#ifndef STLPLUS_SIMPLE_PTR #define STLPLUS_SIMPLE_PTR //////////////////////////////////////////////////////////////////////////////// // Author: Daniel Milton, Andy Rushton // Copyright: (c) Southampton University 1999-2004 // (c) Daniel Milton, Andy Rushton 2004-2009 // License: BSD License, see ../docs/license.html // A smart pointer is a memory-managing pointer to an object. If you like, it // is a zero-dimensional container. // Assignment of smart pointers result in multiple aliases of the same object. // The term alias is used to differentiate from conventional pointers because // the semantics are different. // Aliases can be turned into copies if the pointed-to class supports copying. // These simple_ptr classes from DJDM have slightly different semantics than // the smart_ptr classes of AJR. There are no cross-pointer side effects // that occur when the pointer is cleared. The clear() function is effectively // equivalent to the clear_unique() function of the smart_ptr. The only way // that a "referenced" object will be deleted is if all simple_ptr's that // reference the object are cleared (by deletion, manual clearing or reassignment). // Also, the simple pointer cannot contain a reference to a shared null pointer // (which occurs as a side-effect of clearing a multiply referenced object in // the smart_ptr classes). Which means that if you have a null simple_ptr, then // the assignment of any other null simple_ptr will NOT reassign the reference of // any other simple_ptr. Hence, the simple_ptr class acts a little more like a // normal pointer (with fewer side effects), with the added bonus of containment. // Due to the way that the simple_ptr contains the data, it also allows the // addition of various casting functions, while still keeping the managed data // containment functionality of the underlying object. This means that you can // have two simple_ptr's of different template types, both pointing to the same // data (if the differing template types are derivatives of each other). // The base class is simple_ptr_base which defines the common interface. Then // there are three subclasses which have the same interface but different copy // semantics: // - simple_ptr for simple types and classes which have copy constructors // - simple_ptr_clone for polymorphic class hierarchies which are copied using a clone method // - simple_ptr_nocopy for any class that cannot or should not be copied //////////////////////////////////////////////////////////////////////////////// #include "containers_fixes.hpp" #include "exceptions.hpp" #include "copy_functors.hpp" #include #include namespace stlplus { //////////////////////////////////////////////////////////////////////////////// // Base class //////////////////////////////////////////////////////////////////////////////// template class simple_ptr_base { public: ////////////////////////////////////////////////////////////////////////////// // member type definitions typedef T value_type; typedef T& reference; typedef const T& const_reference; typedef C value_copy; ////////////////////////////////////////////////////////////////////////////// // constructors and destructors // create a null pointer simple_ptr_base(void); // create a pointer containing a *copy* of the object using the template parameter C // this copy is taken because the pointer class maintains a dynamically allocated object // and the T& may not be (usually is not) dynamically allocated explicit simple_ptr_base(const T& data) throw(illegal_copy); // create a pointer containing a dynamically created object // Note: the object must be allocated *by the user* with new // constructor form - must be called in the form smart_ptr_base x(new type(args)) explicit simple_ptr_base(T* data); // copy constructor implements aliasing so no copy is made // note that the copy constructor should NOT be explicit, as this breaks // the returning of pointer objects from functions (at least within GCC 4.4) simple_ptr_base(const simple_ptr_base& r); // assignment operator - required, else the output of GCC suffers segmentation faults simple_ptr_base& operator=(const simple_ptr_base& r); // destructor decrements the reference count and delete only when the last reference is destroyed ~simple_ptr_base(void); ////////////////////////////////////////////////////////////////////////////// // logical tests to see if there is anything contained in the pointer since it can be null // there are two forms:explicit and implicit // implicit: if(!r) or if(r) // explicit: if(r.null()) or if(r.present()) operator bool(void) const; bool operator!(void) const; bool present(void) const; bool null(void) const; ////////////////////////////////////////////////////////////////////////////// // dereference operators and functions // dereference the smart pointer to get the object - use in the form *p1 T& operator*(void) throw(null_dereference); const T& operator*(void) const throw(null_dereference); // used as a prefix to a member access to the contained object e.g. p1->print() calls T::print() T* operator->(void) throw(null_dereference); const T* operator->(void) const throw(null_dereference); ////////////////////////////////////////////////////////////////////////////// // explicit function forms of the above assignment and dereference operators // set the value - note that this does a copy using the C template parameter void set_value(const T& data) throw(illegal_copy); // get the value T& value(void) throw(null_dereference); const T& value(void) const throw(null_dereference); // set the pointer // deletes the previous pointer and adopts the passed pointer instead // Note: the object must be allocated *by the user* with new // Warning: it is very easy to break the memory management with this operation void set(T* data = 0); // get the pointer T* pointer(void); const T* pointer(void) const; ////////////////////////////////////////////////////////////////////////////// // functions to manage aliases // make this an alias of the passed object void alias(const simple_ptr_base&); // test whether two pointers point to the same object(known as aliasing the object) // used in the form if(a.aliases(b)) bool aliases(const simple_ptr_base&) const; // find the number of aliases - used when you need to know whether an // object is still referred to from elsewhere (rare!) unsigned alias_count(void) const; // clear the reference to the object, but only delete the object if there are no // other references to that object. Hence, this does not affect other pointers // that are pointing to the same object. void clear(void); // This is just an alias of the clear() function, provided for completeness of // the interface when acting as a replacement for the smart_ptr classes void clear_unique(void); ////////////////////////////////////////////////////////////////////////////// // functions that involve copying // these functions use the copy functor passed as the template parameter C // to copy the object with the right copy semantics. If the copy functor // is no_copy, an exception will be thrown. // make this pointer unique with respect to any other references to the same object // if this pointer is already unique, it does nothing - otherwise it copies the object void make_unique(void) throw(illegal_copy); // make this pointer a unique copy of the parameter // useful for expressions like p1.copy(p2) which makes p1 a pointer to a unique copy of the contents of p2 void copy(const simple_ptr_base&) throw(illegal_copy); ////////////////////////////////////////////////////////////////////////////// // functions that involve casting #ifdef STLPLUS_MEMBER_TEMPLATES // dynamic cast of underlying pointer to a derived/parent template simple_ptr_base dyn_cast(void) const; // static cast of underlying pointer to a derived/parent template simple_ptr_base stat_cast(void) const; // cast of underlying pointer to a base - while keeping the same ref-counted object template simple_ptr_base cast(void) const; #endif ////////////////////////////////////////////////////////////////////////////// protected: T* m_pointer; unsigned* m_count; public: // internal use only - had to make them public because they need to be // accessed by routines that could not be made friends // can't have a handle due to the way the simple pointer stores it's data // in separate counter and pointer objects unsigned* _count(void) const; T* _pointer(void) const; void _make_alias(T* pointer, unsigned* count); private: void increment(void); bool decrement(void); }; //////////////////////////////////////////////////////////////////////////////// // simple_ptr for simple types and classes which have copy constructors template class simple_ptr : public simple_ptr_base > { public: simple_ptr(void) {} explicit simple_ptr(const T& data) : simple_ptr_base >(data) {} explicit simple_ptr(T* data) : simple_ptr_base >(data) {} simple_ptr& operator=(const T& data) {set_value(data); return *this;} simple_ptr& operator=(T* data) {set(data); return *this;} ~simple_ptr(void) {} }; //////////////////////////////////////////////////////////////////////////////// // smart_ptr_clone for polymorphic class hierarchies which have a clone method template class simple_ptr_clone : public simple_ptr_base > { public: simple_ptr_clone(void) {} explicit simple_ptr_clone(const T& data) : simple_ptr_base >(data) {} explicit simple_ptr_clone(T* data) : simple_ptr_base >(data) {} simple_ptr_clone& operator=(const T& data) {set_value(data); return *this;} simple_ptr_clone& operator=(T* data) {set(data); return *this;} ~simple_ptr_clone(void) {} }; //////////////////////////////////////////////////////////////////////////////// // smart_ptr_nocopy for any class that cannot or should not be copied template class simple_ptr_nocopy : public simple_ptr_base > { public: simple_ptr_nocopy(void) {} explicit simple_ptr_nocopy(const T& data) : simple_ptr_base >(data) {} explicit simple_ptr_nocopy(T* data) : simple_ptr_base >(data) {} simple_ptr_nocopy& operator=(const T& data) {set_value(data); return *this;} simple_ptr_nocopy& operator=(T* data) {set(data); return *this;} ~simple_ptr_nocopy(void) {} }; //////////////////////////////////////////////////////////////////////////////// } // end namespace stlplus #include "simple_ptr.tpp" #endif