aos/events/shm-event-loop.cc - RealtimeRoboticsGroup/test - Gitiles

 #include "aos/events/shm-event-loop.h"

 #include <sys/timerfd.h>
 #include <algorithm>
 #include <atomic>
 #include <chrono>
 #include <stdexcept>

 #include "aos/logging/logging.h"
 #include "aos/queue.h"

 namespace aos {

 ShmEventLoop::ShmEventLoop() : thread_state_(std::make_shared<ThreadState>()) {}

 namespace {
 class ShmFetcher : public RawFetcher {
  public:
   explicit ShmFetcher(RawQueue *queue) : queue_(queue) {}
   ~ShmFetcher() {
     if (msg_) {
       queue_->FreeMessage(msg_);
     }
   }

   bool FetchNext() override {
     const FetchValue *msg = static_cast<const FetchValue *>(
         queue_->ReadMessageIndex(RawQueue::kNonBlock, &index_));
     // Only update the internal pointer if we got a new message.
     if (msg != NULL) {
       queue_->FreeMessage(msg_);
       msg_ = msg;
       set_most_recent(msg_);
     }
     return msg != NULL;
   }

   bool Fetch() override {
     static constexpr Options<RawQueue> kOptions =
         RawQueue::kFromEnd | RawQueue::kNonBlock;
     const FetchValue *msg = static_cast<const FetchValue *>(
         queue_->ReadMessageIndex(kOptions, &index_));
     // Only update the internal pointer if we got a new message.
     if (msg != NULL && msg != msg_) {
       queue_->FreeMessage(msg_);
       msg_ = msg;
       set_most_recent(msg_);
       return true;
     }
     // The message has to get freed if we didn't use it (and
     // RawQueue::FreeMessage is ok to call on NULL).
     queue_->FreeMessage(msg);
     return false;
   }

  private:
   int index_ = 0;
   RawQueue *queue_;
   const FetchValue *msg_ = nullptr;
 };

 class ShmSender : public RawSender {
  public:
   explicit ShmSender(RawQueue *queue) : queue_(queue) {}

   SendContext *GetContext() override {
     return reinterpret_cast<SendContext *>(queue_->GetMessage());
   }

   void Free(SendContext *context) override { queue_->FreeMessage(context); }

   bool Send(SendContext *msg) override {
     assert(queue_ != NULL);
     return queue_->WriteMessage(msg, RawQueue::kOverride);
   }

   const char *name() const override { return queue_->name(); }

  private:
   RawQueue *queue_;
 };
 }  // namespace

 namespace internal {
 class WatcherThreadState {
  public:
   WatcherThreadState(std::shared_ptr<ShmEventLoop::ThreadState> thread_state,
                      RawQueue *queue,
                      std::function<void(const aos::Message *message)> watcher)
       : thread_state_(std::move(thread_state)),
         queue_(queue),
         watcher_(std::move(watcher)) {}

   void Run() {
     thread_state_->WaitForStart();

     if (!thread_state_->is_running()) return;

     int32_t index = 0;

     static constexpr Options<RawQueue> kOptions =
         RawQueue::kFromEnd | RawQueue::kNonBlock;
     const void *msg = queue_->ReadMessageIndex(kOptions, &index);

     while (true) {
       if (msg == nullptr) {
         msg = queue_->ReadMessageIndex(RawQueue::kBlock, &index);
         assert(msg != nullptr);
       }

       {
         MutexLocker locker(&thread_state_->mutex_);
         if (!thread_state_->is_running()) break;

         watcher_(reinterpret_cast<const Message *>(msg));
         // watcher_ may have exited the event loop.
         if (!thread_state_->is_running()) break;
       }
       queue_->FreeMessage(msg);
       msg = nullptr;
     }

     queue_->FreeMessage(msg);
   }

  private:
   std::shared_ptr<ShmEventLoop::ThreadState> thread_state_;
   RawQueue *queue_;
   std::function<void(const Message *message)> watcher_;
 };

 class TimerHandlerState : public TimerHandler {
  public:
   TimerHandlerState(std::shared_ptr<ShmEventLoop::ThreadState> thread_state,
                     ::std::function<void()> fn)
       : thread_state_(std::move(thread_state)), fn_(::std::move(fn)) {
     fd_ = timerfd_create(CLOCK_MONOTONIC, TFD_CLOEXEC);
     PCHECK(fd_ != -1);
   }

   ~TimerHandlerState() {
     PCHECK(close(fd_) == 0);
   }

   void Setup(monotonic_clock::time_point base,
              monotonic_clock::duration repeat_offset) override {
     struct itimerspec new_value;
     new_value.it_interval = ::aos::time::to_timespec(repeat_offset);
     new_value.it_value = ::aos::time::to_timespec(base);
     PCHECK(timerfd_settime(fd_, TFD_TIMER_ABSTIME, &new_value, nullptr) == 0);
   }

   void Disable() override {
     // Disarm the timer by feeding zero values
     Setup(::aos::monotonic_clock::epoch(), ::aos::monotonic_clock::zero());
   }

   void Run() {
     thread_state_->WaitForStart();

     while (true) {
       uint64_t buf;
       ssize_t result = read(fd_, &buf, sizeof(buf));
       PCHECK(result != -1);
       CHECK_EQ(result, static_cast<int>(sizeof(buf)));

       {
         MutexLocker locker(&thread_state_->mutex_);
         if (!thread_state_->is_running()) break;
         fn_();
         // fn_ may have exited the event loop.
         if (!thread_state_->is_running()) break;
       }
     }
   }

  private:
   std::shared_ptr<ShmEventLoop::ThreadState> thread_state_;

   // File descriptor for the timer
   int fd_;

   // Function to be run on the thread
   ::std::function<void()> fn_;
 };
 }  // namespace internal

 std::unique_ptr<RawFetcher> ShmEventLoop::MakeRawFetcher(
     const std::string &path, const QueueTypeInfo &type) {
   return std::unique_ptr<RawFetcher>(new ShmFetcher(
       RawQueue::Fetch(path.c_str(), type.size, type.hash, type.queue_length)));
 }

 std::unique_ptr<RawSender> ShmEventLoop::MakeRawSender(
     const std::string &path, const QueueTypeInfo &type) {
   Take(path);
   return std::unique_ptr<RawSender>(new ShmSender(
       RawQueue::Fetch(path.c_str(), type.size, type.hash, type.queue_length)));
 }

 void ShmEventLoop::MakeRawWatcher(
     const std::string &path, const QueueTypeInfo &type,
     std::function<void(const Message *message)> watcher) {
   Take(path);
   auto *state = new internal::WatcherThreadState(
       thread_state_,
       RawQueue::Fetch(path.c_str(), type.size, type.hash, type.queue_length),
       std::move(watcher));

   std::thread thread([state] {
     state->Run();
     delete state;
   });
   thread.detach();
 }

 TimerHandler *ShmEventLoop::AddTimer(::std::function<void()> callback) {
   internal::TimerHandlerState *timer =
       new internal::TimerHandlerState(thread_state_, ::std::move(callback));

   ::std::thread t([timer] {
     timer->Run();
     delete timer;
   });
   t.detach();

   return timer;
 }

 void ShmEventLoop::OnRun(std::function<void()> on_run) {
   on_run_.push_back(std::move(on_run));
 }

 void ShmEventLoop::Run() {
   set_is_running(true);
   for (const auto &run : on_run_) run();
   // TODO(austin): epoll event loop in main thread (if needed), and async safe
   // quit handler.
   thread_state_->Run();
 }

 void ShmEventLoop::ThreadState::Run() {
   MutexLocker locker(&mutex_);
   loop_running_ = true;
   if (loop_finished_) ::aos::Die("Cannot restart an ShmEventLoop()");
   loop_running_cond_.Broadcast();
   while (loop_running_) {
     if (loop_running_cond_.Wait()) {
       ::aos::Die("ShmEventLoop mutex lock problem.\n");
     }
   }
 }

 void ShmEventLoop::ThreadState::WaitForStart() {
   MutexLocker locker(&mutex_);
   while (!(loop_running_ || loop_finished_)) {
     if (loop_running_cond_.Wait()) {
       ::aos::Die("ShmEventLoop mutex lock problem.\n");
     }
   }
 }

 void ShmEventLoop::Exit() {
   set_is_running(false);
   thread_state_->Exit();
 }

 void ShmEventLoop::ThreadState::Exit() {
   IPCRecursiveMutexLocker locker(&mutex_);
   if (locker.owner_died()) ::aos::Die("Owner died");
   loop_running_ = false;
   loop_finished_ = true;
   loop_running_cond_.Broadcast();
 }

 ShmEventLoop::~ShmEventLoop() {
   if (is_running()) {
     ::aos::Die("ShmEventLoop destroyed while running\n");
   }
 }

 void ShmEventLoop::Take(const std::string &path) {
   if (is_running()) {
     ::aos::Die("Cannot add new objects while running.\n");
   }

   const auto prior = ::std::find(taken_.begin(), taken_.end(), path);
   if (prior != taken_.end()) {
     ::aos::Die("%s is already being used.", path.c_str());
   } else {
     taken_.emplace_back(path);
   }
 }

 }  // namespace aos
	#include "aos/events/shm-event-loop.h"

	#include <sys/timerfd.h>
	#include <algorithm>
	#include <atomic>
	#include <chrono>
	#include <stdexcept>

	#include "aos/logging/logging.h"
	#include "aos/queue.h"

	namespace aos {

	ShmEventLoop::ShmEventLoop() : thread_state_(std::make_shared<ThreadState>()) {}

	namespace {
	class ShmFetcher : public RawFetcher {
	public:
	explicit ShmFetcher(RawQueue *queue) : queue_(queue) {}
	~ShmFetcher() {
	if (msg_) {
	queue_->FreeMessage(msg_);
	}
	}

	bool FetchNext() override {
	const FetchValue msg = static_cast<const FetchValue >(
	queue_->ReadMessageIndex(RawQueue::kNonBlock, &index_));
	// Only update the internal pointer if we got a new message.
	if (msg != NULL) {
	queue_->FreeMessage(msg_);
	msg_ = msg;
	set_most_recent(msg_);
	}
	return msg != NULL;
	}

	bool Fetch() override {
	static constexpr Options<RawQueue> kOptions =
	RawQueue::kFromEnd \| RawQueue::kNonBlock;
	const FetchValue msg = static_cast<const FetchValue >(
	queue_->ReadMessageIndex(kOptions, &index_));
	// Only update the internal pointer if we got a new message.
	if (msg != NULL && msg != msg_) {
	queue_->FreeMessage(msg_);
	msg_ = msg;
	set_most_recent(msg_);
	return true;
	}
	// The message has to get freed if we didn't use it (and
	// RawQueue::FreeMessage is ok to call on NULL).
	queue_->FreeMessage(msg);
	return false;
	}

	private:
	int index_ = 0;
	RawQueue *queue_;
	const FetchValue *msg_ = nullptr;
	};

	class ShmSender : public RawSender {
	public:
	explicit ShmSender(RawQueue *queue) : queue_(queue) {}

	SendContext *GetContext() override {
	return reinterpret_cast<SendContext *>(queue_->GetMessage());
	}

	void Free(SendContext *context) override { queue_->FreeMessage(context); }

	bool Send(SendContext *msg) override {
	assert(queue_ != NULL);
	return queue_->WriteMessage(msg, RawQueue::kOverride);
	}

	const char *name() const override { return queue_->name(); }

	private:
	RawQueue *queue_;
	};
	} // namespace

	namespace internal {
	class WatcherThreadState {
	public:
	WatcherThreadState(std::shared_ptr<ShmEventLoop::ThreadState> thread_state,
	RawQueue *queue,
	std::function<void(const aos::Message *message)> watcher)
	: thread_state_(std::move(thread_state)),
	queue_(queue),
	watcher_(std::move(watcher)) {}

	void Run() {
	thread_state_->WaitForStart();

	if (!thread_state_->is_running()) return;

	int32_t index = 0;

	static constexpr Options<RawQueue> kOptions =
	RawQueue::kFromEnd \| RawQueue::kNonBlock;
	const void *msg = queue_->ReadMessageIndex(kOptions, &index);

	while (true) {
	if (msg == nullptr) {
	msg = queue_->ReadMessageIndex(RawQueue::kBlock, &index);
	assert(msg != nullptr);
	}

	{
	MutexLocker locker(&thread_state_->mutex_);
	if (!thread_state_->is_running()) break;

	watcher_(reinterpret_cast<const Message *>(msg));
	// watcher_ may have exited the event loop.
	if (!thread_state_->is_running()) break;
	}
	queue_->FreeMessage(msg);
	msg = nullptr;
	}

	queue_->FreeMessage(msg);
	}

	private:
	std::shared_ptr<ShmEventLoop::ThreadState> thread_state_;
	RawQueue *queue_;
	std::function<void(const Message *message)> watcher_;
	};

	class TimerHandlerState : public TimerHandler {
	public:
	TimerHandlerState(std::shared_ptr<ShmEventLoop::ThreadState> thread_state,
	::std::function<void()> fn)
	: thread_state_(std::move(thread_state)), fn_(::std::move(fn)) {
	fd_ = timerfd_create(CLOCK_MONOTONIC, TFD_CLOEXEC);
	PCHECK(fd_ != -1);
	}

	~TimerHandlerState() {
	PCHECK(close(fd_) == 0);
	}

	void Setup(monotonic_clock::time_point base,
	monotonic_clock::duration repeat_offset) override {
	struct itimerspec new_value;
	new_value.it_interval = ::aos::time::to_timespec(repeat_offset);
	new_value.it_value = ::aos::time::to_timespec(base);
	PCHECK(timerfd_settime(fd_, TFD_TIMER_ABSTIME, &new_value, nullptr) == 0);
	}

	void Disable() override {
	// Disarm the timer by feeding zero values
	Setup(::aos::monotonic_clock::epoch(), ::aos::monotonic_clock::zero());
	}

	void Run() {
	thread_state_->WaitForStart();

	while (true) {
	uint64_t buf;
	ssize_t result = read(fd_, &buf, sizeof(buf));
	PCHECK(result != -1);
	CHECK_EQ(result, static_cast<int>(sizeof(buf)));

	{
	MutexLocker locker(&thread_state_->mutex_);
	if (!thread_state_->is_running()) break;
	fn_();
	// fn_ may have exited the event loop.
	if (!thread_state_->is_running()) break;
	}
	}
	}

	private:
	std::shared_ptr<ShmEventLoop::ThreadState> thread_state_;

	// File descriptor for the timer
	int fd_;

	// Function to be run on the thread
	::std::function<void()> fn_;
	};
	} // namespace internal

	std::unique_ptr<RawFetcher> ShmEventLoop::MakeRawFetcher(
	const std::string &path, const QueueTypeInfo &type) {
	return std::unique_ptr<RawFetcher>(new ShmFetcher(
	RawQueue::Fetch(path.c_str(), type.size, type.hash, type.queue_length)));
	}

	std::unique_ptr<RawSender> ShmEventLoop::MakeRawSender(
	const std::string &path, const QueueTypeInfo &type) {
	Take(path);
	return std::unique_ptr<RawSender>(new ShmSender(
	RawQueue::Fetch(path.c_str(), type.size, type.hash, type.queue_length)));
	}

	void ShmEventLoop::MakeRawWatcher(
	const std::string &path, const QueueTypeInfo &type,
	std::function<void(const Message *message)> watcher) {
	Take(path);
	auto *state = new internal::WatcherThreadState(
	thread_state_,
	RawQueue::Fetch(path.c_str(), type.size, type.hash, type.queue_length),
	std::move(watcher));

	std::thread thread([state] {
	state->Run();
	delete state;
	});
	thread.detach();
	}

	TimerHandler *ShmEventLoop::AddTimer(::std::function<void()> callback) {
	internal::TimerHandlerState *timer =
	new internal::TimerHandlerState(thread_state_, ::std::move(callback));

	::std::thread t([timer] {
	timer->Run();
	delete timer;
	});
	t.detach();

	return timer;
	}

	void ShmEventLoop::OnRun(std::function<void()> on_run) {
	on_run_.push_back(std::move(on_run));
	}

	void ShmEventLoop::Run() {
	set_is_running(true);
	for (const auto &run : on_run_) run();
	// TODO(austin): epoll event loop in main thread (if needed), and async safe
	// quit handler.
	thread_state_->Run();
	}

	void ShmEventLoop::ThreadState::Run() {
	MutexLocker locker(&mutex_);
	loop_running_ = true;
	if (loop_finished_) ::aos::Die("Cannot restart an ShmEventLoop()");
	loop_running_cond_.Broadcast();
	while (loop_running_) {
	if (loop_running_cond_.Wait()) {
	::aos::Die("ShmEventLoop mutex lock problem.\n");
	}
	}
	}

	void ShmEventLoop::ThreadState::WaitForStart() {
	MutexLocker locker(&mutex_);
	while (!(loop_running_ \|\| loop_finished_)) {
	if (loop_running_cond_.Wait()) {
	::aos::Die("ShmEventLoop mutex lock problem.\n");
	}
	}
	}

	void ShmEventLoop::Exit() {
	set_is_running(false);
	thread_state_->Exit();
	}

	void ShmEventLoop::ThreadState::Exit() {
	IPCRecursiveMutexLocker locker(&mutex_);
	if (locker.owner_died()) ::aos::Die("Owner died");
	loop_running_ = false;
	loop_finished_ = true;
	loop_running_cond_.Broadcast();
	}

	ShmEventLoop::~ShmEventLoop() {
	if (is_running()) {
	::aos::Die("ShmEventLoop destroyed while running\n");
	}
	}

	void ShmEventLoop::Take(const std::string &path) {
	if (is_running()) {
	::aos::Die("Cannot add new objects while running.\n");
	}

	const auto prior = ::std::find(taken_.begin(), taken_.end(), path);
	if (prior != taken_.end()) {
	::aos::Die("%s is already being used.", path.c_str());
	} else {
	taken_.emplace_back(path);
	}
	}

	} // namespace aos