test/CXX/drs/dr20xx.cpp - clang - Git at Google

 // RUN: %clang_cc1 -std=c++98 -triple x86_64-unknown-unknown %s -verify -fexceptions -fcxx-exceptions -pedantic-errors \
 // RUN:            -Wno-variadic-macros -Wno-c11-extensions
 // RUN: %clang_cc1 -std=c++11 -triple x86_64-unknown-unknown %s -verify -fexceptions -fcxx-exceptions -pedantic-errors
 // RUN: %clang_cc1 -std=c++14 -triple x86_64-unknown-unknown %s -verify -fexceptions -fcxx-exceptions -pedantic-errors
 // RUN: %clang_cc1 -std=c++1z -triple x86_64-unknown-unknown %s -verify -fexceptions -fcxx-exceptions -pedantic-errors

 #if __cplusplus < 201103L
 #define static_assert(...) _Static_assert(__VA_ARGS__)
 #endif

 namespace dr2083 { // dr2083: partial
 #if __cplusplus >= 201103L
   void non_const_mem_ptr() {
     struct A {
       int x;
       int y;
     };
     constexpr A a = {1, 2};
     struct B {
       int A::*p;
       constexpr int g() const {
         // OK, not an odr-use of 'a'.
         return a.*p;
       };
     };
     static_assert(B{&A::x}.g() == 1, "");
     static_assert(B{&A::y}.g() == 2, "");
   }
 #endif

   const int a = 1;
   int b;
   // Note, references only get special odr-use / constant initializxer
   // treatment in C++11 onwards. We continue to apply that even after DR2083.
   void ref_to_non_const() {
     int c;
     const int &ra = a; // expected-note 0-1{{here}}
     int &rb = b; // expected-note 0-1{{here}}
     int &rc = c; // expected-note {{here}}
     struct A {
       int f() {
         int a = ra;
         int b = rb;
 #if __cplusplus < 201103L
         // expected-error@-3 {{in enclosing function}}
         // expected-error@-3 {{in enclosing function}}
 #endif
         int c = rc; // expected-error {{in enclosing function}}
         return a + b + c;
       }
     };
   }

 #if __cplusplus >= 201103L
   struct NoMut1 { int a, b; };
   struct NoMut2 { NoMut1 m; };
   struct NoMut3 : NoMut1 {
     constexpr NoMut3(int a, int b) : NoMut1{a, b} {}
   };
   struct Mut1 {
     int a;
     mutable int b;
   };
   struct Mut2 { Mut1 m; };
   struct Mut3 : Mut1 {
     constexpr Mut3(int a, int b) : Mut1{a, b} {}
   };
   void mutable_subobjects() {
     constexpr NoMut1 nm1 = {1, 2};
     constexpr NoMut2 nm2 = {1, 2};
     constexpr NoMut3 nm3 = {1, 2};
     constexpr Mut1 m1 = {1, 2}; // expected-note {{declared here}}
     constexpr Mut2 m2 = {1, 2}; // expected-note {{declared here}}
     constexpr Mut3 m3 = {1, 2}; // expected-note {{declared here}}
     struct A {
       void f() {
         static_assert(nm1.a == 1, "");
         static_assert(nm2.m.a == 1, "");
         static_assert(nm3.a == 1, "");
         // Can't even access a non-mutable member of a variable containing mutable fields.
         static_assert(m1.a == 1, ""); // expected-error {{enclosing function}}
         static_assert(m2.m.a == 1, ""); // expected-error {{enclosing function}}
         static_assert(m3.a == 1, ""); // expected-error {{enclosing function}}
       }
     };
   }
 #endif

   void ellipsis() {
     void ellipsis(...);
     struct A {};
     const int n = 0;
 #if __cplusplus >= 201103L
     constexpr
 #endif
       A a = {}; // expected-note {{here}}
     struct B {
       void f() {
         ellipsis(n);
         // Even though this is technically modelled as an lvalue-to-rvalue
         // conversion, it calls a constructor and binds 'a' to a reference, so
         // it results in an odr-use.
         ellipsis(a); // expected-error {{enclosing function}}
       }
     };
   }

 #if __cplusplus >= 201103L
   void volatile_lval() {
     struct A { int n; };
     constexpr A a = {0}; // expected-note {{here}}
     struct B {
       void f() {
         // An lvalue-to-rvalue conversion of a volatile lvalue always results
         // in odr-use.
         int A::*p = &A::n;
         int x = a.*p;
         volatile int A::*q = p;
         int y = a.*q; // expected-error {{enclosing function}}
       }
     };
   }
 #endif

   void discarded_lval() {
     struct A { int x; mutable int y; volatile int z; };
     A a; // expected-note 1+{{here}}
     int &r = a.x; // expected-note {{here}}
     struct B {
       void f() {
         a.x; // expected-warning {{unused}}
         a.*&A::x; // expected-warning {{unused}}
         true ? a.x : a.y; // expected-warning {{unused}}
         (void)a.x;
         a.x, discarded_lval(); // expected-warning {{unused}}
 #if 1 // FIXME: These errors are all incorrect; the above code is valid.
       // expected-error@-6 {{enclosing function}}
       // expected-error@-6 {{enclosing function}}
       // expected-error@-6 2{{enclosing function}}
       // expected-error@-6 {{enclosing function}}
       // expected-error@-6 {{enclosing function}}
 #endif

         // 'volatile' qualifier triggers an lvalue-to-rvalue conversion.
         a.z; // expected-error {{enclosing function}}
 #if __cplusplus < 201103L
         // expected-warning@-2 {{assign into a variable}}
 #endif

         // References always get "loaded" to determine what they reference,
         // even if the result is discarded.
         r; // expected-error {{enclosing function}} expected-warning {{unused}}
       }
     };
   }

   namespace dr_example_1 {
     extern int globx;
     int main() {
       const int &x = globx;
       struct A {
 #if __cplusplus < 201103L
         // expected-error@+2 {{enclosing function}} expected-note@-3 {{here}}
 #endif
         const int *foo() { return &x; }
       } a;
       return *a.foo();
     }
   }

 #if __cplusplus >= 201103L
   namespace dr_example_2 {
     struct A {
       int q;
       constexpr A(int q) : q(q) {}
       constexpr A(const A &a) : q(a.q * 2) {} // (note, not called)
     };

     int main(void) {
       constexpr A a(42);
       constexpr int aq = a.q;
       struct Q {
         int foo() { return a.q; }
       } q;
       return q.foo();
     }

     // Checking odr-use does not invent an lvalue-to-rvalue conversion (and
     // hence copy construction) on the potential result variable.
     struct B {
       int b = 42;
       constexpr B() {}
       constexpr B(const B&) = delete;
     };
     void f() {
       constexpr B b;
       struct Q {
         constexpr int foo() const { return b.b; }
       };
       static_assert(Q().foo() == 42, "");
     }
   }
 #endif
 }

 namespace dr2094 { // dr2094: 5
   struct A { int n; };
   struct B { volatile int n; };
   static_assert(__is_trivially_copyable(volatile int), "");
   static_assert(__is_trivially_copyable(const volatile int), "");
   static_assert(__is_trivially_copyable(const volatile int[]), "");
   static_assert(__is_trivially_copyable(A), "");
   static_assert(__is_trivially_copyable(volatile A), "");
   static_assert(__is_trivially_copyable(const volatile A), "");
   static_assert(__is_trivially_copyable(const volatile A[]), "");
   static_assert(__is_trivially_copyable(B), "");

   static_assert(__is_trivially_constructible(A, A const&), "");
   static_assert(__is_trivially_constructible(B, B const&), "");

   static_assert(__is_trivially_assignable(A, const A&), "");
   static_assert(__is_trivially_assignable(B, const B&), "");
 }
	// RUN: %clang_cc1 -std=c++98 -triple x86_64-unknown-unknown %s -verify -fexceptions -fcxx-exceptions -pedantic-errors \
	// RUN: -Wno-variadic-macros -Wno-c11-extensions
	// RUN: %clang_cc1 -std=c++11 -triple x86_64-unknown-unknown %s -verify -fexceptions -fcxx-exceptions -pedantic-errors
	// RUN: %clang_cc1 -std=c++14 -triple x86_64-unknown-unknown %s -verify -fexceptions -fcxx-exceptions -pedantic-errors
	// RUN: %clang_cc1 -std=c++1z -triple x86_64-unknown-unknown %s -verify -fexceptions -fcxx-exceptions -pedantic-errors

	#if __cplusplus < 201103L
	#define static_assert(...) _Static_assert(__VA_ARGS__)
	#endif

	namespace dr2083 { // dr2083: partial
	#if __cplusplus >= 201103L
	void non_const_mem_ptr() {
	struct A {
	int x;
	int y;
	};
	constexpr A a = {1, 2};
	struct B {
	int A::*p;
	constexpr int g() const {
	// OK, not an odr-use of 'a'.
	return a.*p;
	};
	};
	static_assert(B{&A::x}.g() == 1, "");
	static_assert(B{&A::y}.g() == 2, "");
	}
	#endif

	const int a = 1;
	int b;
	// Note, references only get special odr-use / constant initializxer
	// treatment in C++11 onwards. We continue to apply that even after DR2083.
	void ref_to_non_const() {
	int c;
	const int &ra = a; // expected-note 0-1{{here}}
	int &rb = b; // expected-note 0-1{{here}}
	int &rc = c; // expected-note {{here}}
	struct A {
	int f() {
	int a = ra;
	int b = rb;
	#if __cplusplus < 201103L
	// expected-error@-3 {{in enclosing function}}
	// expected-error@-3 {{in enclosing function}}
	#endif
	int c = rc; // expected-error {{in enclosing function}}
	return a + b + c;
	}
	};
	}

	#if __cplusplus >= 201103L
	struct NoMut1 { int a, b; };
	struct NoMut2 { NoMut1 m; };
	struct NoMut3 : NoMut1 {
	constexpr NoMut3(int a, int b) : NoMut1{a, b} {}
	};
	struct Mut1 {
	int a;
	mutable int b;
	};
	struct Mut2 { Mut1 m; };
	struct Mut3 : Mut1 {
	constexpr Mut3(int a, int b) : Mut1{a, b} {}
	};
	void mutable_subobjects() {
	constexpr NoMut1 nm1 = {1, 2};
	constexpr NoMut2 nm2 = {1, 2};
	constexpr NoMut3 nm3 = {1, 2};
	constexpr Mut1 m1 = {1, 2}; // expected-note {{declared here}}
	constexpr Mut2 m2 = {1, 2}; // expected-note {{declared here}}
	constexpr Mut3 m3 = {1, 2}; // expected-note {{declared here}}
	struct A {
	void f() {
	static_assert(nm1.a == 1, "");
	static_assert(nm2.m.a == 1, "");
	static_assert(nm3.a == 1, "");
	// Can't even access a non-mutable member of a variable containing mutable fields.
	static_assert(m1.a == 1, ""); // expected-error {{enclosing function}}
	static_assert(m2.m.a == 1, ""); // expected-error {{enclosing function}}
	static_assert(m3.a == 1, ""); // expected-error {{enclosing function}}
	}
	};
	}
	#endif

	void ellipsis() {
	void ellipsis(...);
	struct A {};
	const int n = 0;
	#if __cplusplus >= 201103L
	constexpr
	#endif
	A a = {}; // expected-note {{here}}
	struct B {
	void f() {
	ellipsis(n);
	// Even though this is technically modelled as an lvalue-to-rvalue
	// conversion, it calls a constructor and binds 'a' to a reference, so
	// it results in an odr-use.
	ellipsis(a); // expected-error {{enclosing function}}
	}
	};
	}

	#if __cplusplus >= 201103L
	void volatile_lval() {
	struct A { int n; };
	constexpr A a = {0}; // expected-note {{here}}
	struct B {
	void f() {
	// An lvalue-to-rvalue conversion of a volatile lvalue always results
	// in odr-use.
	int A::*p = &A::n;
	int x = a.*p;
	volatile int A::*q = p;
	int y = a.*q; // expected-error {{enclosing function}}
	}
	};
	}
	#endif

	void discarded_lval() {
	struct A { int x; mutable int y; volatile int z; };
	A a; // expected-note 1+{{here}}
	int &r = a.x; // expected-note {{here}}
	struct B {
	void f() {
	a.x; // expected-warning {{unused}}
	a.*&A::x; // expected-warning {{unused}}
	true ? a.x : a.y; // expected-warning {{unused}}
	(void)a.x;
	a.x, discarded_lval(); // expected-warning {{unused}}
	#if 1 // FIXME: These errors are all incorrect; the above code is valid.
	// expected-error@-6 {{enclosing function}}
	// expected-error@-6 {{enclosing function}}
	// expected-error@-6 2{{enclosing function}}
	// expected-error@-6 {{enclosing function}}
	// expected-error@-6 {{enclosing function}}
	#endif

	// 'volatile' qualifier triggers an lvalue-to-rvalue conversion.
	a.z; // expected-error {{enclosing function}}
	#if __cplusplus < 201103L
	// expected-warning@-2 {{assign into a variable}}
	#endif

	// References always get "loaded" to determine what they reference,
	// even if the result is discarded.
	r; // expected-error {{enclosing function}} expected-warning {{unused}}
	}
	};
	}

	namespace dr_example_1 {
	extern int globx;
	int main() {
	const int &x = globx;
	struct A {
	#if __cplusplus < 201103L
	// expected-error@+2 {{enclosing function}} expected-note@-3 {{here}}
	#endif
	const int *foo() { return &x; }
	} a;
	return *a.foo();
	}
	}

	#if __cplusplus >= 201103L
	namespace dr_example_2 {
	struct A {
	int q;
	constexpr A(int q) : q(q) {}
	constexpr A(const A &a) : q(a.q * 2) {} // (note, not called)
	};

	int main(void) {
	constexpr A a(42);
	constexpr int aq = a.q;
	struct Q {
	int foo() { return a.q; }
	} q;
	return q.foo();
	}

	// Checking odr-use does not invent an lvalue-to-rvalue conversion (and
	// hence copy construction) on the potential result variable.
	struct B {
	int b = 42;
	constexpr B() {}
	constexpr B(const B&) = delete;
	};
	void f() {
	constexpr B b;
	struct Q {
	constexpr int foo() const { return b.b; }
	};
	static_assert(Q().foo() == 42, "");
	}
	}
	#endif
	}

	namespace dr2094 { // dr2094: 5
	struct A { int n; };
	struct B { volatile int n; };
	static_assert(__is_trivially_copyable(volatile int), "");
	static_assert(__is_trivially_copyable(const volatile int), "");
	static_assert(__is_trivially_copyable(const volatile int[]), "");
	static_assert(__is_trivially_copyable(A), "");
	static_assert(__is_trivially_copyable(volatile A), "");
	static_assert(__is_trivially_copyable(const volatile A), "");
	static_assert(__is_trivially_copyable(const volatile A[]), "");
	static_assert(__is_trivially_copyable(B), "");

	static_assert(__is_trivially_constructible(A, A const&), "");
	static_assert(__is_trivially_constructible(B, B const&), "");

	static_assert(__is_trivially_assignable(A, const A&), "");
	static_assert(__is_trivially_assignable(B, const B&), "");
	}