/* PCSX2 - PS2 Emulator for PCs * Copyright (C) 2002-2010 PCSX2 Dev Team * * PCSX2 is free software: you can redistribute it and/or modify it under the terms * of the GNU Lesser General Public License as published by the Free Software Found- * ation, either version 3 of the License, or (at your option) any later version. * * PCSX2 is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; * without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR * PURPOSE. See the GNU General Public License for more details. * * You should have received a copy of the GNU General Public License along with PCSX2. * If not, see . */ #pragma once // -------------------------------------------------------------------------------------- // ScopedPtr // -------------------------------------------------------------------------------------- template< typename T > class ScopedPtr { DeclareNoncopyableObject(ScopedPtr); protected: T* m_ptr; public: typedef T element_type; wxEXPLICIT ScopedPtr(T * ptr = NULL) { m_ptr = ptr; } ~ScopedPtr() throw() { Delete(); } ScopedPtr& Reassign(T * ptr = NULL) { if ( ptr != m_ptr ) { Delete(); m_ptr = ptr; } return *this; } ScopedPtr& Delete() throw() { // Thread-safe deletion: Set the pointer to NULL first, and then issue // the deletion. This allows pending Application messages that might be // dependent on the current object to nullify their actions. T* deleteme = m_ptr; m_ptr = NULL; delete deleteme; return *this; } // Removes the pointer from scoped management, but does not delete! T *DetachPtr() { T *ptr = m_ptr; m_ptr = NULL; return ptr; } // Returns the managed pointer. Can return NULL as a valid result if the ScopedPtr // has no object in management. T* GetPtr() const { return m_ptr; } void SwapPtr(ScopedPtr& other) { T * const tmp = other.m_ptr; other.m_ptr = m_ptr; m_ptr = tmp; } // ---------------------------------------------------------------------------- // ScopedPtr Operators // ---------------------------------------------------------------------------- // I've decided to use the ATL's approach to pointer validity tests, opposed to // the wx/boost approach (which uses some bizarre member method pointer crap, and can't // allow the T* implicit casting. bool operator!() const throw() { return m_ptr == NULL; } operator T*() const { return m_ptr; } // Equality bool operator==(T* pT) const throw() { return m_ptr == pT; } // Inequality bool operator!=(T* pT) const throw() { return !operator==(pT); } // Convenient assignment operator. ScopedPtr = NULL will issue an automatic deletion // of the managed pointer. ScopedPtr& operator=( T* src ) { return Reassign( src ); } // Dereference operator, returns a handle to the managed pointer. // Generates a debug assertion if the object is NULL! T& operator*() const { pxAssert(m_ptr != NULL); return *m_ptr; } T* operator->() const { pxAssert(m_ptr != NULL); return m_ptr; } }; // -------------------------------------------------------------------------------------- // ScopedArray - same as ScopedPtr but uses delete[], and has operator[] // -------------------------------------------------------------------------------------- template< typename T > class ScopedArray { DeclareNoncopyableObject(ScopedArray); protected: T* m_array; uint m_valid_range; public: typedef T element_type; wxEXPLICIT ScopedArray(T * ptr = NULL) : { m_array = ptr; m_valid_range = 0xffffffff; } wxEXPLICIT ScopedArray( int size ) : m_array( pxAssertDev( size >= 0, "Invalid negative size specified." ) ? new T[size] : NULL ) , m_valid_range( (uint)size ) { } // For breaking the 2gb barrier, lets provision this: wxEXPLICIT ScopedArray( s64 size ) : m_array( pxAssertDev( size >= 0 && (size < UINT_MAX), "Invalid negative size specified to ScopedArray." ) ? new T[size] : NULL ) , m_valid_range( (uint)size ) { } ~ScopedArray() throw() { Delete(); } ScopedArray& Reassign(T * ptr = NULL) { if( ptr != m_array ) { Delete(); m_array = ptr; } return *this; } ScopedArray& Delete() throw() { // Thread-safe deletion: Set the pointer to NULL first, and then issue // the deletion. This allows pending Application messages that might be // dependent on the current object to nullify their actions. T* deleteme = m_array; m_array = NULL; delete[] deleteme; return *this; } // Removes the pointer from scoped management, but does not delete! T *DetachPtr() { T *ptr = m_array; m_array = NULL; return ptr; } // Returns the managed pointer. Can return NULL as a valid result if the ScopedPtr // has no object in management. T* GetPtr() const { return m_array; } void SwapPtr(ScopedArray& other) { T * const tmp = other.m_array; other.m_array = m_array; m_array = tmp; } // ---------------------------------------------------------------------------- // ScopedPtr Operators // ---------------------------------------------------------------------------- // I've decided to use the ATL's approach to pointer validity tests, opposed to // the wx/boost approach (which uses some bizarre member method pointer crap, and can't // allow the T* implicit casting. bool operator!() const throw() { return m_array == NULL; } // Equality bool operator==(T* pT) const throw() { return m_array == pT; } // Inequality bool operator!=(T* pT) const throw() { return !operator==(pT); } // Convenient assignment operator. ScopedPtr = NULL will issue an automatic deletion // of the managed pointer. ScopedArray& operator=( T* src ) { return Reassign( src ); } T& operator[]( uint idx ) const { pxAssertDev( idx < m_valid_range, "Array index out of bounds on ScopedArray." ); return m_array[idx]; } }; // -------------------------------------------------------------------------------------- // pxObjPtr -- fancified version of wxScopedPtr // -------------------------------------------------------------------------------------- // This class is a non-null scoped pointer container. What that means is that the object // always resets itself to a valid "placebo" function rather than NULL, such that methods // can be invoked safely without fear of NULL pointer exceptions. This system is useful // for objects where most or all public methods can fail silently, and still allow program // execution flow to continue. // // It also implements basic scoped pointer behavior: when the pxObjPtr class is deleted, // it will automatically delete the pointer in its posession, if the pointer is valid. // // Notes: // * This class intentionally does not implement the "release" API, because it doesn't // really make sense within the context of a non-nullable pointer specification. // template< typename T, T& DefaultStaticInst > class pxObjPtr { DeclareNoncopyableObject(pxObjPtr); protected: T * m_ptr; public: typedef T element_type; explicit pxObjPtr(T * ptr = &DefaultStaticInst) : m_ptr(ptr) { } bool IsEmpty() const { return m_ptr != &DefaultStaticInst; } ~pxObjPtr() { if( !IsEmpty() ) delete m_ptr; m_ptr = NULL; } // test for pointer validity: defining conversion to unspecified_bool_type // and not more obvious bool to avoid implicit conversions to integer types typedef T *(pxObjPtr::*unspecified_bool_type)() const; operator unspecified_bool_type() const { return ( !IsEmpty() ) ? &ScopedPtr::get : NULL; } void reset(T * ptr = &DefaultStaticInst) { if ( ptr != m_ptr ) { if( !IsEmpty() ) delete m_ptr; m_ptr = ptr; } } T& operator*() const { pxAssert(m_ptr != NULL); return *m_ptr; } T* operator->() const { pxAssert(m_ptr != NULL); return m_ptr; } T* get() const { pxAssert(m_ptr != NULL); return m_ptr; } void swap(pxObjPtr& other) { // Neither pointer in either container should ever be NULL... pxAssert(m_ptr != NULL); pxAssert(other.m_ptr != NULL); T * const tmp = other.m_ptr; other.m_ptr = m_ptr; m_ptr = tmp; } };