Recently I've bumped into a realization/implementation of the Singleton design pattern for C++. It has looked like this (I have adopted it from the real life example):

// a lot of methods are omitted here
class Singleton
       static Singleton* getInstance( );
       ~Singleton( );
       Singleton( );
       static Singleton* instance;

From this declaration I can deduce that the instance field is initiated on the heap. That means there is a memory allocation. What is completely unclear for me is when exactly the memory is going to be deallocated? Or is there a bug and memory leak? It seems like there is a problem in the implementation.

My main question is, how do I implement it in the right way?

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    Singletons are bad:…. Don't use them. – sbi Jun 27 '11 at 10:33
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    @sbi - Only a Sith deals in absolutes. Can the vast majority of problems be solved without Singletons? Absolutely. Do Singletons cause problems of their own? Yes. However, I can't honestly say that they're bad, since design is all about considering the tradeoffs and understanding the nuances of your approach. – derekerdmann Jul 28 '11 at 20:10
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    @derekerdmann: I didn't say you never need a global variable (and when you need one, a Singleton sometimes is better). What I said is that they should be used as little as possible. Glorifying Singleton as a valuable design pattern gives the impression it's good to use it, rather than that it is a hack, making code hard to understand, hard to maintain, and hard to test. This is why I posted my comment. None of what you said so far contradicted this. – sbi Jul 29 '11 at 13:26
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    @sbi: What you said was "Don't use them." Not the much more reasonable "they should be used as little as possible" you later changed to - surely you see the difference. – jwd Oct 17 '11 at 22:21

18 Answers 18

up vote 901 down vote accepted

In 2008 I provided a C++98 implementation of the Singleton design pattern that is lazy-evaluated, guaranteed-destruction, not-technically-thread-safe:
Can any one provide me a sample of Singleton in c++?

Here is an updated C++11 implementation of the Singleton design pattern that is lazy-evaluated, correctly-destroyed, and thread-safe.

class S
        static S& getInstance()
            static S    instance; // Guaranteed to be destroyed.
                                  // Instantiated on first use.
            return instance;
        S() {}                    // Constructor? (the {} brackets) are needed here.

        // C++ 03
        // ========
        // Don't forget to declare these two. You want to make sure they
        // are unacceptable otherwise you may accidentally get copies of
        // your singleton appearing.
        S(S const&);              // Don't Implement
        void operator=(S const&); // Don't implement

        // C++ 11
        // =======
        // We can use the better technique of deleting the methods
        // we don't want.
        S(S const&)               = delete;
        void operator=(S const&)  = delete;

        // Note: Scott Meyers mentions in his Effective Modern
        //       C++ book, that deleted functions should generally
        //       be public as it results in better error messages
        //       due to the compilers behavior to check accessibility
        //       before deleted status

See this article about when to use a singleton: (not often)
Singleton: How should it be used

See this two article about initialization order and how to cope:
Static variables initialisation order
Finding C++ static initialization order problems

See this article describing lifetimes:
What is the lifetime of a static variable in a C++ function?

See this article that discusses some threading implications to singletons:
Singleton instance declared as static variable of GetInstance method, is it thread-safe?

See this article that explains why double checked locking will not work on C++:
What are all the common undefined behaviours that a C++ programmer should know about?
Dr Dobbs: C++ and The Perils of Double-Checked Locking: Part I

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    Good answer. But should note that this is not thread-safe… – Varuna Dec 25 '09 at 8:28
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    @Varuna: In C++11 this is now thread-safe. – Mankarse May 4 '12 at 6:11
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    @zourtney: Many people don't realize what you just did :) – Johann Gerell Jan 4 '13 at 7:06
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    @MaximYegorushkin: When this is destroyed is very well defined (there is no ambiguity). See:… – Martin York May 20 '13 at 20:39
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    What irks me most though is the run-time check of the hidden boolean in getInstance() That is an assumption on implementation technique. There need be no assumptions about it being alive. see You can force a situation so that it is always alive (less overhead than Schwarz counter). Global variables have more issues with initialization order (across compilation units) as you not force an order. The advantage of this model is 1) lazy initialization. 2) Ability to enforce an order (Schwarz helps but is uglier). Yep get_instance() is much uglier. – Martin York May 20 '13 at 23:07

Being a Singleton, you usually do not want it to be destructed.

It will get torn down and deallocated when the program terminates, which is the normal, desired behavior for a singleton. If you want to be able to explicitly clean it, it's fairly easy to add a static method to the class that allows you to restore it to a clean state, and have it reallocate next time it's used, but that's outside of the scope of a "classic" singleton.

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    if delete is never explicitly called on the static Singleton* instance, wouldn't this still technically be considered a memory leak? – Andrew Garrison Jun 17 '09 at 16:10
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    It's not a memory leak anymore than a simple declaration of a global variable. – ilya n. Jun 17 '09 at 16:14
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    To set something straight... "memory leak" concerns vis-a-vis singletons are completely irrelevent. If you have stateful resources in which deconstruction order matters, singletons can be dangerous; but all of the memory is cleanly regained by the operating system on program termination... nullifying this totally academic point in 99.9% of cases. If you want to argue the grammar back and forth of what is and is not a "memory leak", that's fine, but realize that it's a distraction from actual design decisions. – jkerian Jun 17 '09 at 16:21
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    @jkerian: Memory leaks and destruction in the C++ context is not really about the memory leaking. Really it is about resource control. If you leak memory the destroctor is not called and thus any resources associated with the object are not correctly released. Memory is just the simple example we use when teaching programming but there are much more complex resources out there. – Martin York Jun 17 '09 at 16:34
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    @Martin I agree with you completely. Even if the only resource is memory, you will still get into trouble trying to find REAL leaks in your program if you have to wade through a list of leaks, filtering out ones that "don't matter." It is better to clean these all up so any tool that reports leaks only reports things that ARE a problem. – Dolphin Jun 17 '09 at 16:53

You could avoid memory allocation. There are many variants, all having problems in case of multithreading environment.

I prefer this kind of implementation (actually, it is not correctly said I prefer, because I avoid singletons as much as possible):

class Singleton

   static Singleton& instance()
      static Singleton INSTANCE;
      return INSTANCE;

It has no dynamic memory allocation.

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    In some instances, this lazy initialization is not the ideal pattern to follow. One example is if the constructor of the singleton allocates memory from the heap and you wish that allocation to be predictable, for instance in an embedded system or other tightly controlled environment. I prefer, when the Singleton pattern is the best pattern to use, to create the instance as a static member of the class. – dma Jun 17 '09 at 17:06
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    For many larger programs, especially those with dynamic libraries. Any global or static object that's none primitive can lead to segfaults/crashes upon program exit on many platforms due to order of destruction issues upon libraries unloading. This is one of the reasons many coding conventions (including Google's) ban the use of non-trivial static and global objects. – obecalp Jun 17 '09 at 18:04
  • It seems that the static instance in such implementation has internal linkage, and will have unique and independent copies in different translation unit, which will cause confusing and wrong behavior. But I saw many such implementation, am I missing something? – FaceBro Feb 25 '17 at 14:12

@Loki Astari's answer is excellent.

However there are times with multiple static objects where you need to be able to guarantee that the singleton will not be destroyed until all your static objects that use the singleton no longer need it.

In this case std::shared_ptr can be used to keep the singleton alive for all users even when the static destructors are being called at the end of the program:

class Singleton
    Singleton(Singleton const&) = delete;
    Singleton& operator=(Singleton const&) = delete;

    static std::shared_ptr<Singleton> instance()
        static std::shared_ptr<Singleton> s{new Singleton};
        return s;

    Singleton() {}

Another non-allocating alternative: create a singleton, say of class C, as you need it:



template <class X>
X& singleton()
    static X x;
    return x;

Neither this nor Cătălin's answer is automatically thread-safe in current C++, but will be in C++0x.

  • Currently under gcc it is thread safe (and has been for a while). – Martin York Jun 17 '09 at 16:26
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    The problem with this design is that if used across multiple libraries. Each library has is own copy of the singleton that that library uses. So it is no longer a singleton. – Martin York Jun 17 '09 at 16:27

If you want to allocate the object in heap, why don't use a unique pointer. Memory will also be deallocated since we are using a unique pointer.

class S
        static S& getInstance()
            if( m_s.get() == 0 )
              m_s.reset( new S() );
            return *m_s;

        static std::unique_ptr<S> m_s;

        S(S const&);            // Don't Implement
        void operator=(S const&); // Don't implement

std::unique_ptr<S> S::m_s(0);

The solution in the accepted answer has a significant drawback - the destructor for the singleton is called after the control leaves the main() function. There may be problems really, when some dependent objects are allocated inside main.

I met this problem, when trying to introduce a Singleton in the Qt application. I decided, that all my setup dialogs must be Singletons, and adopted the pattern above. Unfortunately, Qt's main class QApplication was allocated on stack in the main function, and Qt forbids creating/destroying dialogs when no application object is available.

That is why I prefer heap-allocated singletons. I provide an explicit init() and term() methods for all the singletons and call them inside main. Thus I have a full control over the order of singletons creation/destruction, and also I guarantee that singletons will be created, no matter whether someone called getInstance() or not.

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    Look like you've tried to use it in the wrong way. – Artem Barger Jun 18 '09 at 15:55
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    If you are referring to the currently accepted answer you first statement is wrong. The destructor is not called until all static storage duration objects are destroyed. – Martin York Oct 12 '12 at 16:40

Here is an easy implementation.

#include <Windows.h>
#include <iostream>

using namespace std;

class SingletonClass {

    static SingletonClass* getInstance() {

    return (!m_instanceSingleton) ?
        m_instanceSingleton = new SingletonClass : 

    // private constructor and destructor
    SingletonClass() { cout << "SingletonClass instance created!\n"; }
    ~SingletonClass() {}

    // private copy constructor and assignment operator
    SingletonClass(const SingletonClass&);
    SingletonClass& operator=(const SingletonClass&);

    static SingletonClass *m_instanceSingleton;

SingletonClass* SingletonClass::m_instanceSingleton = nullptr;

int main(int argc, const char * argv[]) {

    SingletonClass *singleton;
    singleton = singleton->getInstance();
    cout << singleton << endl;

    // Another object gets the reference of the first object!
    SingletonClass *anotherSingleton;
    anotherSingleton = anotherSingleton->getInstance();
    cout << anotherSingleton << endl;


    return 0;

Only one object created and this object reference is returned each and every time afterwords.

SingletonClass instance created!

Here 00915CB8 is the memory location of singleton Object, same for the duration of the program but (normally!) different each time the program is run.

N.B. This is not a thread safe one.You have to ensure thread safety.

It is indeed probably allocated from the heap, but without the sources there is no way of knowing.

The typical implementation (taken from some code I have in emacs already) would be:

Singleton * Singleton::getInstance() {
    if (!instance) {
        instance = new Singleton();
    return instance;

...and rely on the program going out of scope to clean up afterwards.

If you work on a platform where cleanup must be done manually, I'd probably add a manual cleanup routine.

Another issue with doing it this way is that it isn't thread-safe. In a multithreaded environment, two threads could get through the "if" before either has a chance to allocate the new instance (so both would). This still isn't too big of a deal if you are relying on program termination to clean up anyway.

  • you can deduce, since you can see that instance variable is a pointer to the class instance. – Artem Barger Jun 17 '09 at 16:18
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    There is no need to dynamically allocate the singleton. In fact this is a bad idea as there is not way to automatically de-allocate using the above design. Let it fall out of scope is does not call destructors and is just lazy. – Martin York Jun 17 '09 at 16:25
  • You can automatically deallocate using the atexit function. That's what we do (not saying it's a good idea) – Joe Jun 17 '09 at 20:15

I did not find a CRTP implementation among the answers, so here it is:

template<typename HeirT>
class Singleton
    Singleton() = delete;

    Singleton(const Singleton &) = delete;

    Singleton &operator=(const Singleton &) = delete;

    static HeirT &instance()
        static HeirT instance;
        return instance;

To use just inherit your class from this, like: class Test : public Singleton<Test>

This is about object life-time management. Suppose you have more than singletons in your software. And they depend on Logger singleton. During application destruction, suppose another singleton object uses Logger to log its destruction steps. You have to guarantee that Logger should be cleaned up last. Therefore, please also check out this paper:

Has anyone mentioned std::call_once and std::once_flag? Most other approaches - including double checked locking - are broken.

One major problem in singleton pattern implementation is safe initialization. The only safe way is to guard the initialization sequence with synchronizing barriers. But those barriers themselves need to be safely initiated. std::once_flag is the mechanism to get guaranteed safe initialization.

#define INS(c) private:void operator=(c const&){};public:static c& I(){static c _instance;return _instance;}


   class CCtrl
        virtual ~CCtrl(void);


In addition to the other discussion here, it may be worth noting that you can have global-ness, without limiting usage to one instance. For example, consider the case of reference counting something...

struct Store{
   std::array<Something, 1024> data;
   size_t get(size_t idx){ /* ... */ }
   void incr_ref(size_t idx){ /* ... */}
   void decr_ref(size_t idx){ /* ... */}

template<Store* store_p>
struct ItemRef{
   size_t idx;
   auto get(){ return store_p->get(idx); };
   ItemRef() { store_p->incr_ref(idx); };
   ~ItemRef() { store_p->decr_ref(idx); };

Store store1_g;
Store store2_g; // we don't restrict the number of global Store instances

Now somewhere inside a function (such as main) you can do:

auto ref1_a = ItemRef<&store1_g>(101);
auto ref2_a = ItemRef<&store2_g>(201); 

The refs don't need to store a pointer back to their respective Store because that information is supplied at compile-time. You also don't have to worry about the Store's lifetime because the compiler requires that it is global. If there is indeed only one instance of Store then there's no overhead in this approach; with more than one instance it's up to the compiler to be clever about code generation. If necessary, the ItemRef class can even be made a friend of Store (you can have templated friends!).

If Store itself is a templated class then things get messier, but it is still possible to use this method, perhaps by implementing a helper class with the following signature:

template <typename Store_t, Store_t* store_p>
struct StoreWrapper{ /* stuff to access store_p, e.g. methods returning 
                       instances of ItemRef<Store_t, store_p>. */ };

The user can now create a StoreWrapper type (and global instance) for each global Store instance, and always access the stores via their wrapper instance (thus forgetting about the gory details of the template parameters needed for using Store).

Simple singleton class, This must be your header class file


class SingletonClass
        static SingletonClass* Instance()
           static SingletonClass* instance = new SingletonClass();
           return instance;

        void Relocate(int X, int Y, int Z);


#define sSingletonClass SingletonClass::Instance()


Access your singleton like this:

sSingletonClass->Relocate(1, 2, 5);

I think You should write a static function wherein your static object is deleted. You should call this function when you are about to close your application. This will ensure you dont have memory leakage.

The paper that was linked to above describes the shortcoming of double checked locking is that the compiler may allocate the memory for the object and set a pointer to the address of the allocated memory, before the object's constructor has been called. It is quite easy in c++ however to use allocaters to allocate the memory manually, and then use a construct call to initialize the memory. Using this appraoch, the double-checked locking works just fine.

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    Unfortunately not. This has been discussed in great depth by some of the best C++ developers out there. Double checked locking is broken in C++03. – Martin York Oct 12 '12 at 16:44

How about using placement new like this:

class singleton
    static singleton *s;
    static unsigned char *buffer[sizeof(singleton)/4 *4] //4 byte align
    static singleton* getinstance()
        if (s == null)
            s = new(buffer) singleton;
        return s;
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    Why. That seems complex. And the destructor is never called. Also you need to fix the expression for calculating size currently it will work on average 25% of the time (try the situation where sizeof(singelton) == 3. Then your above expression results in 0 sized array. – Martin York Oct 12 '12 at 16:42

protected by Mysticial Oct 27 '13 at 6:06

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