test/clang-tidy/checkers/performance-move-const-arg.cpp - clang-tools-extra - Git at Google

 // RUN: %check_clang_tidy %s performance-move-const-arg %t

 namespace std {
 template <typename>
 struct remove_reference;

 template <typename _Tp>
 struct remove_reference {
   typedef _Tp type;
 };

 template <typename _Tp>
 struct remove_reference<_Tp &> {
   typedef _Tp type;
 };

 template <typename _Tp>
 struct remove_reference<_Tp &&> {
   typedef _Tp type;
 };

 template <typename _Tp>
 constexpr typename std::remove_reference<_Tp>::type &&move(_Tp &&__t) {
   return static_cast<typename std::remove_reference<_Tp>::type &&>(__t);
 }

 template <typename _Tp>
 constexpr _Tp &&
 forward(typename remove_reference<_Tp>::type &__t) noexcept {
   return static_cast<_Tp &&>(__t);
 }

 } // namespace std

 class A {
 public:
   A() {}
   A(const A &rhs) {}
   A(A &&rhs) {}
 };

 struct TriviallyCopyable {
   int i;
 };

 void f(TriviallyCopyable) {}

 void g() {
   TriviallyCopyable obj;
   f(std::move(obj));
   // CHECK-MESSAGES: :[[@LINE-1]]:5: warning: std::move of the variable 'obj' of the trivially-copyable type 'TriviallyCopyable' has no effect; remove std::move() [performance-move-const-arg]
   // CHECK-FIXES: f(obj);
 }

 int f1() {
   return std::move(42);
   // CHECK-MESSAGES: :[[@LINE-1]]:10: warning: std::move of the expression of the trivially-copyable type 'int' has no effect; remove std::move() [performance-move-const-arg]
   // CHECK-FIXES: return 42;
 }

 int f2(int x2) {
   return std::move(x2);
   // CHECK-MESSAGES: :[[@LINE-1]]:10: warning: std::move of the variable 'x2' of the trivially-copyable type 'int'
   // CHECK-FIXES: return x2;
 }

 int *f3(int *x3) {
   return std::move(x3);
   // CHECK-MESSAGES: :[[@LINE-1]]:10: warning: std::move of the variable 'x3' of the trivially-copyable type 'int *'
   // CHECK-FIXES: return x3;
 }

 A f4(A x4) { return std::move(x4); }

 A f5(const A x5) {
   return std::move(x5);
   // CHECK-MESSAGES: :[[@LINE-1]]:10: warning: std::move of the const variable 'x5' has no effect; remove std::move() or make the variable non-const [performance-move-const-arg]
   // CHECK-FIXES: return x5;
 }

 template <typename T>
 T f6(const T x6) {
   return std::move(x6);
 }

 void f7() { int a = f6(10); }

 #define M1(x) x
 void f8() {
   const A a;
   M1(A b = std::move(a);)
   // CHECK-MESSAGES: :[[@LINE-1]]:12: warning: std::move of the const variable 'a' has no effect; remove std::move() or make the variable non-const
   // CHECK-FIXES: M1(A b = a;)
 }

 #define M2(x) std::move(x)
 int f9() { return M2(1); }

 template <typename T>
 T f10(const int x10) {
   return std::move(x10);
   // CHECK-MESSAGES: :[[@LINE-1]]:10: warning: std::move of the const variable 'x10' of the trivially-copyable type 'const int' has no effect; remove std::move() [performance-move-const-arg]
   // CHECK-FIXES: return x10;
 }
 void f11() {
   f10<int>(1);
   f10<double>(1);
 }

 class NoMoveSemantics {
 public:
   NoMoveSemantics();
   NoMoveSemantics(const NoMoveSemantics &);

   NoMoveSemantics &operator=(const NoMoveSemantics &);
 };

 void callByConstRef(const NoMoveSemantics &);
 void callByConstRef(int i, const NoMoveSemantics &);

 void moveToConstReferencePositives() {
   NoMoveSemantics obj;

   // Basic case.
   callByConstRef(std::move(obj));
   // CHECK-MESSAGES: :[[@LINE-1]]:18: warning: passing result of std::move() as
   // CHECK-FIXES: callByConstRef(obj);

   // Also works for second argument.
   callByConstRef(1, std::move(obj));
   // CHECK-MESSAGES: :[[@LINE-1]]:21: warning: passing result of std::move() as
   // CHECK-FIXES: callByConstRef(1, obj);

   // Works if std::move() applied to a temporary.
   callByConstRef(std::move(NoMoveSemantics()));
   // CHECK-MESSAGES: :[[@LINE-1]]:18: warning: passing result of std::move() as
   // CHECK-FIXES: callByConstRef(NoMoveSemantics());

   // Works if calling a copy constructor.
   NoMoveSemantics other(std::move(obj));
   // CHECK-MESSAGES: :[[@LINE-1]]:25: warning: passing result of std::move() as
   // CHECK-FIXES: NoMoveSemantics other(obj);

   // Works if calling assignment operator.
   other = std::move(obj);
   // CHECK-MESSAGES: :[[@LINE-1]]:11: warning: passing result of std::move() as
   // CHECK-FIXES: other = obj;
 }

 class MoveSemantics {
 public:
   MoveSemantics();
   MoveSemantics(MoveSemantics &&);

   MoveSemantics &operator=(MoveSemantics &&);
 };

 void callByValue(MoveSemantics);

 void callByRValueRef(MoveSemantics &&);

 template <class T>
 void templateFunction(T obj) {
   T other = std::move(obj);
 }

 #define M3(T, obj)            \
   do {                        \
     T other = std::move(obj); \
   } while (true)

 #define CALL(func) (func)()

 void moveToConstReferenceNegatives() {
   // No warning when actual move takes place.
   MoveSemantics move_semantics;
   callByValue(std::move(move_semantics));
   callByRValueRef(std::move(move_semantics));
   MoveSemantics other(std::move(move_semantics));
   other = std::move(move_semantics);

   // No warning if std::move() not used.
   NoMoveSemantics no_move_semantics;
   callByConstRef(no_move_semantics);

   // No warning if instantiating a template.
   templateFunction(no_move_semantics);

   // No warning inside of macro expansions.
   M3(NoMoveSemantics, no_move_semantics);

   // No warning inside of macro expansion, even if the macro expansion is inside
   // a lambda that is, in turn, an argument to a macro.
   CALL([no_move_semantics] { M3(NoMoveSemantics, no_move_semantics); });

   auto lambda = [] {};
   auto lambda2 = std::move(lambda);
 }

 class MoveOnly {
 public:
   MoveOnly(const MoveOnly &other) = delete;
   MoveOnly &operator=(const MoveOnly &other) = delete;
   MoveOnly(MoveOnly &&other) = default;
   MoveOnly &operator=(MoveOnly &&other) = default;
 };
 template <class T>
 void Q(T);
 void moveOnlyNegatives(MoveOnly val) {
   Q(std::move(val));
 }

 void fmovable(MoveSemantics);

 void lambda1() {
   auto f = [](MoveSemantics m) {
     fmovable(std::move(m));
   };
   f(MoveSemantics());
 }

 template<class T> struct function {};

 template<typename Result, typename... Args>
 class function<Result(Args...)> {
 public:
   function() = default;
   void operator()(Args... args) const {
     fmovable(std::forward<Args>(args)...);
   }
 };

 void functionInvocation() {
   function<void(MoveSemantics)> callback;
   MoveSemantics m;
   callback(std::move(m));
 }

 void lambda2() {
   function<void(MoveSemantics)> callback;

   auto f = [callback = std::move(callback)](MoveSemantics m) mutable {
     // CHECK-MESSAGES: :[[@LINE-1]]:24: warning: std::move of the variable 'callback' of the trivially-copyable type 'function<void (MoveSemantics)>' has no effect; remove std::move()
     // CHECK-FIXES: auto f = [callback = callback](MoveSemantics m) mutable {
     callback(std::move(m));
   };
   f(MoveSemantics());
 }
	// RUN: %check_clang_tidy %s performance-move-const-arg %t

	namespace std {
	template <typename>
	struct remove_reference;

	template <typename _Tp>
	struct remove_reference {
	typedef _Tp type;
	};

	template <typename _Tp>
	struct remove_reference<_Tp &> {
	typedef _Tp type;
	};

	template <typename _Tp>
	struct remove_reference<_Tp &&> {
	typedef _Tp type;
	};

	template <typename _Tp>
	constexpr typename std::remove_reference<_Tp>::type &&move(_Tp &&__t) {
	return static_cast<typename std::remove_reference<_Tp>::type &&>(__t);
	}

	template <typename _Tp>
	constexpr _Tp &&
	forward(typename remove_reference<_Tp>::type &__t) noexcept {
	return static_cast<_Tp &&>(__t);
	}

	} // namespace std

	class A {
	public:
	A() {}
	A(const A &rhs) {}
	A(A &&rhs) {}
	};

	struct TriviallyCopyable {
	int i;
	};

	void f(TriviallyCopyable) {}

	void g() {
	TriviallyCopyable obj;
	f(std::move(obj));
	// CHECK-MESSAGES: :[[@LINE-1]]:5: warning: std::move of the variable 'obj' of the trivially-copyable type 'TriviallyCopyable' has no effect; remove std::move() [performance-move-const-arg]
	// CHECK-FIXES: f(obj);
	}

	int f1() {
	return std::move(42);
	// CHECK-MESSAGES: :[[@LINE-1]]:10: warning: std::move of the expression of the trivially-copyable type 'int' has no effect; remove std::move() [performance-move-const-arg]
	// CHECK-FIXES: return 42;
	}

	int f2(int x2) {
	return std::move(x2);
	// CHECK-MESSAGES: :[[@LINE-1]]:10: warning: std::move of the variable 'x2' of the trivially-copyable type 'int'
	// CHECK-FIXES: return x2;
	}

	int f3(int x3) {
	return std::move(x3);
	// CHECK-MESSAGES: :[[@LINE-1]]:10: warning: std::move of the variable 'x3' of the trivially-copyable type 'int *'
	// CHECK-FIXES: return x3;
	}

	A f4(A x4) { return std::move(x4); }

	A f5(const A x5) {
	return std::move(x5);
	// CHECK-MESSAGES: :[[@LINE-1]]:10: warning: std::move of the const variable 'x5' has no effect; remove std::move() or make the variable non-const [performance-move-const-arg]
	// CHECK-FIXES: return x5;
	}

	template <typename T>
	T f6(const T x6) {
	return std::move(x6);
	}

	void f7() { int a = f6(10); }

	#define M1(x) x
	void f8() {
	const A a;
	M1(A b = std::move(a);)
	// CHECK-MESSAGES: :[[@LINE-1]]:12: warning: std::move of the const variable 'a' has no effect; remove std::move() or make the variable non-const
	// CHECK-FIXES: M1(A b = a;)
	}

	#define M2(x) std::move(x)
	int f9() { return M2(1); }

	template <typename T>
	T f10(const int x10) {
	return std::move(x10);
	// CHECK-MESSAGES: :[[@LINE-1]]:10: warning: std::move of the const variable 'x10' of the trivially-copyable type 'const int' has no effect; remove std::move() [performance-move-const-arg]
	// CHECK-FIXES: return x10;
	}
	void f11() {
	f10<int>(1);
	f10<double>(1);
	}

	class NoMoveSemantics {
	public:
	NoMoveSemantics();
	NoMoveSemantics(const NoMoveSemantics &);

	NoMoveSemantics &operator=(const NoMoveSemantics &);
	};

	void callByConstRef(const NoMoveSemantics &);
	void callByConstRef(int i, const NoMoveSemantics &);

	void moveToConstReferencePositives() {
	NoMoveSemantics obj;

	// Basic case.
	callByConstRef(std::move(obj));
	// CHECK-MESSAGES: :[[@LINE-1]]:18: warning: passing result of std::move() as
	// CHECK-FIXES: callByConstRef(obj);

	// Also works for second argument.
	callByConstRef(1, std::move(obj));
	// CHECK-MESSAGES: :[[@LINE-1]]:21: warning: passing result of std::move() as
	// CHECK-FIXES: callByConstRef(1, obj);

	// Works if std::move() applied to a temporary.
	callByConstRef(std::move(NoMoveSemantics()));
	// CHECK-MESSAGES: :[[@LINE-1]]:18: warning: passing result of std::move() as
	// CHECK-FIXES: callByConstRef(NoMoveSemantics());

	// Works if calling a copy constructor.
	NoMoveSemantics other(std::move(obj));
	// CHECK-MESSAGES: :[[@LINE-1]]:25: warning: passing result of std::move() as
	// CHECK-FIXES: NoMoveSemantics other(obj);

	// Works if calling assignment operator.
	other = std::move(obj);
	// CHECK-MESSAGES: :[[@LINE-1]]:11: warning: passing result of std::move() as
	// CHECK-FIXES: other = obj;
	}

	class MoveSemantics {
	public:
	MoveSemantics();
	MoveSemantics(MoveSemantics &&);

	MoveSemantics &operator=(MoveSemantics &&);
	};

	void callByValue(MoveSemantics);

	void callByRValueRef(MoveSemantics &&);

	template <class T>
	void templateFunction(T obj) {
	T other = std::move(obj);
	}

	#define M3(T, obj) \
	do { \
	T other = std::move(obj); \
	} while (true)

	#define CALL(func) (func)()

	void moveToConstReferenceNegatives() {
	// No warning when actual move takes place.
	MoveSemantics move_semantics;
	callByValue(std::move(move_semantics));
	callByRValueRef(std::move(move_semantics));
	MoveSemantics other(std::move(move_semantics));
	other = std::move(move_semantics);

	// No warning if std::move() not used.
	NoMoveSemantics no_move_semantics;
	callByConstRef(no_move_semantics);

	// No warning if instantiating a template.
	templateFunction(no_move_semantics);

	// No warning inside of macro expansions.
	M3(NoMoveSemantics, no_move_semantics);

	// No warning inside of macro expansion, even if the macro expansion is inside
	// a lambda that is, in turn, an argument to a macro.
	CALL([no_move_semantics] { M3(NoMoveSemantics, no_move_semantics); });

	auto lambda = [] {};
	auto lambda2 = std::move(lambda);
	}

	class MoveOnly {
	public:
	MoveOnly(const MoveOnly &other) = delete;
	MoveOnly &operator=(const MoveOnly &other) = delete;
	MoveOnly(MoveOnly &&other) = default;
	MoveOnly &operator=(MoveOnly &&other) = default;
	};
	template <class T>
	void Q(T);
	void moveOnlyNegatives(MoveOnly val) {
	Q(std::move(val));
	}

	void fmovable(MoveSemantics);

	void lambda1() {
	auto f = [](MoveSemantics m) {
	fmovable(std::move(m));
	};
	f(MoveSemantics());
	}

	template<class T> struct function {};

	template<typename Result, typename... Args>
	class function<Result(Args...)> {
	public:
	function() = default;
	void operator()(Args... args) const {
	fmovable(std::forward<Args>(args)...);
	}
	};

	void functionInvocation() {
	function<void(MoveSemantics)> callback;
	MoveSemantics m;
	callback(std::move(m));
	}

	void lambda2() {
	function<void(MoveSemantics)> callback;

	auto f = [callback = std::move(callback)](MoveSemantics m) mutable {
	// CHECK-MESSAGES: :[[@LINE-1]]:24: warning: std::move of the variable 'callback' of the trivially-copyable type 'function<void (MoveSemantics)>' has no effect; remove std::move()
	// CHECK-FIXES: auto f = [callback = callback](MoveSemantics m) mutable {
	callback(std::move(m));
	};
	f(MoveSemantics());
	}