1 // Copyright 2017 The Chromium Authors
2 // Use of this source code is governed by a BSD-style license that can be
3 // found in the LICENSE file.
4
5 #include "base/task/thread_pool/pooled_single_thread_task_runner_manager.h"
6
7 #include <memory>
8 #include <string>
9 #include <utility>
10
11 #include "base/check.h"
12 #include "base/debug/leak_annotations.h"
13 #include "base/functional/bind.h"
14 #include "base/functional/callback.h"
15 #include "base/memory/ptr_util.h"
16 #include "base/memory/raw_ptr.h"
17 #include "base/ranges/algorithm.h"
18 #include "base/strings/stringprintf.h"
19 #include "base/synchronization/atomic_flag.h"
20 #include "base/task/default_delayed_task_handle_delegate.h"
21 #include "base/task/single_thread_task_runner.h"
22 #include "base/task/task_features.h"
23 #include "base/task/task_traits.h"
24 #include "base/task/thread_pool/delayed_task_manager.h"
25 #include "base/task/thread_pool/priority_queue.h"
26 #include "base/task/thread_pool/sequence.h"
27 #include "base/task/thread_pool/task.h"
28 #include "base/task/thread_pool/task_source.h"
29 #include "base/task/thread_pool/task_tracker.h"
30 #include "base/task/thread_pool/worker_thread_waitable_event.h"
31 #include "base/threading/platform_thread.h"
32 #include "base/time/time.h"
33 #include "build/build_config.h"
34
35 #if BUILDFLAG(IS_WIN)
36 #include <windows.h>
37
38 #include "base/win/scoped_com_initializer.h"
39 #endif // BUILDFLAG(IS_WIN)
40
41 namespace base {
42 namespace internal {
43
44 namespace {
45
46 // Boolean indicating whether there's a PooledSingleThreadTaskRunnerManager
47 // instance alive in this process. This variable should only be set when the
48 // PooledSingleThreadTaskRunnerManager instance is brought up (on the main
49 // thread; before any tasks are posted) and decremented when the instance is
50 // brought down (i.e., only when unit tests tear down the task environment and
51 // never in production). This makes the variable const while worker threads are
52 // up and as such it doesn't need to be atomic. It is used to tell when a task
53 // is posted from the main thread after the task environment was brought down in
54 // unit tests so that PooledSingleThreadTaskRunnerManager bound TaskRunners
55 // can return false on PostTask, letting such callers know they should complete
56 // necessary work synchronously. Note: |!g_manager_is_alive| is generally
57 // equivalent to |!ThreadPoolInstance::Get()| but has the advantage of being
58 // valid in thread_pool unit tests that don't instantiate a full
59 // thread pool.
60 bool g_manager_is_alive = false;
61
62 bool g_use_utility_thread_group = false;
63
GetEnvironmentIndexForTraits(const TaskTraits & traits)64 size_t GetEnvironmentIndexForTraits(const TaskTraits& traits) {
65 const bool is_background =
66 traits.priority() == TaskPriority::BEST_EFFORT &&
67 traits.thread_policy() == ThreadPolicy::PREFER_BACKGROUND &&
68 CanUseBackgroundThreadTypeForWorkerThread();
69 const bool is_utility =
70 !is_background && traits.priority() <= TaskPriority::USER_VISIBLE &&
71 traits.thread_policy() == ThreadPolicy::PREFER_BACKGROUND &&
72 g_use_utility_thread_group;
73 if (traits.may_block() || traits.with_base_sync_primitives()) {
74 return is_background ? BACKGROUND_BLOCKING
75 : is_utility ? UTILITY_BLOCKING
76 : FOREGROUND_BLOCKING;
77 }
78 return is_background ? BACKGROUND : is_utility ? UTILITY : FOREGROUND;
79 }
80
81 // Allows for checking the PlatformThread::CurrentRef() against a set
82 // PlatformThreadRef atomically without using locks.
83 class AtomicThreadRefChecker {
84 public:
85 AtomicThreadRefChecker() = default;
86 AtomicThreadRefChecker(const AtomicThreadRefChecker&) = delete;
87 AtomicThreadRefChecker& operator=(const AtomicThreadRefChecker&) = delete;
88 ~AtomicThreadRefChecker() = default;
89
Set()90 void Set() {
91 thread_ref_ = PlatformThread::CurrentRef();
92 is_set_.Set();
93 }
94
IsCurrentThreadSameAsSetThread()95 bool IsCurrentThreadSameAsSetThread() {
96 return is_set_.IsSet() && thread_ref_ == PlatformThread::CurrentRef();
97 }
98
99 private:
100 AtomicFlag is_set_;
101 PlatformThreadRef thread_ref_;
102 };
103
104 class WorkerThreadDelegate : public WorkerThreadWaitableEvent::Delegate {
105 public:
WorkerThreadDelegate(const std::string & thread_name,WorkerThread::ThreadLabel thread_label,TrackedRef<TaskTracker> task_tracker)106 WorkerThreadDelegate(const std::string& thread_name,
107 WorkerThread::ThreadLabel thread_label,
108 TrackedRef<TaskTracker> task_tracker)
109 : task_tracker_(std::move(task_tracker)),
110 thread_name_(thread_name),
111 thread_label_(thread_label) {}
112 WorkerThreadDelegate(const WorkerThreadDelegate&) = delete;
113 WorkerThreadDelegate& operator=(const WorkerThreadDelegate&) = delete;
114
set_worker(WorkerThreadWaitableEvent * worker)115 void set_worker(WorkerThreadWaitableEvent* worker) {
116 DCHECK(!worker_);
117 worker_ = worker;
118 }
119
GetThreadLabel() const120 WorkerThread::ThreadLabel GetThreadLabel() const final {
121 return thread_label_;
122 }
123
OnMainEntry(WorkerThread *)124 void OnMainEntry(WorkerThread* /* worker */) override {
125 thread_ref_checker_.Set();
126 PlatformThread::SetName(thread_name_);
127 }
128
GetWork(WorkerThread * worker)129 RegisteredTaskSource GetWork(WorkerThread* worker) override {
130 CheckedAutoLock auto_lock(lock_);
131 DCHECK(worker_awake_);
132
133 auto task_source = GetWorkLockRequired(worker);
134 if (!task_source) {
135 // The worker will sleep after this returns nullptr.
136 worker_awake_ = false;
137 return nullptr;
138 }
139 auto run_status = task_source.WillRunTask();
140 DCHECK_NE(run_status, TaskSource::RunStatus::kDisallowed);
141 return task_source;
142 }
143
SwapProcessedTask(RegisteredTaskSource task_source,WorkerThread * worker)144 RegisteredTaskSource SwapProcessedTask(RegisteredTaskSource task_source,
145 WorkerThread* worker) override {
146 std::optional<RegisteredTaskSourceAndTransaction>
147 task_source_with_transaction;
148 if (task_source) {
149 task_source_with_transaction.emplace(
150 RegisteredTaskSourceAndTransaction::FromTaskSource(
151 std::move(task_source)));
152 task_source_with_transaction->task_source.WillReEnqueue(
153 TimeTicks::Now(), &task_source_with_transaction->transaction);
154 }
155 CheckedAutoLock auto_lock(lock_);
156 if (task_source_with_transaction.has_value()) {
157 EnqueueTaskSourceLockRequired(std::move(*task_source_with_transaction));
158 }
159
160 // Calling WakeUp() guarantees that this WorkerThread will run Tasks from
161 // TaskSources returned by the GetWork() method of |delegate_| until it
162 // returns nullptr. Resetting |wake_up_event_| here doesn't break this
163 // invariant and avoids a useless loop iteration before going to sleep if
164 // WakeUp() is called while this WorkerThread is awake.
165 wake_up_event_.Reset();
166
167 auto new_task_source = GetWorkLockRequired(worker);
168 if (!new_task_source) {
169 // The worker will sleep after this returns nullptr.
170 worker_awake_ = false;
171 return nullptr;
172 }
173 auto run_status = new_task_source.WillRunTask();
174 DCHECK_NE(run_status, TaskSource::RunStatus::kDisallowed);
175 return new_task_source;
176 }
177
GetSleepTimeout()178 TimeDelta GetSleepTimeout() override { return TimeDelta::Max(); }
179
PostTaskNow(scoped_refptr<Sequence> sequence,Task task)180 bool PostTaskNow(scoped_refptr<Sequence> sequence, Task task) {
181 auto transaction = sequence->BeginTransaction();
182
183 // |task| will be pushed to |sequence|, and |sequence| will be queued
184 // to |priority_queue_| iff |sequence_should_be_queued| is true.
185 const bool sequence_should_be_queued = transaction.WillPushImmediateTask();
186 RegisteredTaskSource task_source;
187 if (sequence_should_be_queued) {
188 task_source = task_tracker_->RegisterTaskSource(sequence);
189 // We shouldn't push |task| if we're not allowed to queue |task_source|.
190 if (!task_source)
191 return false;
192 }
193 if (!task_tracker_->WillPostTaskNow(task, transaction.traits().priority()))
194 return false;
195 transaction.PushImmediateTask(std::move(task));
196 if (task_source) {
197 bool should_wakeup;
198 {
199 CheckedAutoLock auto_lock(lock_);
200 should_wakeup = EnqueueTaskSourceLockRequired(
201 {std::move(task_source), std::move(transaction)});
202 }
203 if (should_wakeup) {
204 worker_->WakeUp();
205 }
206 }
207 return true;
208 }
209
RunsTasksInCurrentSequence()210 bool RunsTasksInCurrentSequence() {
211 // We check the thread ref instead of the sequence for the benefit of COM
212 // callbacks which may execute without a sequence context.
213 return thread_ref_checker_.IsCurrentThreadSameAsSetThread();
214 }
215
OnMainExit(WorkerThread *)216 void OnMainExit(WorkerThread* /* worker */) override {}
217
DidUpdateCanRunPolicy()218 void DidUpdateCanRunPolicy() {
219 bool should_wakeup = false;
220 {
221 CheckedAutoLock auto_lock(lock_);
222 if (!worker_awake_ && CanRunNextTaskSource()) {
223 should_wakeup = true;
224 worker_awake_ = true;
225 }
226 }
227 if (should_wakeup)
228 worker_->WakeUp();
229 }
230
EnableFlushPriorityQueueTaskSourcesOnDestroyForTesting()231 void EnableFlushPriorityQueueTaskSourcesOnDestroyForTesting() {
232 CheckedAutoLock auto_lock(lock_);
233 priority_queue_.EnableFlushTaskSourcesOnDestroyForTesting();
234 }
235
236 protected:
GetWorkLockRequired(WorkerThread * worker)237 RegisteredTaskSource GetWorkLockRequired(WorkerThread* worker)
238 EXCLUSIVE_LOCKS_REQUIRED(lock_) {
239 if (!CanRunNextTaskSource()) {
240 return nullptr;
241 }
242 return priority_queue_.PopTaskSource();
243 }
244
task_tracker()245 const TrackedRef<TaskTracker>& task_tracker() { return task_tracker_; }
246
247 CheckedLock lock_;
248 bool worker_awake_ GUARDED_BY(lock_) = false;
249
250 const TrackedRef<TaskTracker> task_tracker_;
251
252 private:
253 // Enqueues a task source in this single-threaded worker's priority queue.
254 // Returns true iff the worker must wakeup, i.e. task source is allowed to run
255 // and the worker was not awake.
EnqueueTaskSourceLockRequired(RegisteredTaskSourceAndTransaction transaction_with_task_source)256 bool EnqueueTaskSourceLockRequired(
257 RegisteredTaskSourceAndTransaction transaction_with_task_source)
258 EXCLUSIVE_LOCKS_REQUIRED(lock_) {
259 auto sort_key = transaction_with_task_source.task_source->GetSortKey();
260 // When moving |task_source| into |priority_queue_|, it may be destroyed
261 // on another thread as soon as |lock_| is released, since we're no longer
262 // holding a reference to it. To prevent UAF, release |transaction| before
263 // moving |task_source|. Ref. crbug.com/1412008
264 transaction_with_task_source.transaction.Release();
265 priority_queue_.Push(std::move(transaction_with_task_source.task_source),
266 sort_key);
267 if (!worker_awake_ && CanRunNextTaskSource()) {
268 worker_awake_ = true;
269 return true;
270 }
271 return false;
272 }
273
CanRunNextTaskSource()274 bool CanRunNextTaskSource() EXCLUSIVE_LOCKS_REQUIRED(lock_) {
275 return !priority_queue_.IsEmpty() &&
276 task_tracker_->CanRunPriority(
277 priority_queue_.PeekSortKey().priority());
278 }
279
280 const std::string thread_name_;
281 const WorkerThread::ThreadLabel thread_label_;
282
283 // The WorkerThread that has |this| as a delegate. Must be set before
284 // starting or posting a task to the WorkerThread, because it's used in
285 // OnMainEntry() and PostTaskNow().
286 raw_ptr<WorkerThreadWaitableEvent> worker_ = nullptr;
287
288 PriorityQueue priority_queue_ GUARDED_BY(lock_);
289
290 AtomicThreadRefChecker thread_ref_checker_;
291 };
292
293 #if BUILDFLAG(IS_WIN)
294
295 class WorkerThreadCOMDelegate : public WorkerThreadDelegate {
296 public:
WorkerThreadCOMDelegate(const std::string & thread_name,WorkerThread::ThreadLabel thread_label,TrackedRef<TaskTracker> task_tracker)297 WorkerThreadCOMDelegate(const std::string& thread_name,
298 WorkerThread::ThreadLabel thread_label,
299 TrackedRef<TaskTracker> task_tracker)
300 : WorkerThreadDelegate(thread_name,
301 thread_label,
302 std::move(task_tracker)) {}
303
304 WorkerThreadCOMDelegate(const WorkerThreadCOMDelegate&) = delete;
305 WorkerThreadCOMDelegate& operator=(const WorkerThreadCOMDelegate&) = delete;
~WorkerThreadCOMDelegate()306 ~WorkerThreadCOMDelegate() override { DCHECK(!scoped_com_initializer_); }
307
308 // WorkerThreadWaitableEvent::Delegate:
OnMainEntry(WorkerThread * worker)309 void OnMainEntry(WorkerThread* worker) override {
310 WorkerThreadDelegate::OnMainEntry(worker);
311
312 scoped_com_initializer_ = std::make_unique<win::ScopedCOMInitializer>();
313
314 // CHECK to make sure this COM thread is initialized correctly in an STA.
315 CHECK(scoped_com_initializer_->Succeeded());
316 }
317
GetWork(WorkerThread * worker)318 RegisteredTaskSource GetWork(WorkerThread* worker) override {
319 // This scheme below allows us to cover the following scenarios:
320 // * Only WorkerThreadDelegate::GetWork() has work:
321 // Always return the task source from GetWork().
322 // * Only the Windows Message Queue has work:
323 // Always return the task source from GetWorkFromWindowsMessageQueue();
324 // * Both WorkerThreadDelegate::GetWork() and the Windows Message Queue
325 // have work:
326 // Process task sources from each source round-robin style.
327 CheckedAutoLock auto_lock(lock_);
328
329 // |worker_awake_| is always set before a call to WakeUp(), but it is
330 // not set when messages are added to the Windows Message Queue. Ensure that
331 // it is set before getting work, to avoid unnecessary wake ups.
332 //
333 // Note: It wouldn't be sufficient to set |worker_awake_| in WaitForWork()
334 // when MsgWaitForMultipleObjectsEx() indicates that it was woken up by a
335 // Windows Message, because of the following scenario:
336 // T1: PostTask
337 // Queue task
338 // Set |worker_awake_| to true
339 // T2: Woken up by a Windows Message
340 // Set |worker_awake_| to true
341 // Run the task posted by T1
342 // Wait for work
343 // T1: WakeUp()
344 // T2: Woken up by Waitable Event
345 // Does not set |worker_awake_| (wake up not from Windows Message)
346 // GetWork
347 // !! Getting work while |worker_awake_| is false !!
348 worker_awake_ = true;
349 RegisteredTaskSource task_source;
350 if (get_work_first_) {
351 task_source = WorkerThreadDelegate::GetWorkLockRequired(worker);
352 if (task_source)
353 get_work_first_ = false;
354 }
355
356 if (!task_source) {
357 CheckedAutoUnlock auto_unlock(lock_);
358 task_source = GetWorkFromWindowsMessageQueue();
359 if (task_source)
360 get_work_first_ = true;
361 }
362
363 if (!task_source && !get_work_first_) {
364 // This case is important if we checked the Windows Message Queue first
365 // and found there was no work. We don't want to return null immediately
366 // as that could cause the thread to go to sleep while work is waiting via
367 // WorkerThreadDelegate::GetWork().
368 task_source = WorkerThreadDelegate::GetWorkLockRequired(worker);
369 }
370 if (!task_source) {
371 // The worker will sleep after this returns nullptr.
372 worker_awake_ = false;
373 return nullptr;
374 }
375 auto run_status = task_source.WillRunTask();
376 DCHECK_NE(run_status, TaskSource::RunStatus::kDisallowed);
377 return task_source;
378 }
379
OnMainExit(WorkerThread *)380 void OnMainExit(WorkerThread* /* worker */) override {
381 scoped_com_initializer_.reset();
382 }
383
WaitForWork()384 void WaitForWork() override {
385 const TimeDelta sleep_time = GetSleepTimeout();
386 const DWORD milliseconds_wait = checked_cast<DWORD>(
387 sleep_time.is_max() ? INFINITE : sleep_time.InMilliseconds());
388 const HANDLE wake_up_event_handle = wake_up_event_.handle();
389 MsgWaitForMultipleObjectsEx(1, &wake_up_event_handle, milliseconds_wait,
390 QS_ALLINPUT, 0);
391 }
392
393 private:
GetWorkFromWindowsMessageQueue()394 RegisteredTaskSource GetWorkFromWindowsMessageQueue() {
395 MSG msg;
396 if (PeekMessage(&msg, nullptr, 0, 0, PM_REMOVE) != FALSE) {
397 Task pump_message_task(FROM_HERE,
398 BindOnce(
399 [](MSG msg) {
400 TranslateMessage(&msg);
401 DispatchMessage(&msg);
402 },
403 std::move(msg)),
404 TimeTicks::Now(), TimeDelta());
405 if (task_tracker()->WillPostTask(
406 &pump_message_task, TaskShutdownBehavior::SKIP_ON_SHUTDOWN)) {
407 auto transaction = message_pump_sequence_->BeginTransaction();
408 const bool sequence_should_be_queued =
409 transaction.WillPushImmediateTask();
410 DCHECK(sequence_should_be_queued)
411 << "GetWorkFromWindowsMessageQueue() does not expect "
412 "queueing of pump tasks.";
413 auto registered_task_source = task_tracker_->RegisterTaskSource(
414 std::move(message_pump_sequence_));
415 if (!registered_task_source)
416 return nullptr;
417 transaction.PushImmediateTask(std::move(pump_message_task));
418 return registered_task_source;
419 } else {
420 // `pump_message_task`'s destructor may run sequence-affine code, so it
421 // must be leaked when `WillPostTask` returns false.
422 auto leak = std::make_unique<Task>(std::move(pump_message_task));
423 ANNOTATE_LEAKING_OBJECT_PTR(leak.get());
424 leak.release();
425 }
426 }
427 return nullptr;
428 }
429
430 bool get_work_first_ = true;
431 const scoped_refptr<Sequence> message_pump_sequence_ =
432 MakeRefCounted<Sequence>(TaskTraits{MayBlock()},
433 nullptr,
434 TaskSourceExecutionMode::kParallel);
435 std::unique_ptr<win::ScopedCOMInitializer> scoped_com_initializer_;
436 };
437
438 #endif // BUILDFLAG(IS_WIN)
439
440 } // namespace
441
442 class PooledSingleThreadTaskRunnerManager::PooledSingleThreadTaskRunner
443 : public SingleThreadTaskRunner {
444 public:
445 // Constructs a PooledSingleThreadTaskRunner that indirectly controls the
446 // lifetime of a dedicated |worker| for |traits|.
PooledSingleThreadTaskRunner(PooledSingleThreadTaskRunnerManager * const outer,const TaskTraits & traits,WorkerThreadWaitableEvent * worker,SingleThreadTaskRunnerThreadMode thread_mode)447 PooledSingleThreadTaskRunner(PooledSingleThreadTaskRunnerManager* const outer,
448 const TaskTraits& traits,
449 WorkerThreadWaitableEvent* worker,
450 SingleThreadTaskRunnerThreadMode thread_mode)
451 : outer_(outer),
452 worker_(worker),
453 thread_mode_(thread_mode),
454 sequence_(
455 MakeRefCounted<Sequence>(traits,
456 this,
457 TaskSourceExecutionMode::kSingleThread)) {
458 DCHECK(outer_);
459 DCHECK(worker_);
460 }
461 PooledSingleThreadTaskRunner(const PooledSingleThreadTaskRunner&) = delete;
462 PooledSingleThreadTaskRunner& operator=(const PooledSingleThreadTaskRunner&) =
463 delete;
464
465 // SingleThreadTaskRunner:
PostDelayedTask(const Location & from_here,OnceClosure closure,TimeDelta delay)466 bool PostDelayedTask(const Location& from_here,
467 OnceClosure closure,
468 TimeDelta delay) override {
469 if (!g_manager_is_alive)
470 return false;
471
472 Task task(from_here, std::move(closure), TimeTicks::Now(), delay,
473 GetDefaultTaskLeeway());
474 return PostTask(std::move(task));
475 }
476
PostDelayedTaskAt(subtle::PostDelayedTaskPassKey,const Location & from_here,OnceClosure closure,TimeTicks delayed_run_time,subtle::DelayPolicy delay_policy)477 bool PostDelayedTaskAt(subtle::PostDelayedTaskPassKey,
478 const Location& from_here,
479 OnceClosure closure,
480 TimeTicks delayed_run_time,
481 subtle::DelayPolicy delay_policy) override {
482 if (!g_manager_is_alive)
483 return false;
484
485 Task task(from_here, std::move(closure), TimeTicks::Now(), delayed_run_time,
486 GetDefaultTaskLeeway(), delay_policy);
487 return PostTask(std::move(task));
488 }
489
PostNonNestableDelayedTask(const Location & from_here,OnceClosure closure,TimeDelta delay)490 bool PostNonNestableDelayedTask(const Location& from_here,
491 OnceClosure closure,
492 TimeDelta delay) override {
493 // Tasks are never nested within the thread pool.
494 return PostDelayedTask(from_here, std::move(closure), delay);
495 }
496
RunsTasksInCurrentSequence() const497 bool RunsTasksInCurrentSequence() const override {
498 if (!g_manager_is_alive)
499 return false;
500 return GetDelegate()->RunsTasksInCurrentSequence();
501 }
502
503 private:
~PooledSingleThreadTaskRunner()504 ~PooledSingleThreadTaskRunner() override {
505 // Only unregister if this is a DEDICATED SingleThreadTaskRunner. SHARED
506 // task runner WorkerThreads are managed separately as they are reused.
507 // |g_manager_is_alive| avoids a use-after-free should this
508 // PooledSingleThreadTaskRunner outlive its manager. It is safe to access
509 // |g_manager_is_alive| without synchronization primitives as it is const
510 // for the lifetime of the manager and ~PooledSingleThreadTaskRunner()
511 // either happens prior to the end of JoinForTesting() (which happens-before
512 // manager's destruction) or on main thread after the task environment's
513 // entire destruction (which happens-after the manager's destruction). Yes,
514 // there's a theoretical use case where the last ref to this
515 // PooledSingleThreadTaskRunner is handed to a thread not controlled by
516 // thread_pool and that this ends up causing
517 // ~PooledSingleThreadTaskRunner() to race with
518 // ~PooledSingleThreadTaskRunnerManager() but this is intentionally not
519 // supported (and it doesn't matter in production where we leak the task
520 // environment for such reasons). TSan should catch this weird paradigm
521 // should anyone elect to use it in a unit test and the error would point
522 // here.
523 if (g_manager_is_alive &&
524 thread_mode_ == SingleThreadTaskRunnerThreadMode::DEDICATED) {
525 outer_->UnregisterWorkerThread(worker_);
526 }
527 }
528
PostTask(Task task)529 bool PostTask(Task task) {
530 if (!outer_->task_tracker_->WillPostTask(&task,
531 sequence_->shutdown_behavior())) {
532 // `task`'s destructor may run sequence-affine code, so it must be leaked
533 // when `WillPostTask` returns false.
534 auto leak = std::make_unique<Task>(std::move(task));
535 ANNOTATE_LEAKING_OBJECT_PTR(leak.get());
536 leak.release();
537 return false;
538 }
539
540 if (task.delayed_run_time.is_null())
541 return GetDelegate()->PostTaskNow(sequence_, std::move(task));
542
543 // Unretained(GetDelegate()) is safe because this TaskRunner and its
544 // worker are kept alive as long as there are pending Tasks.
545 outer_->delayed_task_manager_->AddDelayedTask(
546 std::move(task),
547 BindOnce(IgnoreResult(&WorkerThreadDelegate::PostTaskNow),
548 Unretained(GetDelegate()), sequence_),
549 this);
550 return true;
551 }
552
GetDelegate() const553 WorkerThreadDelegate* GetDelegate() const {
554 return static_cast<WorkerThreadDelegate*>(worker_->delegate());
555 }
556
557 // Dangling but safe since use is controlled by `g_manager_is_alive`.
558 const raw_ptr<PooledSingleThreadTaskRunnerManager,
559 DisableDanglingPtrDetection>
560 outer_;
561
562 const raw_ptr<WorkerThreadWaitableEvent, AcrossTasksDanglingUntriaged>
563 worker_;
564 const SingleThreadTaskRunnerThreadMode thread_mode_;
565 const scoped_refptr<Sequence> sequence_;
566 };
567
PooledSingleThreadTaskRunnerManager(TrackedRef<TaskTracker> task_tracker,DelayedTaskManager * delayed_task_manager)568 PooledSingleThreadTaskRunnerManager::PooledSingleThreadTaskRunnerManager(
569 TrackedRef<TaskTracker> task_tracker,
570 DelayedTaskManager* delayed_task_manager)
571 : task_tracker_(std::move(task_tracker)),
572 delayed_task_manager_(delayed_task_manager) {
573 DCHECK(task_tracker_);
574 DCHECK(delayed_task_manager_);
575 #if BUILDFLAG(IS_WIN)
576 static_assert(std::extent<decltype(shared_com_worker_threads_)>() ==
577 std::extent<decltype(shared_worker_threads_)>(),
578 "The size of |shared_com_worker_threads_| must match "
579 "|shared_worker_threads_|");
580 static_assert(
581 std::extent<
582 std::remove_reference<decltype(shared_com_worker_threads_[0])>>() ==
583 std::extent<
584 std::remove_reference<decltype(shared_worker_threads_[0])>>(),
585 "The size of |shared_com_worker_threads_| must match "
586 "|shared_worker_threads_|");
587 #endif // BUILDFLAG(IS_WIN)
588 DCHECK(!g_manager_is_alive);
589 g_manager_is_alive = true;
590 }
591
~PooledSingleThreadTaskRunnerManager()592 PooledSingleThreadTaskRunnerManager::~PooledSingleThreadTaskRunnerManager() {
593 DCHECK(g_manager_is_alive);
594 g_manager_is_alive = false;
595 g_use_utility_thread_group = false;
596 }
597
Start(scoped_refptr<SingleThreadTaskRunner> io_thread_task_runner,WorkerThreadObserver * worker_thread_observer)598 void PooledSingleThreadTaskRunnerManager::Start(
599 scoped_refptr<SingleThreadTaskRunner> io_thread_task_runner,
600 WorkerThreadObserver* worker_thread_observer) {
601 DCHECK(!worker_thread_observer_);
602 worker_thread_observer_ = worker_thread_observer;
603 #if (BUILDFLAG(IS_POSIX) && !BUILDFLAG(IS_NACL)) || BUILDFLAG(IS_FUCHSIA)
604 DCHECK(io_thread_task_runner);
605 io_thread_task_runner_ = std::move(io_thread_task_runner);
606 #endif // (BUILDFLAG(IS_POSIX) && !BUILDFLAG(IS_NACL)) || BUILDFLAG(IS_FUCHSIA)
607
608 g_use_utility_thread_group = CanUseUtilityThreadTypeForWorkerThread() &&
609 FeatureList::IsEnabled(kUseUtilityThreadGroup);
610
611 decltype(workers_) workers_to_start;
612 {
613 CheckedAutoLock auto_lock(lock_);
614 started_ = true;
615 workers_to_start = workers_;
616 }
617
618 // Start workers that were created before this method was called.
619 // Workers that already need to wake up are already signaled as part of
620 // PooledSingleThreadTaskRunner::PostTaskNow(). As a result, it's
621 // unnecessary to call WakeUp() for each worker (in fact, an extraneous
622 // WakeUp() would be racy and wrong - see https://crbug.com/862582).
623 for (scoped_refptr<WorkerThreadWaitableEvent> worker : workers_to_start) {
624 worker->Start(io_thread_task_runner_, worker_thread_observer_);
625 }
626 }
627
DidUpdateCanRunPolicy()628 void PooledSingleThreadTaskRunnerManager::DidUpdateCanRunPolicy() {
629 decltype(workers_) workers_to_update;
630
631 {
632 CheckedAutoLock auto_lock(lock_);
633 if (!started_)
634 return;
635 workers_to_update = workers_;
636 }
637 // Any worker created after the lock is released will see the latest
638 // CanRunPolicy if tasks are posted to it and thus doesn't need a
639 // DidUpdateCanRunPolicy() notification.
640 for (auto& worker : workers_to_update) {
641 static_cast<WorkerThreadDelegate*>(worker->delegate())
642 ->DidUpdateCanRunPolicy();
643 }
644 }
645
646 scoped_refptr<SingleThreadTaskRunner>
CreateSingleThreadTaskRunner(const TaskTraits & traits,SingleThreadTaskRunnerThreadMode thread_mode)647 PooledSingleThreadTaskRunnerManager::CreateSingleThreadTaskRunner(
648 const TaskTraits& traits,
649 SingleThreadTaskRunnerThreadMode thread_mode) {
650 return CreateTaskRunnerImpl<WorkerThreadDelegate>(traits, thread_mode);
651 }
652
653 #if BUILDFLAG(IS_WIN)
654 scoped_refptr<SingleThreadTaskRunner>
CreateCOMSTATaskRunner(const TaskTraits & traits,SingleThreadTaskRunnerThreadMode thread_mode)655 PooledSingleThreadTaskRunnerManager::CreateCOMSTATaskRunner(
656 const TaskTraits& traits,
657 SingleThreadTaskRunnerThreadMode thread_mode) {
658 return CreateTaskRunnerImpl<WorkerThreadCOMDelegate>(traits, thread_mode);
659 }
660 #endif // BUILDFLAG(IS_WIN)
661
662 // static
663 PooledSingleThreadTaskRunnerManager::ContinueOnShutdown
TraitsToContinueOnShutdown(const TaskTraits & traits)664 PooledSingleThreadTaskRunnerManager::TraitsToContinueOnShutdown(
665 const TaskTraits& traits) {
666 if (traits.shutdown_behavior() == TaskShutdownBehavior::CONTINUE_ON_SHUTDOWN)
667 return IS_CONTINUE_ON_SHUTDOWN;
668 return IS_NOT_CONTINUE_ON_SHUTDOWN;
669 }
670
671 template <typename DelegateType>
672 scoped_refptr<PooledSingleThreadTaskRunnerManager::PooledSingleThreadTaskRunner>
CreateTaskRunnerImpl(const TaskTraits & traits,SingleThreadTaskRunnerThreadMode thread_mode)673 PooledSingleThreadTaskRunnerManager::CreateTaskRunnerImpl(
674 const TaskTraits& traits,
675 SingleThreadTaskRunnerThreadMode thread_mode) {
676 DCHECK(thread_mode != SingleThreadTaskRunnerThreadMode::SHARED ||
677 !traits.with_base_sync_primitives())
678 << "Using WithBaseSyncPrimitives() on a shared SingleThreadTaskRunner "
679 "may cause deadlocks. Either reevaluate your usage (e.g. use "
680 "SequencedTaskRunner) or use "
681 "SingleThreadTaskRunnerThreadMode::DEDICATED.";
682 // To simplify the code, |dedicated_worker| is a local only variable that
683 // allows the code to treat both the DEDICATED and SHARED cases similarly for
684 // SingleThreadTaskRunnerThreadMode. In DEDICATED, the scoped_refptr is backed
685 // by a local variable and in SHARED, the scoped_refptr is backed by a member
686 // variable.
687 WorkerThreadWaitableEvent* dedicated_worker = nullptr;
688 WorkerThreadWaitableEvent*& worker =
689 thread_mode == SingleThreadTaskRunnerThreadMode::DEDICATED
690 ? dedicated_worker
691 : GetSharedWorkerThreadForTraits<DelegateType>(traits);
692 bool new_worker = false;
693 bool started;
694 {
695 CheckedAutoLock auto_lock(lock_);
696 if (!worker) {
697 const auto& environment_params =
698 kEnvironmentParams[GetEnvironmentIndexForTraits(traits)];
699 std::string worker_name;
700 if (thread_mode == SingleThreadTaskRunnerThreadMode::SHARED)
701 worker_name += "Shared";
702 worker_name += environment_params.name_suffix;
703 worker = CreateAndRegisterWorkerThread<DelegateType>(
704 worker_name, thread_mode, environment_params.thread_type_hint);
705 new_worker = true;
706 }
707 started = started_;
708 }
709
710 if (new_worker && started)
711 worker->Start(io_thread_task_runner_, worker_thread_observer_);
712
713 return MakeRefCounted<PooledSingleThreadTaskRunner>(this, traits, worker,
714 thread_mode);
715 }
716
JoinForTesting()717 void PooledSingleThreadTaskRunnerManager::JoinForTesting() {
718 decltype(workers_) local_workers;
719 {
720 CheckedAutoLock auto_lock(lock_);
721 local_workers = std::move(workers_);
722 }
723
724 for (const auto& worker : local_workers) {
725 static_cast<WorkerThreadDelegate*>(worker->delegate())
726 ->EnableFlushPriorityQueueTaskSourcesOnDestroyForTesting();
727 worker->JoinForTesting();
728 }
729
730 {
731 CheckedAutoLock auto_lock(lock_);
732 DCHECK(workers_.empty())
733 << "New worker(s) unexpectedly registered during join.";
734 workers_ = std::move(local_workers);
735 }
736
737 // Release shared WorkerThreads at the end so they get joined above. If
738 // this call happens before the joins, the WorkerThreads are effectively
739 // detached and may outlive the PooledSingleThreadTaskRunnerManager.
740 ReleaseSharedWorkerThreads();
741 }
742
743 template <>
744 std::unique_ptr<WorkerThreadDelegate>
CreateWorkerThreadDelegate(const std::string & name,int id,SingleThreadTaskRunnerThreadMode thread_mode)745 PooledSingleThreadTaskRunnerManager::CreateWorkerThreadDelegate<
746 WorkerThreadDelegate>(const std::string& name,
747 int id,
748 SingleThreadTaskRunnerThreadMode thread_mode) {
749 return std::make_unique<WorkerThreadDelegate>(
750 StringPrintf("ThreadPoolSingleThread%s%d", name.c_str(), id),
751 thread_mode == SingleThreadTaskRunnerThreadMode::DEDICATED
752 ? WorkerThread::ThreadLabel::DEDICATED
753 : WorkerThread::ThreadLabel::SHARED,
754 task_tracker_);
755 }
756
757 #if BUILDFLAG(IS_WIN)
758 template <>
759 std::unique_ptr<WorkerThreadDelegate>
CreateWorkerThreadDelegate(const std::string & name,int id,SingleThreadTaskRunnerThreadMode thread_mode)760 PooledSingleThreadTaskRunnerManager::CreateWorkerThreadDelegate<
761 WorkerThreadCOMDelegate>(const std::string& name,
762 int id,
763 SingleThreadTaskRunnerThreadMode thread_mode) {
764 return std::make_unique<WorkerThreadCOMDelegate>(
765 StringPrintf("ThreadPoolSingleThreadCOMSTA%s%d", name.c_str(), id),
766 thread_mode == SingleThreadTaskRunnerThreadMode::DEDICATED
767 ? WorkerThread::ThreadLabel::DEDICATED_COM
768 : WorkerThread::ThreadLabel::SHARED_COM,
769 task_tracker_);
770 }
771 #endif // BUILDFLAG(IS_WIN)
772
773 template <typename DelegateType>
774 WorkerThreadWaitableEvent*
CreateAndRegisterWorkerThread(const std::string & name,SingleThreadTaskRunnerThreadMode thread_mode,ThreadType thread_type_hint)775 PooledSingleThreadTaskRunnerManager::CreateAndRegisterWorkerThread(
776 const std::string& name,
777 SingleThreadTaskRunnerThreadMode thread_mode,
778 ThreadType thread_type_hint) {
779 int id = next_worker_id_++;
780 std::unique_ptr<WorkerThreadDelegate> delegate =
781 CreateWorkerThreadDelegate<DelegateType>(name, id, thread_mode);
782 WorkerThreadDelegate* delegate_raw = delegate.get();
783 scoped_refptr<WorkerThreadWaitableEvent> worker =
784 MakeRefCounted<WorkerThreadWaitableEvent>(thread_type_hint,
785 std::move(delegate),
786 task_tracker_, workers_.size());
787 delegate_raw->set_worker(worker.get());
788 workers_.emplace_back(std::move(worker));
789 return workers_.back().get();
790 }
791
792 template <>
793 WorkerThreadWaitableEvent*&
GetSharedWorkerThreadForTraits(const TaskTraits & traits)794 PooledSingleThreadTaskRunnerManager::GetSharedWorkerThreadForTraits<
795 WorkerThreadDelegate>(const TaskTraits& traits) {
796 return shared_worker_threads_[GetEnvironmentIndexForTraits(traits)]
797 [TraitsToContinueOnShutdown(traits)];
798 }
799
800 #if BUILDFLAG(IS_WIN)
801 template <>
802 WorkerThreadWaitableEvent*&
GetSharedWorkerThreadForTraits(const TaskTraits & traits)803 PooledSingleThreadTaskRunnerManager::GetSharedWorkerThreadForTraits<
804 WorkerThreadCOMDelegate>(const TaskTraits& traits) {
805 return shared_com_worker_threads_[GetEnvironmentIndexForTraits(traits)]
806 [TraitsToContinueOnShutdown(traits)];
807 }
808 #endif // BUILDFLAG(IS_WIN)
809
UnregisterWorkerThread(WorkerThreadWaitableEvent * worker)810 void PooledSingleThreadTaskRunnerManager::UnregisterWorkerThread(
811 WorkerThreadWaitableEvent* worker) {
812 // Cleanup uses a CheckedLock, so call Cleanup() after releasing |lock_|.
813 scoped_refptr<WorkerThreadWaitableEvent> worker_to_destroy;
814 {
815 CheckedAutoLock auto_lock(lock_);
816
817 // Skip when joining (the join logic takes care of the rest).
818 if (workers_.empty())
819 return;
820
821 auto worker_iter = ranges::find(workers_, worker);
822 DCHECK(worker_iter != workers_.end());
823 worker_to_destroy = std::move(*worker_iter);
824 workers_.erase(worker_iter);
825 }
826 worker_to_destroy->Cleanup();
827 }
828
ReleaseSharedWorkerThreads()829 void PooledSingleThreadTaskRunnerManager::ReleaseSharedWorkerThreads() {
830 decltype(shared_worker_threads_) local_shared_worker_threads;
831 #if BUILDFLAG(IS_WIN)
832 decltype(shared_com_worker_threads_) local_shared_com_worker_threads;
833 #endif
834 {
835 CheckedAutoLock auto_lock(lock_);
836 for (size_t i = 0; i < std::size(shared_worker_threads_); ++i) {
837 for (size_t j = 0; j < std::size(shared_worker_threads_[i]); ++j) {
838 local_shared_worker_threads[i][j] = shared_worker_threads_[i][j];
839 shared_worker_threads_[i][j] = nullptr;
840 #if BUILDFLAG(IS_WIN)
841 local_shared_com_worker_threads[i][j] =
842 shared_com_worker_threads_[i][j];
843 shared_com_worker_threads_[i][j] = nullptr;
844 #endif
845 }
846 }
847 }
848
849 for (size_t i = 0; i < std::size(local_shared_worker_threads); ++i) {
850 for (size_t j = 0; j < std::size(local_shared_worker_threads[i]); ++j) {
851 if (local_shared_worker_threads[i][j])
852 UnregisterWorkerThread(local_shared_worker_threads[i][j]);
853 #if BUILDFLAG(IS_WIN)
854 if (local_shared_com_worker_threads[i][j])
855 UnregisterWorkerThread(local_shared_com_worker_threads[i][j]);
856 #endif
857 }
858 }
859 }
860
861 } // namespace internal
862 } // namespace base
863