src/third_party/llvm-project/clang/test/SemaCXX/cxx2a-destroying-delete.cpp - cobalt - Git at Google

 // RUN: %clang_cc1 -std=c++2a -verify %s

 namespace std {
   using size_t = decltype(sizeof(0));
   enum class align_val_t : size_t;

   struct destroying_delete_t {
     struct __construct { explicit __construct() = default; };
     explicit destroying_delete_t(__construct) {}
   };

   inline constexpr destroying_delete_t destroying_delete(destroying_delete_t::__construct());
 }

 void operator delete(void*, std::destroying_delete_t); // ok, just a placement delete

 struct A;
 void operator delete(A*, std::destroying_delete_t); // expected-error {{first parameter of 'operator delete' must have type 'void *'}}

 struct A {
   void operator delete(A*, std::destroying_delete_t);
   void operator delete(A*, std::destroying_delete_t, std::size_t);
   void operator delete(A*, std::destroying_delete_t, std::align_val_t);
   void operator delete(A*, std::destroying_delete_t, std::size_t, std::align_val_t);
   void operator delete(A*, std::destroying_delete_t, int); // expected-error {{destroying operator delete can have only an optional size and optional alignment parameter}}
   // FIXME: It's probably a language defect that we permit usual operator delete to be variadic.
   void operator delete(A*, std::destroying_delete_t, std::size_t, ...);

   void operator delete(struct X*, std::destroying_delete_t, std::size_t, ...); // expected-error {{first parameter of 'operator delete' must have type 'A *'}}

   void operator delete(void*, std::size_t);
 };

 void delete_A(A *a) { delete a; }

 namespace convert_param {
   struct A {
     void operator delete(
         A*,
         std::destroying_delete_t);
   };
   struct B : private A { using A::operator delete; }; // expected-note 2{{declared private here}}
   struct C : B {};
   void delete_C(C *c) { delete c; } // expected-error {{cannot cast 'convert_param::C' to its private base class 'convert_param::A'}}

   // expected-error@-7 {{cannot cast 'convert_param::D' to its private base class 'convert_param::A'}}
   struct D : B { virtual ~D() {} }; // expected-note {{while checking implicit 'delete this' for virtual destructor}}
 }

 namespace delete_selection {
   struct B {
     void operator delete(void*) = delete;
     void operator delete(B *, std::destroying_delete_t) = delete; // expected-note {{deleted}}
   };
   void delete_B(B *b) { delete b; } // expected-error {{deleted}}

   struct C {
     C();
     void *operator new(std::size_t);
     void operator delete(void*) = delete;
     void operator delete(C *, std::destroying_delete_t) = delete;
   };
   // FIXME: This should be ill-formed, but we incorrectly decide that overload
   // resolution failed (because it selected a deleted function) and thus no
   // 'operator delete' should be called.
   C *new_C() { return new C; }

   struct D {
     void operator delete(D *, std::destroying_delete_t) = delete; // expected-note {{deleted}}
     void operator delete(D *, std::destroying_delete_t, std::align_val_t) = delete;
   };
   void delete_D(D *d) { delete d; } // expected-error {{deleted}}

   struct alignas(__STDCPP_DEFAULT_NEW_ALIGNMENT__ * 2) E {
     void operator delete(E *, std::destroying_delete_t) = delete;
     void operator delete(E *, std::destroying_delete_t, std::align_val_t) = delete; // expected-note {{deleted}}
   };
   void delete_E(E *e) { delete e; } // expected-error {{deleted}}

   struct F {
     void operator delete(F *, std::destroying_delete_t) = delete; // expected-note {{deleted}}
     void operator delete(F *, std::destroying_delete_t, std::size_t) = delete;
   };
   void delete_F(F *f) { delete f; } // expected-error {{deleted}}

   struct G {
     void operator delete(G *, std::destroying_delete_t, std::align_val_t) = delete;
     void operator delete(G *, std::destroying_delete_t, std::size_t) = delete; // expected-note {{deleted}}
   };
   void delete_G(G *g) { delete g; } // expected-error {{deleted}}

   struct H {
     void operator delete(H *, std::destroying_delete_t, std::align_val_t) = delete; // expected-note {{deleted}}
     void operator delete(H *, std::destroying_delete_t, std::size_t, std::align_val_t) = delete;
   };
   void delete_H(H *h) { delete h; } // expected-error {{deleted}}

   struct alignas(__STDCPP_DEFAULT_NEW_ALIGNMENT__ * 2) I {
     void operator delete(I *, std::destroying_delete_t, std::size_t) = delete;
     void operator delete(I *, std::destroying_delete_t, std::size_t, std::align_val_t) = delete; // expected-note {{deleted}}
   };
   void delete_I(I *i) { delete i; } // expected-error {{deleted}}
 }

 namespace first_param_conversion {
   struct A {
     void operator delete(A *, std::destroying_delete_t);
   };
   void f(const volatile A *a) {
     delete a; // ok
   }

   struct B {
     void operator delete(B *, std::destroying_delete_t);
   };
   struct C : B {};
   struct D : B {};
   struct E : C, D {};
   void g(E *e) {
     delete e; // expected-error {{ambiguous conversion from derived class 'first_param_conversion::E' to base class 'first_param_conversion::B':}}
   }
 }
	// RUN: %clang_cc1 -std=c++2a -verify %s

	namespace std {
	using size_t = decltype(sizeof(0));
	enum class align_val_t : size_t;

	struct destroying_delete_t {
	struct __construct { explicit __construct() = default; };
	explicit destroying_delete_t(__construct) {}
	};

	inline constexpr destroying_delete_t destroying_delete(destroying_delete_t::__construct());
	}

	void operator delete(void*, std::destroying_delete_t); // ok, just a placement delete

	struct A;
	void operator delete(A, std::destroying_delete_t); // expected-error {{first parameter of 'operator delete' must have type 'void '}}

	struct A {
	void operator delete(A*, std::destroying_delete_t);
	void operator delete(A*, std::destroying_delete_t, std::size_t);
	void operator delete(A*, std::destroying_delete_t, std::align_val_t);
	void operator delete(A*, std::destroying_delete_t, std::size_t, std::align_val_t);
	void operator delete(A*, std::destroying_delete_t, int); // expected-error {{destroying operator delete can have only an optional size and optional alignment parameter}}
	// FIXME: It's probably a language defect that we permit usual operator delete to be variadic.
	void operator delete(A*, std::destroying_delete_t, std::size_t, ...);

	void operator delete(struct X, std::destroying_delete_t, std::size_t, ...); // expected-error {{first parameter of 'operator delete' must have type 'A '}}

	void operator delete(void*, std::size_t);
	};

	void delete_A(A *a) { delete a; }

	namespace convert_param {
	struct A {
	void operator delete(
	A*,
	std::destroying_delete_t);
	};
	struct B : private A { using A::operator delete; }; // expected-note 2{{declared private here}}
	struct C : B {};
	void delete_C(C *c) { delete c; } // expected-error {{cannot cast 'convert_param::C' to its private base class 'convert_param::A'}}

	// expected-error@-7 {{cannot cast 'convert_param::D' to its private base class 'convert_param::A'}}
	struct D : B { virtual ~D() {} }; // expected-note {{while checking implicit 'delete this' for virtual destructor}}
	}

	namespace delete_selection {
	struct B {
	void operator delete(void*) = delete;
	void operator delete(B *, std::destroying_delete_t) = delete; // expected-note {{deleted}}
	};
	void delete_B(B *b) { delete b; } // expected-error {{deleted}}

	struct C {
	C();
	void *operator new(std::size_t);
	void operator delete(void*) = delete;
	void operator delete(C *, std::destroying_delete_t) = delete;
	};
	// FIXME: This should be ill-formed, but we incorrectly decide that overload
	// resolution failed (because it selected a deleted function) and thus no
	// 'operator delete' should be called.
	C *new_C() { return new C; }

	struct D {
	void operator delete(D *, std::destroying_delete_t) = delete; // expected-note {{deleted}}
	void operator delete(D *, std::destroying_delete_t, std::align_val_t) = delete;
	};
	void delete_D(D *d) { delete d; } // expected-error {{deleted}}

	struct alignas(__STDCPP_DEFAULT_NEW_ALIGNMENT__ * 2) E {
	void operator delete(E *, std::destroying_delete_t) = delete;
	void operator delete(E *, std::destroying_delete_t, std::align_val_t) = delete; // expected-note {{deleted}}
	};
	void delete_E(E *e) { delete e; } // expected-error {{deleted}}

	struct F {
	void operator delete(F *, std::destroying_delete_t) = delete; // expected-note {{deleted}}
	void operator delete(F *, std::destroying_delete_t, std::size_t) = delete;
	};
	void delete_F(F *f) { delete f; } // expected-error {{deleted}}

	struct G {
	void operator delete(G *, std::destroying_delete_t, std::align_val_t) = delete;
	void operator delete(G *, std::destroying_delete_t, std::size_t) = delete; // expected-note {{deleted}}
	};
	void delete_G(G *g) { delete g; } // expected-error {{deleted}}

	struct H {
	void operator delete(H *, std::destroying_delete_t, std::align_val_t) = delete; // expected-note {{deleted}}
	void operator delete(H *, std::destroying_delete_t, std::size_t, std::align_val_t) = delete;
	};
	void delete_H(H *h) { delete h; } // expected-error {{deleted}}

	struct alignas(__STDCPP_DEFAULT_NEW_ALIGNMENT__ * 2) I {
	void operator delete(I *, std::destroying_delete_t, std::size_t) = delete;
	void operator delete(I *, std::destroying_delete_t, std::size_t, std::align_val_t) = delete; // expected-note {{deleted}}
	};
	void delete_I(I *i) { delete i; } // expected-error {{deleted}}
	}

	namespace first_param_conversion {
	struct A {
	void operator delete(A *, std::destroying_delete_t);
	};
	void f(const volatile A *a) {
	delete a; // ok
	}

	struct B {
	void operator delete(B *, std::destroying_delete_t);
	};
	struct C : B {};
	struct D : B {};
	struct E : C, D {};
	void g(E *e) {
	delete e; // expected-error {{ambiguous conversion from derived class 'first_param_conversion::E' to base class 'first_param_conversion::B':}}
	}
	}