test/SemaCXX/diagnostic-order.cpp - third_party/swift-clang - Git at Google

 // RUN: not %clang_cc1 -std=c++11 %s -fsyntax-only 2>&1 | FileCheck %s
 // RUN: %clang_cc1 -std=c++11 %s -fsyntax-only -DWARN 2>&1 | FileCheck %s --check-prefix=CHECK-WARN

 #ifndef WARN

 // Ensure that the diagnostics we produce for this situation appear in a
 // deterministic order. This requires ADL to provide lookup results in a
 // deterministic order.
 template<typename T, typename> struct Error { typedef typename T::error error; };
 struct X { template<typename T> friend typename Error<X, T>::error f(X, T); };
 struct Y { template<typename T> friend typename Error<Y, T>::error f(T, Y); };

 void g() {
   f(X(), Y());
 }

 // We don't really care which order these two diagnostics appear (although the
 // order below is source order, which seems best). The crucial fact is that
 // there is one single order that is stable across multiple runs of clang.
 //
 // CHECK: no type named 'error' in 'X'
 // CHECK: no type named 'error' in 'Y'
 // CHECK: no matching function for call to 'f'


 struct Oper {
   template<typename T, typename U = typename Error<Oper, T>::error> operator T();

   operator int*();
   operator float*();
   operator X*();
   operator Y*();

   operator int(*[1])();
   operator int(*[2])();
   operator int(*[3])();
   operator int(*[4])();
   operator int(*[5])();
   operator int(*[6])();
   operator int(*[7])();
   operator int(*[8])();
   operator float(*[1])();
   operator float(*[2])();
   operator float(*[3])();
   operator float(*[4])();
   operator float(*[5])();
   operator float(*[6])();
   operator float(*[7])();
   operator float(*[8])();
 };
 int *p = Oper() + 0;

 // CHECK: no type named 'error' in 'Oper'
 // CHECK: in instantiation of template class 'Error<Oper, int *>'
 // CHECK: no type named 'error' in 'Oper'
 // CHECK: in instantiation of template class 'Error<Oper, float *>'
 // CHECK: no type named 'error' in 'Oper'
 // CHECK: in instantiation of template class 'Error<Oper, X *>'
 // CHECK: no type named 'error' in 'Oper'
 // CHECK: in instantiation of template class 'Error<Oper, Y *>'

 #endif

 template<typename T> struct UndefButUsed {
   static inline int f();
   static int g() { return f(); }
 };
 int undef_but_used = UndefButUsed<int>::g() + UndefButUsed<float>::g() + UndefButUsed<char>::g() + UndefButUsed<void>::g();

 // CHECK-WARN: inline function 'UndefButUsed<int>::f' is not defined
 // CHECK-WARN: inline function 'UndefButUsed<float>::f' is not defined
 // CHECK-WARN: inline function 'UndefButUsed<char>::f' is not defined
 // CHECK-WARN: inline function 'UndefButUsed<void>::f' is not defined
	// RUN: not %clang_cc1 -std=c++11 %s -fsyntax-only 2>&1 \| FileCheck %s
	// RUN: %clang_cc1 -std=c++11 %s -fsyntax-only -DWARN 2>&1 \| FileCheck %s --check-prefix=CHECK-WARN

	#ifndef WARN

	// Ensure that the diagnostics we produce for this situation appear in a
	// deterministic order. This requires ADL to provide lookup results in a
	// deterministic order.
	template<typename T, typename> struct Error { typedef typename T::error error; };
	struct X { template<typename T> friend typename Error<X, T>::error f(X, T); };
	struct Y { template<typename T> friend typename Error<Y, T>::error f(T, Y); };

	void g() {
	f(X(), Y());
	}

	// We don't really care which order these two diagnostics appear (although the
	// order below is source order, which seems best). The crucial fact is that
	// there is one single order that is stable across multiple runs of clang.
	//
	// CHECK: no type named 'error' in 'X'
	// CHECK: no type named 'error' in 'Y'
	// CHECK: no matching function for call to 'f'


	struct Oper {
	template<typename T, typename U = typename Error<Oper, T>::error> operator T();

	operator int*();
	operator float*();
	operator X*();
	operator Y*();

	operator int(*[1])();
	operator int(*[2])();
	operator int(*[3])();
	operator int(*[4])();
	operator int(*[5])();
	operator int(*[6])();
	operator int(*[7])();
	operator int(*[8])();
	operator float(*[1])();
	operator float(*[2])();
	operator float(*[3])();
	operator float(*[4])();
	operator float(*[5])();
	operator float(*[6])();
	operator float(*[7])();
	operator float(*[8])();
	};
	int *p = Oper() + 0;

	// CHECK: no type named 'error' in 'Oper'
	// CHECK: in instantiation of template class 'Error<Oper, int *>'
	// CHECK: no type named 'error' in 'Oper'
	// CHECK: in instantiation of template class 'Error<Oper, float *>'
	// CHECK: no type named 'error' in 'Oper'
	// CHECK: in instantiation of template class 'Error<Oper, X *>'
	// CHECK: no type named 'error' in 'Oper'
	// CHECK: in instantiation of template class 'Error<Oper, Y *>'

	#endif

	template<typename T> struct UndefButUsed {
	static inline int f();
	static int g() { return f(); }
	};
	int undef_but_used = UndefButUsed<int>::g() + UndefButUsed<float>::g() + UndefButUsed<char>::g() + UndefButUsed<void>::g();

	// CHECK-WARN: inline function 'UndefButUsed<int>::f' is not defined
	// CHECK-WARN: inline function 'UndefButUsed<float>::f' is not defined
	// CHECK-WARN: inline function 'UndefButUsed<char>::f' is not defined
	// CHECK-WARN: inline function 'UndefButUsed<void>::f' is not defined