src/async/context.cpp - openbmc/sdbusplus - Gitiles

 #include <poll.h>
 #include <systemd/sd-bus.h>

 #include <sdbusplus/async/context.hpp>

 namespace sdbusplus::async
 {

 namespace details
 {

 /* The sd_bus_wait/process completion event.
  *
  *  The wait/process handshake is modelled as a Sender with the the worker
  *  task `co_await`ing Senders over and over.  This class is the completion
  *  handling for the Sender (to get it back to the Receiver, ie. the worker).
  */
 struct wait_process_completion : bus::details::bus_friend
 {
     explicit wait_process_completion(context& ctx) : ctx(ctx) {}
     virtual ~wait_process_completion() = default;

     // Called by the `caller` to indicate the Sender is completed.
     virtual void complete() noexcept = 0;

     // Arm the completion event.
     void arm() noexcept;

     // Data to share with the worker.
     context& ctx;
     pollfd fd{};
     int timeout = 0;

     static task<> loop(context& ctx);
     static void wait_once(context& ctx);
 };

 /* The completion template based on receiver type.
  *
  * The type of the receivers (typically the co_awaiter) is only known by
  * a template, so we need a sub-class of completion to hold the receiver.
  */
 template <execution::receiver R>
 struct wait_process_operation : public wait_process_completion
 {
     wait_process_operation(context& ctx, R r) :
         wait_process_completion(ctx), receiver(std::move(r))
     {}

     wait_process_operation(wait_process_operation&&) = delete;

     void complete() noexcept override final
     {
         execution::set_value(std::move(this->receiver));
     }

     friend void tag_invoke(execution::start_t,
                            wait_process_operation& self) noexcept
     {
         self.arm();
     }

     R receiver;
 };

 /* The sender for the wait/process event. */
 struct wait_process_sender
 {
     explicit wait_process_sender(context& ctx) : ctx(ctx){};

     friend auto tag_invoke(execution::get_completion_signatures_t,
                            const wait_process_sender&, auto)
         -> execution::completion_signatures<execution::set_value_t()>;

     template <execution::receiver R>
     friend auto tag_invoke(execution::connect_t, wait_process_sender&& self,
                            R r) -> wait_process_operation<R>
     {
         // Create the completion for the wait.
         return {self.ctx, std::move(r)};
     }

   private:
     context& ctx;
 };

 task<> wait_process_completion::loop(context& ctx)
 {
     while (1)
     {
         // Handle the next sdbus event.
         co_await wait_process_sender(ctx);

         // Completion likely happened on the context 'caller' thread, so
         // we need to switch to the worker thread.
         co_await execution::schedule(ctx.loop.get_scheduler());
     }
 }

 } // namespace details

 context::~context() noexcept(false)
 {
     if (worker_thread.joinable())
     {
         throw std::logic_error(
             "sdbusplus::async::context destructed without completion.");
     }
 }

 void context::caller_run(task<> startup)
 {
     // Start up the worker thread.
     worker_thread = std::thread{[this, startup = std::move(startup)]() mutable {
         worker_run(std::move(startup));
     }};

     while (1)
     {
         // Handle 'sd_bus_wait's.
         details::wait_process_completion::wait_once(*this);
     }

     // TODO: We can't actually get here.  Need to deal with stop conditions and
     // then we'll need this code.
     loop.finish();
     if (worker_thread.joinable())
     {
         worker_thread.join();
     }
 }

 void context::worker_run(task<> startup)
 {
     // Begin the 'startup' task.
     // This shouldn't start detached because we want to be able to forward
     // failures back to the 'run'.  execution::ensure_started isn't
     // implemented yet, so we don't have a lot of other options.
     execution::start_detached(std::move(startup));

     // Also start up the sdbus 'wait/process' loop.
     execution::start_detached(details::wait_process_completion::loop(*this));

     // Run the execution::run_loop to handle all the tasks.
     loop.run();
 }

 void details::wait_process_completion::arm() noexcept
 {
     // Call process.  True indicates something was handled and we do not
     // need to `wait`, because there might be yet another pending operation
     // to process, so immediately signal the operation as complete.
     if (ctx.get_bus().process_discard())
     {
         this->complete();
         return;
     }

     // We need to call wait now, so formulate all the data that the 'caller'
     // needs.

     // Get the bus' pollfd data.
     auto b = get_busp(ctx.get_bus());
     fd = pollfd{sd_bus_get_fd(b), static_cast<short>(sd_bus_get_events(b)), 0};

     // Get the bus' timeout.
     uint64_t to_nsec = 0;
     sd_bus_get_timeout(b, &to_nsec);

     if (to_nsec == UINT64_MAX)
     {
         // sd_bus_get_timeout returns UINT64_MAX to indicate 'wait forever'.
         // Turn this into a negative number for `poll`.
         timeout = -1;
     }
     else
     {
         // Otherwise, convert usec from sd_bus to msec for poll.
         // sd_bus manpage suggests you should round-up (ceil).
         timeout = std::chrono::ceil<std::chrono::milliseconds>(
                       std::chrono::microseconds(to_nsec))
                       .count();
     }

     // Assign ourselves as the pending completion and release the caller.
     std::lock_guard lock{ctx.lock};
     ctx.complete = this;
     ctx.caller_wait.notify_one();
 }

 void details::wait_process_completion::wait_once(context& ctx)
 {
     details::wait_process_completion* c = nullptr;

     // Scope for lock.
     {
         std::unique_lock lock{ctx.lock};

         // If there isn't a completion waiting already, wait on the condition
         // variable for one to show up (we can't call `poll` yet because we
         // don't have the required parameters).
         ctx.caller_wait.wait(lock, [&] { return ctx.complete != nullptr; });

         // Save the waiter and call `poll`.
         c = std::exchange(ctx.complete, nullptr);
         poll(&c->fd, 1, c->timeout);
     }

     // Outside the lock complete the operation; this can cause the Receiver
     // task (the worker) to start executing, hence why we do not want the
     // lock held.
     c->complete();
 }

 } // namespace sdbusplus::async
	#include <poll.h>
	#include <systemd/sd-bus.h>

	#include <sdbusplus/async/context.hpp>

	namespace sdbusplus::async
	{

	namespace details
	{

	/* The sd_bus_wait/process completion event.
	*
	* The wait/process handshake is modelled as a Sender with the the worker
	* task `co_await`ing Senders over and over. This class is the completion
	* handling for the Sender (to get it back to the Receiver, ie. the worker).
	*/
	struct wait_process_completion : bus::details::bus_friend
	{
	explicit wait_process_completion(context& ctx) : ctx(ctx) {}
	virtual ~wait_process_completion() = default;

	// Called by the `caller` to indicate the Sender is completed.
	virtual void complete() noexcept = 0;

	// Arm the completion event.
	void arm() noexcept;

	// Data to share with the worker.
	context& ctx;
	pollfd fd{};
	int timeout = 0;

	static task<> loop(context& ctx);
	static void wait_once(context& ctx);
	};

	/* The completion template based on receiver type.
	*
	* The type of the receivers (typically the co_awaiter) is only known by
	* a template, so we need a sub-class of completion to hold the receiver.
	*/
	template <execution::receiver R>
	struct wait_process_operation : public wait_process_completion
	{
	wait_process_operation(context& ctx, R r) :
	wait_process_completion(ctx), receiver(std::move(r))
	{}

	wait_process_operation(wait_process_operation&&) = delete;

	void complete() noexcept override final
	{
	execution::set_value(std::move(this->receiver));
	}

	friend void tag_invoke(execution::start_t,
	wait_process_operation& self) noexcept
	{
	self.arm();
	}

	R receiver;
	};

	/* The sender for the wait/process event. */
	struct wait_process_sender
	{
	explicit wait_process_sender(context& ctx) : ctx(ctx){};

	friend auto tag_invoke(execution::get_completion_signatures_t,
	const wait_process_sender&, auto)
	-> execution::completion_signatures<execution::set_value_t()>;

	template <execution::receiver R>
	friend auto tag_invoke(execution::connect_t, wait_process_sender&& self,
	R r) -> wait_process_operation<R>
	{
	// Create the completion for the wait.
	return {self.ctx, std::move(r)};
	}

	private:
	context& ctx;
	};

	task<> wait_process_completion::loop(context& ctx)
	{
	while (1)
	{
	// Handle the next sdbus event.
	co_await wait_process_sender(ctx);

	// Completion likely happened on the context 'caller' thread, so
	// we need to switch to the worker thread.
	co_await execution::schedule(ctx.loop.get_scheduler());
	}
	}

	} // namespace details

	context::~context() noexcept(false)
	{
	if (worker_thread.joinable())
	{
	throw std::logic_error(
	"sdbusplus::async::context destructed without completion.");
	}
	}

	void context::caller_run(task<> startup)
	{
	// Start up the worker thread.
	worker_thread = std::thread{[this, startup = std::move(startup)]() mutable {
	worker_run(std::move(startup));
	}};

	while (1)
	{
	// Handle 'sd_bus_wait's.
	details::wait_process_completion::wait_once(*this);
	}

	// TODO: We can't actually get here. Need to deal with stop conditions and
	// then we'll need this code.
	loop.finish();
	if (worker_thread.joinable())
	{
	worker_thread.join();
	}
	}

	void context::worker_run(task<> startup)
	{
	// Begin the 'startup' task.
	// This shouldn't start detached because we want to be able to forward
	// failures back to the 'run'. execution::ensure_started isn't
	// implemented yet, so we don't have a lot of other options.
	execution::start_detached(std::move(startup));

	// Also start up the sdbus 'wait/process' loop.
	execution::start_detached(details::wait_process_completion::loop(*this));

	// Run the execution::run_loop to handle all the tasks.
	loop.run();
	}

	void details::wait_process_completion::arm() noexcept
	{
	// Call process. True indicates something was handled and we do not
	// need to `wait`, because there might be yet another pending operation
	// to process, so immediately signal the operation as complete.
	if (ctx.get_bus().process_discard())
	{
	this->complete();
	return;
	}

	// We need to call wait now, so formulate all the data that the 'caller'
	// needs.

	// Get the bus' pollfd data.
	auto b = get_busp(ctx.get_bus());
	fd = pollfd{sd_bus_get_fd(b), static_cast<short>(sd_bus_get_events(b)), 0};

	// Get the bus' timeout.
	uint64_t to_nsec = 0;
	sd_bus_get_timeout(b, &to_nsec);

	if (to_nsec == UINT64_MAX)
	{
	// sd_bus_get_timeout returns UINT64_MAX to indicate 'wait forever'.
	// Turn this into a negative number for `poll`.
	timeout = -1;
	}
	else
	{
	// Otherwise, convert usec from sd_bus to msec for poll.
	// sd_bus manpage suggests you should round-up (ceil).
	timeout = std::chrono::ceil<std::chrono::milliseconds>(
	std::chrono::microseconds(to_nsec))
	.count();
	}

	// Assign ourselves as the pending completion and release the caller.
	std::lock_guard lock{ctx.lock};
	ctx.complete = this;
	ctx.caller_wait.notify_one();
	}

	void details::wait_process_completion::wait_once(context& ctx)
	{
	details::wait_process_completion* c = nullptr;

	// Scope for lock.
	{
	std::unique_lock lock{ctx.lock};

	// If there isn't a completion waiting already, wait on the condition
	// variable for one to show up (we can't call `poll` yet because we
	// don't have the required parameters).
	ctx.caller_wait.wait(lock, [&] { return ctx.complete != nullptr; });

	// Save the waiter and call `poll`.
	c = std::exchange(ctx.complete, nullptr);
	poll(&c->fd, 1, c->timeout);
	}

	// Outside the lock complete the operation; this can cause the Receiver
	// task (the worker) to start executing, hence why we do not want the
	// lock held.
	c->complete();
	}

	} // namespace sdbusplus::async