/** @file * IPRT - C++ Utilities (useful templates, defines and such). */ /* * Copyright (C) 2006-2007 Sun Microsystems, Inc. * * This file is part of VirtualBox Open Source Edition (OSE), as * available from http://www.virtualbox.org. This file is free software; * you can redistribute it and/or modify it under the terms of the GNU * General Public License (GPL) as published by the Free Software * Foundation, in version 2 as it comes in the "COPYING" file of the * VirtualBox OSE distribution. VirtualBox OSE is distributed in the * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind. * * The contents of this file may alternatively be used under the terms * of the Common Development and Distribution License Version 1.0 * (CDDL) only, as it comes in the "COPYING.CDDL" file of the * VirtualBox OSE distribution, in which case the provisions of the * CDDL are applicable instead of those of the GPL. * * You may elect to license modified versions of this file under the * terms and conditions of either the GPL or the CDDL or both. * * Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa * Clara, CA 95054 USA or visit http://www.sun.com if you need * additional information or have any questions. */ #ifndef ___iprt_cpputils_h #define ___iprt_cpputils_h #include #include /** @defgroup grp_rt_cpputils C++ Utilities * @ingroup grp_rt * @{ */ /** * Shortcut to |const_cast()| that automatically derives the correct * type (class) for the const_cast template's argument from its own argument. * Can be used to temporarily cancel the |const| modifier on the left-hand side * of assignment expressions, like this: * @code * const Class that; * ... * unconst (that) = some_value; * @endcode */ template inline C &unconst (const C &that) { return const_cast (that); } /** * Shortcut to |const_cast()| that automatically derives the correct * type (class) for the const_cast template's argument from its own argument. * Can be used to temporarily cancel the |const| modifier on the left-hand side * of assignment expressions, like this: * @code * const Class *that; * ... * unconst (that) = some_value; * @endcode */ template inline C *unconst (const C *that) { return const_cast (that); } /** * Extensions to the std namespace. */ namespace stdx { /* forward */ template class auto_ref_ptr; /** * Base class for objects willing to support smart reference counting using * the auto_ref_ptr template. * * When a class wants to be used with the auto_ref_ptr template it simply * declares the auto_ref class among its public base classes -- there is no * need to implement any additional methods. */ class auto_ref { protected: auto_ref() : mRefs (0) {} /** Increases the reference counter and returns it */ size_t ref() { return ++ mRefs; } /** Decreases the reference counter and returns it */ size_t unref() { Assert (mRefs > 0); return -- mRefs; } private: size_t mRefs; template friend class auto_ref_ptr; }; /** * The auto_ref_ptr template manages pointers to objects that support * reference counting by implementing auto_ref or a similar interface. * * Pointer management includes the following key points: * * 1) Automatic increment of the object's reference counter when the given * auto_ref_ptr instance starts managing a pointer to this object. * * 2) Automatic decrement of the reference counter when the given * auto_ref_ptr instance is destroyed, or before it is assigned a pointer * to a new object. * * 3) Automatic deletion of the managed object whenever its reference * counter reaches zero after a decrement. * * 4) Providing the dereference operator-> that gives direct access to the * managed pointer. * * The object class to manage must provide ref() and unref() methods that have * the same syntax and semantics as defined in the auto_ref class. * * @param C Class to manage. */ template class auto_ref_ptr { public: /** * Creates a null instance that does not manage anything. */ auto_ref_ptr() : m (NULL) {} /** * Creates an instance that starts managing the given pointer. The * reference counter of the object pointed to by @a a is incremented by * one. * * @param a Pointer to manage. */ auto_ref_ptr (C* a) : m (a) { if (m) m->ref(); } /** * Creates an instance that starts managing a pointer managed by the given * instance. The reference counter of the object managed by @a that is * incremented by one. * * @param that Instance to take a pointer to manage from. */ auto_ref_ptr (const auto_ref_ptr &that) : m (that.m) { if (m) m->ref(); } ~auto_ref_ptr() { do_unref(); } /** * Assigns the given pointer to this instance and starts managing it. The * reference counter of the object pointed to by @a a is incremented by * one. The reference counter of the object previously managed by this * instance is decremented by one. * * @param a Pointer to assign. */ auto_ref_ptr &operator= (C *a) { do_reref (a); return *this; } /** * Assigns a pointer managed by the given instance to this instance and * starts managing it. The reference counter of the object managed by @a * that is incremented by one. The reference counter of the object * previously managed by this instance is decremented by one. * * @param that Instance which pointer to reference. */ auto_ref_ptr &operator= (const auto_ref_ptr &that) { do_reref (that.m); return *this; } /** * Returns @c true if this instance is @c null and false otherwise. */ bool is_null() const { return m == NULL; } /** * Dereferences the instance by returning the managed pointer. * Asserts that the managed pointer is not @c NULL. */ C *operator-> () const { AssertMsg (m, ("Managed pointer is NULL!\n")); return m; } /** * Returns the managed pointer or @c NULL if this instance is @c null. */ C *raw() const { return m; } /** * Compares this auto_ref_ptr instance with another instance and returns * @c true if both instances manage the same or @c NULL pointer. * * Note that this method compares pointer values only, it doesn't try to * compare objects themselves. Doing otherwise would a) break the common * 'pointer to something' comparison semantics auto_ref_ptr tries to * follow and b) require to define the comparison operator in the managed * class which is not always possible. You may analyze pointed objects * yourself if you need more precise comparison. * * @param that Instance to compare this instance with. */ bool operator== (const auto_ref_ptr &that) const { return m == that.m; } protected: void do_reref (C *a) { /* be aware of self assignment */ if (a) a->ref(); if (m) { size_t refs = m->unref(); if (refs == 0) { refs = 1; /* stabilize */ delete m; } } m = a; } void do_unref() { do_reref (NULL); } C *m; }; /** * The exception_trap_base class is an abstract base class for all * exception_trap template instantiations. * * Pointer variables of this class are used to store a pointer any object of * any class instantiated from the exception_trap template, or in other words * to store a full copy of any exception wrapped into the exception_trap instance * allocated on the heap. * * See the exception_trap template for more info. */ class exception_trap_base { public: virtual void rethrow() = 0; virtual ~exception_trap_base() {} }; /** * The exception_trap template acts like a wrapper for the given exception * class that stores a full copy of the exception and therefore allows to * rethrow it preserving the actual type information about the exception * class. * * This functionality is useful in situations where it is necessary to catch a * (known) number of exception classes and pass the caught exception instance * to an upper level using a regular variable (rather than the exception * unwinding mechanism itself) *and* preserve all information about the type * (class) of the caight exception so that it may be rethrown on the upper * level unchanged. * * Usage pattern: * @code using namespace std; using namespace stdx; auto_ptr trapped; int callback(); int safe_callback() { try { // callback may throw a set of exceptions but we don't want it to start // unwinding the stack right now return callback(); } catch (const MyException &err) { trapped = new_exception_trap (err); } catch (const MyException2 &err) { trapped = new_exception_trap (err); } catch (...) { trapped = new_exception_trap (logic_error()); } return -1; } void bar() { // call a funciton from some C library that supports callbacks but knows // nothing about exceptions so throwing one from a callback will leave // the library in an undetermined state do_something_with_callback (safe_callback()); // check if we have got an exeption from callback() and rethrow it now // when we are not in the C library any more if (trapped.get() != NULL) trapped->rethrow(); } * @endcode * * @param T Exception class to wrap. */ template class exception_trap : public exception_trap_base { public: exception_trap (const T &aTrapped) : trapped (aTrapped) {} void rethrow() { throw trapped; } T trapped; }; /** * Convenience function that allocates a new exception_trap instance on the * heap by automatically deducing the exception_trap template argument from * the type of the exception passed in @a aTrapped. * * The following two lines of code inside the catch block are equivalent: * * @code using namespace std; using namespace stdx; catch (const MyException &err) { auto_ptr t1 = new exception_trap (err); auto_ptr t2 = new_exception_trap (err); } * @endcode * * @param aTrapped Exception to put to the allocated trap. * * @return Allocated exception_trap object. */ template static exception_trap * new_exception_trap (const T &aTrapped) { return new exception_trap (aTrapped); } /** * Enhancement of std::auto_ptr @ intended to take pointers to char * buffers allocated using new[]. * * This differs from std::auto_ptr @ so that it overloads some methods to * uses delete[] instead of delete to delete the owned data in order to * conform to the C++ standard (and avoid valgrind complaints). * * Note that you should not use instances of this class where pointers or * references to objects of std::auto_ptr @ are expeced. Despite the fact * the classes are related, the base is not polymorphic (in particular, * neither the destructor nor the reset() method are virtual). It means that when * acessing instances of this class through the base pointer, overloaded * methods won't be called. */ class char_auto_ptr : public std::auto_ptr { public: explicit char_auto_ptr (char *a = 0) throw() : std::auto_ptr (a) {} /* Note: we use unconst brute force below because the non-const version * of the copy constructor won't accept temporary const objects * (e.g. function return values) in GCC. std::auto_ptr has the same * "problem" but it seems overcome it using #pragma GCC system_header * which doesn't work here. */ char_auto_ptr (const char_auto_ptr &that) throw() : std::auto_ptr (unconst (that).release()) {} ~char_auto_ptr() { delete[] (release()); } char_auto_ptr &operator= (char_auto_ptr &that) throw() { std::auto_ptr ::operator= (that); return *this; } void reset (char *a) throw() { if (a != get()) { delete[] (release()); std::auto_ptr ::reset (a); } } }; /** * A simple class used to prevent copying and assignment. Inherit from this * class in order to prevent automatic generation of the copy constructor * and assignment operator in your class. */ class non_copyable { protected: non_copyable() {} ~non_copyable() {} private: non_copyable(non_copyable const&); non_copyable const &operator=(non_copyable const&); }; } /* namespace stdx */ /** @} */ #endif