/* * Carla misc utils imported from Juce source code * Copyright (C) 2004-11 Raw Material Software Ltd. * Copyright (C) 2013 Filipe Coelho * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License as * published by the Free Software Foundation; either version 2 of * the License, or any later version. * * This program 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. * * For a full copy of the GNU General Public License see the GPL.txt file */ #ifndef __CARLA_JUCE_UTILS_HPP__ #define __CARLA_JUCE_UTILS_HPP__ #include "CarlaUtils.hpp" #include #define CARLA_DECLARE_NON_COPYABLE(className) \ private: \ className (const className&); \ className& operator= (const className&); /** This is a shorthand way of writing both a CARLA_DECLARE_NON_COPYABLE and CARLA_LEAK_DETECTOR macro for a class. */ #define CARLA_DECLARE_NON_COPYABLE_WITH_LEAK_DETECTOR(className) \ CARLA_DECLARE_NON_COPYABLE(className) \ CARLA_LEAK_DETECTOR(className) /** This macro can be added to class definitions to disable the use of new/delete to allocate the object on the heap, forcing it to only be used as a stack or member variable. */ #define CARLA_PREVENT_HEAP_ALLOCATION \ private: \ static void* operator new (size_t); \ static void operator delete (void*); /** A good old-fashioned C macro concatenation helper. This combines two items (which may themselves be macros) into a single string, avoiding the pitfalls of the ## macro operator. */ #define CARLA_JOIN_MACRO_HELPER(a, b) a ## b #define CARLA_JOIN_MACRO(item1, item2) CARLA_JOIN_MACRO_HELPER (item1, item2) //============================================================================== /** Embedding an instance of this class inside another class can be used as a low-overhead way of detecting leaked instances. This class keeps an internal static count of the number of instances that are active, so that when the app is shutdown and the static destructors are called, it can check whether there are any left-over instances that may have been leaked. To use it, use the CARLA_LEAK_DETECTOR macro as a simple way to put one in your class declaration. Have a look through the juce codebase for examples, it's used in most of the classes. */ template class LeakedObjectDetector { public: //============================================================================== LeakedObjectDetector() { ++(getCounter().numObjects); } LeakedObjectDetector(const LeakedObjectDetector&) { ++(getCounter().numObjects); } ~LeakedObjectDetector() { if (--(getCounter().numObjects) < 0) { carla_stderr("*** Dangling pointer deletion! Class: '%s'", getLeakedObjectClassName()); /** If you hit this, then you've managed to delete more instances of this class than you've created.. That indicates that you're deleting some dangling pointers. Note that although this assertion will have been triggered during a destructor, it might not be this particular deletion that's at fault - the incorrect one may have happened at an earlier point in the program, and simply not been detected until now. Most errors like this are caused by using old-fashioned, non-RAII techniques for your object management. Tut, tut. Always, always use ScopedPointers, OwnedArrays, ReferenceCountedObjects, etc, and avoid the 'delete' operator at all costs! */ assert(false); } } private: //============================================================================== class LeakCounter { public: LeakCounter() { numObjects = 0; } ~LeakCounter() { if (numObjects > 0) { carla_stderr("*** Leaked objects detected: %i instance(s) of class '%s'", numObjects, getLeakedObjectClassName()); /** If you hit this, then you've leaked one or more objects of the type specified by the 'OwnerClass' template parameter - the name should have been printed by the line above. If you're leaking, it's probably because you're using old-fashioned, non-RAII techniques for your object management. Tut, tut. Always, always use ScopedPointers, OwnedArrays, ReferenceCountedObjects, etc, and avoid the 'delete' operator at all costs! */ assert(false); } } int numObjects; }; static const char* getLeakedObjectClassName() { return OwnerClass::getLeakedObjectClassName(); } static LeakCounter& getCounter() { static LeakCounter counter; return counter; } }; #define CARLA_LEAK_DETECTOR(OwnerClass) \ friend class LeakedObjectDetector; \ static const char* getLeakedObjectClassName() { return #OwnerClass; } \ LeakedObjectDetector CARLA_JOIN_MACRO (leakDetector, __LINE__); //============================================================================== /** This class holds a pointer which is automatically deleted when this object goes out of scope. Once a pointer has been passed to a ScopedPointer, it will make sure that the pointer gets deleted when the ScopedPointer is deleted. Using the ScopedPointer on the stack or as member variables is a good way to use RAII to avoid accidentally leaking dynamically created objects. A ScopedPointer can be used in pretty much the same way that you'd use a normal pointer to an object. If you use the assignment operator to assign a different object to a ScopedPointer, the old one will be automatically deleted. Important note: The class is designed to hold a pointer to an object, NOT to an array! It calls delete on its payload, not delete[], so do not give it an array to hold! For that kind of purpose, you should be using HeapBlock or Array instead. A const ScopedPointer is guaranteed not to lose ownership of its object or change the object to which it points during its lifetime. This means that making a copy of a const ScopedPointer is impossible, as that would involve the new copy taking ownership from the old one. If you need to get a pointer out of a ScopedPointer without it being deleted, you can use the release() method. Something to note is the main difference between this class and the std::auto_ptr class, which is that ScopedPointer provides a cast-to-object operator, wheras std::auto_ptr requires that you always call get() to retrieve the pointer. The advantages of providing the cast is that you don't need to call get(), so can use the ScopedPointer in pretty much exactly the same way as a raw pointer. The disadvantage is that the compiler is free to use the cast in unexpected and sometimes dangerous ways - in particular, it becomes difficult to return a ScopedPointer as the result of a function. To avoid this causing errors, ScopedPointer contains an overloaded constructor that should cause a syntax error in these circumstances, but it does mean that instead of returning a ScopedPointer from a function, you'd need to return a raw pointer (or use a std::auto_ptr instead). */ template class ScopedPointer { public: //============================================================================== /** Creates a ScopedPointer containing a null pointer. */ ScopedPointer() : object(nullptr) { } /** Creates a ScopedPointer that owns the specified object. */ ScopedPointer(ObjectType* const objectToTakePossessionOf) : object(objectToTakePossessionOf) { } /** Creates a ScopedPointer that takes its pointer from another ScopedPointer. Because a pointer can only belong to one ScopedPointer, this transfers the pointer from the other object to this one, and the other object is reset to be a null pointer. */ ScopedPointer(ScopedPointer& objectToTransferFrom) : object(objectToTransferFrom.object) { objectToTransferFrom.object = nullptr; } /** Destructor. This will delete the object that this ScopedPointer currently refers to. */ ~ScopedPointer() { delete object; } /** Changes this ScopedPointer to point to a new object. Because a pointer can only belong to one ScopedPointer, this transfers the pointer from the other object to this one, and the other object is reset to be a null pointer. If this ScopedPointer already points to an object, that object will first be deleted. */ ScopedPointer& operator=(ScopedPointer& objectToTransferFrom) { if (this != objectToTransferFrom.getAddress()) { // Two ScopedPointers should never be able to refer to the same object - if // this happens, you must have done something dodgy! assert(object == nullptr || object != objectToTransferFrom.object); ObjectType* const oldObject = object; object = objectToTransferFrom.object; objectToTransferFrom.object = nullptr; delete oldObject; } return *this; } /** Changes this ScopedPointer to point to a new object. If this ScopedPointer already points to an object, that object will first be deleted. The pointer that you pass in may be a nullptr. */ ScopedPointer& operator=(ObjectType* const newObjectToTakePossessionOf) { if (object != newObjectToTakePossessionOf) { ObjectType* const oldObject = object; object = newObjectToTakePossessionOf; delete oldObject; } return *this; } //============================================================================== /** Returns the object that this ScopedPointer refers to. */ operator ObjectType*() const { return object; } /** Returns the object that this ScopedPointer refers to. */ ObjectType* get() const { return object; } /** Returns the object that this ScopedPointer refers to. */ ObjectType& operator*() const { return *object; } /** Lets you access methods and properties of the object that this ScopedPointer refers to. */ ObjectType* operator->() const { return object; } //============================================================================== /** Removes the current object from this ScopedPointer without deleting it. This will return the current object, and set the ScopedPointer to a null pointer. */ ObjectType* release() { ObjectType* const o = object; object = nullptr; return o; } //============================================================================== /** Swaps this object with that of another ScopedPointer. The two objects simply exchange their pointers. */ void swapWith(ScopedPointer& other) { // Two ScopedPointers should never be able to refer to the same object - if // this happens, you must have done something dodgy! assert(object != other.object || this == other.getAddress()); std::swap(object, other.object); } private: //============================================================================== ObjectType* object; // (Required as an alternative to the overloaded & operator). const ScopedPointer* getAddress() const { return this; } #if ! defined(CARLA_CC_MSVC) // (MSVC can't deal with multiple copy constructors) /* These are private to stop people accidentally copying a const ScopedPointer (the compiler would let you do so by implicitly casting the source to its raw object pointer). A side effect of this is that you may hit a puzzling compiler error when you write something like this: ScopedPointer m = new MyClass(); // Compile error: copy constructor is private. Even though the compiler would normally ignore the assignment here, it can't do so when the copy constructor is private. It's very easy to fix though - just write it like this: ScopedPointer m (new MyClass()); // Compiles OK It's good practice to always use the latter form when writing your object declarations anyway, rather than writing them as assignments and assuming (or hoping) that the compiler will be smart enough to replace your construction + assignment with a single constructor. */ ScopedPointer(const ScopedPointer&); ScopedPointer& operator=(const ScopedPointer&); #endif }; //============================================================================== /** Compares a ScopedPointer with another pointer. This can be handy for checking whether this is a null pointer. */ template bool operator==(const ScopedPointer& pointer1, ObjectType* const pointer2) noexcept { return static_cast(pointer1) == pointer2; } /** Compares a ScopedPointer with another pointer. This can be handy for checking whether this is a null pointer. */ template bool operator!=(const ScopedPointer& pointer1, ObjectType* const pointer2) noexcept { return static_cast(pointer1) != pointer2; } #endif // __CARLA_JUCE_UTILS_HPP__