mbed library sources. Supersedes mbed-src.
Dependents: SPIne CH_Communicatuin_Test CH_Communicatuin_Test2 MCP_SPIne ... more
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platform/NonCopyable.h
- Committer:
- benkatz
- Date:
- 2018-05-02
- Revision:
- 179:97f825502e2a
- Parent:
- 168:9672193075cf
File content as of revision 179:97f825502e2a:
/* Copyright (c) 2017 ARM Limited * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #ifndef MBED_NONCOPYABLE_H_ #define MBED_NONCOPYABLE_H_ namespace mbed { /** * Inheriting from this class autogeneration of copy construction and copy * assignement operations. * * Classes which are not value type should inherit privately from this class * to avoid generation of invalid copy constructor or copy assignement operator * which can lead to unoticeable programming errors. * * As an example consider the following signature: * * @code * class Resource; * * class Foo { * public: * Foo() : _resource(new Resource()) { } * ~Foo() { delete _resource; } * private: * Resource* _resource; * } * * Foo get_foo(); * * Foo foo = get_foo(); * @endcode * * There is a bug in this function, it returns a temporary value which will be * byte copied into foo then destroyed. Unfortunately, internaly the Foo class * manage a pointer to a Resource object. This pointer will be released when the * temporary is destroyed and foo will manage a pointer to an already released * Resource. * * Two issues has to be fixed in the example above: * - Function signature has to be changed to reflect the fact that Foo * instances cannot be copied. In that case accessor should return a * reference to give access to objects already existing and managed. * Generator on the other hand should return a pointer to the created object. * * @code * // return a reference to an already managed Foo instance * Foo& get_foo(); * Foo& foo = get_foo(); * * // create a new Foo instance * Foo* make_foo(); * Foo* m = make_foo(); * @endcode * * - Copy constructor and copy assignement operator has to be made private * in the Foo class. It prevents unwanted copy of Foo objects. This can be * done by declaring copy constructor and copy assignement in the private * section of the Foo class. * * @code * class Foo { * public: * Foo() : _resource(new Resource()) { } * ~Foo() { delete _resource; } * private: * // disallow copy operations * Foo(const Foo&); * Foo& operator=(const Foo&); * // data members * Resource* _resource; * } * @endcode * * Another solution is to inherit privately from the NonCopyable class. * It reduces the boiler plate needed to avoid copy operations but more * importantly it clarifies the programer intent and the object semantic. * * class Foo : private NonCopyable<Foo> { * public: * Foo() : _resource(new Resource()) { } * ~Foo() { delete _resource; } * private: * Resource* _resource; * } * * @tparam T The type that should be made non copyable. It prevent cases where * the empty base optimization cannot be applied and therefore ensure that the * cost of this semantic sugar is null. * * As an example, the empty base optimization is prohibited if one of the empty * base class is also a base type of the first non static data member: * * @code * struct A { }; * struct B : A { * int foo; * }; * // thanks to empty base optimization, sizeof(B) == sizeof(int) * * struct C : A { * B b; * }; * * // empty base optimization cannot be applied here because A from C and A from * // B shall have a different address. In that case, with the alignement * // sizeof(C) == 2* sizeof(int) * @endcode * * The solution to that problem is to templatize the empty class to makes it * unique to the type it is applied to: * * @code * template<typename T> * struct A<T> { }; * struct B : A<B> { * int foo; * }; * struct C : A<C> { * B b; * }; * * // empty base optimization can be applied B and C does not refer to the same * // kind of A. sizeof(C) == sizeof(B) == sizeof(int). * @endcode */ template<typename T> class NonCopyable { protected: /** * Disalow construction of NonCopyable objects from outside of its hierarchy. */ NonCopyable() { } /** * Disalow destruction of NonCopyable objects from outside of its hierarchy. */ ~NonCopyable() { } private: /** * Declare copy constructor as private, any attempt to copy construct * a NonCopyable will fail at compile time. */ NonCopyable(const NonCopyable&); /** * Declare copy assignement operator as private, any attempt to copy assign * a NonCopyable will fail at compile time. */ NonCopyable& operator=(const NonCopyable&); }; } // namespace mbed #endif /* MBED_NONCOPYABLE_H_ */