#include "TestSmartPointer"

void fun()

{

    SP<TestSmartPointer> sp1=new TestSmartPointer("A");

    SP<TestSmartPointer> sp2=sp1;

    sp1=sp2;

}

void main()

{

    fun();

    //system("pause");

}

#pragma once

#include "Referenced"

#include "SmartPointer"

#include <string>

class TestSmartPointer : public Referenced

{

    public:

        inline TestSmartPointer(std::string name):Referenced(),_name(name) {}

    protected:

        virtual ~TestSmartPointer() {}

        std::string _name;

};

#ifndef REFERENCED

#define REFERENCED 1

#include <iostream>

using namespace std;

/** Base class from providing referencing counted objects.*/

class Referenced

{

    public:

        Referenced() { _refCount=; }

        Referenced(const Referenced&) { _refCount=; }

        inline Referenced& operator = (const Referenced&) { return *this; }

        /** Increment the reference count by one, indicating that

            this object has another pointer which is referencing it.*/

        inline void ref() const;

        /** Decrement the reference count by one, indicating that

            a pointer to this object is referencing it.  If the

            reference count goes to zero, it is assumed that this object

            is no longer referenced and is automatically deleted.*/

        inline void unref() const;

        /** Decrement the reference count by one, indicating that

            a pointer to this object is referencing it.  However, do

            not delete it, even if ref count goes to 0.  Warning, unref_nodelete()

            should only be called if the user knows exactly who will

            be resonsible for, one should prefer unref() over unref_nodelete()

            as the later can lead to memory leaks.*/

        inline void unref_nodelete() const;

        /** Return the number pointers currently referencing this object. */

        inline int referenceCount() const { return _refCount; }

    protected:

        virtual ~Referenced()

        {

            if (_refCount>)

            {

                cout<<"Warning: deleting still referenced object "<<this<<" of type '"<<typeid(this).name()<<"'"<<std::endl;

                cout<<"the final reference count was "<<_refCount<<", memory corruption possible."<<std::endl;

            }

        }

        mutable int  _refCount;

};

inline void Referenced::ref() const

{

    ++_refCount;

}

inline void Referenced::unref() const

{

    bool needDelete = false;

    --_refCount;

    needDelete = _refCount<=;

    if (needDelete)

    {

        delete this;

    }

}

inline void Referenced::unref_nodelete() const

{

    --_refCount;

}

#endif

#ifndef SMART_POINTER

#define SMART_POINTER 1

/** Smart pointer for handling referenced counted objects.*/

template<class T>

class SP

{

    public:

        typedef T element_type;

        SP() :_ptr(0L) {}

        SP(T* t):_ptr(t)              { if (_ptr) _ptr->ref(); }

        SP(const SP& rp):_ptr(rp._ptr)  { if (_ptr) _ptr->ref(); }

        ~SP()                           { if (_ptr) _ptr->unref(); _ptr=; }

        inline SP& operator = (const SP& rp)

        {

            if (_ptr==rp._ptr) return *this;

            T* tmp_ptr = _ptr;

            _ptr = rp._ptr;

            if (_ptr) _ptr->ref();

            // unref second to prevent any deletion of any object which might

            // be referenced by the other object. i.e rp is child of the

            // original _ptr.

            if (tmp_ptr) tmp_ptr->unref();

            return *this;

        }

        inline SP& operator = (T* ptr)

        {

            if (_ptr==ptr) return *this;

            T* tmp_ptr = _ptr;

            _ptr = ptr;

            if (_ptr) _ptr->ref();

            // unref second to prevent any deletion of any object which might

            // be referenced by the other object. i.e rp is child of the

            // original _ptr.

            if (tmp_ptr) tmp_ptr->unref();

            return *this;

        }

        // comparison operators for SP.

        inline bool operator == (const SP& rp) const { return (_ptr==rp._ptr); }

        inline bool operator != (const SP& rp) const { return (_ptr!=rp._ptr); }

        inline bool operator < (const SP& rp) const { return (_ptr<rp._ptr); }

        inline bool operator > (const SP& rp) const { return (_ptr>rp._ptr); }

        // comparison operator for const T*.

        inline bool operator == (const T* ptr) const { return (_ptr==ptr); }

        inline bool operator != (const T* ptr) const { return (_ptr!=ptr); }

        inline bool operator < (const T* ptr) const { return (_ptr<ptr); }

        inline bool operator > (const T* ptr) const { return (_ptr>ptr); }

        inline T& operator*()  { return *_ptr; }

        inline const T& operator*() const { return *_ptr; }

        inline T* operator->() { return _ptr; }

        inline const T* operator->() const   { return _ptr; }

        inline bool operator!() const   { return _ptr==0L; }

        inline bool valid() const       { return _ptr!=0L; }

        inline T* get() { return _ptr; }

        inline const T* get() const { return _ptr; }

        /** take control over the object pointed to by SP, unreference but do not delete even if ref count goes to 0,

          * return the pointer to the object.

          * Note, do not use this unless you are 100% sure your code handles the deletion of the object correctly, and

          * only use when absolutely required.*/

        inline T* take() { return release();}

        inline T* release() { T* tmp=_ptr; if (_ptr) _ptr->unref_nodelete(); _ptr=; return tmp;}

    private:

        T* _ptr;

};

#endif