1 // Copyright 2013 The Chromium Authors. All rights reserved. 2 // Use of this source code is governed by a BSD-style license that can be 3 // found in the LICENSE file. 4 5 #ifndef BASE_MESSAGE_LOOP_MESSAGE_LOOP_H_ 6 #define BASE_MESSAGE_LOOP_MESSAGE_LOOP_H_ 7 8 #include <memory> 9 #include <queue> 10 #include <string> 11 12 #include "base/base_export.h" 13 #include "base/callback_forward.h" 14 #include "base/debug/task_annotator.h" 15 #include "base/gtest_prod_util.h" 16 #include "base/macros.h" 17 #include "base/memory/ref_counted.h" 18 #include "base/message_loop/incoming_task_queue.h" 19 #include "base/message_loop/message_loop_task_runner.h" 20 #include "base/message_loop/message_pump.h" 21 #include "base/message_loop/timer_slack.h" 22 #include "base/observer_list.h" 23 #include "base/pending_task.h" 24 #include "base/synchronization/lock.h" 25 #include "base/time/time.h" 26 #include "build/build_config.h" 27 28 // TODO(sky): these includes should not be necessary. Nuke them. 29 #if defined(OS_WIN) 30 #include "base/message_loop/message_pump_win.h" 31 #elif defined(OS_IOS) 32 #include "base/message_loop/message_pump_io_ios.h" 33 #elif defined(OS_POSIX) 34 #include "base/message_loop/message_pump_libevent.h" 35 #endif 36 37 #if defined(OS_ANDROID) 38 namespace base { 39 namespace android { 40 41 class JavaMessageHandlerFactory; 42 43 } // namespace android 44 } // namespace base 45 #endif // defined(OS_ANDROID) 46 47 namespace base { 48 49 class RunLoop; 50 class ThreadTaskRunnerHandle; 51 class WaitableEvent; 52 53 // A MessageLoop is used to process events for a particular thread. There is 54 // at most one MessageLoop instance per thread. 55 // 56 // Events include at a minimum Task instances submitted to the MessageLoop's 57 // TaskRunner. Depending on the type of message pump used by the MessageLoop 58 // other events such as UI messages may be processed. On Windows APC calls (as 59 // time permits) and signals sent to a registered set of HANDLEs may also be 60 // processed. 61 // 62 // NOTE: Unless otherwise specified, a MessageLoop's methods may only be called 63 // on the thread where the MessageLoop's Run method executes. 64 // 65 // NOTE: MessageLoop has task reentrancy protection. This means that if a 66 // task is being processed, a second task cannot start until the first task is 67 // finished. Reentrancy can happen when processing a task, and an inner 68 // message pump is created. That inner pump then processes native messages 69 // which could implicitly start an inner task. Inner message pumps are created 70 // with dialogs (DialogBox), common dialogs (GetOpenFileName), OLE functions 71 // (DoDragDrop), printer functions (StartDoc) and *many* others. 72 // 73 // Sample workaround when inner task processing is needed: 74 // HRESULT hr; 75 // { 76 // MessageLoop::ScopedNestableTaskAllower allow(MessageLoop::current()); 77 // hr = DoDragDrop(...); // Implicitly runs a modal message loop. 78 // } 79 // // Process |hr| (the result returned by DoDragDrop()). 80 // 81 // Please be SURE your task is reentrant (nestable) and all global variables 82 // are stable and accessible before calling SetNestableTasksAllowed(true). 83 // 84 class BASE_EXPORT MessageLoop : public MessagePump::Delegate { 85 public: 86 // A MessageLoop has a particular type, which indicates the set of 87 // asynchronous events it may process in addition to tasks and timers. 88 // 89 // TYPE_DEFAULT 90 // This type of ML only supports tasks and timers. 91 // 92 // TYPE_UI 93 // This type of ML also supports native UI events (e.g., Windows messages). 94 // See also MessageLoopForUI. 95 // 96 // TYPE_IO 97 // This type of ML also supports asynchronous IO. See also 98 // MessageLoopForIO. 99 // 100 // TYPE_JAVA 101 // This type of ML is backed by a Java message handler which is responsible 102 // for running the tasks added to the ML. This is only for use on Android. 103 // TYPE_JAVA behaves in essence like TYPE_UI, except during construction 104 // where it does not use the main thread specific pump factory. 105 // 106 // TYPE_CUSTOM 107 // MessagePump was supplied to constructor. 108 // 109 enum Type { 110 TYPE_DEFAULT, 111 TYPE_UI, 112 TYPE_CUSTOM, 113 TYPE_IO, 114 #if defined(OS_ANDROID) 115 TYPE_JAVA, 116 #endif // defined(OS_ANDROID) 117 }; 118 119 // Normally, it is not necessary to instantiate a MessageLoop. Instead, it 120 // is typical to make use of the current thread's MessageLoop instance. 121 explicit MessageLoop(Type type = TYPE_DEFAULT); 122 // Creates a TYPE_CUSTOM MessageLoop with the supplied MessagePump, which must 123 // be non-NULL. 124 explicit MessageLoop(std::unique_ptr<MessagePump> pump); 125 126 ~MessageLoop() override; 127 128 // Returns the MessageLoop object for the current thread, or null if none. 129 static MessageLoop* current(); 130 131 typedef std::unique_ptr<MessagePump>(MessagePumpFactory)(); 132 // Uses the given base::MessagePumpForUIFactory to override the default 133 // MessagePump implementation for 'TYPE_UI'. Returns true if the factory 134 // was successfully registered. 135 static bool InitMessagePumpForUIFactory(MessagePumpFactory* factory); 136 137 // Creates the default MessagePump based on |type|. Caller owns return 138 // value. 139 static std::unique_ptr<MessagePump> CreateMessagePumpForType(Type type); 140 141 // A DestructionObserver is notified when the current MessageLoop is being 142 // destroyed. These observers are notified prior to MessageLoop::current() 143 // being changed to return NULL. This gives interested parties the chance to 144 // do final cleanup that depends on the MessageLoop. 145 // 146 // NOTE: Any tasks posted to the MessageLoop during this notification will 147 // not be run. Instead, they will be deleted. 148 // 149 class BASE_EXPORT DestructionObserver { 150 public: 151 virtual void WillDestroyCurrentMessageLoop() = 0; 152 153 protected: 154 virtual ~DestructionObserver(); 155 }; 156 157 // Add a DestructionObserver, which will start receiving notifications 158 // immediately. 159 void AddDestructionObserver(DestructionObserver* destruction_observer); 160 161 // Remove a DestructionObserver. It is safe to call this method while a 162 // DestructionObserver is receiving a notification callback. 163 void RemoveDestructionObserver(DestructionObserver* destruction_observer); 164 165 // A NestingObserver is notified when a nested message loop begins. The 166 // observers are notified before the first task is processed. 167 class BASE_EXPORT NestingObserver { 168 public: 169 virtual void OnBeginNestedMessageLoop() = 0; 170 171 protected: 172 virtual ~NestingObserver(); 173 }; 174 175 void AddNestingObserver(NestingObserver* observer); 176 void RemoveNestingObserver(NestingObserver* observer); 177 178 // Deprecated: use RunLoop instead. 179 // 180 // Signals the Run method to return when it becomes idle. It will continue to 181 // process pending messages and future messages as long as they are enqueued. 182 // Warning: if the MessageLoop remains busy, it may never quit. Only use this 183 // Quit method when looping procedures (such as web pages) have been shut 184 // down. 185 // 186 // This method may only be called on the same thread that called Run, and Run 187 // must still be on the call stack. 188 // 189 // Use QuitClosure variants if you need to Quit another thread's MessageLoop, 190 // but note that doing so is fairly dangerous if the target thread makes 191 // nested calls to MessageLoop::Run. The problem being that you won't know 192 // which nested run loop you are quitting, so be careful! 193 void QuitWhenIdle(); 194 195 // Deprecated: use RunLoop instead. 196 // 197 // This method is a variant of Quit, that does not wait for pending messages 198 // to be processed before returning from Run. 199 void QuitNow(); 200 201 // Deprecated: use RunLoop instead. 202 // Construct a Closure that will call QuitWhenIdle(). Useful to schedule an 203 // arbitrary MessageLoop to QuitWhenIdle. 204 static Closure QuitWhenIdleClosure(); 205 206 // Set the timer slack for this message loop. SetTimerSlack(TimerSlack timer_slack)207 void SetTimerSlack(TimerSlack timer_slack) { 208 pump_->SetTimerSlack(timer_slack); 209 } 210 211 // Returns true if this loop is |type|. This allows subclasses (especially 212 // those in tests) to specialize how they are identified. 213 virtual bool IsType(Type type) const; 214 215 // Returns the type passed to the constructor. type()216 Type type() const { return type_; } 217 218 // Returns the name of the thread this message loop is bound to. This function 219 // is only valid when this message loop is running, BindToCurrentThread has 220 // already been called and has an "happens-before" relationship with this call 221 // (this relationship is obtained implicitly by the MessageLoop's task posting 222 // system unless calling this very early). 223 std::string GetThreadName() const; 224 225 // Gets the TaskRunner associated with this message loop. task_runner()226 const scoped_refptr<SingleThreadTaskRunner>& task_runner() { 227 return task_runner_; 228 } 229 230 // Sets a new TaskRunner for this message loop. The message loop must already 231 // have been bound to a thread prior to this call, and the task runner must 232 // belong to that thread. Note that changing the task runner will also affect 233 // the ThreadTaskRunnerHandle for the target thread. Must be called on the 234 // thread to which the message loop is bound. 235 void SetTaskRunner(scoped_refptr<SingleThreadTaskRunner> task_runner); 236 237 // Clears task_runner() and the ThreadTaskRunnerHandle for the target thread. 238 // Must be called on the thread to which the message loop is bound. 239 void ClearTaskRunnerForTesting(); 240 241 // Enables or disables the recursive task processing. This happens in the case 242 // of recursive message loops. Some unwanted message loops may occur when 243 // using common controls or printer functions. By default, recursive task 244 // processing is disabled. 245 // 246 // Please use |ScopedNestableTaskAllower| instead of calling these methods 247 // directly. In general, nestable message loops are to be avoided. They are 248 // dangerous and difficult to get right, so please use with extreme caution. 249 // 250 // The specific case where tasks get queued is: 251 // - The thread is running a message loop. 252 // - It receives a task #1 and executes it. 253 // - The task #1 implicitly starts a message loop, like a MessageBox in the 254 // unit test. This can also be StartDoc or GetSaveFileName. 255 // - The thread receives a task #2 before or while in this second message 256 // loop. 257 // - With NestableTasksAllowed set to true, the task #2 will run right away. 258 // Otherwise, it will get executed right after task #1 completes at "thread 259 // message loop level". 260 void SetNestableTasksAllowed(bool allowed); 261 bool NestableTasksAllowed() const; 262 263 // Enables nestable tasks on |loop| while in scope. 264 class ScopedNestableTaskAllower { 265 public: ScopedNestableTaskAllower(MessageLoop * loop)266 explicit ScopedNestableTaskAllower(MessageLoop* loop) 267 : loop_(loop), 268 old_state_(loop_->NestableTasksAllowed()) { 269 loop_->SetNestableTasksAllowed(true); 270 } ~ScopedNestableTaskAllower()271 ~ScopedNestableTaskAllower() { 272 loop_->SetNestableTasksAllowed(old_state_); 273 } 274 275 private: 276 MessageLoop* loop_; 277 bool old_state_; 278 }; 279 280 // Returns true if we are currently running a nested message loop. 281 bool IsNested(); 282 283 // A TaskObserver is an object that receives task notifications from the 284 // MessageLoop. 285 // 286 // NOTE: A TaskObserver implementation should be extremely fast! 287 class BASE_EXPORT TaskObserver { 288 public: 289 TaskObserver(); 290 291 // This method is called before processing a task. 292 virtual void WillProcessTask(const PendingTask& pending_task) = 0; 293 294 // This method is called after processing a task. 295 virtual void DidProcessTask(const PendingTask& pending_task) = 0; 296 297 protected: 298 virtual ~TaskObserver(); 299 }; 300 301 // These functions can only be called on the same thread that |this| is 302 // running on. 303 void AddTaskObserver(TaskObserver* task_observer); 304 void RemoveTaskObserver(TaskObserver* task_observer); 305 306 // Can only be called from the thread that owns the MessageLoop. 307 bool is_running() const; 308 309 // Returns true if the message loop has high resolution timers enabled. 310 // Provided for testing. 311 bool HasHighResolutionTasks(); 312 313 // Returns true if the message loop is "idle". Provided for testing. 314 bool IsIdleForTesting(); 315 316 // Returns the TaskAnnotator which is used to add debug information to posted 317 // tasks. task_annotator()318 debug::TaskAnnotator* task_annotator() { return &task_annotator_; } 319 320 // Runs the specified PendingTask. 321 void RunTask(PendingTask* pending_task); 322 nesting_allowed()323 bool nesting_allowed() const { return allow_nesting_; } 324 325 // Disallow nesting. After this is called, running a nested RunLoop or calling 326 // Add/RemoveNestingObserver() on this MessageLoop will crash. DisallowNesting()327 void DisallowNesting() { allow_nesting_ = false; } 328 329 // Disallow task observers. After this is called, calling 330 // Add/RemoveTaskObserver() on this MessageLoop will crash. DisallowTaskObservers()331 void DisallowTaskObservers() { allow_task_observers_ = false; } 332 333 //---------------------------------------------------------------------------- 334 protected: 335 std::unique_ptr<MessagePump> pump_; 336 337 using MessagePumpFactoryCallback = Callback<std::unique_ptr<MessagePump>()>; 338 339 // Common protected constructor. Other constructors delegate the 340 // initialization to this constructor. 341 // A subclass can invoke this constructor to create a message_loop of a 342 // specific type with a custom loop. The implementation does not call 343 // BindToCurrentThread. If this constructor is invoked directly by a subclass, 344 // then the subclass must subsequently bind the message loop. 345 MessageLoop(Type type, MessagePumpFactoryCallback pump_factory); 346 347 // Configure various members and bind this message loop to the current thread. 348 void BindToCurrentThread(); 349 350 private: 351 friend class internal::IncomingTaskQueue; 352 friend class RunLoop; 353 friend class ScheduleWorkTest; 354 friend class Thread; 355 friend struct PendingTask; 356 FRIEND_TEST_ALL_PREFIXES(MessageLoopTest, DeleteUnboundLoop); 357 friend class PendingTaskTest; 358 359 // Creates a MessageLoop without binding to a thread. 360 // If |type| is TYPE_CUSTOM non-null |pump_factory| must be also given 361 // to create a message pump for this message loop. Otherwise a default 362 // message pump for the |type| is created. 363 // 364 // It is valid to call this to create a new message loop on one thread, 365 // and then pass it to the thread where the message loop actually runs. 366 // The message loop's BindToCurrentThread() method must be called on the 367 // thread the message loop runs on, before calling Run(). 368 // Before BindToCurrentThread() is called, only Post*Task() functions can 369 // be called on the message loop. 370 static std::unique_ptr<MessageLoop> CreateUnbound( 371 Type type, 372 MessagePumpFactoryCallback pump_factory); 373 374 // Sets the ThreadTaskRunnerHandle for the current thread to point to the 375 // task runner for this message loop. 376 void SetThreadTaskRunnerHandle(); 377 378 // Invokes the actual run loop using the message pump. 379 void RunHandler(); 380 381 // Called to process any delayed non-nestable tasks. 382 bool ProcessNextDelayedNonNestableTask(); 383 384 // Calls RunTask or queues the pending_task on the deferred task list if it 385 // cannot be run right now. Returns true if the task was run. 386 bool DeferOrRunPendingTask(PendingTask pending_task); 387 388 // Adds the pending task to delayed_work_queue_. 389 void AddToDelayedWorkQueue(PendingTask pending_task); 390 391 // Delete tasks that haven't run yet without running them. Used in the 392 // destructor to make sure all the task's destructors get called. Returns 393 // true if some work was done. 394 bool DeletePendingTasks(); 395 396 // Loads tasks from the incoming queue to |work_queue_| if the latter is 397 // empty. 398 void ReloadWorkQueue(); 399 400 // Wakes up the message pump. Can be called on any thread. The caller is 401 // responsible for synchronizing ScheduleWork() calls. 402 void ScheduleWork(); 403 404 // Notify observers that a nested message loop is starting. 405 void NotifyBeginNestedLoop(); 406 407 // MessagePump::Delegate methods: 408 bool DoWork() override; 409 bool DoDelayedWork(TimeTicks* next_delayed_work_time) override; 410 bool DoIdleWork() override; 411 412 const Type type_; 413 414 // A list of tasks that need to be processed by this instance. Note that 415 // this queue is only accessed (push/pop) by our current thread. 416 TaskQueue work_queue_; 417 418 #if defined(OS_WIN) 419 // How many high resolution tasks are in the pending task queue. This value 420 // increases by N every time we call ReloadWorkQueue() and decreases by 1 421 // every time we call RunTask() if the task needs a high resolution timer. 422 int pending_high_res_tasks_; 423 // Tracks if we have requested high resolution timers. Its only use is to 424 // turn off the high resolution timer upon loop destruction. 425 bool in_high_res_mode_; 426 #endif 427 428 // Contains delayed tasks, sorted by their 'delayed_run_time' property. 429 DelayedTaskQueue delayed_work_queue_; 430 431 // A recent snapshot of Time::Now(), used to check delayed_work_queue_. 432 TimeTicks recent_time_; 433 434 // A queue of non-nestable tasks that we had to defer because when it came 435 // time to execute them we were in a nested message loop. They will execute 436 // once we're out of nested message loops. 437 TaskQueue deferred_non_nestable_work_queue_; 438 439 ObserverList<DestructionObserver> destruction_observers_; 440 441 ObserverList<NestingObserver> nesting_observers_; 442 443 // A recursion block that prevents accidentally running additional tasks when 444 // insider a (accidentally induced?) nested message pump. 445 bool nestable_tasks_allowed_; 446 447 // pump_factory_.Run() is called to create a message pump for this loop 448 // if type_ is TYPE_CUSTOM and pump_ is null. 449 MessagePumpFactoryCallback pump_factory_; 450 451 RunLoop* run_loop_; 452 453 ObserverList<TaskObserver> task_observers_; 454 455 debug::TaskAnnotator task_annotator_; 456 457 // Used to allow creating a breadcrumb of program counters in PostTask. 458 // This variable is only initialized while a task is being executed and is 459 // meant only to store context for creating a backtrace breadcrumb. Do not 460 // attach other semantics to it without thinking through the use caes 461 // thoroughly. 462 const PendingTask* current_pending_task_; 463 464 scoped_refptr<internal::IncomingTaskQueue> incoming_task_queue_; 465 466 // A task runner which we haven't bound to a thread yet. 467 scoped_refptr<internal::MessageLoopTaskRunner> unbound_task_runner_; 468 469 // The task runner associated with this message loop. 470 scoped_refptr<SingleThreadTaskRunner> task_runner_; 471 std::unique_ptr<ThreadTaskRunnerHandle> thread_task_runner_handle_; 472 473 // Id of the thread this message loop is bound to. Initialized once when the 474 // MessageLoop is bound to its thread and constant forever after. 475 PlatformThreadId thread_id_; 476 477 // Whether nesting is allowed. 478 bool allow_nesting_ = true; 479 480 // Whether task observers are allowed. 481 bool allow_task_observers_ = true; 482 483 DISALLOW_COPY_AND_ASSIGN(MessageLoop); 484 }; 485 486 #if !defined(OS_NACL) 487 488 //----------------------------------------------------------------------------- 489 // MessageLoopForUI extends MessageLoop with methods that are particular to a 490 // MessageLoop instantiated with TYPE_UI. 491 // 492 // This class is typically used like so: 493 // MessageLoopForUI::current()->...call some method... 494 // 495 class BASE_EXPORT MessageLoopForUI : public MessageLoop { 496 public: MessageLoopForUI()497 MessageLoopForUI() : MessageLoop(TYPE_UI) { 498 } 499 500 explicit MessageLoopForUI(std::unique_ptr<MessagePump> pump); 501 502 // Returns the MessageLoopForUI of the current thread. current()503 static MessageLoopForUI* current() { 504 MessageLoop* loop = MessageLoop::current(); 505 DCHECK(loop); 506 DCHECK(loop->IsType(MessageLoop::TYPE_UI)); 507 return static_cast<MessageLoopForUI*>(loop); 508 } 509 IsCurrent()510 static bool IsCurrent() { 511 MessageLoop* loop = MessageLoop::current(); 512 return loop && loop->IsType(MessageLoop::TYPE_UI); 513 } 514 515 #if defined(OS_IOS) 516 // On iOS, the main message loop cannot be Run(). Instead call Attach(), 517 // which connects this MessageLoop to the UI thread's CFRunLoop and allows 518 // PostTask() to work. 519 void Attach(); 520 #endif 521 522 #if defined(OS_ANDROID) 523 // On Android, the UI message loop is handled by Java side. So Run() should 524 // never be called. Instead use Start(), which will forward all the native UI 525 // events to the Java message loop. 526 void Start(); 527 void StartForTesting(base::android::JavaMessageHandlerFactory* factory, 528 WaitableEvent* test_done_event); 529 // In Android there are cases where we want to abort immediately without 530 // calling Quit(), in these cases we call Abort(). 531 void Abort(); 532 #endif 533 534 #if defined(USE_OZONE) || (defined(USE_X11) && !defined(USE_GLIB)) 535 // Please see MessagePumpLibevent for definition. 536 bool WatchFileDescriptor( 537 int fd, 538 bool persistent, 539 MessagePumpLibevent::Mode mode, 540 MessagePumpLibevent::FileDescriptorWatcher* controller, 541 MessagePumpLibevent::Watcher* delegate); 542 #endif 543 }; 544 545 // Do not add any member variables to MessageLoopForUI! This is important b/c 546 // MessageLoopForUI is often allocated via MessageLoop(TYPE_UI). Any extra 547 // data that you need should be stored on the MessageLoop's pump_ instance. 548 static_assert(sizeof(MessageLoop) == sizeof(MessageLoopForUI), 549 "MessageLoopForUI should not have extra member variables"); 550 551 #endif // !defined(OS_NACL) 552 553 //----------------------------------------------------------------------------- 554 // MessageLoopForIO extends MessageLoop with methods that are particular to a 555 // MessageLoop instantiated with TYPE_IO. 556 // 557 // This class is typically used like so: 558 // MessageLoopForIO::current()->...call some method... 559 // 560 class BASE_EXPORT MessageLoopForIO : public MessageLoop { 561 public: MessageLoopForIO()562 MessageLoopForIO() : MessageLoop(TYPE_IO) { 563 } 564 565 // Returns the MessageLoopForIO of the current thread. current()566 static MessageLoopForIO* current() { 567 MessageLoop* loop = MessageLoop::current(); 568 DCHECK(loop) << "Can't call MessageLoopForIO::current() when no message " 569 "loop was created for this thread. Use " 570 " MessageLoop::current() or MessageLoopForIO::IsCurrent()."; 571 DCHECK_EQ(MessageLoop::TYPE_IO, loop->type()); 572 return static_cast<MessageLoopForIO*>(loop); 573 } 574 IsCurrent()575 static bool IsCurrent() { 576 MessageLoop* loop = MessageLoop::current(); 577 return loop && loop->type() == MessageLoop::TYPE_IO; 578 } 579 580 #if !defined(OS_NACL_SFI) 581 582 #if defined(OS_WIN) 583 typedef MessagePumpForIO::IOHandler IOHandler; 584 typedef MessagePumpForIO::IOContext IOContext; 585 #elif defined(OS_IOS) 586 typedef MessagePumpIOSForIO::Watcher Watcher; 587 typedef MessagePumpIOSForIO::FileDescriptorWatcher 588 FileDescriptorWatcher; 589 590 enum Mode { 591 WATCH_READ = MessagePumpIOSForIO::WATCH_READ, 592 WATCH_WRITE = MessagePumpIOSForIO::WATCH_WRITE, 593 WATCH_READ_WRITE = MessagePumpIOSForIO::WATCH_READ_WRITE 594 }; 595 #elif defined(OS_POSIX) 596 typedef MessagePumpLibevent::Watcher Watcher; 597 typedef MessagePumpLibevent::FileDescriptorWatcher 598 FileDescriptorWatcher; 599 600 enum Mode { 601 WATCH_READ = MessagePumpLibevent::WATCH_READ, 602 WATCH_WRITE = MessagePumpLibevent::WATCH_WRITE, 603 WATCH_READ_WRITE = MessagePumpLibevent::WATCH_READ_WRITE 604 }; 605 #endif 606 607 #if defined(OS_WIN) 608 // Please see MessagePumpWin for definitions of these methods. 609 void RegisterIOHandler(HANDLE file, IOHandler* handler); 610 bool RegisterJobObject(HANDLE job, IOHandler* handler); 611 bool WaitForIOCompletion(DWORD timeout, IOHandler* filter); 612 #elif defined(OS_POSIX) 613 // Please see MessagePumpIOSForIO/MessagePumpLibevent for definition. 614 bool WatchFileDescriptor(int fd, 615 bool persistent, 616 Mode mode, 617 FileDescriptorWatcher* controller, 618 Watcher* delegate); 619 #endif // defined(OS_IOS) || defined(OS_POSIX) 620 #endif // !defined(OS_NACL_SFI) 621 }; 622 623 // Do not add any member variables to MessageLoopForIO! This is important b/c 624 // MessageLoopForIO is often allocated via MessageLoop(TYPE_IO). Any extra 625 // data that you need should be stored on the MessageLoop's pump_ instance. 626 static_assert(sizeof(MessageLoop) == sizeof(MessageLoopForIO), 627 "MessageLoopForIO should not have extra member variables"); 628 629 } // namespace base 630 631 #endif // BASE_MESSAGE_LOOP_MESSAGE_LOOP_H_ 632