Add ICU message format support
[chromium-blink-merge.git] / content / browser / renderer_host / render_widget_resize_helper.cc
blob3cc329d71eed8be8e64fbe77b7199ac3d02e829e
1 // Copyright 2014 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.
5 #include "content/browser/renderer_host/render_widget_resize_helper.h"
7 #include <list>
9 #include "content/browser/gpu/gpu_process_host_ui_shim.h"
10 #include "content/browser/renderer_host/render_process_host_impl.h"
11 #include "content/public/browser/browser_thread.h"
13 namespace content {
14 namespace {
16 class WrappedTask;
17 class PumpableTaskRunner;
18 typedef std::list<WrappedTask*> WrappedTaskQueue;
19 typedef base::Callback<void(base::WaitableEvent*, base::TimeDelta)>
20 EventTimedWaitCallback;
22 // A wrapper for IPCs and tasks that we may potentially execute in
23 // WaitForSingleTaskToRun. Because these tasks are sent to two places to run,
24 // we to wrap them in this structure and track whether or not they have run
25 // yet, to avoid running them twice.
26 class WrappedTask {
27 public:
28 WrappedTask(
29 const base::Closure& closure,
30 base::TimeDelta delay);
31 ~WrappedTask();
32 bool ShouldRunBefore(const WrappedTask& other);
33 void Run();
34 void AddToTaskRunnerQueue(PumpableTaskRunner* pumpable_task_runner);
35 void RemoveFromTaskRunnerQueue();
36 const base::TimeTicks& can_run_time() const { return can_run_time_; }
38 private:
39 base::Closure closure_;
40 base::TimeTicks can_run_time_;
41 bool has_run_;
42 uint64 sequence_number_;
43 WrappedTaskQueue::iterator iterator_;
45 // Back pointer to the pumpable task runner that this task is enqueued in.
46 scoped_refptr<PumpableTaskRunner> pumpable_task_runner_;
48 DISALLOW_COPY_AND_ASSIGN(WrappedTask);
51 // The PumpableTaskRunner is a task runner that will wrap tasks in an
52 // WrappedTask, enqueues that wrapped task in the queue to be pumped via
53 // WaitForSingleWrappedTaskToRun during resizes, and posts the task to a
54 // target task runner. The posted task will run only once, either through a
55 // WaitForSingleWrappedTaskToRun call or through the target task runner.
56 class PumpableTaskRunner
57 : public base::SingleThreadTaskRunner {
58 public:
59 explicit PumpableTaskRunner(
60 const EventTimedWaitCallback& event_timed_wait_callback);
62 // Enqueue WrappedTask and post it to |target_task_runner_|.
63 bool EnqueueAndPostWrappedTask(
64 const tracked_objects::Location& from_here,
65 WrappedTask* task,
66 base::TimeDelta delay);
68 // Wait at most |max_delay| to run an enqueued task.
69 bool WaitForSingleWrappedTaskToRun(const base::TimeDelta& max_delay);
71 // Remove a wrapped task from the queue.
72 void RemoveWrappedTaskFromQueue(WrappedTask* task);
74 // base::SingleThreadTaskRunner implementation:
75 bool PostDelayedTask(const tracked_objects::Location& from_here,
76 const base::Closure& task,
77 base::TimeDelta delay) override;
79 bool PostNonNestableDelayedTask(const tracked_objects::Location& from_here,
80 const base::Closure& task,
81 base::TimeDelta delay) override;
83 bool RunsTasksOnCurrentThread() const override;
85 private:
86 friend class WrappedTask;
88 ~PumpableTaskRunner() override;
90 // A queue of live messages. Must hold |task_queue_lock_| to access. Tasks
91 // are added only on the IO thread and removed only on the UI thread. The
92 // WrappedTask objects are removed from the queue when they are run (by
93 // |target_task_runner_| or by a call to WaitForSingleWrappedTaskToRun
94 // removing them out of the queue, or by TaskRunner when it is destroyed).
95 WrappedTaskQueue task_queue_;
96 base::Lock task_queue_lock_;
98 // Event used to wake up the UI thread if it is sleeping in
99 // WaitForSingleTaskToRun.
100 base::WaitableEvent event_;
102 // Callback to call TimedWait on |event_| from an appropriate class.
103 EventTimedWaitCallback event_timed_wait_callback_;
105 scoped_refptr<base::SingleThreadTaskRunner> target_task_runner_;
107 DISALLOW_COPY_AND_ASSIGN(PumpableTaskRunner);
110 void HandleGpuIPC(int gpu_host_id, const IPC::Message& message) {
111 GpuProcessHostUIShim* host = GpuProcessHostUIShim::FromID(gpu_host_id);
112 if (host)
113 host->OnMessageReceived(message);
116 void HandleRendererIPC(int render_process_id, const IPC::Message& message) {
117 RenderProcessHost* host = RenderProcessHost::FromID(render_process_id);
118 if (host)
119 host->OnMessageReceived(message);
122 base::LazyInstance<RenderWidgetResizeHelper> g_render_widget_task_runner =
123 LAZY_INSTANCE_INITIALIZER;
125 ////////////////////////////////////////////////////////////////////////////////
126 // WrappedTask
128 WrappedTask::WrappedTask(
129 const base::Closure& closure,
130 base::TimeDelta delay)
131 : closure_(closure),
132 can_run_time_(base::TimeTicks::Now() + delay),
133 has_run_(false),
134 sequence_number_(0) {
137 WrappedTask::~WrappedTask() {
138 RemoveFromTaskRunnerQueue();
141 bool WrappedTask::ShouldRunBefore(const WrappedTask& other) {
142 if (can_run_time_ < other.can_run_time_)
143 return true;
144 if (can_run_time_ > other.can_run_time_)
145 return false;
146 if (sequence_number_ < other.sequence_number_)
147 return true;
148 if (sequence_number_ > other.sequence_number_)
149 return false;
150 // Sequence numbers are unique, so this should never happen.
151 NOTREACHED();
152 return false;
155 void WrappedTask::Run() {
156 if (has_run_)
157 return;
158 RemoveFromTaskRunnerQueue();
159 has_run_ = true;
160 closure_.Run();
163 void WrappedTask::AddToTaskRunnerQueue(
164 PumpableTaskRunner* pumpable_task_runner) {
165 pumpable_task_runner_ = pumpable_task_runner;
166 base::AutoLock lock(pumpable_task_runner_->task_queue_lock_);
167 static uint64 last_sequence_number = 0;
168 last_sequence_number += 1;
169 sequence_number_ = last_sequence_number;
170 iterator_ = pumpable_task_runner_->task_queue_.insert(
171 pumpable_task_runner_->task_queue_.end(), this);
174 void WrappedTask::RemoveFromTaskRunnerQueue() {
175 if (!pumpable_task_runner_.get())
176 return;
177 // The scope of the task runner's lock must be limited because removing
178 // this reference to the task runner may destroy it.
180 base::AutoLock lock(pumpable_task_runner_->task_queue_lock_);
181 pumpable_task_runner_->task_queue_.erase(iterator_);
182 iterator_ = pumpable_task_runner_->task_queue_.end();
184 pumpable_task_runner_ = NULL;
187 ////////////////////////////////////////////////////////////////////////////////
188 // PumpableTaskRunner
190 PumpableTaskRunner::PumpableTaskRunner(
191 const EventTimedWaitCallback& event_timed_wait_callback)
192 : event_(false /* auto-reset */, false /* initially signalled */),
193 event_timed_wait_callback_(event_timed_wait_callback),
194 target_task_runner_(BrowserThread::GetMessageLoopProxyForThread(
195 BrowserThread::UI)) {}
197 PumpableTaskRunner::~PumpableTaskRunner() {
198 // Because tasks hold a reference to the task runner, the task queue must
199 // be empty when it is destroyed.
200 DCHECK(task_queue_.empty());
203 bool PumpableTaskRunner::WaitForSingleWrappedTaskToRun(
204 const base::TimeDelta& max_delay) {
205 base::TimeTicks stop_waiting_time = base::TimeTicks::Now() + max_delay;
207 for (;;) {
208 base::TimeTicks current_time = base::TimeTicks::Now();
209 base::TimeTicks next_task_time = stop_waiting_time;
211 // Find the first task to execute in the list. This lookup takes O(n) time,
212 // but n is rarely more than 2, and has never been observed to be more than
213 // 12.
214 WrappedTask* task_to_execute = NULL;
216 base::AutoLock lock(task_queue_lock_);
218 for (WrappedTaskQueue::iterator it = task_queue_.begin(); it !=
219 task_queue_.end(); ++it) {
220 WrappedTask* potential_task = *it;
222 // If this task is scheduled for the future, take it into account when
223 // deciding how long to sleep, and continue on to the next task.
224 if (potential_task->can_run_time() > current_time) {
225 if (potential_task->can_run_time() < next_task_time)
226 next_task_time = potential_task->can_run_time();
227 continue;
229 // If there is a better candidate than this task, continue to the next
230 // task.
231 if (task_to_execute &&
232 task_to_execute->ShouldRunBefore(*potential_task)) {
233 continue;
235 task_to_execute = potential_task;
239 if (task_to_execute) {
240 task_to_execute->Run();
241 return true;
244 // Calculate how much time we have left before we have to stop waiting or
245 // until a currently-enqueued task will be ready to run.
246 base::TimeDelta max_sleep_time = next_task_time - current_time;
247 if (max_sleep_time <= base::TimeDelta::FromMilliseconds(0))
248 break;
250 event_timed_wait_callback_.Run(&event_, max_sleep_time);
253 return false;
256 bool PumpableTaskRunner::EnqueueAndPostWrappedTask(
257 const tracked_objects::Location& from_here,
258 WrappedTask* task,
259 base::TimeDelta delay) {
260 task->AddToTaskRunnerQueue(this);
262 // Notify anyone waiting on the UI thread that there is a new entry in the
263 // task map. If they don't find the entry they are looking for, then they
264 // will just continue waiting.
265 event_.Signal();
267 return target_task_runner_->PostDelayedTask(
268 from_here, base::Bind(&WrappedTask::Run, base::Owned(task)), delay);
271 ////////////////////////////////////////////////////////////////////////////////
272 // PumpableTaskRunner, base::SingleThreadTaskRunner implementation:
274 bool PumpableTaskRunner::PostDelayedTask(
275 const tracked_objects::Location& from_here,
276 const base::Closure& task,
277 base::TimeDelta delay) {
278 return EnqueueAndPostWrappedTask(
279 from_here,
280 new WrappedTask(task, delay),
281 delay);
284 bool PumpableTaskRunner::PostNonNestableDelayedTask(
285 const tracked_objects::Location& from_here,
286 const base::Closure& task,
287 base::TimeDelta delay) {
288 // The correctness of non-nestable events hasn't been proven for this
289 // structure.
290 NOTREACHED();
291 return false;
294 bool PumpableTaskRunner::RunsTasksOnCurrentThread() const {
295 return target_task_runner_->RunsTasksOnCurrentThread();
298 } // namespace
300 ////////////////////////////////////////////////////////////////////////////////
301 // RenderWidgetResizeHelper
303 scoped_refptr<base::SingleThreadTaskRunner>
304 RenderWidgetResizeHelper::task_runner() const {
305 return task_runner_;
308 // static
309 RenderWidgetResizeHelper* RenderWidgetResizeHelper::Get() {
310 return g_render_widget_task_runner.Pointer();
313 bool RenderWidgetResizeHelper::WaitForSingleTaskToRun(
314 const base::TimeDelta& max_delay) {
315 PumpableTaskRunner* pumpable_task_runner =
316 reinterpret_cast<PumpableTaskRunner*>(task_runner_.get());
317 return pumpable_task_runner->WaitForSingleWrappedTaskToRun(max_delay);
320 void RenderWidgetResizeHelper::PostRendererProcessMsg(
321 int render_process_id, const IPC::Message& msg) {
322 PumpableTaskRunner* pumpable_task_runner =
323 reinterpret_cast<PumpableTaskRunner*>(task_runner_.get());
324 pumpable_task_runner->EnqueueAndPostWrappedTask(
325 FROM_HERE,
326 new WrappedTask(base::Bind(HandleRendererIPC, render_process_id, msg),
327 base::TimeDelta()),
328 base::TimeDelta());
331 void RenderWidgetResizeHelper::PostGpuProcessMsg(
332 int gpu_host_id, const IPC::Message& msg) {
333 PumpableTaskRunner* pumpable_task_runner =
334 reinterpret_cast<PumpableTaskRunner*>(task_runner_.get());
335 pumpable_task_runner->EnqueueAndPostWrappedTask(
336 FROM_HERE,
337 new WrappedTask(base::Bind(HandleGpuIPC, gpu_host_id, msg),
338 base::TimeDelta()),
339 base::TimeDelta());
342 RenderWidgetResizeHelper::RenderWidgetResizeHelper() {
343 task_runner_ = new PumpableTaskRunner(base::Bind(&EventTimedWait));
346 RenderWidgetResizeHelper::~RenderWidgetResizeHelper() {}
348 // static
349 void RenderWidgetResizeHelper::EventTimedWait(
350 base::WaitableEvent* event, base::TimeDelta delay) {
351 base::ThreadRestrictions::ScopedAllowWait allow_wait;
352 event->TimedWait(delay);
355 } // namespace content