ;) – BЈовић Jan 30 '12 at 8:09
How does it get destroyed? What does it do if it gets used after it's destroyed? Could you have a main thread which creates the object and passes it to the threads that need it? In my experience, singletons are usually unnecessary, and complicate comprehension. Just make one and pass it around. – Peter Wood Jan 30 '12 at 8:11
@KennyTM: You'd have to check that your compiler initialises local statics in a thread safe way. It's required by C++11, but no compiler fully implements C++11 yet. – Mike Seymour Jan 30 '12 at 11:24
up vote 3 down vote accepted

No, this doesn't help. If the writes to created and instance are non-atomic then there is no guarantee that the values are visible to a thread that doesn't lock the mutex.

e.g. Thread 1 calls getInstance. created is false, and instance is null, so it locks the mutex and creates a new instance. Thread 1 calls getInstance again, and this time sets created to true. Thread 2 now calls getInstance. By the vagaries of the processor's memory management it sees created as true, but there is no guarantee that it also sees instance as non-null, and even if it does there is no guarantee that the memory values for the pointed-to instance are consistent.

If you're not using atomics then you need to use mutexes, and must use them for all accesses to a protected variable.

Additional info: If you are using mutexes, then the compiler and runtime work together to ensure that when one thread releases a mutex lock and another thread acquires a lock on that same mutex then the second thread can see all the writes done by the first. This is not true for non-atomic accesses, and may or may not be true for atomic accesses, depending on what memory ordering constraints the compiler and runtime guarantee for you (with C++11 atomics you can choose the ordering constraints).

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I updated my question regarding your answer. Thank you. – Ross Jan 30 '12 at 8:48
Updated answer with additional info. – Anthony Williams Jan 30 '12 at 9:00
I did use a lock (Lock lock;). Isn't it the same? – Ross Jan 30 '12 at 9:11
This is only the same if all threads use the lock, which is precisely what you are trying to avoid! – Anthony Williams Jan 30 '12 at 9:31
I just thought if a thread releases a lock, all the memory changes it made will be visible to all other threads. Is there any reference about what mutexes will do on the thread's cache? When I read about mutexes, I can't really find information about how thread's memory is flushed to the shared memory, and the visibility of the changes as well. Thanks a lot. – Ross Jan 31 '12 at 2:57

It has the same reliability of the double-checked locking. You can get more with "triple check", or even "quadruple-check", but full reliability can be demonstrated to be impossible.

Please note that declaring a local-static variable will make the compiler to implement itself your same logic.

#include "Instance.h" //or whatever...

Instance* GetInstance()
    static std::unique_ptr<Instance> p(new Instance);
    return p.get();

If the compiler is configured for multithreading environment, it sould protect the static p with a mutex and manage the lock when initializing p at the very first call. It also should chain p destruction to the tail of the "at_exit" chain, so that -at program end- proper destruction will be performed.

[EDIT] Since this is a requirement for C++11 and is implemented only in some C++03 pre-standard, check the compiler implementation and settings.

Right now, I can only ensure MinGW 4.6 on and VS2010 already did it.

share|improve this answer
While this is required of C++11 compilers, not all current compilers provide the necessary synchronization for local static objects in a multithreaded environment. – Anthony Williams Jan 30 '12 at 8:09
It isn't double checked if you look carefully. It is double-lock, in which different threads must be locked at least twice which ensure ordering in assignment of created and instance. Just stating it is not correct isn't helpful. Is there any situation that you think is invalid? – Ross Jan 30 '12 at 8:12
@AnthonyWilliams: Thanks: just edited – Emilio Garavaglia Jan 30 '12 at 8:16
@Ross: behind this kind of problem there is always a conceptual limit that is described as "the two General problem". (see'_Problem for an brief description) There is no solution. Double check, double lock, double commit etc. etc. are all approximations. Note that -although wikipedia describes it as a "networking problem"- it can similarly formulated -by changing the subjects appropriatly- in whatever "network of lock" set of "actors" (the thread, in this case) can act. – Emilio Garavaglia Jan 30 '12 at 8:22
@Ross: "Is there any situation that you think is invalid?" - three threads. The first one creates the object. The second one sets the flag. The third one sees the change to the flag and so never takes the lock. As a result it reads the instance without taking the lock, and due to some quirk of incoherent caching, doesn't see the change to the instance even though, in your opinion as an omniscient observer, the change to the instance "occurred before" the change to the flag. In fact from the POV of thread 3, it did not occur before it. So thread 3 returns a null pointer from the function. – Steve Jessop Jan 30 '12 at 11:23

No. There's absolutely no difference between your code and double checked locking. The correct implementation is:

static std::mutex m;

    static Singleton* theOneAndOnly;
    std::lock_guard l(m);
    if (theOneAndOnly == NULL)
        theOneAndOnly = new Singleton;
    return *theOneAndOnly;

It's hard to imagine a case where this would cause a problem, and it is guaranteed. You do aquire the lock each time, but aquiring an uncontested mutex should be fairly cheap, you're not accessing Singleton's that much, and if you do end up having to access it in the middle of a tight loop, there's nothing to stop you from acquiring a reference to it before entering the loop, and using it.

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This code contains a race-condition, in that created can be read while it is concurrently being written to by a different thread.

As a result, it has undefined behaviour, and is not a valid way of writing that code.

As KennyTM pointed out in the comments, a far better alternative is:

Instance* GetInstance() { static Instance instance; return &instance; }
share|improve this answer
Since instance is an expensive object, and it may not be used. So lazy initialization is needed. – Ross Jan 30 '12 at 10:11
@Ross: this is lazy initialization -- function-scope statics are initialized the first time program execution "crosses" their definition. This code hands your problem over to the implementation to solve, which is great if your implementation already implements thread-safe local statics. Not so great if it doesn't. – Steve Jessop Jan 30 '12 at 11:27

your solution will work fine, but it does one more check.

the right double check locking looks like,

static Instance *instance = 0; 

Instance *GetInstance() { 
    if (instance == NULL)  //first check.
        Lock lock; //scope lock.
        if (instance == NULL) //second check, the second check must under the lock.
           instance = new Instance;

    return instance;

the double check locking will have a good performance for it does not acquire the lock every time. and it is thread-safe the locking will gurentee there is only one instance created.

share|improve this answer
Please read to see why it is broken. – Ross Jan 30 '12 at 8:47

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