///////////////////////////////////////////////////////////////////////////// // Name: object.h // Purpose: interface of wxObjectRefData // Author: wxWidgets team // RCS-ID: $Id$ // Licence: wxWindows license ///////////////////////////////////////////////////////////////////////////// /** @class wxObjectRefData This class is used to store reference-counted data. Derive classes from this to store your own data. When retrieving information from a wxObject's reference data, you will need to cast to your own derived class. @section objectrefdata_example Example @code // include file // ------------ class MyCar : public wxObject { public: MyCar() { } MyCar( int price ); bool IsOk() const { return m_refData != NULL; } bool operator == ( const MyCar& car ) const; bool operator != (const MyCar& car) const { return !(*this == car); } void SetPrice( int price ); int GetPrice() const; protected: virtual wxObjectRefData *CreateRefData() const; virtual wxObjectRefData *CloneRefData(const wxObjectRefData *data) const; DECLARE_DYNAMIC_CLASS(MyCar) }; // implementation // -------------- // the reference data class is typically a private class only visible in the // implementation source file of the refcounted class. class MyCarRefData : public wxObjectRefData { public: MyCarRefData() { m_price = 0; } MyCarRefData( const MyCarRefData& data ) : wxObjectRefData() { // copy refcounted data; this is usually a time- and memory-consuming operation // and is only done when two (or more) MyCar instances need to unshare a // common instance of MyCarRefData m_price = data.m_price; } bool operator == (const MyCarRefData& data) const { return m_price == data.m_price; } private: // in real world, reference counting is usually used only when // the wxObjectRefData-derived class holds data very memory-consuming; // in this example the various MyCar instances may share a MyCarRefData // instance which however only takes 4 bytes for this integer! int m_price; }; #define M_CARDATA ((MyCarRefData *)m_refData) IMPLEMENT_DYNAMIC_CLASS(MyCar,wxObject) MyCar::MyCar( int price ) { // here we init the MyCar internal data: m_refData = new MyCarRefData(); M_CARDATA->m_price = price; } wxObjectRefData *MyCar::CreateRefData() const { return new MyCarRefData; } wxObjectRefData *MyCar::CloneRefData(const wxObjectRefData *data) const { return new MyCarRefData(*(MyCarRefData *)data); } bool MyCar::operator == ( const MyCar& car ) const { if (m_refData == car.m_refData) return true; if (!m_refData || !car.m_refData) return false; // here we use the MyCarRefData::operator==() function. // Note however that this comparison may be very slow if the // reference data contains a lot of data to be compared. return ( *(MyCarRefData*)m_refData == *(MyCarRefData*)car.m_refData ); } void MyCar::SetPrice( int price ) { // since this function modifies one of the MyCar internal property, // we need to be sure that the other MyCar instances which share the // same MyCarRefData instance are not affected by this call. // I.e. it's very important to call UnShare() in all setters of // refcounted classes! UnShare(); M_CARDATA->m_price = price; } int MyCar::GetPrice() const { wxCHECK_MSG( IsOk(), -1, "invalid car" ); return M_CARDATA->m_price; } @endcode @library{wxbase} @category{rtti} @see wxObject, wxObjectDataPtr, @ref overview_refcount */ class wxObjectRefData { protected: /** Destructor. It's declared @c protected so that wxObjectRefData instances will never be destroyed directly but only as result of a DecRef() call. */ virtual ~wxObjectRefData(); public: /** Default constructor. Initialises the internal reference count to 1. */ wxObjectRefData(); /** Decrements the reference count associated with this shared data and, if it reaches zero, destroys this instance of wxObjectRefData releasing its memory. Please note that after calling this function, the caller should absolutely avoid to use the pointer to this instance since it may not be valid anymore. */ void DecRef(); /** Returns the reference count associated with this shared data. When this goes to zero during a DecRef() call, the object will auto-free itself. */ int GetRefCount() const; /** Increments the reference count associated with this shared data. */ void IncRef(); }; /** @class wxObject This is the root class of many of the wxWidgets classes. It declares a virtual destructor which ensures that destructors get called for all derived class objects where necessary. wxObject is the hub of a dynamic object creation scheme, enabling a program to create instances of a class only knowing its string class name, and to query the class hierarchy. The class contains optional debugging versions of @b new and @b delete, which can help trace memory allocation and deallocation problems. wxObject can be used to implement @ref overview_refcount "reference counted" objects, such as wxPen, wxBitmap and others (see @ref overview_refcount_list "this list"). See wxObjectRefData and @ref overview_refcount for more info about reference counting. @library{wxbase} @category{rtti} @see wxClassInfo, @ref overview_debugging, @ref overview_refcount, wxObjectRefData, wxObjectDataPtr */ class wxObject { public: /** Default ctor; initializes to @NULL the internal reference data. */ wxObject(); /** Copy ctor. Sets the internal wxObject::m_refData pointer to point to the same instance of the wxObjectRefData-derived class pointed by @c other and increments the refcount of wxObject::m_refData. */ wxObject(const wxObject& other); /** Destructor. Performs dereferencing, for those objects that use reference counting. */ virtual ~wxObject(); /** This virtual function is redefined for every class that requires run-time type information, when using the ::DECLARE_CLASS macro (or similar). */ virtual wxClassInfo* GetClassInfo() const; /** Returns the wxObject::m_refData pointer, i.e. the data referenced by this object. @see Ref(), UnRef(), wxObject::m_refData, SetRefData(), wxObjectRefData */ wxObjectRefData* GetRefData() const; /** Determines whether this class is a subclass of (or the same class as) the given class. Example: @code bool tmp = obj->IsKindOf(CLASSINFO(wxFrame)); @endcode @param info A pointer to a class information object, which may be obtained by using the ::CLASSINFO macro. @return @true if the class represented by info is the same class as this one or is derived from it. */ bool IsKindOf(const wxClassInfo* info) const; /** Returns @true if this object has the same data pointer as @a obj. Notice that @true is returned if the data pointers are @NULL in both objects. This function only does a @e shallow comparison, i.e. it doesn't compare the objects pointed to by the data pointers of these objects. @see @ref overview_refcount */ bool IsSameAs(const wxObject& obj) const; /** Makes this object refer to the data in @a clone. @param clone The object to 'clone'. @remarks First this function calls UnRef() on itself to decrement (and perhaps free) the data it is currently referring to. It then sets its own wxObject::m_refData to point to that of @a clone, and increments the reference count inside the data. @see UnRef(), SetRefData(), GetRefData(), wxObjectRefData */ void Ref(const wxObject& clone); /** Sets the wxObject::m_refData pointer. @see Ref(), UnRef(), GetRefData(), wxObjectRefData */ void SetRefData(wxObjectRefData* data); /** Decrements the reference count in the associated data, and if it is zero, deletes the data. The wxObject::m_refData member is set to @NULL. @see Ref(), SetRefData(), GetRefData(), wxObjectRefData */ void UnRef(); /** This is the same of AllocExclusive() but this method is public. */ void UnShare(); /** The @e delete operator is defined for debugging versions of the library only, when the identifier @c __WXDEBUG__ is defined. It takes over memory deallocation, allowing wxDebugContext operations. */ void operator delete(void *buf); /** The @e new operator is defined for debugging versions of the library only, when the identifier @c __WXDEBUG__ is defined. It takes over memory allocation, allowing wxDebugContext operations. */ void* operator new(size_t size, const wxString& filename = NULL, int lineNum = 0); protected: /** Ensure that this object's data is not shared with any other object. If we have no data, it is created using CreateRefData(); if we have shared data (i.e. data with a reference count greater than 1), it is copied using CloneRefData(); otherwise nothing is done (the data is already present and is not shared by other object instances). If you use this function you should make sure that you override the CreateRefData() and CloneRefData() functions in your class otherwise an assertion will fail at runtime. */ void AllocExclusive(); /** Creates a new instance of the wxObjectRefData-derived class specific to this object and returns it. This is usually implemented as a one-line call: @code wxObjectRefData *MyObject::CreateRefData() const { return new MyObjectRefData; } @endcode */ virtual wxObjectRefData *CreateRefData() const; /** Creates a new instance of the wxObjectRefData-derived class specific to this object and initializes it copying @a data. This is usually implemented as a one-line call: @code wxObjectRefData *MyObject::CloneRefData(const wxObjectRefData *data) const { // rely on the MyObjectRefData copy ctor: return new MyObjectRefData(*(MyObjectRefData *)data); } @endcode */ virtual wxObjectRefData *CloneRefData(const wxObjectRefData *data) const; /** Pointer to an object which is the object's reference-counted data. @see Ref(), UnRef(), SetRefData(), GetRefData(), wxObjectRefData */ wxObjectRefData* m_refData; }; /** @class wxClassInfo This class stores meta-information about classes. Instances of this class are not generally defined directly by an application, but indirectly through use of macros such as ::DECLARE_DYNAMIC_CLASS and ::IMPLEMENT_DYNAMIC_CLASS. @library{wxbase} @category{rtti} @see @ref overview_rtti_classinfo, wxObject */ class wxClassInfo { public: /** Constructs a wxClassInfo object. The supplied macros implicitly construct objects of this class, so there is no need to create such objects explicitly in an application. */ wxClassInfo(const wxChar* className, const wxClassInfo* baseClass1, const wxClassInfo* baseClass2, int size, wxObjectConstructorFn fn); /** Creates an object of the appropriate kind. @return @NULL if the class has not been declared dynamically creatable (typically, this happens for abstract classes). */ wxObject* CreateObject() const; /** Finds the wxClassInfo object for a class with the given @a name. */ static wxClassInfo* FindClass(const wxString& className); /** Returns the name of the first base class (@NULL if none). */ const wxChar* GetBaseClassName1() const; /** Returns the name of the second base class (@NULL if none). */ const wxChar* GetBaseClassName2() const; /** Returns the string form of the class name. */ const wxChar* GetClassName() const; /** Returns the size of the class. */ int GetSize() const; /** Returns @true if this class info can create objects of the associated class. */ bool IsDynamic() const; /** Returns @true if this class is a kind of (inherits from) the given class. */ bool IsKindOf(const wxClassInfo* info) const; }; /** This is an helper template class primarily written to avoid memory leaks because of missing calls to wxObjectRefData::DecRef(). Despite the name this template can actually be used as a smart pointer for any class implementing the reference counting interface which only consists of the two methods @b T::IncRef() and @b T::DecRef(). The difference to wxSharedPtr is that wxObjectDataPtr relies on the reference counting to be in the class pointed to, where instead wxSharedPtr implements the reference counting itself. @section objectdataptr_example Example @code class MyCarRefData: public wxObjectRefData { public: MyCarRefData() { m_price = 0; } MyCarRefData( const MyCarRefData& data ) : wxObjectRefData() { m_price = data.m_price; } void SetPrice( int price ) { m_price = price; } int GetPrice() const { return m_price; } bool operator == ( const MyCarRefData& other ) const { return m_price == other.m_price; } protected: int m_price; }; class MyCar { public: // initializes this MyCar assigning to the // internal data pointer a new instance of MyCarRefData MyCar( int price ) : m_data( new MyCarRefData ) { m_data->SetPrice( price ); } MyCar& operator =( const MyCar& tocopy ) { // shallow copy: this is just a fast copy of pointers; the real // memory-consuming data which typically is stored inside // MyCarRefData is not copied here! m_data = tocopy.m_data; return *this; } bool operator == ( const MyCar& other ) const { if (m_data.get() == other.m_data.get()) return true; // this instance and the 'other' one share the // same MyCarRefData data... // rely on the MyCarRefData::operator==() return (*m_data.get()) == (*other.m_data.get()); } void SetPrice( int price ) { // make sure changes to this class do not affect other instances // currently sharing our same refcounted data: UnShare(); m_data->SetPrice( price ); } int GetPrice() const { return m_data->GetPrice(); } wxObjectDataPtr m_data; protected: void UnShare() { if (m_data->GetRefCount() == 1) return; m_data.reset( new MyCarRefData( *m_data ) ); } }; @endcode @library{wxbase} @category{rtti,smartpointers} @see wxObject, wxObjectRefData, @ref overview_refcount, wxSharedPtr, wxScopedPtr, wxWeakRef */ template class wxObjectDataPtr { public: /** Constructor. @a ptr is a pointer to the reference counted object to which this class points. If @a ptr is not NULL @b T::IncRef() will be called on the object. */ wxObjectDataPtr(T* ptr = NULL); /** This copy constructor increases the count of the reference counted object to which @a tocopy points and then this class will point to, as well. */ wxObjectDataPtr(const wxObjectDataPtr& tocopy); /** Decreases the reference count of the object to which this class points. */ ~wxObjectDataPtr(); /** Gets a pointer to the reference counted object to which this class points. */ T* get() const; /** Reset this class to ptr which points to a reference counted object and calls T::DecRef() on the previously owned object. */ void reset(T *ptr); /** Conversion to a boolean expression (in a variant which is not convertable to anything but a boolean expression). If this class contains a valid pointer it will return @true, if it contains a @NULL pointer it will return @false. */ operator unspecified_bool_type() const; /** Returns a reference to the object. If the internal pointer is @NULL this method will cause an assert in debug mode. */ T& operator*() const; /** Returns a pointer to the reference counted object to which this class points. If this the internal pointer is @NULL, this method will assert in debug mode. */ T* operator->() const; //@{ /** Assignment operator. */ wxObjectDataPtr& operator=(const wxObjectDataPtr& tocopy); wxObjectDataPtr& operator=(T* ptr); //@} }; // ============================================================================ // Global functions/macros // ============================================================================ /** @addtogroup group_funcmacro_rtti */ //@{ /** Returns a pointer to the wxClassInfo object associated with this class. @header{wx/object.h} */ #define CLASSINFO( className ) /** Used inside a class declaration to declare that the class should be made known to the class hierarchy, but objects of this class cannot be created dynamically. The same as DECLARE_ABSTRACT_CLASS(). @header{wx/object.h} */ #define DECLARE_CLASS( className ) /** Used inside a class declaration to declare that the class should be made known to the class hierarchy, but objects of this class cannot be created dynamically. The same as DECLARE_CLASS(). @header{wx/object.h} Example: @code class wxCommand: public wxObject { DECLARE_ABSTRACT_CLASS(wxCommand) private: ... public: ... }; @endcode */ #define DECLARE_ABSTRACT_CLASS( className ) /** Used inside a class declaration to make the class known to wxWidgets RTTI system and also declare that the objects of this class should be dynamically creatable from run-time type information. Notice that this implies that the class should have a default constructor, if this is not the case consider using DECLARE_CLASS(). @header{wx/object.h} Example: @code class wxFrame: public wxWindow { DECLARE_DYNAMIC_CLASS(wxFrame) private: const wxString& frameTitle; public: ... }; @endcode */ #define DECLARE_DYNAMIC_CLASS( className ) /** Used in a C++ implementation file to complete the declaration of a class that has run-time type information. The same as IMPLEMENT_ABSTRACT_CLASS(). @header{wx/object.h} */ #define IMPLEMENT_CLASS( className, baseClassName ) /** Used in a C++ implementation file to complete the declaration of a class that has run-time type information and two base classes. The same as IMPLEMENT_ABSTRACT_CLASS2(). @header{wx/object.h} */ #define IMPLEMENT_CLASS2( className, baseClassName1, baseClassName2 ) /** Used in a C++ implementation file to complete the declaration of a class that has run-time type information. The same as IMPLEMENT_CLASS(). @header{wx/object.h} Example: @code IMPLEMENT_ABSTRACT_CLASS(wxCommand, wxObject) wxCommand::wxCommand(void) { ... } @endcode */ #define IMPLEMENT_ABSTRACT_CLASS( className, baseClassName ) /** Used in a C++ implementation file to complete the declaration of a class that has run-time type information and two base classes. The same as IMPLEMENT_CLASS2(). @header{wx/object.h} */ #define IMPLEMENT_ABSTRACT_CLASS2( className, baseClassName1, baseClassName2 ) /** Used in a C++ implementation file to complete the declaration of a class that has run-time type information, and whose instances can be created dynamically. @header{wx/object.h} Example: @code IMPLEMENT_DYNAMIC_CLASS(wxFrame, wxWindow) wxFrame::wxFrame(void) { ... } @endcode */ #define IMPLEMENT_DYNAMIC_CLASS( className, baseClassName ) /** Used in a C++ implementation file to complete the declaration of a class that has run-time type information, and whose instances can be created dynamically. Use this for classes derived from two base classes. @header{wx/object.h} */ #define IMPLEMENT_DYNAMIC_CLASS2( className, baseClassName1, baseClassName2 ) /** Same as @c const_cast(x) if the compiler supports const cast or @c (T)x for old compilers. Unlike wxConstCast(), the cast it to the type @c T and not to T * and also the order of arguments is the same as for the standard cast. @header{wx/defs.h} @see wx_reinterpret_cast(), wx_static_cast() */ #define wx_const_cast(T, x) /** Same as @c reinterpret_cast(x) if the compiler supports reinterpret cast or @c (T)x for old compilers. @header{wx/defs.h} @see wx_const_cast(), wx_static_cast() */ #define wx_reinterpret_cast(T, x) /** Same as @c static_cast(x) if the compiler supports static cast or @c (T)x for old compilers. Unlike wxStaticCast(), there are no checks being done and the meaning of the macro arguments is exactly the same as for the standard static cast, i.e. @a T is the full type name and star is not appended to it. @header{wx/defs.h} @see wx_const_cast(), wx_reinterpret_cast(), wx_truncate_cast() */ #define wx_static_cast(T, x) /** This case doesn’t correspond to any standard cast but exists solely to make casts which possibly result in a truncation of an integer value more readable. @header{wx/defs.h} */ #define wx_truncate_cast(T, x) /** This macro expands into const_cast(ptr) if the compiler supports const_cast or into an old, C-style cast, otherwise. @header{wx/defs.h} @see wx_const_cast(), wxDynamicCast(), wxStaticCast() */ #define wxConstCast( ptr, classname ) /** This macro returns the pointer @e ptr cast to the type @e classname * if the pointer is of this type (the check is done during the run-time) or @NULL otherwise. Usage of this macro is preferred over obsoleted wxObject::IsKindOf() function. The @e ptr argument may be @NULL, in which case @NULL will be returned. @header{wx/object.h} Example: @code wxWindow *win = wxWindow::FindFocus(); wxTextCtrl *text = wxDynamicCast(win, wxTextCtrl); if ( text ) { // a text control has the focus... } else { // no window has the focus or it is not a text control } @endcode @see @ref overview_rtti, wxDynamicCastThis(), wxConstCast(), wxStaticCast() */ #define wxDynamicCast( ptr, classname ) /** This macro is equivalent to wxDynamicCast(this, classname) but the latter provokes spurious compilation warnings from some compilers (because it tests whether @c this pointer is non-@NULL which is always true), so this macro should be used to avoid them. @header{wx/object.h} @see wxDynamicCast() */ #define wxDynamicCastThis( classname ) /** This macro checks that the cast is valid in debug mode (an assert failure will result if wxDynamicCast(ptr, classname) == @NULL) and then returns the result of executing an equivalent of static_cast(ptr). @header{wx/object.h} @see wx_static_cast(), wxDynamicCast(), wxConstCast() */ #define wxStaticCast( ptr, classname ) /** Creates and returns an object of the given class, if the class has been registered with the dynamic class system using DECLARE... and IMPLEMENT... macros. @header{wx/object.h} */ wxObject *wxCreateDynamicObject(const wxString& className); //@} /** @addtogroup group_funcmacro_debug */ //@{ /** This is defined in debug mode to be call the redefined new operator with filename and line number arguments. The definition is: @code #define WXDEBUG_NEW new(__FILE__,__LINE__) @endcode In non-debug mode, this is defined as the normal new operator. @header{wx/object.h} */ #define WXDEBUG_NEW( arg ) //@}