runtime/bin/eventhandler_macos.cc - sdk - Git at Google

 // Copyright (c) 2012, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.

 #include "platform/globals.h"
 #if defined(HOST_OS_MACOS)

 #include "bin/eventhandler.h"
 #include "bin/eventhandler_macos.h"

 #include <errno.h>      // NOLINT
 #include <fcntl.h>      // NOLINT
 #include <pthread.h>    // NOLINT
 #include <stdio.h>      // NOLINT
 #include <string.h>     // NOLINT
 #include <sys/event.h>  // NOLINT
 #include <unistd.h>     // NOLINT

 #include "bin/dartutils.h"
 #include "bin/fdutils.h"
 #include "bin/lockers.h"
 #include "bin/socket.h"
 #include "bin/thread.h"
 #include "bin/utils.h"
 #include "platform/hashmap.h"
 #include "platform/syslog.h"
 #include "platform/utils.h"

 namespace dart {
 namespace bin {

 bool DescriptorInfo::HasReadEvent() {
   return (Mask() & (1 << kInEvent)) != 0;
 }

 bool DescriptorInfo::HasWriteEvent() {
   return (Mask() & (1 << kOutEvent)) != 0;
 }

 // Unregister the file descriptor for a SocketData structure with kqueue.
 static void RemoveFromKqueue(intptr_t kqueue_fd_, DescriptorInfo* di) {
   if (!di->tracked_by_kqueue()) {
     return;
   }
   static const intptr_t kMaxChanges = 2;
   struct kevent events[kMaxChanges];
   EV_SET(events, di->fd(), EVFILT_READ, EV_DELETE, 0, 0, NULL);
   VOID_NO_RETRY_EXPECTED(kevent(kqueue_fd_, events, 1, NULL, 0, NULL));
   EV_SET(events, di->fd(), EVFILT_WRITE, EV_DELETE, 0, 0, NULL);
   VOID_NO_RETRY_EXPECTED(kevent(kqueue_fd_, events, 1, NULL, 0, NULL));
   di->set_tracked_by_kqueue(false);
 }

 // Update the kqueue registration for SocketData structure to reflect
 // the events currently of interest.
 static void AddToKqueue(intptr_t kqueue_fd_, DescriptorInfo* di) {
   ASSERT(!di->tracked_by_kqueue());
   static const intptr_t kMaxChanges = 2;
   intptr_t changes = 0;
   struct kevent events[kMaxChanges];
   int flags = EV_ADD;
   if (!di->IsListeningSocket()) {
     flags |= EV_CLEAR;
   }

   ASSERT(di->HasReadEvent() || di->HasWriteEvent());

   // Register or unregister READ filter if needed.
   if (di->HasReadEvent()) {
     EV_SET(events + changes, di->fd(), EVFILT_READ, flags, 0, 0, di);
     ++changes;
   }
   // Register or unregister WRITE filter if needed.
   if (di->HasWriteEvent()) {
     EV_SET(events + changes, di->fd(), EVFILT_WRITE, flags, 0, 0, di);
     ++changes;
   }
   ASSERT(changes > 0);
   ASSERT(changes <= kMaxChanges);
   int status =
       NO_RETRY_EXPECTED(kevent(kqueue_fd_, events, changes, NULL, 0, NULL));
   if (status == -1) {
     // TODO(dart:io): Verify that the dart end is handling this correctly.

     // kQueue does not accept the file descriptor. It could be due to
     // already closed file descriptor, or unuspported devices, such
     // as /dev/null. In such case, mark the file descriptor as closed,
     // so dart will handle it accordingly.
     di->NotifyAllDartPorts(1 << kCloseEvent);
   } else {
     di->set_tracked_by_kqueue(true);
   }
 }

 EventHandlerImplementation::EventHandlerImplementation()
     : socket_map_(&SimpleHashMap::SamePointerValue, 16) {
   intptr_t result;
   result = NO_RETRY_EXPECTED(pipe(interrupt_fds_));
   if (result != 0) {
     FATAL("Pipe creation failed");
   }
   if (!FDUtils::SetNonBlocking(interrupt_fds_[0])) {
     FATAL("Failed to set pipe fd non-blocking\n");
   }
   if (!FDUtils::SetCloseOnExec(interrupt_fds_[0])) {
     FATAL("Failed to set pipe fd close on exec\n");
   }
   if (!FDUtils::SetCloseOnExec(interrupt_fds_[1])) {
     FATAL("Failed to set pipe fd close on exec\n");
   }
   shutdown_ = false;

   kqueue_fd_ = NO_RETRY_EXPECTED(kqueue());
   if (kqueue_fd_ == -1) {
     FATAL("Failed creating kqueue");
   }
   if (!FDUtils::SetCloseOnExec(kqueue_fd_)) {
     FATAL("Failed to set kqueue fd close on exec\n");
   }
   // Register the interrupt_fd with the kqueue.
   struct kevent event;
   EV_SET(&event, interrupt_fds_[0], EVFILT_READ, EV_ADD, 0, 0, NULL);
   int status = NO_RETRY_EXPECTED(kevent(kqueue_fd_, &event, 1, NULL, 0, NULL));
   if (status == -1) {
     const int kBufferSize = 1024;
     char error_message[kBufferSize];
     Utils::StrError(errno, error_message, kBufferSize);
     FATAL1("Failed adding interrupt fd to kqueue: %s\n", error_message);
   }
 }

 static void DeleteDescriptorInfo(void* info) {
   DescriptorInfo* di = reinterpret_cast<DescriptorInfo*>(info);
   di->Close();
   delete di;
 }

 EventHandlerImplementation::~EventHandlerImplementation() {
   socket_map_.Clear(DeleteDescriptorInfo);
   close(kqueue_fd_);
   close(interrupt_fds_[0]);
   close(interrupt_fds_[1]);
 }

 void EventHandlerImplementation::UpdateKQueueInstance(intptr_t old_mask,
                                                       DescriptorInfo* di) {
   intptr_t new_mask = di->Mask();
   if (old_mask != 0 && new_mask == 0) {
     RemoveFromKqueue(kqueue_fd_, di);
   } else if ((old_mask == 0) && (new_mask != 0)) {
     AddToKqueue(kqueue_fd_, di);
   } else if ((old_mask != 0) && (new_mask != 0) && (old_mask != new_mask)) {
     ASSERT(!di->IsListeningSocket());
     RemoveFromKqueue(kqueue_fd_, di);
     AddToKqueue(kqueue_fd_, di);
   }
 }

 DescriptorInfo* EventHandlerImplementation::GetDescriptorInfo(
     intptr_t fd,
     bool is_listening) {
   ASSERT(fd >= 0);
   SimpleHashMap::Entry* entry = socket_map_.Lookup(
       GetHashmapKeyFromFd(fd), GetHashmapHashFromFd(fd), true);
   ASSERT(entry != NULL);
   DescriptorInfo* di = reinterpret_cast<DescriptorInfo*>(entry->value);
   if (di == NULL) {
     // If there is no data in the hash map for this file descriptor a
     // new DescriptorInfo for the file descriptor is inserted.
     if (is_listening) {
       di = new DescriptorInfoMultiple(fd);
     } else {
       di = new DescriptorInfoSingle(fd);
     }
     entry->value = di;
   }
   ASSERT(fd == di->fd());
   return di;
 }

 void EventHandlerImplementation::WakeupHandler(intptr_t id,
                                                Dart_Port dart_port,
                                                int64_t data) {
   InterruptMessage msg;
   msg.id = id;
   msg.dart_port = dart_port;
   msg.data = data;
   // WriteToBlocking will write up to 512 bytes atomically, and since our msg
   // is smaller than 512, we don't need a thread lock.
   ASSERT(kInterruptMessageSize < PIPE_BUF);
   intptr_t result =
       FDUtils::WriteToBlocking(interrupt_fds_[1], &msg, kInterruptMessageSize);
   if (result != kInterruptMessageSize) {
     if (result == -1) {
       perror("Interrupt message failure:");
     }
     FATAL1("Interrupt message failure. Wrote %" Pd " bytes.", result);
   }
 }

 void EventHandlerImplementation::HandleInterruptFd() {
   const intptr_t MAX_MESSAGES = kInterruptMessageSize;
   InterruptMessage msg[MAX_MESSAGES];
   ssize_t bytes = TEMP_FAILURE_RETRY(
       read(interrupt_fds_[0], msg, MAX_MESSAGES * kInterruptMessageSize));
   for (ssize_t i = 0; i < bytes / kInterruptMessageSize; i++) {
     if (msg[i].id == kTimerId) {
       timeout_queue_.UpdateTimeout(msg[i].dart_port, msg[i].data);
     } else if (msg[i].id == kShutdownId) {
       shutdown_ = true;
     } else {
       ASSERT((msg[i].data & COMMAND_MASK) != 0);
       Socket* socket = reinterpret_cast<Socket*>(msg[i].id);
       RefCntReleaseScope<Socket> rs(socket);
       if (socket->fd() == -1) {
         continue;
       }
       DescriptorInfo* di =
           GetDescriptorInfo(socket->fd(), IS_LISTENING_SOCKET(msg[i].data));
       if (IS_COMMAND(msg[i].data, kShutdownReadCommand)) {
         ASSERT(!di->IsListeningSocket());
         // Close the socket for reading.
         VOID_NO_RETRY_EXPECTED(shutdown(di->fd(), SHUT_RD));
       } else if (IS_COMMAND(msg[i].data, kShutdownWriteCommand)) {
         ASSERT(!di->IsListeningSocket());
         // Close the socket for writing.
         VOID_NO_RETRY_EXPECTED(shutdown(di->fd(), SHUT_WR));
       } else if (IS_COMMAND(msg[i].data, kCloseCommand)) {
         // Close the socket and free system resources and move on to next
         // message.
         intptr_t old_mask = di->Mask();
         Dart_Port port = msg[i].dart_port;
         if (port != ILLEGAL_PORT) {
           di->RemovePort(port);
         }
         intptr_t new_mask = di->Mask();
         UpdateKQueueInstance(old_mask, di);

         intptr_t fd = di->fd();
         if (di->IsListeningSocket()) {
           // We only close the socket file descriptor from the operating
           // system if there are no other dart socket objects which
           // are listening on the same (address, port) combination.
           ListeningSocketRegistry* registry =
               ListeningSocketRegistry::Instance();

           MutexLocker locker(registry->mutex());

           if (registry->CloseSafe(socket)) {
             ASSERT(new_mask == 0);
             socket_map_.Remove(GetHashmapKeyFromFd(fd),
                                GetHashmapHashFromFd(fd));
             di->Close();
             delete di;
           }
           socket->CloseFd();
         } else {
           ASSERT(new_mask == 0);
           socket_map_.Remove(GetHashmapKeyFromFd(fd), GetHashmapHashFromFd(fd));
           di->Close();
           delete di;
           socket->CloseFd();
         }

         DartUtils::PostInt32(port, 1 << kDestroyedEvent);
       } else if (IS_COMMAND(msg[i].data, kReturnTokenCommand)) {
         intptr_t old_mask = di->Mask();
         di->ReturnTokens(msg[i].dart_port, TOKEN_COUNT(msg[i].data));
         UpdateKQueueInstance(old_mask, di);
       } else if (IS_COMMAND(msg[i].data, kSetEventMaskCommand)) {
         // `events` can only have kInEvent/kOutEvent flags set.
         intptr_t events = msg[i].data & EVENT_MASK;
         ASSERT(0 == (events & ~(1 << kInEvent | 1 << kOutEvent)));

         intptr_t old_mask = di->Mask();
         di->SetPortAndMask(msg[i].dart_port, msg[i].data & EVENT_MASK);
         UpdateKQueueInstance(old_mask, di);
       } else {
         UNREACHABLE();
       }
     }
   }
 }

 #ifdef DEBUG_KQUEUE
 static void PrintEventMask(intptr_t fd, struct kevent* event) {
   Syslog::Print("%d ", static_cast<int>(fd));

   Syslog::Print("filter=0x%x:", event->filter);
   if (event->filter == EVFILT_READ) {
     Syslog::Print("EVFILT_READ ");
   }
   if (event->filter == EVFILT_WRITE) {
     Syslog::Print("EVFILT_WRITE ");
   }

   Syslog::Print("flags: %x: ", event->flags);
   if ((event->flags & EV_EOF) != 0) {
     Syslog::Print("EV_EOF ");
   }
   if ((event->flags & EV_ERROR) != 0) {
     Syslog::Print("EV_ERROR ");
   }
   if ((event->flags & EV_CLEAR) != 0) {
     Syslog::Print("EV_CLEAR ");
   }
   if ((event->flags & EV_ADD) != 0) {
     Syslog::Print("EV_ADD ");
   }
   if ((event->flags & EV_DELETE) != 0) {
     Syslog::Print("EV_DELETE ");
   }

   Syslog::Print("- fflags: %d ", event->fflags);
   Syslog::Print("- data: %ld ", event->data);
   Syslog::Print("(available %d) ",
                 static_cast<int>(FDUtils::AvailableBytes(fd)));
   Syslog::Print("\n");
 }
 #endif

 intptr_t EventHandlerImplementation::GetEvents(struct kevent* event,
                                                DescriptorInfo* di) {
 #ifdef DEBUG_KQUEUE
   PrintEventMask(di->fd(), event);
 #endif
   intptr_t event_mask = 0;
   if (di->IsListeningSocket()) {
     // On a listening socket the READ event means that there are
     // connections ready to be accepted.
     if (event->filter == EVFILT_READ) {
       if ((event->flags & EV_EOF) != 0) {
         if (event->fflags != 0) {
           event_mask |= (1 << kErrorEvent);
         } else {
           event_mask |= (1 << kCloseEvent);
         }
       }
       if (event_mask == 0) {
         event_mask |= (1 << kInEvent);
       }
     } else {
       UNREACHABLE();
     }
   } else {
     // Prioritize data events over close and error events.
     if (event->filter == EVFILT_READ) {
       event_mask = (1 << kInEvent);
       if ((event->flags & EV_EOF) != 0) {
         if (event->fflags != 0) {
           event_mask = (1 << kErrorEvent);
         } else {
           event_mask |= (1 << kCloseEvent);
         }
       }
     } else if (event->filter == EVFILT_WRITE) {
       event_mask |= (1 << kOutEvent);
       if ((event->flags & EV_EOF) != 0) {
         if (event->fflags != 0) {
           event_mask = (1 << kErrorEvent);
         }
       }
     } else {
       UNREACHABLE();
     }
   }

   return event_mask;
 }

 void EventHandlerImplementation::HandleEvents(struct kevent* events, int size) {
   bool interrupt_seen = false;
   for (int i = 0; i < size; i++) {
     // If flag EV_ERROR is set it indicates an error in kevent processing.
     if ((events[i].flags & EV_ERROR) != 0) {
       const int kBufferSize = 1024;
       char error_message[kBufferSize];
       Utils::StrError(events[i].data, error_message, kBufferSize);
       FATAL1("kevent failed %s\n", error_message);
     }
     if (events[i].udata == NULL) {
       interrupt_seen = true;
     } else {
       DescriptorInfo* di = reinterpret_cast<DescriptorInfo*>(events[i].udata);
       const intptr_t old_mask = di->Mask();
       const intptr_t event_mask = GetEvents(events + i, di);
       if ((event_mask & (1 << kErrorEvent)) != 0) {
         di->NotifyAllDartPorts(event_mask);
         UpdateKQueueInstance(old_mask, di);
       } else if (event_mask != 0) {
         Dart_Port port = di->NextNotifyDartPort(event_mask);
         ASSERT(port != 0);
         UpdateKQueueInstance(old_mask, di);
         DartUtils::PostInt32(port, event_mask);
       }
     }
   }
   if (interrupt_seen) {
     // Handle after socket events, so we avoid closing a socket before we handle
     // the current events.
     HandleInterruptFd();
   }
 }

 int64_t EventHandlerImplementation::GetTimeout() {
   if (!timeout_queue_.HasTimeout()) {
     return kInfinityTimeout;
   }
   int64_t millis =
       timeout_queue_.CurrentTimeout() - TimerUtils::GetCurrentMonotonicMillis();
   return (millis < 0) ? 0 : millis;
 }

 void EventHandlerImplementation::HandleTimeout() {
   if (timeout_queue_.HasTimeout()) {
     int64_t millis = timeout_queue_.CurrentTimeout() -
                      TimerUtils::GetCurrentMonotonicMillis();
     if (millis <= 0) {
       DartUtils::PostNull(timeout_queue_.CurrentPort());
       timeout_queue_.RemoveCurrent();
     }
   }
 }

 void EventHandlerImplementation::EventHandlerEntry(uword args) {
   static const intptr_t kMaxEvents = 16;
   struct kevent events[kMaxEvents];
   EventHandler* handler = reinterpret_cast<EventHandler*>(args);
   EventHandlerImplementation* handler_impl = &handler->delegate_;
   ASSERT(handler_impl != NULL);

   while (!handler_impl->shutdown_) {
     int64_t millis = handler_impl->GetTimeout();
     ASSERT(millis == kInfinityTimeout || millis >= 0);
     if (millis > kMaxInt32) {
       millis = kMaxInt32;
     }
     // NULL pointer timespec for infinite timeout.
     ASSERT(kInfinityTimeout < 0);
     struct timespec* timeout = NULL;
     struct timespec ts;
     if (millis >= 0) {
       int32_t millis32 = static_cast<int32_t>(millis);
       int32_t secs = millis32 / 1000;
       ts.tv_sec = secs;
       ts.tv_nsec = (millis32 - (secs * 1000)) * 1000000;
       timeout = &ts;
     }
     // We have to use TEMP_FAILURE_RETRY for mac, as kevent can modify the
     // current sigmask.
     intptr_t result = TEMP_FAILURE_RETRY(
         kevent(handler_impl->kqueue_fd_, NULL, 0, events, kMaxEvents, timeout));
     if (result == -1) {
       const int kBufferSize = 1024;
       char error_message[kBufferSize];
       Utils::StrError(errno, error_message, kBufferSize);
       FATAL1("kevent failed %s\n", error_message);
     } else {
       handler_impl->HandleTimeout();
       handler_impl->HandleEvents(events, result);
     }
   }
   DEBUG_ASSERT(ReferenceCounted<Socket>::instances() == 0);
   handler->NotifyShutdownDone();
 }

 void EventHandlerImplementation::Start(EventHandler* handler) {
   int result = Thread::Start("dart:io EventHandler",
                              &EventHandlerImplementation::EventHandlerEntry,
                              reinterpret_cast<uword>(handler));
   if (result != 0) {
     FATAL1("Failed to start event handler thread %d", result);
   }
 }

 void EventHandlerImplementation::Shutdown() {
   SendData(kShutdownId, 0, 0);
 }

 void EventHandlerImplementation::SendData(intptr_t id,
                                           Dart_Port dart_port,
                                           int64_t data) {
   WakeupHandler(id, dart_port, data);
 }

 void* EventHandlerImplementation::GetHashmapKeyFromFd(intptr_t fd) {
   // The hashmap does not support keys with value 0.
   return reinterpret_cast<void*>(fd + 1);
 }

 uint32_t EventHandlerImplementation::GetHashmapHashFromFd(intptr_t fd) {
   // The hashmap does not support keys with value 0.
   return dart::Utils::WordHash(fd + 1);
 }

 }  // namespace bin
 }  // namespace dart

 #endif  // defined(HOST_OS_MACOS)
	// Copyright (c) 2012, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.

	#include "platform/globals.h"
	#if defined(HOST_OS_MACOS)

	#include "bin/eventhandler.h"
	#include "bin/eventhandler_macos.h"

	#include <errno.h> // NOLINT
	#include <fcntl.h> // NOLINT
	#include <pthread.h> // NOLINT
	#include <stdio.h> // NOLINT
	#include <string.h> // NOLINT
	#include <sys/event.h> // NOLINT
	#include <unistd.h> // NOLINT

	#include "bin/dartutils.h"
	#include "bin/fdutils.h"
	#include "bin/lockers.h"
	#include "bin/socket.h"
	#include "bin/thread.h"
	#include "bin/utils.h"
	#include "platform/hashmap.h"
	#include "platform/syslog.h"
	#include "platform/utils.h"

	namespace dart {
	namespace bin {

	bool DescriptorInfo::HasReadEvent() {
	return (Mask() & (1 << kInEvent)) != 0;
	}

	bool DescriptorInfo::HasWriteEvent() {
	return (Mask() & (1 << kOutEvent)) != 0;
	}

	// Unregister the file descriptor for a SocketData structure with kqueue.
	static void RemoveFromKqueue(intptr_t kqueue_fd_, DescriptorInfo* di) {
	if (!di->tracked_by_kqueue()) {
	return;
	}
	static const intptr_t kMaxChanges = 2;
	struct kevent events[kMaxChanges];
	EV_SET(events, di->fd(), EVFILT_READ, EV_DELETE, 0, 0, NULL);
	VOID_NO_RETRY_EXPECTED(kevent(kqueue_fd_, events, 1, NULL, 0, NULL));
	EV_SET(events, di->fd(), EVFILT_WRITE, EV_DELETE, 0, 0, NULL);
	VOID_NO_RETRY_EXPECTED(kevent(kqueue_fd_, events, 1, NULL, 0, NULL));
	di->set_tracked_by_kqueue(false);
	}

	// Update the kqueue registration for SocketData structure to reflect
	// the events currently of interest.
	static void AddToKqueue(intptr_t kqueue_fd_, DescriptorInfo* di) {
	ASSERT(!di->tracked_by_kqueue());
	static const intptr_t kMaxChanges = 2;
	intptr_t changes = 0;
	struct kevent events[kMaxChanges];
	int flags = EV_ADD;
	if (!di->IsListeningSocket()) {
	flags \|= EV_CLEAR;
	}

	ASSERT(di->HasReadEvent() \|\| di->HasWriteEvent());

	// Register or unregister READ filter if needed.
	if (di->HasReadEvent()) {
	EV_SET(events + changes, di->fd(), EVFILT_READ, flags, 0, 0, di);
	++changes;
	}
	// Register or unregister WRITE filter if needed.
	if (di->HasWriteEvent()) {
	EV_SET(events + changes, di->fd(), EVFILT_WRITE, flags, 0, 0, di);
	++changes;
	}
	ASSERT(changes > 0);
	ASSERT(changes <= kMaxChanges);
	int status =
	NO_RETRY_EXPECTED(kevent(kqueue_fd_, events, changes, NULL, 0, NULL));
	if (status == -1) {
	// TODO(dart:io): Verify that the dart end is handling this correctly.

	// kQueue does not accept the file descriptor. It could be due to
	// already closed file descriptor, or unuspported devices, such
	// as /dev/null. In such case, mark the file descriptor as closed,
	// so dart will handle it accordingly.
	di->NotifyAllDartPorts(1 << kCloseEvent);
	} else {
	di->set_tracked_by_kqueue(true);
	}
	}

	EventHandlerImplementation::EventHandlerImplementation()
	: socket_map_(&SimpleHashMap::SamePointerValue, 16) {
	intptr_t result;
	result = NO_RETRY_EXPECTED(pipe(interrupt_fds_));
	if (result != 0) {
	FATAL("Pipe creation failed");
	}
	if (!FDUtils::SetNonBlocking(interrupt_fds_[0])) {
	FATAL("Failed to set pipe fd non-blocking\n");
	}
	if (!FDUtils::SetCloseOnExec(interrupt_fds_[0])) {
	FATAL("Failed to set pipe fd close on exec\n");
	}
	if (!FDUtils::SetCloseOnExec(interrupt_fds_[1])) {
	FATAL("Failed to set pipe fd close on exec\n");
	}
	shutdown_ = false;

	kqueue_fd_ = NO_RETRY_EXPECTED(kqueue());
	if (kqueue_fd_ == -1) {
	FATAL("Failed creating kqueue");
	}
	if (!FDUtils::SetCloseOnExec(kqueue_fd_)) {
	FATAL("Failed to set kqueue fd close on exec\n");
	}
	// Register the interrupt_fd with the kqueue.
	struct kevent event;
	EV_SET(&event, interrupt_fds_[0], EVFILT_READ, EV_ADD, 0, 0, NULL);
	int status = NO_RETRY_EXPECTED(kevent(kqueue_fd_, &event, 1, NULL, 0, NULL));
	if (status == -1) {
	const int kBufferSize = 1024;
	char error_message[kBufferSize];
	Utils::StrError(errno, error_message, kBufferSize);
	FATAL1("Failed adding interrupt fd to kqueue: %s\n", error_message);
	}
	}

	static void DeleteDescriptorInfo(void* info) {
	DescriptorInfo* di = reinterpret_cast<DescriptorInfo*>(info);
	di->Close();
	delete di;
	}

	EventHandlerImplementation::~EventHandlerImplementation() {
	socket_map_.Clear(DeleteDescriptorInfo);
	close(kqueue_fd_);
	close(interrupt_fds_[0]);
	close(interrupt_fds_[1]);
	}

	void EventHandlerImplementation::UpdateKQueueInstance(intptr_t old_mask,
	DescriptorInfo* di) {
	intptr_t new_mask = di->Mask();
	if (old_mask != 0 && new_mask == 0) {
	RemoveFromKqueue(kqueue_fd_, di);
	} else if ((old_mask == 0) && (new_mask != 0)) {
	AddToKqueue(kqueue_fd_, di);
	} else if ((old_mask != 0) && (new_mask != 0) && (old_mask != new_mask)) {
	ASSERT(!di->IsListeningSocket());
	RemoveFromKqueue(kqueue_fd_, di);
	AddToKqueue(kqueue_fd_, di);
	}
	}

	DescriptorInfo* EventHandlerImplementation::GetDescriptorInfo(
	intptr_t fd,
	bool is_listening) {
	ASSERT(fd >= 0);
	SimpleHashMap::Entry* entry = socket_map_.Lookup(
	GetHashmapKeyFromFd(fd), GetHashmapHashFromFd(fd), true);
	ASSERT(entry != NULL);
	DescriptorInfo* di = reinterpret_cast<DescriptorInfo*>(entry->value);
	if (di == NULL) {
	// If there is no data in the hash map for this file descriptor a
	// new DescriptorInfo for the file descriptor is inserted.
	if (is_listening) {
	di = new DescriptorInfoMultiple(fd);
	} else {
	di = new DescriptorInfoSingle(fd);
	}
	entry->value = di;
	}
	ASSERT(fd == di->fd());
	return di;
	}

	void EventHandlerImplementation::WakeupHandler(intptr_t id,
	Dart_Port dart_port,
	int64_t data) {
	InterruptMessage msg;
	msg.id = id;
	msg.dart_port = dart_port;
	msg.data = data;
	// WriteToBlocking will write up to 512 bytes atomically, and since our msg
	// is smaller than 512, we don't need a thread lock.
	ASSERT(kInterruptMessageSize < PIPE_BUF);
	intptr_t result =
	FDUtils::WriteToBlocking(interrupt_fds_[1], &msg, kInterruptMessageSize);
	if (result != kInterruptMessageSize) {
	if (result == -1) {
	perror("Interrupt message failure:");
	}
	FATAL1("Interrupt message failure. Wrote %" Pd " bytes.", result);
	}
	}

	void EventHandlerImplementation::HandleInterruptFd() {
	const intptr_t MAX_MESSAGES = kInterruptMessageSize;
	InterruptMessage msg[MAX_MESSAGES];
	ssize_t bytes = TEMP_FAILURE_RETRY(
	read(interrupt_fds_[0], msg, MAX_MESSAGES * kInterruptMessageSize));
	for (ssize_t i = 0; i < bytes / kInterruptMessageSize; i++) {
	if (msg[i].id == kTimerId) {
	timeout_queue_.UpdateTimeout(msg[i].dart_port, msg[i].data);
	} else if (msg[i].id == kShutdownId) {
	shutdown_ = true;
	} else {
	ASSERT((msg[i].data & COMMAND_MASK) != 0);
	Socket* socket = reinterpret_cast<Socket*>(msg[i].id);
	RefCntReleaseScope<Socket> rs(socket);
	if (socket->fd() == -1) {
	continue;
	}
	DescriptorInfo* di =
	GetDescriptorInfo(socket->fd(), IS_LISTENING_SOCKET(msg[i].data));
	if (IS_COMMAND(msg[i].data, kShutdownReadCommand)) {
	ASSERT(!di->IsListeningSocket());
	// Close the socket for reading.
	VOID_NO_RETRY_EXPECTED(shutdown(di->fd(), SHUT_RD));
	} else if (IS_COMMAND(msg[i].data, kShutdownWriteCommand)) {
	ASSERT(!di->IsListeningSocket());
	// Close the socket for writing.
	VOID_NO_RETRY_EXPECTED(shutdown(di->fd(), SHUT_WR));
	} else if (IS_COMMAND(msg[i].data, kCloseCommand)) {
	// Close the socket and free system resources and move on to next
	// message.
	intptr_t old_mask = di->Mask();
	Dart_Port port = msg[i].dart_port;
	if (port != ILLEGAL_PORT) {
	di->RemovePort(port);
	}
	intptr_t new_mask = di->Mask();
	UpdateKQueueInstance(old_mask, di);

	intptr_t fd = di->fd();
	if (di->IsListeningSocket()) {
	// We only close the socket file descriptor from the operating
	// system if there are no other dart socket objects which
	// are listening on the same (address, port) combination.
	ListeningSocketRegistry* registry =
	ListeningSocketRegistry::Instance();

	MutexLocker locker(registry->mutex());

	if (registry->CloseSafe(socket)) {
	ASSERT(new_mask == 0);
	socket_map_.Remove(GetHashmapKeyFromFd(fd),
	GetHashmapHashFromFd(fd));
	di->Close();
	delete di;
	}
	socket->CloseFd();
	} else {
	ASSERT(new_mask == 0);
	socket_map_.Remove(GetHashmapKeyFromFd(fd), GetHashmapHashFromFd(fd));
	di->Close();
	delete di;
	socket->CloseFd();
	}

	DartUtils::PostInt32(port, 1 << kDestroyedEvent);
	} else if (IS_COMMAND(msg[i].data, kReturnTokenCommand)) {
	intptr_t old_mask = di->Mask();
	di->ReturnTokens(msg[i].dart_port, TOKEN_COUNT(msg[i].data));
	UpdateKQueueInstance(old_mask, di);
	} else if (IS_COMMAND(msg[i].data, kSetEventMaskCommand)) {
	// `events` can only have kInEvent/kOutEvent flags set.
	intptr_t events = msg[i].data & EVENT_MASK;
	ASSERT(0 == (events & ~(1 << kInEvent \| 1 << kOutEvent)));

	intptr_t old_mask = di->Mask();
	di->SetPortAndMask(msg[i].dart_port, msg[i].data & EVENT_MASK);
	UpdateKQueueInstance(old_mask, di);
	} else {
	UNREACHABLE();
	}
	}
	}
	}

	#ifdef DEBUG_KQUEUE
	static void PrintEventMask(intptr_t fd, struct kevent* event) {
	Syslog::Print("%d ", static_cast<int>(fd));

	Syslog::Print("filter=0x%x:", event->filter);
	if (event->filter == EVFILT_READ) {
	Syslog::Print("EVFILT_READ ");
	}
	if (event->filter == EVFILT_WRITE) {
	Syslog::Print("EVFILT_WRITE ");
	}

	Syslog::Print("flags: %x: ", event->flags);
	if ((event->flags & EV_EOF) != 0) {
	Syslog::Print("EV_EOF ");
	}
	if ((event->flags & EV_ERROR) != 0) {
	Syslog::Print("EV_ERROR ");
	}
	if ((event->flags & EV_CLEAR) != 0) {
	Syslog::Print("EV_CLEAR ");
	}
	if ((event->flags & EV_ADD) != 0) {
	Syslog::Print("EV_ADD ");
	}
	if ((event->flags & EV_DELETE) != 0) {
	Syslog::Print("EV_DELETE ");
	}

	Syslog::Print("- fflags: %d ", event->fflags);
	Syslog::Print("- data: %ld ", event->data);
	Syslog::Print("(available %d) ",
	static_cast<int>(FDUtils::AvailableBytes(fd)));
	Syslog::Print("\n");
	}
	#endif

	intptr_t EventHandlerImplementation::GetEvents(struct kevent* event,
	DescriptorInfo* di) {
	#ifdef DEBUG_KQUEUE
	PrintEventMask(di->fd(), event);
	#endif
	intptr_t event_mask = 0;
	if (di->IsListeningSocket()) {
	// On a listening socket the READ event means that there are
	// connections ready to be accepted.
	if (event->filter == EVFILT_READ) {
	if ((event->flags & EV_EOF) != 0) {
	if (event->fflags != 0) {
	event_mask \|= (1 << kErrorEvent);
	} else {
	event_mask \|= (1 << kCloseEvent);
	}
	}
	if (event_mask == 0) {
	event_mask \|= (1 << kInEvent);
	}
	} else {
	UNREACHABLE();
	}
	} else {
	// Prioritize data events over close and error events.
	if (event->filter == EVFILT_READ) {
	event_mask = (1 << kInEvent);
	if ((event->flags & EV_EOF) != 0) {
	if (event->fflags != 0) {
	event_mask = (1 << kErrorEvent);
	} else {
	event_mask \|= (1 << kCloseEvent);
	}
	}
	} else if (event->filter == EVFILT_WRITE) {
	event_mask \|= (1 << kOutEvent);
	if ((event->flags & EV_EOF) != 0) {
	if (event->fflags != 0) {
	event_mask = (1 << kErrorEvent);
	}
	}
	} else {
	UNREACHABLE();
	}
	}

	return event_mask;
	}

	void EventHandlerImplementation::HandleEvents(struct kevent* events, int size) {
	bool interrupt_seen = false;
	for (int i = 0; i < size; i++) {
	// If flag EV_ERROR is set it indicates an error in kevent processing.
	if ((events[i].flags & EV_ERROR) != 0) {
	const int kBufferSize = 1024;
	char error_message[kBufferSize];
	Utils::StrError(events[i].data, error_message, kBufferSize);
	FATAL1("kevent failed %s\n", error_message);
	}
	if (events[i].udata == NULL) {
	interrupt_seen = true;
	} else {
	DescriptorInfo* di = reinterpret_cast<DescriptorInfo*>(events[i].udata);
	const intptr_t old_mask = di->Mask();
	const intptr_t event_mask = GetEvents(events + i, di);
	if ((event_mask & (1 << kErrorEvent)) != 0) {
	di->NotifyAllDartPorts(event_mask);
	UpdateKQueueInstance(old_mask, di);
	} else if (event_mask != 0) {
	Dart_Port port = di->NextNotifyDartPort(event_mask);
	ASSERT(port != 0);
	UpdateKQueueInstance(old_mask, di);
	DartUtils::PostInt32(port, event_mask);
	}
	}
	}
	if (interrupt_seen) {
	// Handle after socket events, so we avoid closing a socket before we handle
	// the current events.
	HandleInterruptFd();
	}
	}

	int64_t EventHandlerImplementation::GetTimeout() {
	if (!timeout_queue_.HasTimeout()) {
	return kInfinityTimeout;
	}
	int64_t millis =
	timeout_queue_.CurrentTimeout() - TimerUtils::GetCurrentMonotonicMillis();
	return (millis < 0) ? 0 : millis;
	}

	void EventHandlerImplementation::HandleTimeout() {
	if (timeout_queue_.HasTimeout()) {
	int64_t millis = timeout_queue_.CurrentTimeout() -
	TimerUtils::GetCurrentMonotonicMillis();
	if (millis <= 0) {
	DartUtils::PostNull(timeout_queue_.CurrentPort());
	timeout_queue_.RemoveCurrent();
	}
	}
	}

	void EventHandlerImplementation::EventHandlerEntry(uword args) {
	static const intptr_t kMaxEvents = 16;
	struct kevent events[kMaxEvents];
	EventHandler* handler = reinterpret_cast<EventHandler*>(args);
	EventHandlerImplementation* handler_impl = &handler->delegate_;
	ASSERT(handler_impl != NULL);

	while (!handler_impl->shutdown_) {
	int64_t millis = handler_impl->GetTimeout();
	ASSERT(millis == kInfinityTimeout \|\| millis >= 0);
	if (millis > kMaxInt32) {
	millis = kMaxInt32;
	}
	// NULL pointer timespec for infinite timeout.
	ASSERT(kInfinityTimeout < 0);
	struct timespec* timeout = NULL;
	struct timespec ts;
	if (millis >= 0) {
	int32_t millis32 = static_cast<int32_t>(millis);
	int32_t secs = millis32 / 1000;
	ts.tv_sec = secs;
	ts.tv_nsec = (millis32 - (secs * 1000)) * 1000000;
	timeout = &ts;
	}
	// We have to use TEMP_FAILURE_RETRY for mac, as kevent can modify the
	// current sigmask.
	intptr_t result = TEMP_FAILURE_RETRY(
	kevent(handler_impl->kqueue_fd_, NULL, 0, events, kMaxEvents, timeout));
	if (result == -1) {
	const int kBufferSize = 1024;
	char error_message[kBufferSize];
	Utils::StrError(errno, error_message, kBufferSize);
	FATAL1("kevent failed %s\n", error_message);
	} else {
	handler_impl->HandleTimeout();
	handler_impl->HandleEvents(events, result);
	}
	}
	DEBUG_ASSERT(ReferenceCounted<Socket>::instances() == 0);
	handler->NotifyShutdownDone();
	}

	void EventHandlerImplementation::Start(EventHandler* handler) {
	int result = Thread::Start("dart:io EventHandler",
	&EventHandlerImplementation::EventHandlerEntry,
	reinterpret_cast<uword>(handler));
	if (result != 0) {
	FATAL1("Failed to start event handler thread %d", result);
	}
	}

	void EventHandlerImplementation::Shutdown() {
	SendData(kShutdownId, 0, 0);
	}

	void EventHandlerImplementation::SendData(intptr_t id,
	Dart_Port dart_port,
	int64_t data) {
	WakeupHandler(id, dart_port, data);
	}

	void* EventHandlerImplementation::GetHashmapKeyFromFd(intptr_t fd) {
	// The hashmap does not support keys with value 0.
	return reinterpret_cast<void*>(fd + 1);
	}

	uint32_t EventHandlerImplementation::GetHashmapHashFromFd(intptr_t fd) {
	// The hashmap does not support keys with value 0.
	return dart::Utils::WordHash(fd + 1);
	}

	} // namespace bin
	} // namespace dart

	#endif // defined(HOST_OS_MACOS)