test/PCH/cxx-templates.h - third_party/swift-clang - Git at Google

 // Header for PCH test cxx-templates.cpp

 template <typename T1, typename T2>
 struct S;

 template <typename T1, typename T2>
 struct S {
   S() { }
   static void templ();
 };

 template <typename T>
 struct S<int, T> {
     static void partial();
 };

 template <>
 struct S<int, float> {
     static void explicit_special();
 };

 template <int x>
 int tmpl_f2() { return x; }

 template <typename T, int y>
 T templ_f(T x) {
   int z = templ_f<int, 5>(3);
   z = tmpl_f2<y+2>();
   T data[y];
   return x+y;
 }

 void govl(int);
 void govl(char);

 template <typename T>
 struct Unresolv {
   void f() {
     govl(T());
   }
 };

 template <typename T>
 struct Dep {
   typedef typename T::type Ty;
   void f() {
     Ty x = Ty();
     T::my_f();
     int y = T::template my_templf<int>(0);
     ovl(y);
   }

   void ovl(int);
   void ovl(float);
 };

 template<typename T, typename A1>
 inline T make_a(const A1& a1) {
   T::depend_declref();
   return T(a1);
 }

 template <class T> class UseBase {
   void foo();
   typedef int bar;
 };

 template <class T> class UseA : public UseBase<T> {
   using UseBase<T>::foo;
   using typename UseBase<T>::bar;
 };

 template <class T> class Sub : public UseBase<int> { };

 template <class _Ret, class _Tp>
   class mem_fun_t
   {
   public:
     explicit
     mem_fun_t(_Ret (_Tp::*__pf)())
      {}

   private:
     _Ret (_Tp::*_M_f)();
   };

 template<unsigned N>
 bool isInt(int x);

 template<> bool isInt<8>(int x) {
   try { ++x; } catch(...) { --x; }
   return true;
 }

 template<typename _CharT>
 int __copy_streambufs_eof(_CharT);

 class basic_streambuf
 {
   void m() { }
   friend int __copy_streambufs_eof<>(int);
 };

 // PR 7660
 template<typename T> struct S_PR7660 { void g(void (*)(T)); };
  template<> void S_PR7660<int>::g(void(*)(int)) {}

 // PR 7670
 template<typename> class C_PR7670;
 template<> class C_PR7670<int>;
 template<> class C_PR7670<int>;

 template <bool B>
 struct S2 {
     static bool V;
 };

 extern template class S2<true>;

 template <typename T>
 struct S3 {
     void m();
 };

 template <typename T>
 inline void S3<T>::m() { }

 template <typename T>
 struct S4 {
     void m() { }
 };
 extern template struct S4<int>;

 void S4ImplicitInst() {
     S4<int> s;
     s.m();
 }

 struct S5 {
   S5(int x);
 };

 struct TS5 {
   S5 s;
   template <typename T>
   TS5(T y) : s(y) {}
 };

 // PR 8134
 template<class T> void f_PR8134(T);
 template<class T> void f_PR8134(T);
 void g_PR8134() { f_PR8134(0); f_PR8134('x'); }

 // rdar8580149
 template <typename T>
 struct S6;

 template <typename T, unsigned N>
 struct S6<const T [N]>
 {
 private:
    typedef const T t1[N];
 public:
    typedef t1& t2;
 };

 template<typename T>
   struct S7;

 template<unsigned N>
 struct S7<int[N]> : S6<const int[N]> { };

 // Zero-length template argument lists
 namespace ZeroLengthExplicitTemplateArgs {
   template<typename T> void h();

   struct Y {
     template<typename T> void f();
   };

   template<typename T>
     void f(T *ptr) {
     T::template g<>(17);
     ptr->template g2<>(17);
     h<T>();
     h<int>();
     Y y;
     y.f<int>();
   }

   struct X {
     template<typename T> static void g(T);
     template<typename T> void g2(T);
   };
 }

 namespace NonTypeTemplateParmContext {
   template<typename T, int inlineCapacity = 0> class Vector { };

   struct String {
     template<int inlineCapacity>
     static String adopt(Vector<char, inlineCapacity>&);
   };

   template<int inlineCapacity>
     inline bool equalIgnoringNullity(const Vector<char, inlineCapacity>& a, const String& b) { return false; }
 }

 // <rdar://problem/11112464>
 template< typename > class Foo;

 template< typename T >
 class Foo : protected T
 {
  public:
   Foo& operator=( const Foo& other );
 };

 template<typename...A> struct NestedExpansion {
   template<typename...B> auto f(A...a, B...b) -> decltype(g(a + b...));
 };
 template struct NestedExpansion<char, char, char>;

 namespace rdar13135282 {
 template < typename _Alloc >
 void foo(_Alloc = _Alloc());

 template < bool > class __pool;

 template < template < bool > class _PoolTp >
 struct __common_pool {
   typedef _PoolTp < 0 > pool_type;
 };

 template < template < bool > class _PoolTp >
 struct __common_pool_base : __common_pool < _PoolTp > {};

 template < template < bool > class _PoolTp >
 struct A : __common_pool_base < _PoolTp > {};

 template < typename _Poolp = A < __pool > >
 struct __mt_alloc {
   typedef typename _Poolp::pool_type __pool_type;
   __mt_alloc() {
     foo<__mt_alloc<> >();
   }
 };
 }

 namespace PR13020 {
 template<typename T>
 void f() {
  enum E {
    enumerator
  };

  T t = enumerator;
 }

 template void f<int>();
 }

 template<typename T> void doNotDeserialize() {}
 template<typename T> struct ContainsDoNotDeserialize {
   static int doNotDeserialize;
 };
 template<typename T> struct ContainsDoNotDeserialize2 {
   static void doNotDeserialize();
 };
 template<typename T> int ContainsDoNotDeserialize<T>::doNotDeserialize = 0;
 template<typename T> void ContainsDoNotDeserialize2<T>::doNotDeserialize() {}


 template<typename T> void DependentSpecializedFunc(T x) { x.foo(); }
 template<typename T> class DependentSpecializedFuncClass {
   void foo() {}
   friend void DependentSpecializedFunc<>(DependentSpecializedFuncClass);
 };

 namespace cyclic_module_load {
   // Reduced from a libc++ modules crasher.
   namespace std {
     template<class> class mask_array;
     template<class> class valarray {
     public:
       valarray(const valarray &v);
     };

     class gslice {
       valarray<int> x;
       valarray<int> stride() const { return x; }
     };

     template<class> class mask_array {
       template<class> friend class valarray;
     };
   }
 }

 namespace local_extern {
   template<typename T> int f() {
     extern int arr[3];
     {
       extern T arr;
       return sizeof(arr);
     }
   }
   template<typename T> int g() {
     extern int arr[3];
     extern T arr;
     return sizeof(arr);
   }
 }

 namespace rdar15468709a {
   template<typename> struct decay {};

   template<typename FooParamTy> auto foo(FooParamTy fooParam) -> decltype(fooParam);
   template<typename BarParamTy> auto bar(BarParamTy barParam) -> decay<decltype(barParam)>;

   struct B {};

   void crash() {
     B some;
     bar(some);
   }
 }

 namespace rdar15468709b {
   template<typename> struct decay {};

   template<typename... Foos> int returnsInt(Foos... foos);

   template<typename... FooParamTy> auto foo(FooParamTy... fooParam) -> decltype(returnsInt(fooParam...));
   template<typename... BarParamTy> auto bar(BarParamTy... barParam) -> decay<decltype(returnsInt(barParam...))>;

   struct B {};

   void crash() {
     B some;
     bar(some);
   }
 }

 namespace rdar15468709c {
   template<typename> struct decay {};

   template<class... Foos> int returnsInt(Foos... foos);

   template<typename FooParamTy> void foo(FooParamTy fooParam) { decltype(fooParam) a; }
   template<typename BarParamTy> auto bar(BarParamTy barParam) -> decay<decltype(barParam)>;

   struct B {};

   void crash() {
     B some;
     bar(some);
   }
 }

 namespace MemberSpecializationLocation {
   template<typename T> struct A { static int n; };
 }
	// Header for PCH test cxx-templates.cpp

	template <typename T1, typename T2>
	struct S;

	template <typename T1, typename T2>
	struct S {
	S() { }
	static void templ();
	};

	template <typename T>
	struct S<int, T> {
	static void partial();
	};

	template <>
	struct S<int, float> {
	static void explicit_special();
	};

	template <int x>
	int tmpl_f2() { return x; }

	template <typename T, int y>
	T templ_f(T x) {
	int z = templ_f<int, 5>(3);
	z = tmpl_f2<y+2>();
	T data[y];
	return x+y;
	}

	void govl(int);
	void govl(char);

	template <typename T>
	struct Unresolv {
	void f() {
	govl(T());
	}
	};

	template <typename T>
	struct Dep {
	typedef typename T::type Ty;
	void f() {
	Ty x = Ty();
	T::my_f();
	int y = T::template my_templf<int>(0);
	ovl(y);
	}

	void ovl(int);
	void ovl(float);
	};

	template<typename T, typename A1>
	inline T make_a(const A1& a1) {
	T::depend_declref();
	return T(a1);
	}

	template <class T> class UseBase {
	void foo();
	typedef int bar;
	};

	template <class T> class UseA : public UseBase<T> {
	using UseBase<T>::foo;
	using typename UseBase<T>::bar;
	};

	template <class T> class Sub : public UseBase<int> { };

	template <class _Ret, class _Tp>
	class mem_fun_t
	{
	public:
	explicit
	mem_fun_t(_Ret (_Tp::*__pf)())
	{}

	private:
	_Ret (_Tp::*_M_f)();
	};

	template<unsigned N>
	bool isInt(int x);

	template<> bool isInt<8>(int x) {
	try { ++x; } catch(...) { --x; }
	return true;
	}

	template<typename _CharT>
	int __copy_streambufs_eof(_CharT);

	class basic_streambuf
	{
	void m() { }
	friend int __copy_streambufs_eof<>(int);
	};

	// PR 7660
	template<typename T> struct S_PR7660 { void g(void (*)(T)); };
	template<> void S_PR7660<int>::g(void(*)(int)) {}

	// PR 7670
	template<typename> class C_PR7670;
	template<> class C_PR7670<int>;
	template<> class C_PR7670<int>;

	template <bool B>
	struct S2 {
	static bool V;
	};

	extern template class S2<true>;

	template <typename T>
	struct S3 {
	void m();
	};

	template <typename T>
	inline void S3<T>::m() { }

	template <typename T>
	struct S4 {
	void m() { }
	};
	extern template struct S4<int>;

	void S4ImplicitInst() {
	S4<int> s;
	s.m();
	}

	struct S5 {
	S5(int x);
	};

	struct TS5 {
	S5 s;
	template <typename T>
	TS5(T y) : s(y) {}
	};

	// PR 8134
	template<class T> void f_PR8134(T);
	template<class T> void f_PR8134(T);
	void g_PR8134() { f_PR8134(0); f_PR8134('x'); }

	// rdar8580149
	template <typename T>
	struct S6;

	template <typename T, unsigned N>
	struct S6<const T [N]>
	{
	private:
	typedef const T t1[N];
	public:
	typedef t1& t2;
	};

	template<typename T>
	struct S7;

	template<unsigned N>
	struct S7<int[N]> : S6<const int[N]> { };

	// Zero-length template argument lists
	namespace ZeroLengthExplicitTemplateArgs {
	template<typename T> void h();

	struct Y {
	template<typename T> void f();
	};

	template<typename T>
	void f(T *ptr) {
	T::template g<>(17);
	ptr->template g2<>(17);
	h<T>();
	h<int>();
	Y y;
	y.f<int>();
	}

	struct X {
	template<typename T> static void g(T);
	template<typename T> void g2(T);
	};
	}

	namespace NonTypeTemplateParmContext {
	template<typename T, int inlineCapacity = 0> class Vector { };

	struct String {
	template<int inlineCapacity>
	static String adopt(Vector<char, inlineCapacity>&);
	};

	template<int inlineCapacity>
	inline bool equalIgnoringNullity(const Vector<char, inlineCapacity>& a, const String& b) { return false; }
	}

	// <rdar://problem/11112464>
	template< typename > class Foo;

	template< typename T >
	class Foo : protected T
	{
	public:
	Foo& operator=( const Foo& other );
	};

	template<typename...A> struct NestedExpansion {
	template<typename...B> auto f(A...a, B...b) -> decltype(g(a + b...));
	};
	template struct NestedExpansion<char, char, char>;

	namespace rdar13135282 {
	template < typename _Alloc >
	void foo(_Alloc = _Alloc());

	template < bool > class __pool;

	template < template < bool > class _PoolTp >
	struct __common_pool {
	typedef _PoolTp < 0 > pool_type;
	};

	template < template < bool > class _PoolTp >
	struct __common_pool_base : __common_pool < _PoolTp > {};

	template < template < bool > class _PoolTp >
	struct A : __common_pool_base < _PoolTp > {};

	template < typename _Poolp = A < __pool > >
	struct __mt_alloc {
	typedef typename _Poolp::pool_type __pool_type;
	__mt_alloc() {
	foo<__mt_alloc<> >();
	}
	};
	}

	namespace PR13020 {
	template<typename T>
	void f() {
	enum E {
	enumerator
	};

	T t = enumerator;
	}

	template void f<int>();
	}

	template<typename T> void doNotDeserialize() {}
	template<typename T> struct ContainsDoNotDeserialize {
	static int doNotDeserialize;
	};
	template<typename T> struct ContainsDoNotDeserialize2 {
	static void doNotDeserialize();
	};
	template<typename T> int ContainsDoNotDeserialize<T>::doNotDeserialize = 0;
	template<typename T> void ContainsDoNotDeserialize2<T>::doNotDeserialize() {}


	template<typename T> void DependentSpecializedFunc(T x) { x.foo(); }
	template<typename T> class DependentSpecializedFuncClass {
	void foo() {}
	friend void DependentSpecializedFunc<>(DependentSpecializedFuncClass);
	};

	namespace cyclic_module_load {
	// Reduced from a libc++ modules crasher.
	namespace std {
	template<class> class mask_array;
	template<class> class valarray {
	public:
	valarray(const valarray &v);
	};

	class gslice {
	valarray<int> x;
	valarray<int> stride() const { return x; }
	};

	template<class> class mask_array {
	template<class> friend class valarray;
	};
	}
	}

	namespace local_extern {
	template<typename T> int f() {
	extern int arr[3];
	{
	extern T arr;
	return sizeof(arr);
	}
	}
	template<typename T> int g() {
	extern int arr[3];
	extern T arr;
	return sizeof(arr);
	}
	}

	namespace rdar15468709a {
	template<typename> struct decay {};

	template<typename FooParamTy> auto foo(FooParamTy fooParam) -> decltype(fooParam);
	template<typename BarParamTy> auto bar(BarParamTy barParam) -> decay<decltype(barParam)>;

	struct B {};

	void crash() {
	B some;
	bar(some);
	}
	}

	namespace rdar15468709b {
	template<typename> struct decay {};

	template<typename... Foos> int returnsInt(Foos... foos);

	template<typename... FooParamTy> auto foo(FooParamTy... fooParam) -> decltype(returnsInt(fooParam...));
	template<typename... BarParamTy> auto bar(BarParamTy... barParam) -> decay<decltype(returnsInt(barParam...))>;

	struct B {};

	void crash() {
	B some;
	bar(some);
	}
	}

	namespace rdar15468709c {
	template<typename> struct decay {};

	template<class... Foos> int returnsInt(Foos... foos);

	template<typename FooParamTy> void foo(FooParamTy fooParam) { decltype(fooParam) a; }
	template<typename BarParamTy> auto bar(BarParamTy barParam) -> decay<decltype(barParam)>;

	struct B {};

	void crash() {
	B some;
	bar(some);
	}
	}

	namespace MemberSpecializationLocation {
	template<typename T> struct A { static int n; };
	}