clang-tools-extra/test/clang-tidy/checkers/bugprone-spuriously-wake-up-functions.cpp - llvm-project - Git at Google

 // RUN: %check_clang_tidy %s bugprone-spuriously-wake-up-functions %t -- --
 #define NULL 0

 namespace std {
 using intmax_t = int;

 template <intmax_t N, intmax_t D = 1>
 class ratio {
 public:
   static constexpr intmax_t num = 0;
   static constexpr intmax_t den = 0;
   typedef ratio<num, den> type;
 };
 typedef ratio<1, 1000> milli;
 namespace chrono {

 template <class Rep, class Period = ratio<1>>
 class duration {
 public:
   using rep = Rep;
   using period = Period;

 public:
   constexpr duration() = default;
   template <class Rep2>
   constexpr explicit duration(const Rep2 &r);
   template <class Rep2, class Period2>
   constexpr duration(const duration<Rep2, Period2> &d);
   ~duration() = default;
   duration(const duration &) = default;
 };

 template <class Clock, class Duration = typename Clock::duration>
 class time_point {
 public:
   using clock = Clock;
   using duration = Duration;

 public:
   constexpr time_point();
   constexpr explicit time_point(const duration &d);
   template <class Duration2>
   constexpr time_point(const time_point<clock, Duration2> &t);
 };

 using milliseconds = duration<int, milli>;

 class system_clock {
 public:
   typedef milliseconds duration;
   typedef duration::rep rep;
   typedef duration::period period;
   typedef chrono::time_point<system_clock> time_point;

   static time_point now() noexcept;
 };
 } // namespace chrono

 class mutex;
 template <class Mutex>
 class unique_lock {
 public:
   typedef Mutex mutex_type;

   unique_lock() noexcept;
   explicit unique_lock(mutex_type &m);
 };

 class mutex {
 public:
   constexpr mutex() noexcept;
   ~mutex();
   mutex(const mutex &) = delete;
   mutex &operator=(const mutex &) = delete;
 };

 enum class cv_status {
   no_timeout,
   timeout
 };

 class condition_variable {
 public:
   condition_variable();
   ~condition_variable();
   condition_variable(const condition_variable &) = delete;

   void wait(unique_lock<mutex> &lock);
   template <class Predicate>
   void wait(unique_lock<mutex> &lock, Predicate pred);
   template <class Clock, class Duration>
   cv_status wait_until(unique_lock<mutex> &lock,
                        const chrono::time_point<Clock, Duration> &abs_time){};
   template <class Clock, class Duration, class Predicate>
   bool wait_until(unique_lock<mutex> &lock,
                   const chrono::time_point<Clock, Duration> &abs_time,
                   Predicate pred){};
   template <class Rep, class Period>
   cv_status wait_for(unique_lock<mutex> &lock,
                      const chrono::duration<Rep, Period> &rel_time){};
   template <class Rep, class Period, class Predicate>
   bool wait_for(unique_lock<mutex> &lock,
                 const chrono::duration<Rep, Period> &rel_time,
                 Predicate pred){};
 };

 } // namespace std

 struct Node1 {
   void *Node1;
   struct Node1 *next;
 };

 static Node1 list;
 static std::mutex m;
 static std::condition_variable condition;

 void consume_list_element(std::condition_variable &condition) {
   std::unique_lock<std::mutex> lk(m);

   if (list.next == nullptr) {
     condition.wait(lk);
     // CHECK-MESSAGES: :[[@LINE-1]]:15: warning: 'wait' should be placed inside a while statement or used with a conditional parameter [bugprone-spuriously-wake-up-functions]
   }

   while (list.next == nullptr) {
     condition.wait(lk);
   }

   do {
     condition.wait(lk);
   } while (list.next == nullptr);

   for (;; list.next == nullptr) {
     condition.wait(lk);
   }

   if (list.next == nullptr) {
     while (list.next == nullptr) {
       condition.wait(lk);
     }
   }

   if (list.next == nullptr) {
     do {
       condition.wait(lk);
     } while (list.next == nullptr);
   }

   if (list.next == nullptr) {
     for (;; list.next == nullptr) {
       condition.wait(lk);
     }
   }
   using durtype = std::chrono::duration<int, std::milli>;
   durtype dur = std::chrono::duration<int, std::milli>();
   if (list.next == nullptr) {
     condition.wait_for(lk, dur);
     // CHECK-MESSAGES: :[[@LINE-1]]:15: warning: 'wait_for' should be placed inside a while statement or used with a conditional parameter [bugprone-spuriously-wake-up-functions]
   }
   if (list.next == nullptr) {
     condition.wait_for(lk, dur, [] { return 1; });
   }
   while (list.next == nullptr) {
     condition.wait_for(lk, dur);
   }
   do {
     condition.wait_for(lk, dur);
   } while (list.next == nullptr);
   for (;; list.next == nullptr) {
     condition.wait_for(lk, dur);
   }

   auto now = std::chrono::system_clock::now();
   if (list.next == nullptr) {
     condition.wait_until(lk, now);
     // CHECK-MESSAGES: :[[@LINE-1]]:15: warning: 'wait_until' should be placed inside a while statement or used with a conditional parameter [bugprone-spuriously-wake-up-functions]
   }
   if (list.next == nullptr) {
     condition.wait_until(lk, now, [] { return 1; });
   }
   while (list.next == nullptr) {
     condition.wait_until(lk, now);
   }
   do {
     condition.wait_until(lk, now);
   } while (list.next == nullptr);
   for (;; list.next == nullptr) {
     condition.wait_until(lk, now);
   }
 }
	// RUN: %check_clang_tidy %s bugprone-spuriously-wake-up-functions %t -- --
	#define NULL 0

	namespace std {
	using intmax_t = int;

	template <intmax_t N, intmax_t D = 1>
	class ratio {
	public:
	static constexpr intmax_t num = 0;
	static constexpr intmax_t den = 0;
	typedef ratio<num, den> type;
	};
	typedef ratio<1, 1000> milli;
	namespace chrono {

	template <class Rep, class Period = ratio<1>>
	class duration {
	public:
	using rep = Rep;
	using period = Period;

	public:
	constexpr duration() = default;
	template <class Rep2>
	constexpr explicit duration(const Rep2 &r);
	template <class Rep2, class Period2>
	constexpr duration(const duration<Rep2, Period2> &d);
	~duration() = default;
	duration(const duration &) = default;
	};

	template <class Clock, class Duration = typename Clock::duration>
	class time_point {
	public:
	using clock = Clock;
	using duration = Duration;

	public:
	constexpr time_point();
	constexpr explicit time_point(const duration &d);
	template <class Duration2>
	constexpr time_point(const time_point<clock, Duration2> &t);
	};

	using milliseconds = duration<int, milli>;

	class system_clock {
	public:
	typedef milliseconds duration;
	typedef duration::rep rep;
	typedef duration::period period;
	typedef chrono::time_point<system_clock> time_point;

	static time_point now() noexcept;
	};
	} // namespace chrono

	class mutex;
	template <class Mutex>
	class unique_lock {
	public:
	typedef Mutex mutex_type;

	unique_lock() noexcept;
	explicit unique_lock(mutex_type &m);
	};

	class mutex {
	public:
	constexpr mutex() noexcept;
	~mutex();
	mutex(const mutex &) = delete;
	mutex &operator=(const mutex &) = delete;
	};

	enum class cv_status {
	no_timeout,
	timeout
	};

	class condition_variable {
	public:
	condition_variable();
	~condition_variable();
	condition_variable(const condition_variable &) = delete;

	void wait(unique_lock<mutex> &lock);
	template <class Predicate>
	void wait(unique_lock<mutex> &lock, Predicate pred);
	template <class Clock, class Duration>
	cv_status wait_until(unique_lock<mutex> &lock,
	const chrono::time_point<Clock, Duration> &abs_time){};
	template <class Clock, class Duration, class Predicate>
	bool wait_until(unique_lock<mutex> &lock,
	const chrono::time_point<Clock, Duration> &abs_time,
	Predicate pred){};
	template <class Rep, class Period>
	cv_status wait_for(unique_lock<mutex> &lock,
	const chrono::duration<Rep, Period> &rel_time){};
	template <class Rep, class Period, class Predicate>
	bool wait_for(unique_lock<mutex> &lock,
	const chrono::duration<Rep, Period> &rel_time,
	Predicate pred){};
	};

	} // namespace std

	struct Node1 {
	void *Node1;
	struct Node1 *next;
	};

	static Node1 list;
	static std::mutex m;
	static std::condition_variable condition;

	void consume_list_element(std::condition_variable &condition) {
	std::unique_lock<std::mutex> lk(m);

	if (list.next == nullptr) {
	condition.wait(lk);
	// CHECK-MESSAGES: :[[@LINE-1]]:15: warning: 'wait' should be placed inside a while statement or used with a conditional parameter [bugprone-spuriously-wake-up-functions]
	}

	while (list.next == nullptr) {
	condition.wait(lk);
	}

	do {
	condition.wait(lk);
	} while (list.next == nullptr);

	for (;; list.next == nullptr) {
	condition.wait(lk);
	}

	if (list.next == nullptr) {
	while (list.next == nullptr) {
	condition.wait(lk);
	}
	}

	if (list.next == nullptr) {
	do {
	condition.wait(lk);
	} while (list.next == nullptr);
	}

	if (list.next == nullptr) {
	for (;; list.next == nullptr) {
	condition.wait(lk);
	}
	}
	using durtype = std::chrono::duration<int, std::milli>;
	durtype dur = std::chrono::duration<int, std::milli>();
	if (list.next == nullptr) {
	condition.wait_for(lk, dur);
	// CHECK-MESSAGES: :[[@LINE-1]]:15: warning: 'wait_for' should be placed inside a while statement or used with a conditional parameter [bugprone-spuriously-wake-up-functions]
	}
	if (list.next == nullptr) {
	condition.wait_for(lk, dur, [] { return 1; });
	}
	while (list.next == nullptr) {
	condition.wait_for(lk, dur);
	}
	do {
	condition.wait_for(lk, dur);
	} while (list.next == nullptr);
	for (;; list.next == nullptr) {
	condition.wait_for(lk, dur);
	}

	auto now = std::chrono::system_clock::now();
	if (list.next == nullptr) {
	condition.wait_until(lk, now);
	// CHECK-MESSAGES: :[[@LINE-1]]:15: warning: 'wait_until' should be placed inside a while statement or used with a conditional parameter [bugprone-spuriously-wake-up-functions]
	}
	if (list.next == nullptr) {
	condition.wait_until(lk, now, [] { return 1; });
	}
	while (list.next == nullptr) {
	condition.wait_until(lk, now);
	}
	do {
	condition.wait_until(lk, now);
	} while (list.next == nullptr);
	for (;; list.next == nullptr) {
	condition.wait_until(lk, now);
	}
	}