/**************************************************************************** ** ** Copyright (C) 2009 Nokia Corporation and/or its subsidiary(-ies). ** Contact: Nokia Corporation (qt-info@nokia.com) ** ** This file is part of the QtCore module of the Qt Toolkit. ** ** $QT_BEGIN_LICENSE:LGPL$ ** No Commercial Usage ** This file contains pre-release code and may not be distributed. ** You may use this file in accordance with the terms and conditions ** contained in the Technology Preview License Agreement accompanying ** this package. ** ** GNU Lesser General Public License Usage ** Alternatively, this file may be used under the terms of the GNU Lesser ** General Public License version 2.1 as published by the Free Software ** Foundation and appearing in the file LICENSE.LGPL included in the ** packaging of this file. Please review the following information to ** ensure the GNU Lesser General Public License version 2.1 requirements ** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. ** ** In addition, as a special exception, Nokia gives you certain ** additional rights. These rights are described in the Nokia Qt LGPL ** Exception version 1.1, included in the file LGPL_EXCEPTION.txt in this ** package. ** ** If you have questions regarding the use of this file, please contact ** Nokia at qt-info@nokia.com. ** ** ** ** ** ** ** ** ** $QT_END_LICENSE$ ** ****************************************************************************/ #include "qsharedpointer.h" // to be sure we aren't causing a namespace clash: #include "qshareddata.h" /*! \class QSharedPointer \brief The QSharedPointer class holds a strong reference to a shared pointer \since 4.5 \reentrant The QSharedPointer is an automatic, shared pointer in C++. It behaves exactly like a normal pointer for normal purposes, including respect for constness. QSharedPointer will delete the pointer it is holding when it goes out of scope, provided no other QSharedPointer objects are referencing it. A QSharedPointer object can be created from a normal pointer, another QSharedPointer object or by promoting a QWeakPointer object to a strong reference. \section1 Thread-Safety QSharedPointer and QWeakPointer are thread-safe and operate atomically on the pointer value. Different threads can also access the same QSharedPointer or QWeakPointer object at the same time without need for locking mechanisms. It should be noted that, while the pointer value can be accessed in this manner, QSharedPointer and QWeakPointer provide no guarantee about the object being pointed to. Thread-safety and reentrancy rules for that object still apply. \section1 Other Pointer Classes Qt also provides two other pointer wrapper classes: QPointer and QSharedDataPointer. They are incompatible with one another, since each has its very different use case. QSharedPointer holds a shared pointer by means of an external reference count (i.e., a reference counter placed outside the object). Like its name indicates, the pointer value is shared among all instances of QSharedPointer and QWeakPointer. The contents of the object pointed to by the pointer should not considered shared, however: there is only one object. For that reason, QSharedPointer does not provide a way to detach or make copies of the pointed object. QSharedDataPointer, on the other hand, holds a pointer to shared data (i.e., a class derived from QSharedData). It does so by means of an internal reference count, placed in the QSharedData base class. This class can, therefore, detach based on the type of access made to the data being guarded: if it's a non-const access, it creates a copy atomically for the operation to complete. QExplicitlySharedDataPointer is a variant of QSharedDataPointer, except that it only detaches if QExplicitlySharedDataPointer::detach() is explicitly called (hence the name). QScopedPointer simply holds a pointer to a heap allocated object and deletes it in its destructor. This class is useful when an object needs to be heap allocated and deleted, but no more. QScopedPointer is lightweight, it makes no use of additional structure or reference counting. Finally, QPointer holds a pointer to a QObject-derived object, but it does so weakly. QPointer can be replaced by QWeakPointer in almost all cases, since they have the same functionality. See \l{QWeakPointer#tracking-qobject} for more information. \section1 Optional pointer tracking A feature of QSharedPointer that can be enabled at compile-time for debugging purposes is a pointer tracking mechanism. When enabled, QSharedPointer registers in a global set all the pointers that it tracks. This allows one to catch mistakes like assigning the same pointer to two QSharedPointer objects. This function is enabled by defining the \tt{QT_SHAREDPOINTER_TRACK_POINTERS} macro before including the QSharedPointer header. It is safe to use this feature even with code compiled without the feature. QSharedPointer will ensure that the pointer is removed from the tracker even from code compiled without pointer tracking. Note, however, that the pointer tracking feature has limitations on multiple- or virtual-inheritance (that is, in cases where two different pointer addresses can refer to the same object). In that case, if a pointer is cast to a different type and its value changes, QSharedPointer's pointer tracking mechanism mail fail to detect that the object being tracked is the same. \omit \secton1 QSharedPointer internals QSharedPointer is in reality implemented by two ancestor classes: QtSharedPointer::Basic and QtSharedPointer::ExternalRefCount. The reason for having that split is now mostly legacy: in the beginning, QSharedPointer was meant to support both internal reference counting and external reference counting. QtSharedPointer::Basic implements the basic functionality that is shared between internal- and external-reference counting. That is, it's mostly the accessor functions into QSharedPointer. Those are all inherited by QSharedPointer, which adds another level of shared functionality (the constructors and assignment operators). The Basic class has one member variable, which is the actual pointer being tracked. QtSharedPointer::ExternalRefCount implements the actual reference counting and introduces the d-pointer for QSharedPointer. That d-pointer itself is shared with with other QSharedPointer objects as well as QWeakPointer. The reason for keeping the pointer value itself outside the d-pointer is because of multiple inheritance needs. If you have two QSharedPointer objects of different pointer types, but pointing to the same object in memory, it could happen that the pointer values are different. The \tt differentPointers autotest exemplifies this problem. The same thing could happen in the case of virtual inheritance: a pointer of class matching the virtual base has different address compared to the pointer of the complete object. See the \tt virtualBaseDifferentPointers autotest for this problem. The d pointer is of type QtSharedPointer::ExternalRefCountData for simple QSharedPointer objects, but could be of a derived type in some cases. It is basically a reference-counted reference-counter. \section2 d-pointer \section3 QtSharedPointer::ExternalRefCountData This class is basically a reference-counted reference-counter. It has two members: \tt strongref and \tt weakref. The strong reference counter is controlling the lifetime of the object tracked by QSharedPointer. a positive value indicates that the object is alive. It's also the number of QSharedObject instances that are attached to this Data. When the strong reference count decreases to zero, the object is deleted (see below for information on custom deleters). The strong reference count can also exceptionally be -1, indicating that there are no QSharedPointers attached to an object, which is tracked too. The only case where this is possible is that of \l{QWeakPointer#tracking-qobject}{QWeakPointers tracking a QObject}. The weak reference count controls the lifetime of the d-pointer itself. It can be thought of as an internal/intrusive reference count for ExternalRefCountData itself. This count is equal to the number of QSharedPointers and QWeakPointers that are tracking this object. (In case the object tracked derives from QObject, this number is increased by 1, since QObjectPrivate tracks it too). ExternalRefCountData is a virtual class: it has a virtual destructor and a virtual destroy() function. The destroy() function is supposed to delete the object being tracked and return true if it does so. Otherwise, it returns false to indicate that the caller must simply call delete. This allows the normal use-case of QSharedPointer without custom deleters to use only one 12- or 16-byte (depending on whether it's a 32- or 64-bit architecture) external descriptor structure, without paying the price for the custom deleter that it isn't using. \section3 QtSharedPointer::ExternalRefCountDataWithDestroyFn This class is not used directly, per se. It only exists to enable the two classes that derive from it. It adds one member variable, which is a pointer to a function (which returns void and takes an ExternalRefCountData* as a parameter). It also overrides the destroy() function: it calls that function pointer with \tt this as parameter, and returns true. That means when ExternalRefCountDataWithDestroyFn is used, the \tt destroyer field must be set to a valid function that \b will delete the object tracked. This class also adds an operator delete function to ensure that simply calls the global operator delete. That should be the behaviour in all compilers already, but to be on the safe side, this class ensures that no funny business happens. On a 32-bit architecture, this class is 16 bytes in size, whereas it's 24 bytes on 64-bit. (On Itanium where function pointers contain the global pointer, it can be 32 bytes). \section3 QtSharedPointer::ExternalRefCountWithCustomDeleter This class derives from ExternalRefCountDataWithDestroyFn and is a template class. As template parameters, it has the type of the pointer being tracked (\tt T) and a \tt Deleter, which is anything. It adds two fields to its parent class, matching those template parameters: a member of type \tt Deleter and a member of type \tt T*. The purpose of this class is to store the pointer to be deleted and the deleter code along with the d-pointer. This allows the last strong reference to call any arbitrary function that disposes of the object. For example, this allows calling QObject::deleteLater() on a given object. The pointer to the object is kept here to avoid the extra cost of keeping the deleter in the generic case. This class is never instantiated directly: the constructors and destructor are private. Only the create() function may be called to return an object of this type. See below for construction details. The size of this class depends on the size of \tt Deleter. If it's an empty functor (i.e., no members), ABIs generally assign it the size of 1. But given that it's followed by a pointer, up to 3 or 7 padding bytes may be inserted: in that case, the size of this class is 16+4+4 = 24 bytes on 32-bit architectures, or 24+8+8 = 40 bytes on 64-bit architectures (48 bytes on Itanium with global pointers stored). If \tt Deleter is a function pointer, the size should be the same as the empty structure case, except for Itanium where it may be 56 bytes due to another global pointer. If \tt Deleter is a pointer to a member function (PMF), the size will be even bigger and will depend on the ABI. For architectures using the Itanium C++ ABI, a PMF is twice the size of a normal pointer, or 24 bytes on Itanium itself. In that case, the size of this structure will be 16+8+4 = 28 bytes on 32-bit architectures, 24+16+8 = 48 bytes on 64-bit, and 32+24+8 = 64 bytes on Itanium. (Values for Itanium consider an LP64 architecture; for ILP32, pointers are 32-bit in length, function pointers are 64-bit and PMF are 96-bit, so the sizes are slightly less) \section3 QtSharedPointer::ExternalRefCountWithContiguousData This class also derives from ExternalRefCountDataWithDestroyFn and it is also a template class. The template parameter is the type \tt T of the class which QSharedPointer tracks. It adds only one member to its parent, which is of type \tt T (the actual type, not a pointer to it). The purpose of this class is to lay the \tt T object out next to the reference counts, saving one memory allocation per shared pointer. This is particularly interesting for small \tt T or for the cases when there are few if any QWeakPointer tracking the object. This class exists to implement the QSharedPointer::create() call. Like ExternalRefCountWithCustomDeleter, this class is never instantiated directly. This class also provides a create() member that returns the pointer, and hides its constructors and destructor. (With C++0x, we'd delete them). The size of this class depends on the size of \tt T. \section3 Instantiating ExternalRefCountWithCustomDeleter and ExternalRefCountWithContiguousData Like explained above, these classes have private constructors. Moreover, they are not defined anywhere, so trying to call \tt{new ClassType} would result in a compilation or linker error. Instead, these classes must be constructed via their create() methods. Instead of instantiating the class by the normal way, the create() method calls \tt{operator new} directly with the size of the class, then calls the parent class's constructor only (ExternalRefCountDataWithDestroyFn). This ensures that the inherited members are initialised properly, as well as the virtual table pointer, which must point to ExternalRefCountDataWithDestroyFn's virtual table. That way, we also ensure that the virtual destructor being called is ExternalRefCountDataWithDestroyFn's. After initialising the base class, the ExternalRefCountWithCustomDeleter::create() function initialises the new members directly, by using the placement \tt{operator new}. In the case of the ExternalRefCountWithContiguousData::create() function, the address to the still-uninitialised \tt T member is saved for the callee to use. The member is only initialised in QSharedPointer::create(), so that we avoid having many variants of the internal functions according to the arguments in use for calling the constructor. When initialising the parent class, the create() functions pass the address of the static deleter() member function. That is, when the virtual destroy() is called by QSharedPointer, the deleter() functions are called instead. These functiosn static_cast the ExternalRefCountData* parameter to their own type and execute their deletion: for the ExternalRefCountWithCustomDeleter::deleter() case, it runs the user's custom deleter, then destroys the deleter; for ExternalRefCountWithContiguousData::deleter, it simply calls the \tt T destructor directly. By not calling the constructor of the derived classes, we avoid instantiating their virtual tables. Since these classes are template-based, there would be one virtual table per \tt T and \tt Deleter type. (This is what Qt 4.5 did) Instead, only one non-inline function is required per template, which is the deleter() static member. All the other functions can be inlined. What's more, the address of deleter() is calculated only in code, which can be resolved at link-time if the linker can determine that the function lies in the current application or library module (since these classes are not exported, that is the case for Windows or for builds with \tt{-fvisibility=hidden}). In contrast, a virtual table would require at least 3 relocations to be resolved at module load-time, per module where these classes are used. (In the Itanium C++ ABI, there would be more relocations, due to the RTTI) \section3 Modifications due to pointer-tracking To ensure that pointers created with pointer-tracking enabled get un-tracked when destroyed, even if destroyed by code compiled without the feature, QSharedPointer modifies slightly the instructions of the previous sections. When ExternalRefCountWithCustomDeleter or ExternalRefCountWithContiguousData are used, their create() functions will set the ExternalRefCountDataWithDestroyFn::destroyer function pointer to safetyCheckDeleter() instead. These static member functions simply call internalSafetyCheckRemove2() before passing control to the normal deleter() function. If neither custom deleter nor QSharedPointer::create() are used, then QSharedPointer uses a custom deleter of its own: the normalDeleter() function, which simply calls \tt delete. By using a custom deleter, the safetyCheckDeleter() procedure described above kicks in. \endomit \sa QSharedDataPointer, QWeakPointer, QScopedPointer */ /*! \class QWeakPointer \brief The QWeakPointer class holds a weak reference to a shared pointer \since 4.5 \reentrant The QWeakPointer is an automatic weak reference to a pointer in C++. It cannot be used to dereference the pointer directly, but it can be used to verify if the pointer has been deleted or not in another context. QWeakPointer objects can only be created by assignment from a QSharedPointer. The exception is pointers derived from QObject: in that case, QWeakPointer serves as a replacement to QPointer. It's important to note that QWeakPointer provides no automatic casting operators to prevent mistakes from happening. Even though QWeakPointer tracks a pointer, it should not be considered a pointer itself, since it doesn't guarantee that the pointed object remains valid. Therefore, to access the pointer that QWeakPointer is tracking, you must first promote it to QSharedPointer and verify if the resulting object is null or not. QSharedPointer guarantees that the object isn't deleted, so if you obtain a non-null object, you may use the pointer. See QWeakPointer::toStrongRef() for more an example. QWeakPointer also provides the QWeakPointer::data() method that returns the tracked pointer without ensuring that it remains valid. This function is provided if you can guarantee by external means that the object will not get deleted (or if you only need the pointer value) and the cost of creating a QSharedPointer using toStrongRef() is too high. That function can also be used to obtain the tracked pointer for QWeakPointers that cannot be promoted to QSharedPointer, such as those created directly from a QObject pointer (not via QSharedPointer). \section1 Tracking QObject QWeakPointer can be used to track deletion classes derives from QObject, even if they are not managed by QSharedPointer. When used in that role, QWeakPointer replaces the older QPointer in all use-cases. QWeakPointer is also more efficient than QPointer, so it should be preferred in all new code. To do that, QWeakPointer provides a special constructor that is only available if the template parameter \tt T is either QObject or a class deriving from it. Trying to use that constructor if \tt T does not derive from QObject will result in compilation errors. To obtain the QObject being tracked by QWeakPointer, you must use the QWeakPointer::data() function, but only if you can guarantee that the object cannot get deleted by another context. It should be noted that QPointer had the same constraint, so use of QWeakPointer forces you to consider whether the pointer is still valid. QObject-derived classes can only be deleted in the thread they have affinity to (which is the thread they were created in or moved to, using QObject::moveToThread()). In special, QWidget-derived classes cannot be created in non-GUI threads nor moved there. Therefore, guaranteeing that the tracked QObject has affinity to the current thread is enough to also guarantee that it won't be deleted asynchronously. Note that QWeakPointer's size and data layout do not match QPointer, so it cannot replace that class in a binary-compatible manner. Care must also be taken with QWeakPointers created directly from QObject pointers when dealing with code that was compiled with Qt versions prior to 4.6. Those versions may not track the reference counters correctly, so QWeakPointers created from QObject should never be passed to code that hasn't been recompiled. \omit \secton1 QWeakPointer internals QWeakPointer shares most of its internal functionality with \l{QSharedPointer#qsharedpointer-internals}{QSharedPointer}, so see that class's internal documentation for more information. QWeakPointer requires an external reference counter in order to operate. Therefore, it is incompatible by design with \l QSharedData-derived classes. It has a special QObject constructor, which works by calling QtSharedPointer::ExternalRefCountData::getAndRef, which retrieves the d-pointer from QObjectPrivate. If one isn't set yet, that function creates the d-pointer and atomically sets it. If getAndRef needs to create a d-pointer, it sets the strongref to -1, indicating that the QObject is not shared: QWeakPointer is used only to determine whether the QObject has been deleted. In that case, it cannot be upgraded to QSharedPointer (see the previous section). \endomit \sa QSharedPointer, QScopedPointer */ /*! \fn QSharedPointer::QSharedPointer() Creates a QSharedPointer that points to null (0). */ /*! \fn QSharedPointer::~QSharedPointer() Destroys this QSharedPointer object. If it is the last reference to the pointer stored, this will delete the pointer as well. */ /*! \fn QSharedPointer::QSharedPointer(T *ptr) Creates a QSharedPointer that points to \a ptr. The pointer \a ptr becomes managed by this QSharedPointer and must not be passed to another QSharedPointer object or deleted outside this object. */ /*! \fn QSharedPointer::QSharedPointer(T *ptr, Deleter deleter) Creates a QSharedPointer that points to \a ptr. The pointer \a ptr becomes managed by this QSharedPointer and must not be passed to another QSharedPointer object or deleted outside this object. The \a deleter paramter specifies the custom deleter for this object. The custom deleter is called when the strong reference count drops to 0 instead of the operator delete(). This is useful, for instance, for calling deleteLater() in a QObject instead: \code static void doDeleteLater(MyObject *obj) { obj->deleteLater(); } void otherFunction() { QSharedPointer obj = QSharedPointer(new MyObject, doDeleteLater); // continue using obj obj.clear(); // calls obj->deleteLater(); } \endcode It is also possible to specify a member function directly, as in: \code QSharedPointer obj = QSharedPointer(new MyObject, &QObject::deleteLater); \endcode \sa clear() */ /*! \fn QSharedPointer::QSharedPointer(const QSharedPointer &other) Creates a QSharedPointer object that shares \a other's pointer. If \tt T is a derived type of the template parameter of this class, QSharedPointer will perform an automatic cast. Otherwise, you will get a compiler error. */ /*! \fn QSharedPointer::QSharedPointer(const QWeakPointer &other) Creates a QSharedPointer by promoting the weak reference \a other to strong reference and sharing its pointer. If \tt T is a derived type of the template parameter of this class, QSharedPointer will perform an automatic cast. Otherwise, you will get a compiler error. \sa QWeakPointer::toStrongRef() */ /*! \fn QSharedPointer &QSharedPointer::operator=(const QSharedPointer &other) Makes this object share \a other's pointer. The current pointer reference is discarded and, if it was the last, the pointer will be deleted. If \tt T is a derived type of the template parameter of this class, QSharedPointer will perform an automatic cast. Otherwise, you will get a compiler error. */ /*! \fn QSharedPointer &QSharedPointer::operator=(const QWeakPointer &other) Promotes \a other to a strong reference and makes this object share a reference to the pointer referenced by it. The current pointer reference is discarded and, if it was the last, the pointer will be deleted. If \tt T is a derived type of the template parameter of this class, QSharedPointer will perform an automatic cast. Otherwise, you will get a compiler error. */ /*! \fn T *QSharedPointer::data() const Returns the value of the pointer referenced by this object. Note: do not delete the pointer returned by this function or pass it to another function that could delete it, including creating QSharedPointer or QWeakPointer objects. */ /*! \fn T &QSharedPointer::operator *() const Provides access to the shared pointer's members. \sa isNull() */ /*! \fn T *QSharedPointer::operator ->() const Provides access to the shared pointer's members. \sa isNull() */ /*! \fn bool QSharedPointer::isNull() const Returns true if this object is holding a reference to a null pointer. */ /*! \fn QSharedPointer::operator bool() const Returns true if this object is not null. This function is suitable for use in \tt if-constructs, like: \code if (sharedptr) { ... } \endcode \sa isNull() */ /*! \fn bool QSharedPointer::operator !() const Returns true if this object is null. This function is suitable for use in \tt if-constructs, like: \code if (!sharedptr) { ... } \endcode \sa isNull() */ /*! \fn QSharedPointer QSharedPointer::staticCast() const Performs a static cast from this pointer's type to \tt X and returns a QSharedPointer that shares the reference. This function can be used for up- and for down-casting, but is more useful for up-casting. Note: the template type \c X must have the same const and volatile qualifiers as the template of this object, or the cast will fail. Use constCast() if you need to drop those qualifiers. \sa dynamicCast(), constCast(), qSharedPointerCast() */ /*! \fn QSharedPointer QSharedPointer::dynamicCast() const Performs a dynamic cast from this pointer's type to \tt X and returns a QSharedPointer that shares the reference. If this function is used to up-cast, then QSharedPointer will perform a \tt dynamic_cast, which means that if the object being pointed by this QSharedPointer is not of type \tt X, the returned object will be null. Note: the template type \c X must have the same const and volatile qualifiers as the template of this object, or the cast will fail. Use constCast() if you need to drop those qualifiers. \sa qSharedPointerDynamicCast() */ /*! \fn QSharedPointer QSharedPointer::constCast() const Performs a \tt const_cast from this pointer's type to \tt X and returns a QSharedPointer that shares the reference. This function can be used for up- and for down-casting, but is more useful for up-casting. \sa isNull(), qSharedPointerConstCast() */ /*! \fn QSharedPointer QSharedPointer::objectCast() const \since 4.6 Performs a \l qobject_cast() from this pointer's type to \tt X and returns a QSharedPointer that shares the reference. If this function is used to up-cast, then QSharedPointer will perform a \tt qobject_cast, which means that if the object being pointed by this QSharedPointer is not of type \tt X, the returned object will be null. Note: the template type \c X must have the same const and volatile qualifiers as the template of this object, or the cast will fail. Use constCast() if you need to drop those qualifiers. \sa qSharedPointerObjectCast() */ /*! \fn QWeakPointer QSharedPointer::toWeakRef() const Returns a weak reference object that shares the pointer referenced by this object. \sa QWeakPointer::QWeakPointer() */ /*! \fn void QSharedPointer::clear() Clears this QSharedPointer object, dropping the reference that it may have had to the pointer. If this was the last reference, then the pointer itself will be deleted. */ /*! \fn QWeakPointer::QWeakPointer() Creates a QWeakPointer that points to nothing. */ /*! \fn QWeakPointer::~QWeakPointer() Destroys this QWeakPointer object. The pointer referenced by this object will not be deleted. */ /*! \fn QWeakPointer::QWeakPointer(const QWeakPointer &other) Creates a QWeakPointer that holds a weak reference to the pointer referenced by \a other. If \tt T is a derived type of the template parameter of this class, QWeakPointer will perform an automatic cast. Otherwise, you will get a compiler error. */ /*! \fn QWeakPointer::QWeakPointer(const QSharedPointer &other) Creates a QWeakPointer that holds a weak reference to the pointer referenced by \a other. If \tt T is a derived type of the template parameter of this class, QWeakPointer will perform an automatic cast. Otherwise, you will get a compiler error. */ /*! \fn QWeakPointer::QWeakPointer(const QObject *obj) \since 4.6 Creates a QWeakPointer that holds a weak reference directly to the QObject \a obj. This constructor is only available if the template type \tt T is QObject or derives from it (otherwise a compilation error will result). You can use this constructor with any QObject, even if they were not created with \l QSharedPointer. Note that QWeakPointers created this way on arbitrary QObjects usually cannot be promoted to QSharedPointer. \sa QSharedPointer, QWeakPointer#tracking-qobject */ /*! \fn QWeakPointer &QWeakPointer::operator=(const QObject *obj) \since 4.6 Makes this QWeakPointer hold a weak reference to directly to the QObject \a obj. This function is only available if the template type \tt T is QObject or derives from it. \sa QWeakPointer#tracking-qobject */ /*! \fn QWeakPointer &QWeakPointer::operator=(const QWeakPointer &other) Makes this object share \a other's pointer. The current pointer reference is discarded but is not deleted. If \tt T is a derived type of the template parameter of this class, QWeakPointer will perform an automatic cast. Otherwise, you will get a compiler error. */ /*! \fn QWeakPointer &QWeakPointer::operator=(const QSharedPointer &other) Makes this object share \a other's pointer. The current pointer reference is discarded but is not deleted. If \tt T is a derived type of the template parameter of this class, QWeakPointer will perform an automatic cast. Otherwise, you will get a compiler error. */ /*! \fn bool QWeakPointer::isNull() const Returns true if this object is holding a reference to a null pointer. Note that, due to the nature of weak references, the pointer that QWeakPointer references can become null at any moment, so the value returned from this function can change from false to true from one call to the next. */ /*! \fn QWeakPointer::operator bool() const Returns true if this object is not null. This function is suitable for use in \tt if-constructs, like: \code if (weakref) { ... } \endcode Note that, due to the nature of weak references, the pointer that QWeakPointer references can become null at any moment, so the value returned from this function can change from true to false from one call to the next. \sa isNull() */ /*! \fn bool QWeakPointer::operator !() const Returns true if this object is null. This function is suitable for use in \tt if-constructs, like: \code if (!weakref) { ... } \endcode Note that, due to the nature of weak references, the pointer that QWeakPointer references can become null at any moment, so the value returned from this function can change from false to true from one call to the next. \sa isNull() */ /*! \fn T *QWeakPointer::data() const \since 4.6 Returns the value of the pointer being tracked by this QWeakPointer, \b without ensuring that it cannot get deleted. To have that guarantee, use toStrongRef(), which returns a QSharedPointer object. If this function can determine that the pointer has already been deleted, it returns 0. It is ok to obtain the value of the pointer and using that value itself, like for example in debugging statements: \code qDebug("Tracking %p", weakref.data()); \endcode However, dereferencing the pointer is only allowed if you can guarantee by external means that the pointer does not get deleted. For example, if you can be certain that no other thread can delete it, nor the functions that you may call. If that is the case, then the following code is valid: \code // this pointer cannot be used in another thread // so other threads cannot delete it QWeakPointer weakref = obtainReference(); Object *obj = weakref.data(); if (obj) { // if the pointer wasn't deleted yet, we know it can't get // deleted by our own code here nor the functions we call otherFunction(obj); } \endcode Use this function with care. \sa isNull(), toStrongRef() */ /*! \fn QSharedPointer QWeakPointer::toStrongRef() const Promotes this weak reference to a strong one and returns a QSharedPointer object holding that reference. When promoting to QSharedPointer, this function verifies if the object has been deleted already or not. If it hasn't, this function increases the reference count to the shared object, thus ensuring that it will not get deleted. Since this function can fail to obtain a valid strong reference to the shared object, you should always verify if the conversion succeeded, by calling QSharedPointer::isNull() on the returned object. For example, the following code promotes a QWeakPointer that was held to a strong reference and, if it succeeded, it prints the value of the integer that was held: \code QWeakPointer weakref; // ... QSharedPointer strong = weakref.toStrongRef(); if (strong) qDebug() << "The value is:" << *strong; else qDebug() << "The value has already been deleted"; \endcode \sa QSharedPointer::QSharedPointer() */ /*! \fn void QWeakPointer::clear() Clears this QWeakPointer object, dropping the reference that it may have had to the pointer. */ /*! \fn bool operator==(const QSharedPointer &ptr1, const QSharedPointer &ptr2) \relates QSharedPointer Returns true if the pointer referenced by \a ptr1 is the same pointer as that referenced by \a ptr2. If \a ptr2's template parameter is different from \a ptr1's, QSharedPointer will attempt to perform an automatic \tt static_cast to ensure that the pointers being compared are equal. If \a ptr2's template parameter is not a base or a derived type from \a ptr1's, you will get a compiler error. */ /*! \fn bool operator!=(const QSharedPointer &ptr1, const QSharedPointer &ptr2) \relates QSharedPointer Returns true if the pointer referenced by \a ptr1 is not the same pointer as that referenced by \a ptr2. If \a ptr2's template parameter is different from \a ptr1's, QSharedPointer will attempt to perform an automatic \tt static_cast to ensure that the pointers being compared are equal. If \a ptr2's template parameter is not a base or a derived type from \a ptr1's, you will get a compiler error. */ /*! \fn bool operator==(const QSharedPointer &ptr1, const X *ptr2) \relates QSharedPointer Returns true if the pointer referenced by \a ptr1 is the same pointer as \a ptr2. If \a ptr2's type is different from \a ptr1's, QSharedPointer will attempt to perform an automatic \tt static_cast to ensure that the pointers being compared are equal. If \a ptr2's type is not a base or a derived type from this \a ptr1's, you will get a compiler error. */ /*! \fn bool operator!=(const QSharedPointer &ptr1, const X *ptr2) \relates QSharedPointer Returns true if the pointer referenced by \a ptr1 is not the same pointer as \a ptr2. If \a ptr2's type is different from \a ptr1's, QSharedPointer will attempt to perform an automatic \tt static_cast to ensure that the pointers being compared are equal. If \a ptr2's type is not a base or a derived type from this \a ptr1's, you will get a compiler error. */ /*! \fn bool operator==(const T *ptr1, const QSharedPointer &ptr2) \relates QSharedPointer Returns true if the pointer \a ptr1 is the same pointer as that referenced by \a ptr2. If \a ptr2's template parameter is different from \a ptr1's type, QSharedPointer will attempt to perform an automatic \tt static_cast to ensure that the pointers being compared are equal. If \a ptr2's template parameter is not a base or a derived type from \a ptr1's type, you will get a compiler error. */ /*! \fn bool operator!=(const T *ptr1, const QSharedPointer &ptr2) \relates QSharedPointer Returns true if the pointer \a ptr1 is not the same pointer as that referenced by \a ptr2. If \a ptr2's template parameter is different from \a ptr1's type, QSharedPointer will attempt to perform an automatic \tt static_cast to ensure that the pointers being compared are equal. If \a ptr2's template parameter is not a base or a derived type from \a ptr1's type, you will get a compiler error. */ /*! \fn bool operator==(const QSharedPointer &ptr1, const QWeakPointer &ptr2) \relates QWeakPointer Returns true if the pointer referenced by \a ptr1 is the same pointer as that referenced by \a ptr2. If \a ptr2's template parameter is different from \a ptr1's, QSharedPointer will attempt to perform an automatic \tt static_cast to ensure that the pointers being compared are equal. If \a ptr2's template parameter is not a base or a derived type from \a ptr1's, you will get a compiler error. */ /*! \fn bool operator!=(const QSharedPointer &ptr1, const QWeakPointer &ptr2) \relates QWeakPointer Returns true if the pointer referenced by \a ptr1 is not the same pointer as that referenced by \a ptr2. If \a ptr2's template parameter is different from \a ptr1's, QSharedPointer will attempt to perform an automatic \tt static_cast to ensure that the pointers being compared are equal. If \a ptr2's template parameter is not a base or a derived type from \a ptr1's, you will get a compiler error. */ /*! \fn bool operator==(const QWeakPointer &ptr1, const QSharedPointer &ptr2) \relates QWeakPointer Returns true if the pointer referenced by \a ptr1 is the same pointer as that referenced by \a ptr2. If \a ptr2's template parameter is different from \a ptr1's, QSharedPointer will attempt to perform an automatic \tt static_cast to ensure that the pointers being compared are equal. If \a ptr2's template parameter is not a base or a derived type from \a ptr1's, you will get a compiler error. */ /*! \fn bool operator!=(const QWeakPointer &ptr1, const QSharedPointer &ptr2) \relates QWeakPointer Returns true if the pointer referenced by \a ptr1 is not the same pointer as that referenced by \a ptr2. If \a ptr2's template parameter is different from \a ptr1's, QSharedPointer will attempt to perform an automatic \tt static_cast to ensure that the pointers being compared are equal. If \a ptr2's template parameter is not a base or a derived type from \a ptr1's, you will get a compiler error. */ /*! \fn QSharedPointer qSharedPointerCast(const QSharedPointer &other) \relates QSharedPointer Returns a shared pointer to the pointer held by \a other, cast to type \tt X. The types \tt T and \tt X must belong to one hierarchy for the \tt static_cast to succeed. Note that \tt X must have the same cv-qualifiers (\tt const and \tt volatile) that \tt T has, or the code will fail to compile. Use qSharedPointerConstCast to cast away the constness. \sa QSharedPointer::staticCast(), qSharedPointerDynamicCast(), qSharedPointerConstCast() */ /*! \fn QSharedPointer qSharedPointerCast(const QWeakPointer &other) \relates QSharedPointer \relates QWeakPointer Returns a shared pointer to the pointer held by \a other, cast to type \tt X. The types \tt T and \tt X must belong to one hierarchy for the \tt static_cast to succeed. The \a other object is converted first to a strong reference. If that conversion fails (because the object it's pointing to has already been deleted), this function returns a null QSharedPointer. Note that \tt X must have the same cv-qualifiers (\tt const and \tt volatile) that \tt T has, or the code will fail to compile. Use qSharedPointerConstCast to cast away the constness. \sa QWeakPointer::toStrongRef(), qSharedPointerDynamicCast(), qSharedPointerConstCast() */ /*! \fn QSharedPointer qSharedPointerDynamicCast(const QSharedPointer &other) \relates QSharedPointer Returns a shared pointer to the pointer held by \a other, using a dynamic cast to type \tt X to obtain an internal pointer of the appropriate type. If the \tt dynamic_cast fails, the object returned will be null. Note that \tt X must have the same cv-qualifiers (\tt const and \tt volatile) that \tt T has, or the code will fail to compile. Use qSharedPointerConstCast to cast away the constness. \sa QSharedPointer::dynamicCast(), qSharedPointerCast(), qSharedPointerConstCast() */ /*! \fn QSharedPointer qSharedPointerDynamicCast(const QWeakPointer &other) \relates QSharedPointer \relates QWeakPointer Returns a shared pointer to the pointer held by \a other, using a dynamic cast to type \tt X to obtain an internal pointer of the appropriate type. If the \tt dynamic_cast fails, the object returned will be null. The \a other object is converted first to a strong reference. If that conversion fails (because the object it's pointing to has already been deleted), this function also returns a null QSharedPointer. Note that \tt X must have the same cv-qualifiers (\tt const and \tt volatile) that \tt T has, or the code will fail to compile. Use qSharedPointerConstCast to cast away the constness. \sa QWeakPointer::toStrongRef(), qSharedPointerCast(), qSharedPointerConstCast() */ /*! \fn QSharedPointer qSharedPointerConstCast(const QSharedPointer &other) \relates QSharedPointer Returns a shared pointer to the pointer held by \a other, cast to type \tt X. The types \tt T and \tt X must belong to one hierarchy for the \tt const_cast to succeed. The \tt const and \tt volatile differences between \tt T and \tt X are ignored. \sa QSharedPointer::constCast(), qSharedPointerCast(), qSharedPointerDynamicCast() */ /*! \fn QSharedPointer qSharedPointerConstCast(const QWeakPointer &other) \relates QSharedPointer \relates QWeakPointer Returns a shared pointer to the pointer held by \a other, cast to type \tt X. The types \tt T and \tt X must belong to one hierarchy for the \tt const_cast to succeed. The \tt const and \tt volatile differences between \tt T and \tt X are ignored. The \a other object is converted first to a strong reference. If that conversion fails (because the object it's pointing to has already been deleted), this function returns a null QSharedPointer. \sa QWeakPointer::toStrongRef(), qSharedPointerCast(), qSharedPointerDynamicCast() */ /*! \fn QSharedPointer qSharedPointerObjectCast(const QSharedPointer &other) \relates QSharedPointer \since 4.6 Returns a shared pointer to the pointer held by \a other, using a \l qobject_cast() to type \tt X to obtain an internal pointer of the appropriate type. If the \tt qobject_cast fails, the object returned will be null. Note that \tt X must have the same cv-qualifiers (\tt const and \tt volatile) that \tt T has, or the code will fail to compile. Use qSharedPointerConstCast to cast away the constness. \sa QSharedPointer::objectCast(), qSharedPointerCast(), qSharedPointerConstCast() */ /*! \fn QSharedPointer qSharedPointerObjectCast(const QWeakPointer &other) \relates QSharedPointer \relates QWeakPointer \since 4.6 Returns a shared pointer to the pointer held by \a other, using a \l qobject_cast() to type \tt X to obtain an internal pointer of the appropriate type. If the \tt qobject_cast fails, the object returned will be null. The \a other object is converted first to a strong reference. If that conversion fails (because the object it's pointing to has already been deleted), this function also returns a null QSharedPointer. Note that \tt X must have the same cv-qualifiers (\tt const and \tt volatile) that \tt T has, or the code will fail to compile. Use qSharedPointerConstCast to cast away the constness. \sa QWeakPointer::toStrongRef(), qSharedPointerCast(), qSharedPointerConstCast() */ /*! \fn QWeakPointer qWeakPointerCast(const QWeakPointer &other) \relates QWeakPointer Returns a weak pointer to the pointer held by \a other, cast to type \tt X. The types \tt T and \tt X must belong to one hierarchy for the \tt static_cast to succeed. Note that \tt X must have the same cv-qualifiers (\tt const and \tt volatile) that \tt T has, or the code will fail to compile. Use qSharedPointerConstCast to cast away the constness. */ #include #include #if !defined(QT_NO_QOBJECT) #include "private/qobject_p.h" QT_BEGIN_NAMESPACE /*! \internal This function is called for a just-created QObject \a obj, to enable the use of QSharedPointer and QWeakPointer. When QSharedPointer is active in a QObject, the object must not be deleted directly: the lifetime is managed by the QSharedPointer object. In that case, the deleteLater() and parent-child relationship in QObject only decrease the strong reference count, instead of deleting the object. */ void QtSharedPointer::ExternalRefCountData::setQObjectShared(const QObject *obj, bool) { Q_ASSERT(obj); QObjectPrivate *d = QObjectPrivate::get(const_cast(obj)); if (d->sharedRefcount) qFatal("QSharedPointer: pointer %p already has reference counting", obj); d->sharedRefcount = this; // QObject decreases the refcount too, so increase it up weakref.ref(); } QtSharedPointer::ExternalRefCountData *QtSharedPointer::ExternalRefCountData::getAndRef(const QObject *obj) { Q_ASSERT(obj); QObjectPrivate *d = QObjectPrivate::get(const_cast(obj)); Q_ASSERT_X(!d->wasDeleted, "QWeakPointer", "Detected QWeakPointer creation in a QObject being deleted"); ExternalRefCountData *that = d->sharedRefcount; if (that) { that->weakref.ref(); return that; } // we can create the refcount data because it doesn't exist ExternalRefCountData *x = new ExternalRefCountData(Qt::Uninitialized); x->strongref = -1; x->weakref = 2; // the QWeakPointer that called us plus the QObject itself if (!d->sharedRefcount.testAndSetRelease(0, x)) { delete x; d->sharedRefcount->weakref.ref(); } return d->sharedRefcount; } QT_END_NAMESPACE #endif #if !defined(QT_NO_MEMBER_TEMPLATES) //# define QT_SHARED_POINTER_BACKTRACE_SUPPORT # ifdef QT_SHARED_POINTER_BACKTRACE_SUPPORT # if defined(__GLIBC__) && (__GLIBC__ >= 2) && !defined(__UCLIBC__) && !defined(QT_LINUXBASE) # define BACKTRACE_SUPPORTED # elif defined(Q_OS_MACX) # define BACKTRACE_SUPPORTED # endif # endif # if defined(BACKTRACE_SUPPORTED) # include # include # include # include # include QT_BEGIN_NAMESPACE static inline QByteArray saveBacktrace() __attribute__((always_inline)); static inline QByteArray saveBacktrace() { static const int maxFrames = 32; QByteArray stacktrace; stacktrace.resize(sizeof(void*) * maxFrames); int stack_size = backtrace((void**)stacktrace.data(), maxFrames); stacktrace.resize(sizeof(void*) * stack_size); return stacktrace; } static void printBacktrace(QByteArray stacktrace) { void *const *stack = (void *const *)stacktrace.constData(); int stack_size = stacktrace.size() / sizeof(void*); char **stack_symbols = backtrace_symbols(stack, stack_size); int filter[2]; pid_t child = -1; if (pipe(filter) != -1) child = fork(); if (child == 0) { // child process dup2(fileno(stderr), fileno(stdout)); dup2(filter[0], fileno(stdin)); close(filter[0]); close(filter[1]); execlp("c++filt", "c++filt", "-n", NULL); // execlp failed execl("/bin/cat", "/bin/cat", NULL); _exit(127); } // parent process close(filter[0]); FILE *output; if (child == -1) { // failed forking close(filter[1]); output = stderr; } else { output = fdopen(filter[1], "w"); } fprintf(stderr, "Backtrace of the first creation (most recent frame first):\n"); for (int i = 0; i < stack_size; ++i) { if (strlen(stack_symbols[i])) fprintf(output, "#%-2d %s\n", i, stack_symbols[i]); else fprintf(output, "#%-2d %p\n", i, stack[i]); } if (child != -1) { fclose(output); waitpid(child, 0, 0); } } QT_END_NAMESPACE # endif // BACKTRACE_SUPPORTED namespace { QT_USE_NAMESPACE struct Data { const volatile void *pointer; # ifdef BACKTRACE_SUPPORTED QByteArray backtrace; # endif }; class KnownPointers { public: QMutex mutex; QHash dPointers; QHash dataPointers; }; } Q_GLOBAL_STATIC(KnownPointers, knownPointers) QT_BEGIN_NAMESPACE namespace QtSharedPointer { Q_CORE_EXPORT void internalSafetyCheckAdd(const volatile void *); Q_CORE_EXPORT void internalSafetyCheckRemove(const volatile void *); Q_AUTOTEST_EXPORT void internalSafetyCheckCleanCheck(); } /*! \internal */ void QtSharedPointer::internalSafetyCheckAdd(const volatile void *) { // Qt 4.5 compatibility // this function is broken by design, so it was replaced with internalSafetyCheckAdd2 // // it's broken because we tracked the pointers added and // removed from QSharedPointer, converted to void*. // That is, this is supposed to track the "top-of-object" pointer in // case of multiple inheritance. // // However, it doesn't work well in some compilers: // if you create an object with a class of type A and the last reference // is dropped of type B, then the value passed to internalSafetyCheckRemove could // be different than was added. That would leave dangling addresses. // // So instead, we track the pointer by the d-pointer instead. } /*! \internal */ void QtSharedPointer::internalSafetyCheckRemove(const volatile void *) { // Qt 4.5 compatibility // see comments above } /*! \internal */ void QtSharedPointer::internalSafetyCheckAdd2(const void *d_ptr, const volatile void *ptr) { // see comments above for the rationale for this function KnownPointers *const kp = knownPointers(); if (!kp) return; // end-game: the application is being destroyed already QMutexLocker lock(&kp->mutex); Q_ASSERT(!kp->dPointers.contains(d_ptr)); //qDebug("Adding d=%p value=%p", d_ptr, ptr); const void *other_d_ptr = kp->dataPointers.value(ptr, 0); if (other_d_ptr) { # ifdef BACKTRACE_SUPPORTED printBacktrace(knownPointers()->dPointers.value(other_d_ptr).backtrace); # endif qFatal("QSharedPointer: internal self-check failed: pointer %p was already tracked " "by another QSharedPointer object %p", ptr, other_d_ptr); } Data data; data.pointer = ptr; # ifdef BACKTRACE_SUPPORTED data.backtrace = saveBacktrace(); # endif kp->dPointers.insert(d_ptr, data); kp->dataPointers.insert(ptr, d_ptr); Q_ASSERT(kp->dPointers.size() == kp->dataPointers.size()); } /*! \internal */ void QtSharedPointer::internalSafetyCheckRemove2(const void *d_ptr) { KnownPointers *const kp = knownPointers(); if (!kp) return; // end-game: the application is being destroyed already QMutexLocker lock(&kp->mutex); QHash::iterator it = kp->dPointers.find(d_ptr); if (it == kp->dPointers.end()) { qFatal("QSharedPointer: internal self-check inconsistency: pointer %p was not tracked. " "To use QT_SHAREDPOINTER_TRACK_POINTERS, you have to enable it throughout " "in your code.", d_ptr); } QHash::iterator it2 = kp->dataPointers.find(it->pointer); Q_ASSERT(it2 != kp->dataPointers.end()); //qDebug("Removing d=%p value=%p", d_ptr, it->pointer); // remove entries kp->dataPointers.erase(it2); kp->dPointers.erase(it); Q_ASSERT(kp->dPointers.size() == kp->dataPointers.size()); } /*! \internal Called by the QSharedPointer autotest */ void QtSharedPointer::internalSafetyCheckCleanCheck() { # ifdef QT_BUILD_INTERNAL KnownPointers *const kp = knownPointers(); Q_ASSERT_X(kp, "internalSafetyCheckSelfCheck()", "Called after global statics deletion!"); if (kp->dPointers.size() != kp->dataPointers.size()) qFatal("Internal consistency error: the number of pointers is not equal!"); if (!kp->dPointers.isEmpty()) qFatal("Pointer cleaning failed: %d entries remaining", kp->dPointers.size()); # endif } QT_END_NAMESPACE #endif