src/third_party/llvm-project/clang/test/SemaObjCXX/arc-templates.mm - cobalt - Git at Google

 // RUN: %clang_cc1 -fobjc-runtime-has-weak -fsyntax-only -fobjc-arc -verify -fblocks -std=c++11 %s

 #define CONSUMED __attribute__((ns_consumed))
 #define PRODUCED __attribute__((ns_returns_retained))

 @interface A
 @end

 @class NSString;

 template<typename T, typename U>
 struct is_same {
   static const bool value = false;
 };

 template<typename T>
 struct is_same<T, T> {
   static const bool value = true;
 };

 // Instantiation for reference/pointer types that will get lifetime
 // adjustments.
 template<typename T>
 struct X0 {
   typedef T* pointer; // okay: ends up being strong.
   typedef T& reference; // okay: ends up being strong
 };

 void test_X0() {
   X0<id> x0id;
   X0<A*> x0a;
   X0<__strong A*> x0sa;

   id __strong *ptr;
   id __strong val;
   X0<__strong id>::pointer &ptr_ref = ptr;
   X0<__strong id>::reference ref = val;
 }

 int check_infer_strong[is_same<id, __strong id>::value? 1 : -1];

 // Check template argument deduction (e.g., for specialization) using
 // lifetime qualifiers.
 template<typename T>
 struct is_pointer_strong {
   static const bool value = false;
 };

 template<typename T>
 struct is_pointer_strong<__strong T*> {
   static const bool value = true;
 };

 int check_ptr_strong1[is_pointer_strong<__strong id*>::value? 1 : -1];
 int check_ptr_strong2[is_pointer_strong<__weak id*>::value? -1 : 1];
 int check_ptr_strong3[is_pointer_strong<__autoreleasing id*>::value? -1 : 1];
 int check_ptr_strong4[is_pointer_strong<__unsafe_unretained id*>::value? -1 : 1];
 int check_ptr_strong5[is_pointer_strong<id>::value? -1 : 1];

 // Check substitution into lifetime-qualified dependent types.
 template<typename T>
 struct make_strong_pointer {
   typedef __strong T *type;
 };

 template<typename T>
 struct make_strong_pointer<__weak T> {
   typedef __strong T *type;
 };

 template<typename T>
 struct make_strong_pointer<__autoreleasing T> {
   typedef __strong T *type;
 };

 template<typename T>
 struct make_strong_pointer<__unsafe_unretained T> {
   typedef __strong T *type;
 };

 // Adding qualifiers
 int check_make_strong1[is_same<make_strong_pointer<id>::type, __strong id *>::value ? 1 : -1];
 int check_make_strong2[is_same<make_strong_pointer<A*>::type, A* __strong *>::value ? 1 : -1];

 // Adding redundant qualifiers
 int check_make_strong3[is_same<make_strong_pointer<__strong id>::type, __strong id *>::value ? 1 : -1];
 int check_make_strong4[is_same<make_strong_pointer<__strong A*>::type, A* __strong *>::value ? 1 : -1];

 // Adding nonsensical qualifiers.
 int check_make_strong5[is_same<make_strong_pointer<int>::type, int *>::value ? 1 : -1];
 int check_make_strong6[is_same<make_strong_pointer<__weak id>::type, __strong id *>::value ? 1 : -1];

 template<typename T>
 struct make_weak {
   typedef __weak T type;
 };

 int check_make_weak0[is_same<make_weak<id>::type, __weak id>::value? 1 : -1];
 int check_make_weak1[is_same<make_weak<__strong id>::type, __weak id>::value? 1 : -1];
 int check_make_weak2[is_same<make_weak<__autoreleasing id>::type, __weak id>::value? 1 : -1];

 template<typename T>
 struct make_weak_fail {
   typedef T T_type;
   typedef __weak T_type type; // expected-error{{the type 'make_weak_fail<__weak id>::T_type' (aka '__weak id') is already explicitly ownership-qualified}} \
   // expected-error{{the type 'make_weak_fail<id>::T_type' (aka '__strong id') is already explicitly ownership-qualified}}
 };

 int check_make_weak_fail0[is_same<make_weak_fail<__weak id>::type, __weak id>::value? 1 : -1]; // expected-note{{in instantiation of template class 'make_weak_fail<__weak id>' requested here}}

 int check_make_weak_fail1[is_same<make_weak_fail<id>::type, __weak id>::value? -1 : 1]; // expected-note{{in instantiation of template class 'make_weak_fail<id>' requested here}}

 // Check template argument deduction from function templates.
 template<typename T> struct identity { };

 template<typename T> identity<T> accept_strong_ptr(__strong T*);
 template<typename T> identity<T> accept_strong_ref(__strong T&);

 template<typename T> identity<T> accept_any_ptr(T*);
 template<typename T> identity<T> accept_any_ref(T&);

 void test_func_deduction_id() {
   __strong id *sip;
   __weak id *wip;
   __autoreleasing id *aip;
   __unsafe_unretained id *uip;

   identity<id> res1 = accept_strong_ptr(sip);
   identity<__strong id> res2 = accept_any_ptr(sip);

   __strong id si;
   __weak id wi;
   __autoreleasing id ai;
   __unsafe_unretained id ui;
   identity<id> res3 = accept_strong_ref(si);
   identity<__strong id> res4 = accept_any_ref(si);
   identity<__weak id> res5 = accept_any_ref(wi);
   identity<__autoreleasing id> res6 = accept_any_ref(ai);
   identity<__unsafe_unretained id> res7 = accept_any_ref(ui);
 }

 void test_func_deduction_A() {
   __strong A * *sip;
   __weak A * *wip;
   __autoreleasing A * *aip;
   __unsafe_unretained A * *uip;

   identity<A *> res1 = accept_strong_ptr(sip);
   identity<__strong A *> res2 = accept_any_ptr(sip);

   __strong A * si;
   __weak A * wi;
   __autoreleasing A * ai;
   __unsafe_unretained A * ui;
   identity<A *> res3 = accept_strong_ref(si);
   identity<__strong A *> res4 = accept_any_ref(si);
   identity<__weak A *> res5 = accept_any_ref(wi);
   identity<__autoreleasing A *> res6 = accept_any_ref(ai);
   identity<__unsafe_unretained A *> res7 = accept_any_ref(ui);
 }

 // Test partial ordering (qualified vs. non-qualified).
 template<typename T>
 struct classify_pointer_pointer {
   static const unsigned value = 0;
 };

 template<typename T>
 struct classify_pointer_pointer<T*> {
   static const unsigned value = 1;
 };

 template<typename T>
 struct classify_pointer_pointer<__strong T*> {
   static const unsigned value = 2;
 };

 template<typename T>
 struct classify_pointer_pointer<__weak T*> {
   static const unsigned value = 3;
 };

 template<typename T>
 struct classify_pointer_pointer<T&> {
   static const unsigned value = 4;
 };

 template<typename T>
 struct classify_pointer_pointer<__strong T&> {
   static const unsigned value = 5;
 };

 template<typename T>
 struct classify_pointer_pointer<__weak T&> {
   static const unsigned value = 6;
 };

 int classify_ptr1[classify_pointer_pointer<int>::value == 0? 1 : -1];
 int classify_ptr2[classify_pointer_pointer<int *>::value == 1? 1 : -1];
 int classify_ptr3[classify_pointer_pointer<id __strong *>::value == 2? 1 : -1];
 int classify_ptr4[classify_pointer_pointer<id __weak *>::value == 3? 1 : -1];
 int classify_ptr5[classify_pointer_pointer<int&>::value == 4? 1 : -1];
 int classify_ptr6[classify_pointer_pointer<id __strong&>::value == 5? 1 : -1];
 int classify_ptr7[classify_pointer_pointer<id __weak&>::value == 6? 1 : -1];
 int classify_ptr8[classify_pointer_pointer<id __autoreleasing&>::value == 4? 1 : -1];
 int classify_ptr9[classify_pointer_pointer<id __unsafe_unretained&>::value == 4? 1 : -1];
 int classify_ptr10[classify_pointer_pointer<id __autoreleasing *>::value == 1? 1 : -1];
 int classify_ptr11[classify_pointer_pointer<id __unsafe_unretained *>::value == 1? 1 : -1];
 int classify_ptr12[classify_pointer_pointer<int *>::value == 1? 1 : -1];
 int classify_ptr13[classify_pointer_pointer<A * __strong *>::value == 2? 1 : -1];
 int classify_ptr14[classify_pointer_pointer<A * __weak *>::value == 3? 1 : -1];
 int classify_ptr15[classify_pointer_pointer<int&>::value == 4? 1 : -1];
 int classify_ptr16[classify_pointer_pointer<A * __strong&>::value == 5? 1 : -1];
 int classify_ptr17[classify_pointer_pointer<A * __weak&>::value == 6? 1 : -1];
 int classify_ptr18[classify_pointer_pointer<A * __autoreleasing&>::value == 4? 1 : -1];
 int classify_ptr19[classify_pointer_pointer<A * __unsafe_unretained&>::value == 4? 1 : -1];
 int classify_ptr20[classify_pointer_pointer<A * __autoreleasing *>::value == 1? 1 : -1];
 int classify_ptr21[classify_pointer_pointer<A * __unsafe_unretained *>::value == 1? 1 : -1];

 template<typename T> int& qual_vs_unqual_ptr(__strong T*);
 template<typename T> double& qual_vs_unqual_ptr(__weak T*);
 template<typename T> float& qual_vs_unqual_ptr(T*);
 template<typename T> int& qual_vs_unqual_ref(__strong T&);
 template<typename T> double& qual_vs_unqual_ref(__weak T&);
 template<typename T> float& qual_vs_unqual_ref(T&);

 void test_qual_vs_unqual_id() {
   __strong id *sip;
   __weak id *wip;
   __autoreleasing id *aip;
   __unsafe_unretained id *uip;

   int &ir1 = qual_vs_unqual_ptr(sip);
   double &dr1 = qual_vs_unqual_ptr(wip);
   float &fr1 = qual_vs_unqual_ptr(aip);
   float &fr2 = qual_vs_unqual_ptr(uip);

   int &ir2 = qual_vs_unqual_ref(*sip);
   double &dr2 = qual_vs_unqual_ref(*wip);
   float &fr3 = qual_vs_unqual_ref(*aip);
   float &fr4 = qual_vs_unqual_ref(*uip);
 }

 void test_qual_vs_unqual_a() {
   __strong A * *sap;
   __weak A * *wap;
   __autoreleasing A * *aap;
   __unsafe_unretained A * *uap;

   int &ir1 = qual_vs_unqual_ptr(sap);
   double &dr1 = qual_vs_unqual_ptr(wap);
   float &fr1 = qual_vs_unqual_ptr(aap);
   float &fr2 = qual_vs_unqual_ptr(uap);

   int &ir2 = qual_vs_unqual_ref(*sap);
   double &dr2 = qual_vs_unqual_ref(*wap);
   float &fr3 = qual_vs_unqual_ref(*aap);
   float &fr4 = qual_vs_unqual_ref(*uap);
 }

 namespace rdar9828157 {
   // Template argument deduction involving lifetime qualifiers and
   // non-lifetime types.
   class A { };

   template<typename T> float& f(T&);
   template<typename T> int& f(__strong T&);
   template<typename T> double& f(__weak T&);

   void test_f(A* ap) {
     float &fr = (f)(ap);
   }
 }

 namespace rdar10862386 {
   // More deduction with lifetime qualifiers.
   template <typename T>
   int testing(const T &) {
       return 1;
   }

   void test() {
      testing(1);
       testing("hi");
       testing<NSString *>(@"hi");
       testing(@"hi");
  }
 }

 namespace rdar12367446 {
   template <class T> class A;
   template <class R> class A<R()> {};

   void test() {
     A<id()> value;
   }
 }

 namespace rdar14467941 {
   template<typename T> int &takePtr(const T &);
   template<typename T> float &takePtr(T * const &);

   void testTakePtr(A *a) {
     float &fr1 = takePtr(a);
     float &fr2 = takePtr<A>(a);
   }
 }

 namespace rdar15713945 {
   template <class T> int &f(__strong T &);
   template <class T> float &f(__weak T &);
   template <class T> double &f(__unsafe_unretained T &);
   template <class T> char &f(T &);

   void foo() {
     __strong NSString * const strong = 0;
     int &ir = (f)(strong);
     __weak NSString * const weak = 0;
     float &fr = (f)(weak);
     __unsafe_unretained NSString * const unsafe = 0;
     double &dr = (f)(unsafe);
   }
 }

 namespace consumed {
   void take_yes_no(void (&)(id CONSUMED, id)); // expected-note 2 {{candidate function not viable}}
   void take_no_yes(void (&)(id, CONSUMED id)); // expected-note 2 {{candidate function not viable}}
   void take_yes_yes(void (&)(CONSUMED id, CONSUMED id)); // expected-note 2 {{candidate function not viable}}

   template <class... As> void consumes_first(id CONSUMED, As...);
   void test1() {
     take_yes_no(consumes_first<id>);
     take_no_yes(consumes_first<id>); // expected-error {{no matching function}}
     take_yes_yes(consumes_first<id>); // expected-error {{no matching function}}
   }

   template <class... As> void consumes_rest(id, CONSUMED As...);
   void test2() {
     take_yes_no(consumes_rest<id>); // expected-error {{no matching function}}
     take_no_yes(consumes_rest<id>);
     take_yes_yes(consumes_rest<id>); // expected-error {{no matching function}}
   }

   template <class T, class U> void consumes_two(CONSUMED T, CONSUMED U);
   void test3() {
     take_yes_no(consumes_two); // expected-error {{no matching function}}
     take_no_yes(consumes_two); // expected-error {{no matching function}}
     take_yes_yes(consumes_two);
   }
 }

 namespace consumed_nested {
   void take_yes_no(void (&)(id CONSUMED, id)); // expected-note 4 {{candidate function not viable}}
   void take_no_yes(void (&)(id, CONSUMED id)); // expected-note 4 {{candidate function not viable}}
   void take_yes_yes(void (&)(CONSUMED id, CONSUMED id)); // expected-note 4 {{candidate function not viable}}

   template <unsigned N> struct consumes_first {
     template <class... As> static void fn(id CONSUMED, As...);
   };
   void test1() {
     take_yes_no(consumes_first<1>::fn<id>);
     take_no_yes(consumes_first<2>::fn<id>); // expected-error {{no matching function}}
     take_yes_yes(consumes_first<3>::fn<id>); // expected-error {{no matching function}}
     take_yes_no(consumes_first<4>::fn);
     take_no_yes(consumes_first<5>::fn); // expected-error {{no matching function}}
     take_yes_yes(consumes_first<6>::fn); // expected-error {{no matching function}}
   }

   template <unsigned N> struct consumes_rest {
     template <class... As> static void fn(id, CONSUMED As...);
   };
   void test2() {
     take_yes_no(consumes_rest<1>::fn<id>); // expected-error {{no matching function}}
     take_no_yes(consumes_rest<2>::fn<id>);
     take_yes_yes(consumes_rest<3>::fn<id>); // expected-error {{no matching function}}
     take_yes_no(consumes_rest<4>::fn<id>); // expected-error {{no matching function}}
     take_no_yes(consumes_rest<5>::fn<id>);
     take_yes_yes(consumes_rest<6>::fn<id>); // expected-error {{no matching function}}
   }

   template <unsigned N> struct consumes_two {
     template <class T, class U> static void fn(CONSUMED T, CONSUMED U);
   };
   void test3() {
     take_yes_no(consumes_two<1>::fn<id, id>); // expected-error {{no matching function}}
     take_no_yes(consumes_two<2>::fn<id, id>); // expected-error {{no matching function}}
     take_yes_yes(consumes_two<3>::fn<id, id>);
     take_yes_no(consumes_two<1>::fn); // expected-error {{no matching function}}
     take_no_yes(consumes_two<2>::fn); // expected-error {{no matching function}}
     take_yes_yes(consumes_two<3>::fn);
   }
 }

 namespace produced {
   void take_yes(PRODUCED id (&)()); // expected-note 2 {{candidate function not viable}}
   void take_no(id (&)()); // expected-note 2 {{candidate function not viable}}

   template <class T> T non_produces1();
   template <class T> T non_produces2();
   template <class T> T non_produces3();
   template <class T> T non_produces4();
   void test1() {
     take_yes(non_produces1<id>); // expected-error {{no matching function}}
     take_yes(non_produces2); // expected-error {{no matching function}}
     take_no(non_produces3<id>);
     take_no(non_produces4);
   }

   template <class T> PRODUCED T produces1();
   template <class T> PRODUCED T produces2();
   template <class T> PRODUCED T produces3();
   template <class T> PRODUCED T produces4();
   void test2() {
     take_yes(produces1<id>);
     take_yes(produces2);
     take_no(produces3<id>); // expected-error {{no matching function}}
     take_no(produces4); // expected-error {{no matching function}}
   }
 }

 namespace produced_nested {
   void take_yes(PRODUCED id (&)()); // expected-note 2 {{candidate function not viable}}
   void take_no(id (&)()); // expected-note 2 {{candidate function not viable}}

   template <unsigned N> struct non_produces {
     template <class T> static T fn();
   };
   void test1() {
     take_yes(non_produces<1>::fn<id>); // expected-error {{no matching function}}
     take_yes(non_produces<2>::fn); // expected-error {{no matching function}}
     take_no(non_produces<3>::fn<id>);
     take_no(non_produces<4>::fn);
   }

   template <unsigned N> struct produces {
     template <class T> static PRODUCED T fn();
   };
   void test2() {
     take_yes(produces<1>::fn<id>);
     take_yes(produces<2>::fn);
     take_no(produces<3>::fn<id>); // expected-error {{no matching function}}
     take_no(produces<4>::fn); // expected-error {{no matching function}}
   }
 }

 namespace instantiate_consumed {
   template <class T> void take(CONSUMED T t) {} // expected-note {{candidate template ignored: substitution failure [with T = int]: ns_consumed attribute only applies to Objective-C object parameters}}
   void test() {
     take((id) 0);
     take((int) 0); // expected-error {{no matching function for call to 'take'}}
   }
 }
	// RUN: %clang_cc1 -fobjc-runtime-has-weak -fsyntax-only -fobjc-arc -verify -fblocks -std=c++11 %s

	#define CONSUMED __attribute__((ns_consumed))
	#define PRODUCED __attribute__((ns_returns_retained))

	@interface A
	@end

	@class NSString;

	template<typename T, typename U>
	struct is_same {
	static const bool value = false;
	};

	template<typename T>
	struct is_same<T, T> {
	static const bool value = true;
	};

	// Instantiation for reference/pointer types that will get lifetime
	// adjustments.
	template<typename T>
	struct X0 {
	typedef T* pointer; // okay: ends up being strong.
	typedef T& reference; // okay: ends up being strong
	};

	void test_X0() {
	X0<id> x0id;
	X0<A*> x0a;
	X0<__strong A*> x0sa;

	id __strong *ptr;
	id __strong val;
	X0<__strong id>::pointer &ptr_ref = ptr;
	X0<__strong id>::reference ref = val;
	}

	int check_infer_strong[is_same<id, __strong id>::value? 1 : -1];

	// Check template argument deduction (e.g., for specialization) using
	// lifetime qualifiers.
	template<typename T>
	struct is_pointer_strong {
	static const bool value = false;
	};

	template<typename T>
	struct is_pointer_strong<__strong T*> {
	static const bool value = true;
	};

	int check_ptr_strong1[is_pointer_strong<__strong id*>::value? 1 : -1];
	int check_ptr_strong2[is_pointer_strong<__weak id*>::value? -1 : 1];
	int check_ptr_strong3[is_pointer_strong<__autoreleasing id*>::value? -1 : 1];
	int check_ptr_strong4[is_pointer_strong<__unsafe_unretained id*>::value? -1 : 1];
	int check_ptr_strong5[is_pointer_strong<id>::value? -1 : 1];

	// Check substitution into lifetime-qualified dependent types.
	template<typename T>
	struct make_strong_pointer {
	typedef __strong T *type;
	};

	template<typename T>
	struct make_strong_pointer<__weak T> {
	typedef __strong T *type;
	};

	template<typename T>
	struct make_strong_pointer<__autoreleasing T> {
	typedef __strong T *type;
	};

	template<typename T>
	struct make_strong_pointer<__unsafe_unretained T> {
	typedef __strong T *type;
	};

	// Adding qualifiers
	int check_make_strong1[is_same<make_strong_pointer<id>::type, __strong id *>::value ? 1 : -1];
	int check_make_strong2[is_same<make_strong_pointer<A>::type, A __strong *>::value ? 1 : -1];

	// Adding redundant qualifiers
	int check_make_strong3[is_same<make_strong_pointer<__strong id>::type, __strong id *>::value ? 1 : -1];
	int check_make_strong4[is_same<make_strong_pointer<__strong A>::type, A __strong *>::value ? 1 : -1];

	// Adding nonsensical qualifiers.
	int check_make_strong5[is_same<make_strong_pointer<int>::type, int *>::value ? 1 : -1];
	int check_make_strong6[is_same<make_strong_pointer<__weak id>::type, __strong id *>::value ? 1 : -1];

	template<typename T>
	struct make_weak {
	typedef __weak T type;
	};

	int check_make_weak0[is_same<make_weak<id>::type, __weak id>::value? 1 : -1];
	int check_make_weak1[is_same<make_weak<__strong id>::type, __weak id>::value? 1 : -1];
	int check_make_weak2[is_same<make_weak<__autoreleasing id>::type, __weak id>::value? 1 : -1];

	template<typename T>
	struct make_weak_fail {
	typedef T T_type;
	typedef __weak T_type type; // expected-error{{the type 'make_weak_fail<__weak id>::T_type' (aka '__weak id') is already explicitly ownership-qualified}} \
	// expected-error{{the type 'make_weak_fail<id>::T_type' (aka '__strong id') is already explicitly ownership-qualified}}
	};

	int check_make_weak_fail0[is_same<make_weak_fail<__weak id>::type, __weak id>::value? 1 : -1]; // expected-note{{in instantiation of template class 'make_weak_fail<__weak id>' requested here}}

	int check_make_weak_fail1[is_same<make_weak_fail<id>::type, __weak id>::value? -1 : 1]; // expected-note{{in instantiation of template class 'make_weak_fail<id>' requested here}}

	// Check template argument deduction from function templates.
	template<typename T> struct identity { };

	template<typename T> identity<T> accept_strong_ptr(__strong T*);
	template<typename T> identity<T> accept_strong_ref(__strong T&);

	template<typename T> identity<T> accept_any_ptr(T*);
	template<typename T> identity<T> accept_any_ref(T&);

	void test_func_deduction_id() {
	__strong id *sip;
	__weak id *wip;
	__autoreleasing id *aip;
	__unsafe_unretained id *uip;

	identity<id> res1 = accept_strong_ptr(sip);
	identity<__strong id> res2 = accept_any_ptr(sip);

	__strong id si;
	__weak id wi;
	__autoreleasing id ai;
	__unsafe_unretained id ui;
	identity<id> res3 = accept_strong_ref(si);
	identity<__strong id> res4 = accept_any_ref(si);
	identity<__weak id> res5 = accept_any_ref(wi);
	identity<__autoreleasing id> res6 = accept_any_ref(ai);
	identity<__unsafe_unretained id> res7 = accept_any_ref(ui);
	}

	void test_func_deduction_A() {
	__strong A * *sip;
	__weak A * *wip;
	__autoreleasing A * *aip;
	__unsafe_unretained A * *uip;

	identity<A *> res1 = accept_strong_ptr(sip);
	identity<__strong A *> res2 = accept_any_ptr(sip);

	__strong A * si;
	__weak A * wi;
	__autoreleasing A * ai;
	__unsafe_unretained A * ui;
	identity<A *> res3 = accept_strong_ref(si);
	identity<__strong A *> res4 = accept_any_ref(si);
	identity<__weak A *> res5 = accept_any_ref(wi);
	identity<__autoreleasing A *> res6 = accept_any_ref(ai);
	identity<__unsafe_unretained A *> res7 = accept_any_ref(ui);
	}

	// Test partial ordering (qualified vs. non-qualified).
	template<typename T>
	struct classify_pointer_pointer {
	static const unsigned value = 0;
	};

	template<typename T>
	struct classify_pointer_pointer<T*> {
	static const unsigned value = 1;
	};

	template<typename T>
	struct classify_pointer_pointer<__strong T*> {
	static const unsigned value = 2;
	};

	template<typename T>
	struct classify_pointer_pointer<__weak T*> {
	static const unsigned value = 3;
	};

	template<typename T>
	struct classify_pointer_pointer<T&> {
	static const unsigned value = 4;
	};

	template<typename T>
	struct classify_pointer_pointer<__strong T&> {
	static const unsigned value = 5;
	};

	template<typename T>
	struct classify_pointer_pointer<__weak T&> {
	static const unsigned value = 6;
	};

	int classify_ptr1[classify_pointer_pointer<int>::value == 0? 1 : -1];
	int classify_ptr2[classify_pointer_pointer<int *>::value == 1? 1 : -1];
	int classify_ptr3[classify_pointer_pointer<id __strong *>::value == 2? 1 : -1];
	int classify_ptr4[classify_pointer_pointer<id __weak *>::value == 3? 1 : -1];
	int classify_ptr5[classify_pointer_pointer<int&>::value == 4? 1 : -1];
	int classify_ptr6[classify_pointer_pointer<id __strong&>::value == 5? 1 : -1];
	int classify_ptr7[classify_pointer_pointer<id __weak&>::value == 6? 1 : -1];
	int classify_ptr8[classify_pointer_pointer<id __autoreleasing&>::value == 4? 1 : -1];
	int classify_ptr9[classify_pointer_pointer<id __unsafe_unretained&>::value == 4? 1 : -1];
	int classify_ptr10[classify_pointer_pointer<id __autoreleasing *>::value == 1? 1 : -1];
	int classify_ptr11[classify_pointer_pointer<id __unsafe_unretained *>::value == 1? 1 : -1];
	int classify_ptr12[classify_pointer_pointer<int *>::value == 1? 1 : -1];
	int classify_ptr13[classify_pointer_pointer<A * __strong *>::value == 2? 1 : -1];
	int classify_ptr14[classify_pointer_pointer<A * __weak *>::value == 3? 1 : -1];
	int classify_ptr15[classify_pointer_pointer<int&>::value == 4? 1 : -1];
	int classify_ptr16[classify_pointer_pointer<A * __strong&>::value == 5? 1 : -1];
	int classify_ptr17[classify_pointer_pointer<A * __weak&>::value == 6? 1 : -1];
	int classify_ptr18[classify_pointer_pointer<A * __autoreleasing&>::value == 4? 1 : -1];
	int classify_ptr19[classify_pointer_pointer<A * __unsafe_unretained&>::value == 4? 1 : -1];
	int classify_ptr20[classify_pointer_pointer<A * __autoreleasing *>::value == 1? 1 : -1];
	int classify_ptr21[classify_pointer_pointer<A * __unsafe_unretained *>::value == 1? 1 : -1];

	template<typename T> int& qual_vs_unqual_ptr(__strong T*);
	template<typename T> double& qual_vs_unqual_ptr(__weak T*);
	template<typename T> float& qual_vs_unqual_ptr(T*);
	template<typename T> int& qual_vs_unqual_ref(__strong T&);
	template<typename T> double& qual_vs_unqual_ref(__weak T&);
	template<typename T> float& qual_vs_unqual_ref(T&);

	void test_qual_vs_unqual_id() {
	__strong id *sip;
	__weak id *wip;
	__autoreleasing id *aip;
	__unsafe_unretained id *uip;

	int &ir1 = qual_vs_unqual_ptr(sip);
	double &dr1 = qual_vs_unqual_ptr(wip);
	float &fr1 = qual_vs_unqual_ptr(aip);
	float &fr2 = qual_vs_unqual_ptr(uip);

	int &ir2 = qual_vs_unqual_ref(*sip);
	double &dr2 = qual_vs_unqual_ref(*wip);
	float &fr3 = qual_vs_unqual_ref(*aip);
	float &fr4 = qual_vs_unqual_ref(*uip);
	}

	void test_qual_vs_unqual_a() {
	__strong A * *sap;
	__weak A * *wap;
	__autoreleasing A * *aap;
	__unsafe_unretained A * *uap;

	int &ir1 = qual_vs_unqual_ptr(sap);
	double &dr1 = qual_vs_unqual_ptr(wap);
	float &fr1 = qual_vs_unqual_ptr(aap);
	float &fr2 = qual_vs_unqual_ptr(uap);

	int &ir2 = qual_vs_unqual_ref(*sap);
	double &dr2 = qual_vs_unqual_ref(*wap);
	float &fr3 = qual_vs_unqual_ref(*aap);
	float &fr4 = qual_vs_unqual_ref(*uap);
	}

	namespace rdar9828157 {
	// Template argument deduction involving lifetime qualifiers and
	// non-lifetime types.
	class A { };

	template<typename T> float& f(T&);
	template<typename T> int& f(__strong T&);
	template<typename T> double& f(__weak T&);

	void test_f(A* ap) {
	float &fr = (f)(ap);
	}
	}

	namespace rdar10862386 {
	// More deduction with lifetime qualifiers.
	template <typename T>
	int testing(const T &) {
	return 1;
	}

	void test() {
	testing(1);
	testing("hi");
	testing<NSString *>(@"hi");
	testing(@"hi");
	}
	}

	namespace rdar12367446 {
	template <class T> class A;
	template <class R> class A<R()> {};

	void test() {
	A<id()> value;
	}
	}

	namespace rdar14467941 {
	template<typename T> int &takePtr(const T &);
	template<typename T> float &takePtr(T * const &);

	void testTakePtr(A *a) {
	float &fr1 = takePtr(a);
	float &fr2 = takePtr<A>(a);
	}
	}

	namespace rdar15713945 {
	template <class T> int &f(__strong T &);
	template <class T> float &f(__weak T &);
	template <class T> double &f(__unsafe_unretained T &);
	template <class T> char &f(T &);

	void foo() {
	__strong NSString * const strong = 0;
	int &ir = (f)(strong);
	__weak NSString * const weak = 0;
	float &fr = (f)(weak);
	__unsafe_unretained NSString * const unsafe = 0;
	double &dr = (f)(unsafe);
	}
	}

	namespace consumed {
	void take_yes_no(void (&)(id CONSUMED, id)); // expected-note 2 {{candidate function not viable}}
	void take_no_yes(void (&)(id, CONSUMED id)); // expected-note 2 {{candidate function not viable}}
	void take_yes_yes(void (&)(CONSUMED id, CONSUMED id)); // expected-note 2 {{candidate function not viable}}

	template <class... As> void consumes_first(id CONSUMED, As...);
	void test1() {
	take_yes_no(consumes_first<id>);
	take_no_yes(consumes_first<id>); // expected-error {{no matching function}}
	take_yes_yes(consumes_first<id>); // expected-error {{no matching function}}
	}

	template <class... As> void consumes_rest(id, CONSUMED As...);
	void test2() {
	take_yes_no(consumes_rest<id>); // expected-error {{no matching function}}
	take_no_yes(consumes_rest<id>);
	take_yes_yes(consumes_rest<id>); // expected-error {{no matching function}}
	}

	template <class T, class U> void consumes_two(CONSUMED T, CONSUMED U);
	void test3() {
	take_yes_no(consumes_two); // expected-error {{no matching function}}
	take_no_yes(consumes_two); // expected-error {{no matching function}}
	take_yes_yes(consumes_two);
	}
	}

	namespace consumed_nested {
	void take_yes_no(void (&)(id CONSUMED, id)); // expected-note 4 {{candidate function not viable}}
	void take_no_yes(void (&)(id, CONSUMED id)); // expected-note 4 {{candidate function not viable}}
	void take_yes_yes(void (&)(CONSUMED id, CONSUMED id)); // expected-note 4 {{candidate function not viable}}

	template <unsigned N> struct consumes_first {
	template <class... As> static void fn(id CONSUMED, As...);
	};
	void test1() {
	take_yes_no(consumes_first<1>::fn<id>);
	take_no_yes(consumes_first<2>::fn<id>); // expected-error {{no matching function}}
	take_yes_yes(consumes_first<3>::fn<id>); // expected-error {{no matching function}}
	take_yes_no(consumes_first<4>::fn);
	take_no_yes(consumes_first<5>::fn); // expected-error {{no matching function}}
	take_yes_yes(consumes_first<6>::fn); // expected-error {{no matching function}}
	}

	template <unsigned N> struct consumes_rest {
	template <class... As> static void fn(id, CONSUMED As...);
	};
	void test2() {
	take_yes_no(consumes_rest<1>::fn<id>); // expected-error {{no matching function}}
	take_no_yes(consumes_rest<2>::fn<id>);
	take_yes_yes(consumes_rest<3>::fn<id>); // expected-error {{no matching function}}
	take_yes_no(consumes_rest<4>::fn<id>); // expected-error {{no matching function}}
	take_no_yes(consumes_rest<5>::fn<id>);
	take_yes_yes(consumes_rest<6>::fn<id>); // expected-error {{no matching function}}
	}

	template <unsigned N> struct consumes_two {
	template <class T, class U> static void fn(CONSUMED T, CONSUMED U);
	};
	void test3() {
	take_yes_no(consumes_two<1>::fn<id, id>); // expected-error {{no matching function}}
	take_no_yes(consumes_two<2>::fn<id, id>); // expected-error {{no matching function}}
	take_yes_yes(consumes_two<3>::fn<id, id>);
	take_yes_no(consumes_two<1>::fn); // expected-error {{no matching function}}
	take_no_yes(consumes_two<2>::fn); // expected-error {{no matching function}}
	take_yes_yes(consumes_two<3>::fn);
	}
	}

	namespace produced {
	void take_yes(PRODUCED id (&)()); // expected-note 2 {{candidate function not viable}}
	void take_no(id (&)()); // expected-note 2 {{candidate function not viable}}

	template <class T> T non_produces1();
	template <class T> T non_produces2();
	template <class T> T non_produces3();
	template <class T> T non_produces4();
	void test1() {
	take_yes(non_produces1<id>); // expected-error {{no matching function}}
	take_yes(non_produces2); // expected-error {{no matching function}}
	take_no(non_produces3<id>);
	take_no(non_produces4);
	}

	template <class T> PRODUCED T produces1();
	template <class T> PRODUCED T produces2();
	template <class T> PRODUCED T produces3();
	template <class T> PRODUCED T produces4();
	void test2() {
	take_yes(produces1<id>);
	take_yes(produces2);
	take_no(produces3<id>); // expected-error {{no matching function}}
	take_no(produces4); // expected-error {{no matching function}}
	}
	}

	namespace produced_nested {
	void take_yes(PRODUCED id (&)()); // expected-note 2 {{candidate function not viable}}
	void take_no(id (&)()); // expected-note 2 {{candidate function not viable}}

	template <unsigned N> struct non_produces {
	template <class T> static T fn();
	};
	void test1() {
	take_yes(non_produces<1>::fn<id>); // expected-error {{no matching function}}
	take_yes(non_produces<2>::fn); // expected-error {{no matching function}}
	take_no(non_produces<3>::fn<id>);
	take_no(non_produces<4>::fn);
	}

	template <unsigned N> struct produces {
	template <class T> static PRODUCED T fn();
	};
	void test2() {
	take_yes(produces<1>::fn<id>);
	take_yes(produces<2>::fn);
	take_no(produces<3>::fn<id>); // expected-error {{no matching function}}
	take_no(produces<4>::fn); // expected-error {{no matching function}}
	}
	}

	namespace instantiate_consumed {
	template <class T> void take(CONSUMED T t) {} // expected-note {{candidate template ignored: substitution failure [with T = int]: ns_consumed attribute only applies to Objective-C object parameters}}
	void test() {
	take((id) 0);
	take((int) 0); // expected-error {{no matching function for call to 'take'}}
	}
	}