test/SemaCXX/warn-unreachable.cpp - third_party/swift-clang - Git at Google

 // RUN: %clang_cc1 %s -fcxx-exceptions -fexceptions -fsyntax-only -verify -fblocks -std=c++11 -Wunreachable-code-aggressive -Wno-unused-value -Wno-tautological-compare

 int &halt() __attribute__((noreturn));
 int &live();
 int dead();
 int liveti() throw(int);
 int (*livetip)() throw(int);

 int test1() {
   try {
     live();
   } catch (int i) {
     live();
   }
   return 1;
 }

 void test2() {
   try {
     live();
   } catch (int i) {
     live();
   }
   try {
     liveti();
   } catch (int i) {
     live();
   }
   try {
     livetip();
   } catch (int i) {
     live();
   }
   throw 1;
   dead();       // expected-warning {{will never be executed}}
 }


 void test3() {
   halt()
     --;         // expected-warning {{will never be executed}}
   // FIXME: The unreachable part is just the '?', but really all of this
   // code is unreachable and shouldn't be separately reported.
   halt()        // expected-warning {{will never be executed}}
     ?
     dead() : dead();
   live(),
     float
       (halt()); // expected-warning {{will never be executed}}
 }

 void test4() {
   struct S {
     int mem;
   } s;
   S &foor();
   halt(), foor()// expected-warning {{will never be executed}}
     .mem;
 }

 void test5() {
   struct S {
     int mem;
   } s;
   S &foonr() __attribute__((noreturn));
   foonr()
     .mem;       // expected-warning {{will never be executed}}
 }

 void test6() {
   struct S {
     ~S() { }
     S(int i) { }
   };
   live(),
     S
       (halt());  // expected-warning {{will never be executed}}
 }

 // Don't warn about unreachable code in template instantiations, as
 // they may only be unreachable in that specific instantiation.
 void isUnreachable();

 template <typename T> void test_unreachable_templates() {
   T::foo();
   isUnreachable();  // no-warning
 }

 struct TestUnreachableA {
   static void foo() __attribute__((noreturn));
 };
 struct TestUnreachableB {
   static void foo();
 };

 void test_unreachable_templates_harness() {
   test_unreachable_templates<TestUnreachableA>();
   test_unreachable_templates<TestUnreachableB>();
 }

 // Do warn about explict template specializations, as they represent
 // actual concrete functions that somebody wrote.

 template <typename T> void funcToSpecialize() {}
 template <> void funcToSpecialize<int>() {
   halt();
   dead(); // expected-warning {{will never be executed}}
 }

 // Handle 'try' code dominating a dead return.
 enum PR19040_test_return_t
 { PR19040_TEST_FAILURE };
 namespace PR19040_libtest
 {
   class A {
   public:
     ~A ();
   };
 }
 PR19040_test_return_t PR19040_fn1 ()
 {
     try
     {
         throw PR19040_libtest::A ();
     } catch (...)
     {
         return PR19040_TEST_FAILURE;
     }
     return PR19040_TEST_FAILURE; // expected-warning {{will never be executed}}
 }

 __attribute__((noreturn))
 void raze();

 namespace std {
 template<typename T> struct basic_string {
   basic_string(const T* x) {}
   ~basic_string() {};
 };
 typedef basic_string<char> string;
 }

 std::string testStr() {
   raze();
   return ""; // expected-warning {{'return' will never be executed}}
 }

 std::string testStrWarn(const char *s) {
   raze();
   return s; // expected-warning {{will never be executed}}
 }

 bool testBool() {
   raze();
   return true; // expected-warning {{'return' will never be executed}}
 }

 static const bool ConditionVar = 1;
 int test_global_as_conditionVariable() {
   if (ConditionVar)
     return 1;
   return 0; // no-warning
 }

 // Handle unreachable temporary destructors.
 class A {
 public:
   A();
   ~A();
 };

 __attribute__((noreturn))
 void raze(const A& x);

 void test_with_unreachable_tmp_dtors(int x) {
   raze(x ? A() : A()); // no-warning
 }

 // Test sizeof - sizeof in enum declaration.
 enum { BrownCow = sizeof(long) - sizeof(char) };
 enum { CowBrown = 8 - 1 };


 int test_enum_sizeof_arithmetic() {
   if (BrownCow)
     return 1;
   return 2;
 }

 int test_enum_arithmetic() {
   if (CowBrown)
     return 1;
   return 2; // expected-warning {{never be executed}}
 }

 int test_arithmetic() {
   if (8 -1)
     return 1;
   return 2; // expected-warning {{never be executed}}
 }

 int test_treat_const_bool_local_as_config_value() {
   const bool controlValue = false;
   if (!controlValue)
     return 1;
   test_treat_const_bool_local_as_config_value(); // no-warning
   return 0;
 }

 int test_treat_non_const_bool_local_as_non_config_value() {
   bool controlValue = false;
   if (!controlValue)
     return 1;
   // There is no warning here because 'controlValue' isn't really
   // a control value at all.  The CFG will not treat this
   // branch as unreachable.
   test_treat_non_const_bool_local_as_non_config_value(); // no-warning
   return 0;
 }

 void test_do_while(int x) {
   // Handle trivial expressions with
   // implicit casts to bool.
   do {
     break;
   } while (0); // no-warning
 }

 class Frobozz {
 public:
   Frobozz(int x);
   ~Frobozz();
 };

 Frobozz test_return_object(int flag) {
   return Frobozz(flag);
   return Frobozz(42);  // expected-warning {{'return' will never be executed}}
 }

 Frobozz test_return_object_control_flow(int flag) {
   return Frobozz(flag);
   return Frobozz(flag ? 42 : 24); // expected-warning {{code will never be executed}}
 }

 void somethingToCall();

 static constexpr bool isConstExprConfigValue() { return true; }

 int test_const_expr_config_value() {
  if (isConstExprConfigValue()) {
    somethingToCall();
    return 0;
  }
  somethingToCall(); // no-warning
  return 1;
 }
 int test_const_expr_config_value_2() {
  if (!isConstExprConfigValue()) {
    somethingToCall(); // no-warning
    return 0;
  }
  somethingToCall();
  return 1;
 }

 class Frodo {
 public:
   static const bool aHobbit = true;
 };

 void test_static_class_var() {
   if (Frodo::aHobbit)
     somethingToCall();
   else
     somethingToCall(); // no-warning
 }

 void test_static_class_var(Frodo &F) {
   if (F.aHobbit)
     somethingToCall();
   else
     somethingToCall(); // no-warning
 }

 void test_unreachable_for_null_increment() {
   for (unsigned i = 0; i < 10 ; ) // no-warning
     break;
 }

 void test_unreachable_forrange_increment() {
   int x[10] = { 0 };
   for (auto i : x) { // expected-warning {{loop will run at most once (loop increment never executed)}}
     break;
   }
 }

 void calledFun() {}

 // Test "silencing" with parentheses.
 void test_with_paren_silencing(int x) {
   if (false) calledFun(); // expected-warning {{will never be executed}} expected-note {{silence by adding parentheses to mark code as explicitly dead}}
   if ((false)) calledFun(); // no-warning

   if (true) // expected-note {{silence by adding parentheses to mark code as explicitly dead}}
     calledFun();
   else
     calledFun(); // expected-warning {{will never be executed}}

   if ((true))
     calledFun();
   else
     calledFun(); // no-warning

   if (!true) // expected-note {{silence by adding parentheses to mark code as explicitly dead}}
     calledFun(); // expected-warning {{code will never be executed}}
   else
     calledFun();

   if ((!true))
     calledFun(); // no-warning
   else
     calledFun();

   if (!(true))
     calledFun(); // no-warning
   else
     calledFun();
 }

 void test_with_paren_silencing_impcast(int x) {
   if (0) calledFun(); // expected-warning {{will never be executed}} expected-note {{silence by adding parentheses to mark code as explicitly dead}}
   if ((0)) calledFun(); // no-warning

   if (1) // expected-note {{silence by adding parentheses to mark code as explicitly dead}}
     calledFun();
   else
     calledFun(); // expected-warning {{will never be executed}}

   if ((1))
     calledFun();
   else
     calledFun(); // no-warning

   if (!1) // expected-note {{silence by adding parentheses to mark code as explicitly dead}}
     calledFun(); // expected-warning {{code will never be executed}}
   else
     calledFun();

   if ((!1))
     calledFun(); // no-warning
   else
     calledFun();

   if (!(1))
     calledFun(); // no-warning
   else
     calledFun();
 }

 void tautological_compare(bool x, int y) {
   if (x > 10)           // expected-note {{silence}}
     calledFun();        // expected-warning {{will never be executed}}
   if (10 < x)           // expected-note {{silence}}
     calledFun();        // expected-warning {{will never be executed}}
   if (x == 10)          // expected-note {{silence}}
     calledFun();        // expected-warning {{will never be executed}}

   if (x < 10)           // expected-note {{silence}}
     calledFun();
   else
     calledFun();        // expected-warning {{will never be executed}}
   if (10 > x)           // expected-note {{silence}}
     calledFun();
   else
     calledFun();        // expected-warning {{will never be executed}}
   if (x != 10)          // expected-note {{silence}}
     calledFun();
   else
     calledFun();        // expected-warning {{will never be executed}}

   if (y != 5 && y == 5) // expected-note {{silence}}
     calledFun();        // expected-warning {{will never be executed}}

   if (y > 5 && y < 4)   // expected-note {{silence}}
     calledFun();        // expected-warning {{will never be executed}}

   if (y < 10 || y > 5)  // expected-note {{silence}}
     calledFun();
   else
     calledFun();        // expected-warning {{will never be executed}}

   // TODO: Extend warning to the following code:
   if (x < -1)
     calledFun();
   if (x == -1)
     calledFun();

   if (x != -1)
     calledFun();
   else
     calledFun();
   if (-1 > x)
     calledFun();
   else
     calledFun();

   if (y == -1 && y != -1)
     calledFun();
 }
	// RUN: %clang_cc1 %s -fcxx-exceptions -fexceptions -fsyntax-only -verify -fblocks -std=c++11 -Wunreachable-code-aggressive -Wno-unused-value -Wno-tautological-compare

	int &halt() __attribute__((noreturn));
	int &live();
	int dead();
	int liveti() throw(int);
	int (*livetip)() throw(int);

	int test1() {
	try {
	live();
	} catch (int i) {
	live();
	}
	return 1;
	}

	void test2() {
	try {
	live();
	} catch (int i) {
	live();
	}
	try {
	liveti();
	} catch (int i) {
	live();
	}
	try {
	livetip();
	} catch (int i) {
	live();
	}
	throw 1;
	dead(); // expected-warning {{will never be executed}}
	}


	void test3() {
	halt()
	--; // expected-warning {{will never be executed}}
	// FIXME: The unreachable part is just the '?', but really all of this
	// code is unreachable and shouldn't be separately reported.
	halt() // expected-warning {{will never be executed}}
	?
	dead() : dead();
	live(),
	float
	(halt()); // expected-warning {{will never be executed}}
	}

	void test4() {
	struct S {
	int mem;
	} s;
	S &foor();
	halt(), foor()// expected-warning {{will never be executed}}
	.mem;
	}

	void test5() {
	struct S {
	int mem;
	} s;
	S &foonr() __attribute__((noreturn));
	foonr()
	.mem; // expected-warning {{will never be executed}}
	}

	void test6() {
	struct S {
	~S() { }
	S(int i) { }
	};
	live(),
	S
	(halt()); // expected-warning {{will never be executed}}
	}

	// Don't warn about unreachable code in template instantiations, as
	// they may only be unreachable in that specific instantiation.
	void isUnreachable();

	template <typename T> void test_unreachable_templates() {
	T::foo();
	isUnreachable(); // no-warning
	}

	struct TestUnreachableA {
	static void foo() __attribute__((noreturn));
	};
	struct TestUnreachableB {
	static void foo();
	};

	void test_unreachable_templates_harness() {
	test_unreachable_templates<TestUnreachableA>();
	test_unreachable_templates<TestUnreachableB>();
	}

	// Do warn about explict template specializations, as they represent
	// actual concrete functions that somebody wrote.

	template <typename T> void funcToSpecialize() {}
	template <> void funcToSpecialize<int>() {
	halt();
	dead(); // expected-warning {{will never be executed}}
	}

	// Handle 'try' code dominating a dead return.
	enum PR19040_test_return_t
	{ PR19040_TEST_FAILURE };
	namespace PR19040_libtest
	{
	class A {
	public:
	~A ();
	};
	}
	PR19040_test_return_t PR19040_fn1 ()
	{
	try
	{
	throw PR19040_libtest::A ();
	} catch (...)
	{
	return PR19040_TEST_FAILURE;
	}
	return PR19040_TEST_FAILURE; // expected-warning {{will never be executed}}
	}

	__attribute__((noreturn))
	void raze();

	namespace std {
	template<typename T> struct basic_string {
	basic_string(const T* x) {}
	~basic_string() {};
	};
	typedef basic_string<char> string;
	}

	std::string testStr() {
	raze();
	return ""; // expected-warning {{'return' will never be executed}}
	}

	std::string testStrWarn(const char *s) {
	raze();
	return s; // expected-warning {{will never be executed}}
	}

	bool testBool() {
	raze();
	return true; // expected-warning {{'return' will never be executed}}
	}

	static const bool ConditionVar = 1;
	int test_global_as_conditionVariable() {
	if (ConditionVar)
	return 1;
	return 0; // no-warning
	}

	// Handle unreachable temporary destructors.
	class A {
	public:
	A();
	~A();
	};

	__attribute__((noreturn))
	void raze(const A& x);

	void test_with_unreachable_tmp_dtors(int x) {
	raze(x ? A() : A()); // no-warning
	}

	// Test sizeof - sizeof in enum declaration.
	enum { BrownCow = sizeof(long) - sizeof(char) };
	enum { CowBrown = 8 - 1 };


	int test_enum_sizeof_arithmetic() {
	if (BrownCow)
	return 1;
	return 2;
	}

	int test_enum_arithmetic() {
	if (CowBrown)
	return 1;
	return 2; // expected-warning {{never be executed}}
	}

	int test_arithmetic() {
	if (8 -1)
	return 1;
	return 2; // expected-warning {{never be executed}}
	}

	int test_treat_const_bool_local_as_config_value() {
	const bool controlValue = false;
	if (!controlValue)
	return 1;
	test_treat_const_bool_local_as_config_value(); // no-warning
	return 0;
	}

	int test_treat_non_const_bool_local_as_non_config_value() {
	bool controlValue = false;
	if (!controlValue)
	return 1;
	// There is no warning here because 'controlValue' isn't really
	// a control value at all. The CFG will not treat this
	// branch as unreachable.
	test_treat_non_const_bool_local_as_non_config_value(); // no-warning
	return 0;
	}

	void test_do_while(int x) {
	// Handle trivial expressions with
	// implicit casts to bool.
	do {
	break;
	} while (0); // no-warning
	}

	class Frobozz {
	public:
	Frobozz(int x);
	~Frobozz();
	};

	Frobozz test_return_object(int flag) {
	return Frobozz(flag);
	return Frobozz(42); // expected-warning {{'return' will never be executed}}
	}

	Frobozz test_return_object_control_flow(int flag) {
	return Frobozz(flag);
	return Frobozz(flag ? 42 : 24); // expected-warning {{code will never be executed}}
	}

	void somethingToCall();

	static constexpr bool isConstExprConfigValue() { return true; }

	int test_const_expr_config_value() {
	if (isConstExprConfigValue()) {
	somethingToCall();
	return 0;
	}
	somethingToCall(); // no-warning
	return 1;
	}
	int test_const_expr_config_value_2() {
	if (!isConstExprConfigValue()) {
	somethingToCall(); // no-warning
	return 0;
	}
	somethingToCall();
	return 1;
	}

	class Frodo {
	public:
	static const bool aHobbit = true;
	};

	void test_static_class_var() {
	if (Frodo::aHobbit)
	somethingToCall();
	else
	somethingToCall(); // no-warning
	}

	void test_static_class_var(Frodo &F) {
	if (F.aHobbit)
	somethingToCall();
	else
	somethingToCall(); // no-warning
	}

	void test_unreachable_for_null_increment() {
	for (unsigned i = 0; i < 10 ; ) // no-warning
	break;
	}

	void test_unreachable_forrange_increment() {
	int x[10] = { 0 };
	for (auto i : x) { // expected-warning {{loop will run at most once (loop increment never executed)}}
	break;
	}
	}

	void calledFun() {}

	// Test "silencing" with parentheses.
	void test_with_paren_silencing(int x) {
	if (false) calledFun(); // expected-warning {{will never be executed}} expected-note {{silence by adding parentheses to mark code as explicitly dead}}
	if ((false)) calledFun(); // no-warning

	if (true) // expected-note {{silence by adding parentheses to mark code as explicitly dead}}
	calledFun();
	else
	calledFun(); // expected-warning {{will never be executed}}

	if ((true))
	calledFun();
	else
	calledFun(); // no-warning

	if (!true) // expected-note {{silence by adding parentheses to mark code as explicitly dead}}
	calledFun(); // expected-warning {{code will never be executed}}
	else
	calledFun();

	if ((!true))
	calledFun(); // no-warning
	else
	calledFun();

	if (!(true))
	calledFun(); // no-warning
	else
	calledFun();
	}

	void test_with_paren_silencing_impcast(int x) {
	if (0) calledFun(); // expected-warning {{will never be executed}} expected-note {{silence by adding parentheses to mark code as explicitly dead}}
	if ((0)) calledFun(); // no-warning

	if (1) // expected-note {{silence by adding parentheses to mark code as explicitly dead}}
	calledFun();
	else
	calledFun(); // expected-warning {{will never be executed}}

	if ((1))
	calledFun();
	else
	calledFun(); // no-warning

	if (!1) // expected-note {{silence by adding parentheses to mark code as explicitly dead}}
	calledFun(); // expected-warning {{code will never be executed}}
	else
	calledFun();

	if ((!1))
	calledFun(); // no-warning
	else
	calledFun();

	if (!(1))
	calledFun(); // no-warning
	else
	calledFun();
	}

	void tautological_compare(bool x, int y) {
	if (x > 10) // expected-note {{silence}}
	calledFun(); // expected-warning {{will never be executed}}
	if (10 < x) // expected-note {{silence}}
	calledFun(); // expected-warning {{will never be executed}}
	if (x == 10) // expected-note {{silence}}
	calledFun(); // expected-warning {{will never be executed}}

	if (x < 10) // expected-note {{silence}}
	calledFun();
	else
	calledFun(); // expected-warning {{will never be executed}}
	if (10 > x) // expected-note {{silence}}
	calledFun();
	else
	calledFun(); // expected-warning {{will never be executed}}
	if (x != 10) // expected-note {{silence}}
	calledFun();
	else
	calledFun(); // expected-warning {{will never be executed}}

	if (y != 5 && y == 5) // expected-note {{silence}}
	calledFun(); // expected-warning {{will never be executed}}

	if (y > 5 && y < 4) // expected-note {{silence}}
	calledFun(); // expected-warning {{will never be executed}}

	if (y < 10 \|\| y > 5) // expected-note {{silence}}
	calledFun();
	else
	calledFun(); // expected-warning {{will never be executed}}

	// TODO: Extend warning to the following code:
	if (x < -1)
	calledFun();
	if (x == -1)
	calledFun();

	if (x != -1)
	calledFun();
	else
	calledFun();
	if (-1 > x)
	calledFun();
	else
	calledFun();

	if (y == -1 && y != -1)
	calledFun();
	}