test/SemaCXX/member-pointer-ms.cpp - platform/external/clang - Gitiles

 // RUN: %clang_cc1 -std=c++11 -cxx-abi microsoft -fms-compatibility -fsyntax-only -triple=i386-pc-win32 -verify %s
 // RUN: %clang_cc1 -std=c++11 -cxx-abi microsoft -fms-compatibility -fsyntax-only -triple=x86_64-pc-win32 -verify %s
 //
 // This file should also give no diagnostics when run through cl.exe from MSVS
 // 2012, which supports C++11 and static_assert.  It should pass for both 64-bit
 // and 32-bit x86.
 //
 // Test the size of various member pointer combinations:
 // - complete and incomplete
 // - single, multiple, and virtual inheritance (and unspecified for incomplete)
 // - data and function pointers
 // - templated with declared specializations with annotations
 // - template that can be instantiated

 // http://llvm.org/PR12070
 struct Foo {
   typedef int Foo::*FooInt;
   int f;
 };

 enum {
   kSingleDataSize             = 1 * sizeof(int),
   kSingleFunctionSize         = 1 * sizeof(void *),
   kMultipleDataSize           = 1 * sizeof(int),
   kMultipleFunctionSize       = 2 * sizeof(void *),
   kVirtualDataSize            = 2 * sizeof(int),
   kVirtualFunctionSize        = 2 * sizeof(int) + 1 * sizeof(void *),
   // Unspecified is weird, it's 1 more slot than virtual.
   kUnspecifiedDataSize        = kVirtualDataSize + 1 * sizeof(int),
   kUnspecifiedFunctionSize    = kVirtualFunctionSize + 1 * sizeof(void *),
 };

 // incomplete types
 class __single_inheritance IncSingle;
 class __multiple_inheritance IncMultiple;
 class __virtual_inheritance IncVirtual;
 static_assert(sizeof(int IncSingle::*)        == kSingleDataSize, "");
 static_assert(sizeof(int IncMultiple::*)      == kMultipleDataSize, "");
 static_assert(sizeof(int IncVirtual::*)       == kVirtualDataSize, "");
 static_assert(sizeof(void (IncSingle::*)())   == kSingleFunctionSize, "");
 static_assert(sizeof(void (IncMultiple::*)()) == kMultipleFunctionSize, "");
 static_assert(sizeof(void (IncVirtual::*)())  == kVirtualFunctionSize, "");

 // An incomplete type with an unspecified inheritance model seems to take one
 // more slot than virtual.  It's not clear what it's used for yet.
 class IncUnspecified;
 static_assert(sizeof(int IncUnspecified::*) == kUnspecifiedDataSize, "");
 static_assert(sizeof(void (IncUnspecified::*)()) == kUnspecifiedFunctionSize, "");

 // complete types
 struct B1 { };
 struct B2 { };
 struct Single { };
 struct Multiple : B1, B2 { };
 struct Virtual : virtual B1 { };
 static_assert(sizeof(int Single::*)        == kSingleDataSize, "");
 static_assert(sizeof(int Multiple::*)      == kMultipleDataSize, "");
 static_assert(sizeof(int Virtual::*)       == kVirtualDataSize, "");
 static_assert(sizeof(void (Single::*)())   == kSingleFunctionSize, "");
 static_assert(sizeof(void (Multiple::*)()) == kMultipleFunctionSize, "");
 static_assert(sizeof(void (Virtual::*)())  == kVirtualFunctionSize, "");

 // Test both declared and defined templates.
 template <typename T> class X;
 template <> class __single_inheritance   X<IncSingle>;
 template <> class __multiple_inheritance X<IncMultiple>;
 template <> class __virtual_inheritance  X<IncVirtual>;
 // Don't declare X<IncUnspecified>.
 static_assert(sizeof(int X<IncSingle>::*)           == kSingleDataSize, "");
 static_assert(sizeof(int X<IncMultiple>::*)         == kMultipleDataSize, "");
 static_assert(sizeof(int X<IncVirtual>::*)          == kVirtualDataSize, "");
 static_assert(sizeof(int X<IncUnspecified>::*)      == kUnspecifiedDataSize, "");
 static_assert(sizeof(void (X<IncSingle>::*)())      == kSingleFunctionSize, "");
 static_assert(sizeof(void (X<IncMultiple>::*)())    == kMultipleFunctionSize, "");
 static_assert(sizeof(void (X<IncVirtual>::*)())     == kVirtualFunctionSize, "");
 static_assert(sizeof(void (X<IncUnspecified>::*)()) == kUnspecifiedFunctionSize, "");

 template <typename T>
 struct Y : T { };
 static_assert(sizeof(int Y<Single>::*)        == kSingleDataSize, "");
 static_assert(sizeof(int Y<Multiple>::*)      == kMultipleDataSize, "");
 static_assert(sizeof(int Y<Virtual>::*)       == kVirtualDataSize, "");
 static_assert(sizeof(void (Y<Single>::*)())   == kSingleFunctionSize, "");
 static_assert(sizeof(void (Y<Multiple>::*)()) == kMultipleFunctionSize, "");
 static_assert(sizeof(void (Y<Virtual>::*)())  == kVirtualFunctionSize, "");

 struct A { int x; void bar(); };
 struct B : A { virtual void foo(); };
 static_assert(sizeof(int B::*) == kSingleDataSize, "");
 // A non-primary base class uses the multiple inheritance model for member
 // pointers.
 static_assert(sizeof(void (B::*)()) == kMultipleFunctionSize, "");

 struct AA { int x; virtual void foo(); };
 struct BB : AA { void bar(); };
 struct CC : BB { virtual void baz(); };
 static_assert(sizeof(void (CC::*)()) == kSingleFunctionSize, "");

 // We start out unspecified.
 struct ForwardDecl1;
 struct ForwardDecl2;

 // Re-declare to force us to iterate decls when adding attributes.
 struct ForwardDecl1;
 struct ForwardDecl2;

 typedef int ForwardDecl1::*MemPtr1;
 typedef int ForwardDecl2::*MemPtr2;
 MemPtr1 variable_forces_sizing;

 struct ForwardDecl1 : B {
   virtual void foo();
 };
 struct ForwardDecl2 : B {
   virtual void foo();
 };

 static_assert(sizeof(variable_forces_sizing) == kUnspecifiedDataSize, "");
 static_assert(sizeof(MemPtr1) == kUnspecifiedDataSize, "");
 // FIXME: Clang fails this assert because it locks in the inheritance model at
 // the point of the typedef instead of the first usage, while MSVC does not.
 //static_assert(sizeof(MemPtr2) == kSingleDataSize, "");

 struct MemPtrInBody {
   typedef int MemPtrInBody::*MemPtr;
   int a;
   operator MemPtr() const {
     return a ? &MemPtrInBody::a : 0;
   }
 };

 static_assert(sizeof(MemPtrInBody::MemPtr) == kSingleDataSize, "");

 // Passing a member pointer through a template should get the right size.
 template<typename T>
 struct SingleTemplate;
 template<typename T>
 struct SingleTemplate<void (T::*)(void)> {
   static_assert(sizeof(int T::*) == kSingleDataSize, "");
   static_assert(sizeof(void (T::*)()) == kSingleFunctionSize, "");
 };

 template<typename T>
 struct UnspecTemplate;
 template<typename T>
 struct UnspecTemplate<void (T::*)(void)> {
   static_assert(sizeof(int T::*) == kUnspecifiedDataSize, "");
   static_assert(sizeof(void (T::*)()) == kUnspecifiedFunctionSize, "");
 };

 struct NewUnspecified;
 SingleTemplate<void (IncSingle::*)()> tmpl_single;
 UnspecTemplate<void (NewUnspecified::*)()> tmpl_unspec;

 struct NewUnspecified { };

 static_assert(sizeof(void (NewUnspecified::*)()) == kUnspecifiedFunctionSize, "");

 template <typename T>
 struct MemPtrInTemplate {
   // We can't require that the template arg be complete until we're
   // instantiated.
   int T::*data_ptr;
   void (T::*func_ptr)();
 };

 int Virtual::*CastTest = reinterpret_cast<int Virtual::*>(&AA::x);
   // expected-error@-1 {{cannot reinterpret_cast from member pointer type}}
	// RUN: %clang_cc1 -std=c++11 -cxx-abi microsoft -fms-compatibility -fsyntax-only -triple=i386-pc-win32 -verify %s
	// RUN: %clang_cc1 -std=c++11 -cxx-abi microsoft -fms-compatibility -fsyntax-only -triple=x86_64-pc-win32 -verify %s
	//
	// This file should also give no diagnostics when run through cl.exe from MSVS
	// 2012, which supports C++11 and static_assert. It should pass for both 64-bit
	// and 32-bit x86.
	//
	// Test the size of various member pointer combinations:
	// - complete and incomplete
	// - single, multiple, and virtual inheritance (and unspecified for incomplete)
	// - data and function pointers
	// - templated with declared specializations with annotations
	// - template that can be instantiated

	// http://llvm.org/PR12070
	struct Foo {
	typedef int Foo::*FooInt;
	int f;
	};

	enum {
	kSingleDataSize = 1 * sizeof(int),
	kSingleFunctionSize = 1 * sizeof(void *),
	kMultipleDataSize = 1 * sizeof(int),
	kMultipleFunctionSize = 2 * sizeof(void *),
	kVirtualDataSize = 2 * sizeof(int),
	kVirtualFunctionSize = 2 * sizeof(int) + 1 * sizeof(void *),
	// Unspecified is weird, it's 1 more slot than virtual.
	kUnspecifiedDataSize = kVirtualDataSize + 1 * sizeof(int),
	kUnspecifiedFunctionSize = kVirtualFunctionSize + 1 * sizeof(void *),
	};

	// incomplete types
	class __single_inheritance IncSingle;
	class __multiple_inheritance IncMultiple;
	class __virtual_inheritance IncVirtual;
	static_assert(sizeof(int IncSingle::*) == kSingleDataSize, "");
	static_assert(sizeof(int IncMultiple::*) == kMultipleDataSize, "");
	static_assert(sizeof(int IncVirtual::*) == kVirtualDataSize, "");
	static_assert(sizeof(void (IncSingle::*)()) == kSingleFunctionSize, "");
	static_assert(sizeof(void (IncMultiple::*)()) == kMultipleFunctionSize, "");
	static_assert(sizeof(void (IncVirtual::*)()) == kVirtualFunctionSize, "");

	// An incomplete type with an unspecified inheritance model seems to take one
	// more slot than virtual. It's not clear what it's used for yet.
	class IncUnspecified;
	static_assert(sizeof(int IncUnspecified::*) == kUnspecifiedDataSize, "");
	static_assert(sizeof(void (IncUnspecified::*)()) == kUnspecifiedFunctionSize, "");

	// complete types
	struct B1 { };
	struct B2 { };
	struct Single { };
	struct Multiple : B1, B2 { };
	struct Virtual : virtual B1 { };
	static_assert(sizeof(int Single::*) == kSingleDataSize, "");
	static_assert(sizeof(int Multiple::*) == kMultipleDataSize, "");
	static_assert(sizeof(int Virtual::*) == kVirtualDataSize, "");
	static_assert(sizeof(void (Single::*)()) == kSingleFunctionSize, "");
	static_assert(sizeof(void (Multiple::*)()) == kMultipleFunctionSize, "");
	static_assert(sizeof(void (Virtual::*)()) == kVirtualFunctionSize, "");

	// Test both declared and defined templates.
	template <typename T> class X;
	template <> class __single_inheritance X<IncSingle>;
	template <> class __multiple_inheritance X<IncMultiple>;
	template <> class __virtual_inheritance X<IncVirtual>;
	// Don't declare X<IncUnspecified>.
	static_assert(sizeof(int X<IncSingle>::*) == kSingleDataSize, "");
	static_assert(sizeof(int X<IncMultiple>::*) == kMultipleDataSize, "");
	static_assert(sizeof(int X<IncVirtual>::*) == kVirtualDataSize, "");
	static_assert(sizeof(int X<IncUnspecified>::*) == kUnspecifiedDataSize, "");
	static_assert(sizeof(void (X<IncSingle>::*)()) == kSingleFunctionSize, "");
	static_assert(sizeof(void (X<IncMultiple>::*)()) == kMultipleFunctionSize, "");
	static_assert(sizeof(void (X<IncVirtual>::*)()) == kVirtualFunctionSize, "");
	static_assert(sizeof(void (X<IncUnspecified>::*)()) == kUnspecifiedFunctionSize, "");

	template <typename T>
	struct Y : T { };
	static_assert(sizeof(int Y<Single>::*) == kSingleDataSize, "");
	static_assert(sizeof(int Y<Multiple>::*) == kMultipleDataSize, "");
	static_assert(sizeof(int Y<Virtual>::*) == kVirtualDataSize, "");
	static_assert(sizeof(void (Y<Single>::*)()) == kSingleFunctionSize, "");
	static_assert(sizeof(void (Y<Multiple>::*)()) == kMultipleFunctionSize, "");
	static_assert(sizeof(void (Y<Virtual>::*)()) == kVirtualFunctionSize, "");

	struct A { int x; void bar(); };
	struct B : A { virtual void foo(); };
	static_assert(sizeof(int B::*) == kSingleDataSize, "");
	// A non-primary base class uses the multiple inheritance model for member
	// pointers.
	static_assert(sizeof(void (B::*)()) == kMultipleFunctionSize, "");

	struct AA { int x; virtual void foo(); };
	struct BB : AA { void bar(); };
	struct CC : BB { virtual void baz(); };
	static_assert(sizeof(void (CC::*)()) == kSingleFunctionSize, "");

	// We start out unspecified.
	struct ForwardDecl1;
	struct ForwardDecl2;

	// Re-declare to force us to iterate decls when adding attributes.
	struct ForwardDecl1;
	struct ForwardDecl2;

	typedef int ForwardDecl1::*MemPtr1;
	typedef int ForwardDecl2::*MemPtr2;
	MemPtr1 variable_forces_sizing;

	struct ForwardDecl1 : B {
	virtual void foo();
	};
	struct ForwardDecl2 : B {
	virtual void foo();
	};

	static_assert(sizeof(variable_forces_sizing) == kUnspecifiedDataSize, "");
	static_assert(sizeof(MemPtr1) == kUnspecifiedDataSize, "");
	// FIXME: Clang fails this assert because it locks in the inheritance model at
	// the point of the typedef instead of the first usage, while MSVC does not.
	//static_assert(sizeof(MemPtr2) == kSingleDataSize, "");

	struct MemPtrInBody {
	typedef int MemPtrInBody::*MemPtr;
	int a;
	operator MemPtr() const {
	return a ? &MemPtrInBody::a : 0;
	}
	};

	static_assert(sizeof(MemPtrInBody::MemPtr) == kSingleDataSize, "");

	// Passing a member pointer through a template should get the right size.
	template<typename T>
	struct SingleTemplate;
	template<typename T>
	struct SingleTemplate<void (T::*)(void)> {
	static_assert(sizeof(int T::*) == kSingleDataSize, "");
	static_assert(sizeof(void (T::*)()) == kSingleFunctionSize, "");
	};

	template<typename T>
	struct UnspecTemplate;
	template<typename T>
	struct UnspecTemplate<void (T::*)(void)> {
	static_assert(sizeof(int T::*) == kUnspecifiedDataSize, "");
	static_assert(sizeof(void (T::*)()) == kUnspecifiedFunctionSize, "");
	};

	struct NewUnspecified;
	SingleTemplate<void (IncSingle::*)()> tmpl_single;
	UnspecTemplate<void (NewUnspecified::*)()> tmpl_unspec;

	struct NewUnspecified { };

	static_assert(sizeof(void (NewUnspecified::*)()) == kUnspecifiedFunctionSize, "");

	template <typename T>
	struct MemPtrInTemplate {
	// We can't require that the template arg be complete until we're
	// instantiated.
	int T::*data_ptr;
	void (T::*func_ptr)();
	};

	int Virtual::CastTest = reinterpret_cast<int Virtual::>(&AA::x);
	// expected-error@-1 {{cannot reinterpret_cast from member pointer type}}