include/sdbusplus/event.hpp - openbmc/sdbusplus - Gitiles

 #pragma once

 #include <systemd/sd-event.h>

 #include <chrono>
 #include <mutex>
 #include <utility>

 namespace sdbusplus
 {
 namespace event
 {
 class event;

 /** RAII holder for sd_event_sources */
 class source
 {
   public:
     friend event;

     source() = default;
     explicit source(event& e) : ev(&e) {}

     source(const source&) = delete;
     source(source&&);
     source& operator=(const source&) = delete;
     source& operator=(source&&);
     ~source();

   private:
     source(event& e, sd_event_source*& s) : ev(&e)
     {
         sourcep = std::exchange(s, nullptr);
     }

     event* ev = nullptr;
     sd_event_source* sourcep = nullptr;
 };

 /** sd-event wrapper for eventfd
  *
  *  This can be used to create something similar to a std::condition_variable
  *  but backed by sd-event.
  */
 class condition
 {
   public:
     friend event;

     condition() = delete;
     explicit condition(event& e) : condition_source(e) {}
     condition(const condition&) = delete;
     condition(condition&&);

     condition& operator=(const condition&) = delete;
     condition& operator=(condition&&);

     ~condition()
     {
         if (fd >= 0)
         {
             close(fd);
         }
     }

     /** Increment the signal count on the eventfd. */
     void signal();
     /** Acknowledge all pending signals on the eventfd. */
     void ack();

   private:
     condition(source&& s, int&& f) :
         condition_source(std::move(s)), fd(std::exchange(f, -1))
     {}

     source condition_source;
     int fd = -1;
 };

 /** sd-event based run-loop implementation.
  *
  *  This is sd-event is thread-safe in the sense that one thread may be
  *  executing 'run_one' while other threads create (or destruct) additional
  *  sources.  This might result in the 'run_one' exiting having done no
  *  work, but the state of the underlying sd-event structures is kept
  *  thread-safe.
  */
 class event
 {
   public:
     using time_resolution = std::chrono::microseconds;

     event();
     event(const event&) = delete;
     event(event&& e) = delete;

     ~event()
     {
         sd_event_unref(eventp);
     }

     /** Execute a single iteration of the run-loop (see sd_event_run). */
     void run_one(time_resolution timeout = time_resolution::max());
     /** Force a pending `run_one` to exit. */
     void break_run();

     /** Add a file-descriptor source to the sd-event (see sd_event_add_io). */
     source add_io(int fd, uint32_t events, sd_event_io_handler_t handler,
                   void* data);

     /** Add a eventfd-based sdbusplus::event::condition to the run-loop. */
     condition add_condition(sd_event_io_handler_t handler, void* data);

     /** Add a one shot timer source to the run-loop. */
     source add_oneshot_timer(
         sd_event_time_handler_t handler, void* data, time_resolution time,
         time_resolution accuracy = std::chrono::milliseconds(1));

     friend source;

   private:
     static int run_wakeup(sd_event_source*, int, uint32_t, void*);

     sd_event* eventp = nullptr;

     // Condition to allow 'break_run' to exit the run-loop.
     condition run_condition{*this};

     // Lock for the sd_event.
     //
     // There are cases where we need to lock the mutex from inside the context
     // of a sd-event callback, while the lock is already held.  Use a
     // recursive_mutex to allow this.
     std::recursive_mutex lock{};

     // Safely get the lock, possibly signaling the running 'run_one' to exit.
     template <bool Signal = true>
     std::unique_lock<std::recursive_mutex> obtain_lock();
     // When obtain_lock signals 'run_one' to exit, we want a priority of
     // obtaining the lock so that the 'run_one' task doesn't run and reclaim
     // the lock before the signaller can run.  This stage is first obtained
     // prior to getting the primary lock in order to set an order.
     std::mutex obtain_lock_stage{};
 };

 } // namespace event

 using event_t = event::event;
 using event_source_t = event::source;
 using event_cond_t = event::condition;

 } // namespace sdbusplus
	#pragma once

	#include <systemd/sd-event.h>

	#include <chrono>
	#include <mutex>
	#include <utility>

	namespace sdbusplus
	{
	namespace event
	{
	class event;

	/** RAII holder for sd_event_sources */
	class source
	{
	public:
	friend event;

	source() = default;
	explicit source(event& e) : ev(&e) {}

	source(const source&) = delete;
	source(source&&);
	source& operator=(const source&) = delete;
	source& operator=(source&&);
	~source();

	private:
	source(event& e, sd_event_source*& s) : ev(&e)
	{
	sourcep = std::exchange(s, nullptr);
	}

	event* ev = nullptr;
	sd_event_source* sourcep = nullptr;
	};

	/** sd-event wrapper for eventfd
	*
	* This can be used to create something similar to a std::condition_variable
	* but backed by sd-event.
	*/
	class condition
	{
	public:
	friend event;

	condition() = delete;
	explicit condition(event& e) : condition_source(e) {}
	condition(const condition&) = delete;
	condition(condition&&);

	condition& operator=(const condition&) = delete;
	condition& operator=(condition&&);

	~condition()
	{
	if (fd >= 0)
	{
	close(fd);
	}
	}

	/** Increment the signal count on the eventfd. */
	void signal();
	/** Acknowledge all pending signals on the eventfd. */
	void ack();

	private:
	condition(source&& s, int&& f) :
	condition_source(std::move(s)), fd(std::exchange(f, -1))
	{}

	source condition_source;
	int fd = -1;
	};

	/** sd-event based run-loop implementation.
	*
	* This is sd-event is thread-safe in the sense that one thread may be
	* executing 'run_one' while other threads create (or destruct) additional
	* sources. This might result in the 'run_one' exiting having done no
	* work, but the state of the underlying sd-event structures is kept
	* thread-safe.
	*/
	class event
	{
	public:
	using time_resolution = std::chrono::microseconds;

	event();
	event(const event&) = delete;
	event(event&& e) = delete;

	~event()
	{
	sd_event_unref(eventp);
	}

	/** Execute a single iteration of the run-loop (see sd_event_run). */
	void run_one(time_resolution timeout = time_resolution::max());
	/** Force a pending `run_one` to exit. */
	void break_run();

	/** Add a file-descriptor source to the sd-event (see sd_event_add_io). */
	source add_io(int fd, uint32_t events, sd_event_io_handler_t handler,
	void* data);

	/** Add a eventfd-based sdbusplus::event::condition to the run-loop. */
	condition add_condition(sd_event_io_handler_t handler, void* data);

	/** Add a one shot timer source to the run-loop. */
	source add_oneshot_timer(
	sd_event_time_handler_t handler, void* data, time_resolution time,
	time_resolution accuracy = std::chrono::milliseconds(1));

	friend source;

	private:
	static int run_wakeup(sd_event_source, int, uint32_t, void);

	sd_event* eventp = nullptr;

	// Condition to allow 'break_run' to exit the run-loop.
	condition run_condition{*this};

	// Lock for the sd_event.
	//
	// There are cases where we need to lock the mutex from inside the context
	// of a sd-event callback, while the lock is already held. Use a
	// recursive_mutex to allow this.
	std::recursive_mutex lock{};

	// Safely get the lock, possibly signaling the running 'run_one' to exit.
	template <bool Signal = true>
	std::unique_lock<std::recursive_mutex> obtain_lock();
	// When obtain_lock signals 'run_one' to exit, we want a priority of
	// obtaining the lock so that the 'run_one' task doesn't run and reclaim
	// the lock before the signaller can run. This stage is first obtained
	// prior to getting the primary lock in order to set an order.
	std::mutex obtain_lock_stage{};
	};

	} // namespace event

	using event_t = event::event;
	using event_source_t = event::source;
	using event_cond_t = event::condition;

	} // namespace sdbusplus