271 lines
8.1 KiB
C++
271 lines
8.1 KiB
C++
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// Copyright (c) 2012 The Chromium Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style license that can be
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// found in the LICENSE file.
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#include "base/test/sequenced_task_runner_test_template.h"
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#include <ostream>
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#include "base/location.h"
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namespace base {
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namespace internal {
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TaskEvent::TaskEvent(int i, Type type)
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: i(i), type(type) {
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}
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SequencedTaskTracker::SequencedTaskTracker()
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: next_post_i_(0),
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task_end_count_(0),
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task_end_cv_(&lock_) {
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}
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void SequencedTaskTracker::PostWrappedNonNestableTask(
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const scoped_refptr<SequencedTaskRunner>& task_runner,
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const Closure& task) {
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AutoLock event_lock(lock_);
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const int post_i = next_post_i_++;
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Closure wrapped_task = Bind(&SequencedTaskTracker::RunTask, this,
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task, post_i);
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task_runner->PostNonNestableTask(FROM_HERE, wrapped_task);
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TaskPosted(post_i);
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}
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void SequencedTaskTracker::PostWrappedNestableTask(
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const scoped_refptr<SequencedTaskRunner>& task_runner,
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const Closure& task) {
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AutoLock event_lock(lock_);
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const int post_i = next_post_i_++;
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Closure wrapped_task = Bind(&SequencedTaskTracker::RunTask, this,
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task, post_i);
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task_runner->PostTask(FROM_HERE, wrapped_task);
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TaskPosted(post_i);
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}
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void SequencedTaskTracker::PostWrappedDelayedNonNestableTask(
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const scoped_refptr<SequencedTaskRunner>& task_runner,
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const Closure& task,
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TimeDelta delay) {
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AutoLock event_lock(lock_);
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const int post_i = next_post_i_++;
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Closure wrapped_task = Bind(&SequencedTaskTracker::RunTask, this,
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task, post_i);
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task_runner->PostNonNestableDelayedTask(FROM_HERE, wrapped_task, delay);
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TaskPosted(post_i);
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}
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void SequencedTaskTracker::PostNonNestableTasks(
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const scoped_refptr<SequencedTaskRunner>& task_runner,
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int task_count) {
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for (int i = 0; i < task_count; ++i) {
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PostWrappedNonNestableTask(task_runner, Closure());
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}
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}
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void SequencedTaskTracker::RunTask(const Closure& task, int task_i) {
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TaskStarted(task_i);
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if (!task.is_null())
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task.Run();
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TaskEnded(task_i);
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}
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void SequencedTaskTracker::TaskPosted(int i) {
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// Caller must own |lock_|.
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events_.push_back(TaskEvent(i, TaskEvent::POST));
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}
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void SequencedTaskTracker::TaskStarted(int i) {
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AutoLock lock(lock_);
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events_.push_back(TaskEvent(i, TaskEvent::START));
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}
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void SequencedTaskTracker::TaskEnded(int i) {
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AutoLock lock(lock_);
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events_.push_back(TaskEvent(i, TaskEvent::END));
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++task_end_count_;
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task_end_cv_.Signal();
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}
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const std::vector<TaskEvent>&
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SequencedTaskTracker::GetTaskEvents() const {
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return events_;
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}
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void SequencedTaskTracker::WaitForCompletedTasks(int count) {
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AutoLock lock(lock_);
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while (task_end_count_ < count)
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task_end_cv_.Wait();
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}
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SequencedTaskTracker::~SequencedTaskTracker() {
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}
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void PrintTo(const TaskEvent& event, std::ostream* os) {
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*os << "(i=" << event.i << ", type=";
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switch (event.type) {
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case TaskEvent::POST: *os << "POST"; break;
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case TaskEvent::START: *os << "START"; break;
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case TaskEvent::END: *os << "END"; break;
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}
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*os << ")";
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}
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namespace {
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// Returns the task ordinals for the task event type |type| in the order that
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// they were recorded.
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std::vector<int> GetEventTypeOrder(const std::vector<TaskEvent>& events,
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TaskEvent::Type type) {
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std::vector<int> tasks;
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std::vector<TaskEvent>::const_iterator event;
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for (event = events.begin(); event != events.end(); ++event) {
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if (event->type == type)
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tasks.push_back(event->i);
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}
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return tasks;
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}
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// Returns all task events for task |task_i|.
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std::vector<TaskEvent::Type> GetEventsForTask(
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const std::vector<TaskEvent>& events,
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int task_i) {
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std::vector<TaskEvent::Type> task_event_orders;
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std::vector<TaskEvent>::const_iterator event;
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for (event = events.begin(); event != events.end(); ++event) {
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if (event->i == task_i)
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task_event_orders.push_back(event->type);
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}
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return task_event_orders;
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}
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// Checks that the task events for each task in |events| occur in the order
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// {POST, START, END}, and that there is only one instance of each event type
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// per task.
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::testing::AssertionResult CheckEventOrdersForEachTask(
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const std::vector<TaskEvent>& events,
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int task_count) {
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std::vector<TaskEvent::Type> expected_order;
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expected_order.push_back(TaskEvent::POST);
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expected_order.push_back(TaskEvent::START);
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expected_order.push_back(TaskEvent::END);
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// This is O(n^2), but it runs fast enough currently so is not worth
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// optimizing.
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for (int i = 0; i < task_count; ++i) {
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const std::vector<TaskEvent::Type> task_events =
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GetEventsForTask(events, i);
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if (task_events != expected_order) {
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return ::testing::AssertionFailure()
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<< "Events for task " << i << " are out of order; expected: "
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<< ::testing::PrintToString(expected_order) << "; actual: "
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<< ::testing::PrintToString(task_events);
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}
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}
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return ::testing::AssertionSuccess();
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}
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// Checks that no two tasks were running at the same time. I.e. the only
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// events allowed between the START and END of a task are the POSTs of other
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// tasks.
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::testing::AssertionResult CheckNoTaskRunsOverlap(
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const std::vector<TaskEvent>& events) {
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// If > -1, we're currently inside a START, END pair.
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int current_task_i = -1;
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std::vector<TaskEvent>::const_iterator event;
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for (event = events.begin(); event != events.end(); ++event) {
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bool spurious_event_found = false;
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if (current_task_i == -1) { // Not inside a START, END pair.
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switch (event->type) {
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case TaskEvent::POST:
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break;
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case TaskEvent::START:
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current_task_i = event->i;
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break;
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case TaskEvent::END:
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spurious_event_found = true;
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break;
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}
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} else { // Inside a START, END pair.
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bool interleaved_task_detected = false;
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switch (event->type) {
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case TaskEvent::POST:
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if (event->i == current_task_i)
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spurious_event_found = true;
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break;
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case TaskEvent::START:
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interleaved_task_detected = true;
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break;
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case TaskEvent::END:
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if (event->i != current_task_i)
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interleaved_task_detected = true;
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else
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current_task_i = -1;
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break;
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}
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if (interleaved_task_detected) {
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return ::testing::AssertionFailure()
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<< "Found event " << ::testing::PrintToString(*event)
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<< " between START and END events for task " << current_task_i
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<< "; event dump: " << ::testing::PrintToString(events);
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}
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}
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if (spurious_event_found) {
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const int event_i = event - events.begin();
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return ::testing::AssertionFailure()
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<< "Spurious event " << ::testing::PrintToString(*event)
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<< " at position " << event_i << "; event dump: "
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<< ::testing::PrintToString(events);
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}
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}
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return ::testing::AssertionSuccess();
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}
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} // namespace
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::testing::AssertionResult CheckNonNestableInvariants(
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const std::vector<TaskEvent>& events,
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int task_count) {
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const std::vector<int> post_order =
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GetEventTypeOrder(events, TaskEvent::POST);
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const std::vector<int> start_order =
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GetEventTypeOrder(events, TaskEvent::START);
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const std::vector<int> end_order =
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GetEventTypeOrder(events, TaskEvent::END);
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if (start_order != post_order) {
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return ::testing::AssertionFailure()
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<< "Expected START order (which equals actual POST order): \n"
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<< ::testing::PrintToString(post_order)
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<< "\n Actual START order:\n"
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<< ::testing::PrintToString(start_order);
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}
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if (end_order != post_order) {
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return ::testing::AssertionFailure()
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<< "Expected END order (which equals actual POST order): \n"
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<< ::testing::PrintToString(post_order)
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<< "\n Actual END order:\n"
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<< ::testing::PrintToString(end_order);
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}
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const ::testing::AssertionResult result =
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CheckEventOrdersForEachTask(events, task_count);
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if (!result)
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return result;
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return CheckNoTaskRunsOverlap(events);
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}
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} // namespace internal
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} // namespace base
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