// Copyright (c) 2012 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. // Test of classes in the tracked_objects.h classes. #include "base/tracked_objects.h" #include #include "base/memory/scoped_ptr.h" #include "base/process/process_handle.h" #include "base/time/time.h" #include "base/tracking_info.h" #include "testing/gtest/include/gtest/gtest.h" const int kLineNumber = 1776; const char kFile[] = "FixedUnitTestFileName"; const char kWorkerThreadName[] = "WorkerThread-1"; const char kMainThreadName[] = "SomeMainThreadName"; const char kStillAlive[] = "Still_Alive"; namespace tracked_objects { class TrackedObjectsTest : public testing::Test { protected: TrackedObjectsTest() { // On entry, leak any database structures in case they are still in use by // prior threads. ThreadData::ShutdownSingleThreadedCleanup(true); } virtual ~TrackedObjectsTest() { // We should not need to leak any structures we create, since we are // single threaded, and carefully accounting for items. ThreadData::ShutdownSingleThreadedCleanup(false); } // Reset the profiler state. void Reset() { ThreadData::ShutdownSingleThreadedCleanup(false); } // Simulate a birth on the thread named |thread_name|, at the given // |location|. void TallyABirth(const Location& location, const std::string& thread_name) { // If the |thread_name| is empty, we don't initialize system with a thread // name, so we're viewed as a worker thread. if (!thread_name.empty()) ThreadData::InitializeThreadContext(kMainThreadName); // Do not delete |birth|. We don't own it. Births* birth = ThreadData::TallyABirthIfActive(location); if (ThreadData::status() == ThreadData::DEACTIVATED) EXPECT_EQ(reinterpret_cast(NULL), birth); else EXPECT_NE(reinterpret_cast(NULL), birth); } // Helper function to verify the most common test expectations. void ExpectSimpleProcessData(const ProcessDataSnapshot& process_data, const std::string& function_name, const std::string& birth_thread, const std::string& death_thread, int count, int run_ms, int queue_ms) { ASSERT_EQ(1u, process_data.tasks.size()); EXPECT_EQ(kFile, process_data.tasks[0].birth.location.file_name); EXPECT_EQ(function_name, process_data.tasks[0].birth.location.function_name); EXPECT_EQ(kLineNumber, process_data.tasks[0].birth.location.line_number); EXPECT_EQ(birth_thread, process_data.tasks[0].birth.thread_name); EXPECT_EQ(count, process_data.tasks[0].death_data.count); EXPECT_EQ(count * run_ms, process_data.tasks[0].death_data.run_duration_sum); EXPECT_EQ(run_ms, process_data.tasks[0].death_data.run_duration_max); EXPECT_EQ(run_ms, process_data.tasks[0].death_data.run_duration_sample); EXPECT_EQ(count * queue_ms, process_data.tasks[0].death_data.queue_duration_sum); EXPECT_EQ(queue_ms, process_data.tasks[0].death_data.queue_duration_max); EXPECT_EQ(queue_ms, process_data.tasks[0].death_data.queue_duration_sample); EXPECT_EQ(death_thread, process_data.tasks[0].death_thread_name); EXPECT_EQ(0u, process_data.descendants.size()); EXPECT_EQ(base::GetCurrentProcId(), process_data.process_id); } }; TEST_F(TrackedObjectsTest, MinimalStartupShutdown) { // Minimal test doesn't even create any tasks. if (!ThreadData::InitializeAndSetTrackingStatus( ThreadData::PROFILING_CHILDREN_ACTIVE)) return; EXPECT_FALSE(ThreadData::first()); // No activity even on this thread. ThreadData* data = ThreadData::Get(); EXPECT_TRUE(ThreadData::first()); // Now class was constructed. ASSERT_TRUE(data); EXPECT_FALSE(data->next()); EXPECT_EQ(data, ThreadData::Get()); ThreadData::BirthMap birth_map; ThreadData::DeathMap death_map; ThreadData::ParentChildSet parent_child_set; data->SnapshotMaps(false, &birth_map, &death_map, &parent_child_set); EXPECT_EQ(0u, birth_map.size()); EXPECT_EQ(0u, death_map.size()); EXPECT_EQ(0u, parent_child_set.size()); // Clean up with no leaking. Reset(); // Do it again, just to be sure we reset state completely. EXPECT_TRUE(ThreadData::InitializeAndSetTrackingStatus( ThreadData::PROFILING_CHILDREN_ACTIVE)); EXPECT_FALSE(ThreadData::first()); // No activity even on this thread. data = ThreadData::Get(); EXPECT_TRUE(ThreadData::first()); // Now class was constructed. ASSERT_TRUE(data); EXPECT_FALSE(data->next()); EXPECT_EQ(data, ThreadData::Get()); birth_map.clear(); death_map.clear(); parent_child_set.clear(); data->SnapshotMaps(false, &birth_map, &death_map, &parent_child_set); EXPECT_EQ(0u, birth_map.size()); EXPECT_EQ(0u, death_map.size()); EXPECT_EQ(0u, parent_child_set.size()); } TEST_F(TrackedObjectsTest, TinyStartupShutdown) { if (!ThreadData::InitializeAndSetTrackingStatus( ThreadData::PROFILING_CHILDREN_ACTIVE)) return; // Instigate tracking on a single tracked object, on our thread. const char kFunction[] = "TinyStartupShutdown"; Location location(kFunction, kFile, kLineNumber, NULL); Births* first_birth = ThreadData::TallyABirthIfActive(location); ThreadData* data = ThreadData::first(); ASSERT_TRUE(data); EXPECT_FALSE(data->next()); EXPECT_EQ(data, ThreadData::Get()); ThreadData::BirthMap birth_map; ThreadData::DeathMap death_map; ThreadData::ParentChildSet parent_child_set; data->SnapshotMaps(false, &birth_map, &death_map, &parent_child_set); EXPECT_EQ(1u, birth_map.size()); // 1 birth location. EXPECT_EQ(1, birth_map.begin()->second->birth_count()); // 1 birth. EXPECT_EQ(0u, death_map.size()); // No deaths. EXPECT_EQ(0u, parent_child_set.size()); // No children. // Now instigate another birth, while we are timing the run of the first // execution. ThreadData::NowForStartOfRun(first_birth); // Create a child (using the same birth location). // TrackingInfo will call TallyABirth() during construction. base::TimeTicks kBogusBirthTime; base::TrackingInfo pending_task(location, kBogusBirthTime); TrackedTime start_time(pending_task.time_posted); // Finally conclude the outer run. TrackedTime end_time = ThreadData::NowForEndOfRun(); ThreadData::TallyRunOnNamedThreadIfTracking(pending_task, start_time, end_time); birth_map.clear(); death_map.clear(); parent_child_set.clear(); data->SnapshotMaps(false, &birth_map, &death_map, &parent_child_set); EXPECT_EQ(1u, birth_map.size()); // 1 birth location. EXPECT_EQ(2, birth_map.begin()->second->birth_count()); // 2 births. EXPECT_EQ(1u, death_map.size()); // 1 location. EXPECT_EQ(1, death_map.begin()->second.count()); // 1 death. if (ThreadData::TrackingParentChildStatus()) { EXPECT_EQ(1u, parent_child_set.size()); // 1 child. EXPECT_EQ(parent_child_set.begin()->first, parent_child_set.begin()->second); } else { EXPECT_EQ(0u, parent_child_set.size()); // no stats. } // The births were at the same location as the one known death. EXPECT_EQ(birth_map.begin()->second, death_map.begin()->first); ProcessDataSnapshot process_data; ThreadData::Snapshot(false, &process_data); const int32 time_elapsed = (end_time - start_time).InMilliseconds(); ASSERT_EQ(1u, process_data.tasks.size()); EXPECT_EQ(kFile, process_data.tasks[0].birth.location.file_name); EXPECT_EQ(kFunction, process_data.tasks[0].birth.location.function_name); EXPECT_EQ(kLineNumber, process_data.tasks[0].birth.location.line_number); EXPECT_EQ(kWorkerThreadName, process_data.tasks[0].birth.thread_name); EXPECT_EQ(1, process_data.tasks[0].death_data.count); EXPECT_EQ(time_elapsed, process_data.tasks[0].death_data.run_duration_sum); EXPECT_EQ(time_elapsed, process_data.tasks[0].death_data.run_duration_max); EXPECT_EQ(time_elapsed, process_data.tasks[0].death_data.run_duration_sample); EXPECT_EQ(0, process_data.tasks[0].death_data.queue_duration_sum); EXPECT_EQ(0, process_data.tasks[0].death_data.queue_duration_max); EXPECT_EQ(0, process_data.tasks[0].death_data.queue_duration_sample); EXPECT_EQ(kWorkerThreadName, process_data.tasks[0].death_thread_name); if (ThreadData::TrackingParentChildStatus()) { ASSERT_EQ(1u, process_data.descendants.size()); EXPECT_EQ(kFile, process_data.descendants[0].parent.location.file_name); EXPECT_EQ(kFunction, process_data.descendants[0].parent.location.function_name); EXPECT_EQ(kLineNumber, process_data.descendants[0].parent.location.line_number); EXPECT_EQ(kWorkerThreadName, process_data.descendants[0].parent.thread_name); EXPECT_EQ(kFile, process_data.descendants[0].child.location.file_name); EXPECT_EQ(kFunction, process_data.descendants[0].child.location.function_name); EXPECT_EQ(kLineNumber, process_data.descendants[0].child.location.line_number); EXPECT_EQ(kWorkerThreadName, process_data.descendants[0].child.thread_name); } else { EXPECT_EQ(0u, process_data.descendants.size()); } } TEST_F(TrackedObjectsTest, DeathDataTest) { if (!ThreadData::InitializeAndSetTrackingStatus( ThreadData::PROFILING_CHILDREN_ACTIVE)) return; scoped_ptr data(new DeathData()); ASSERT_NE(data, reinterpret_cast(NULL)); EXPECT_EQ(data->run_duration_sum(), 0); EXPECT_EQ(data->run_duration_sample(), 0); EXPECT_EQ(data->queue_duration_sum(), 0); EXPECT_EQ(data->queue_duration_sample(), 0); EXPECT_EQ(data->count(), 0); int32 run_ms = 42; int32 queue_ms = 8; const int kUnrandomInt = 0; // Fake random int that ensure we sample data. data->RecordDeath(queue_ms, run_ms, kUnrandomInt); EXPECT_EQ(data->run_duration_sum(), run_ms); EXPECT_EQ(data->run_duration_sample(), run_ms); EXPECT_EQ(data->queue_duration_sum(), queue_ms); EXPECT_EQ(data->queue_duration_sample(), queue_ms); EXPECT_EQ(data->count(), 1); data->RecordDeath(queue_ms, run_ms, kUnrandomInt); EXPECT_EQ(data->run_duration_sum(), run_ms + run_ms); EXPECT_EQ(data->run_duration_sample(), run_ms); EXPECT_EQ(data->queue_duration_sum(), queue_ms + queue_ms); EXPECT_EQ(data->queue_duration_sample(), queue_ms); EXPECT_EQ(data->count(), 2); DeathDataSnapshot snapshot(*data); EXPECT_EQ(2, snapshot.count); EXPECT_EQ(2 * run_ms, snapshot.run_duration_sum); EXPECT_EQ(run_ms, snapshot.run_duration_max); EXPECT_EQ(run_ms, snapshot.run_duration_sample); EXPECT_EQ(2 * queue_ms, snapshot.queue_duration_sum); EXPECT_EQ(queue_ms, snapshot.queue_duration_max); EXPECT_EQ(queue_ms, snapshot.queue_duration_sample); } TEST_F(TrackedObjectsTest, DeactivatedBirthOnlyToSnapshotWorkerThread) { // Start in the deactivated state. if (!ThreadData::InitializeAndSetTrackingStatus(ThreadData::DEACTIVATED)) return; const char kFunction[] = "DeactivatedBirthOnlyToSnapshotWorkerThread"; Location location(kFunction, kFile, kLineNumber, NULL); TallyABirth(location, std::string()); ProcessDataSnapshot process_data; ThreadData::Snapshot(false, &process_data); EXPECT_EQ(0u, process_data.tasks.size()); EXPECT_EQ(0u, process_data.descendants.size()); EXPECT_EQ(base::GetCurrentProcId(), process_data.process_id); } TEST_F(TrackedObjectsTest, DeactivatedBirthOnlyToSnapshotMainThread) { // Start in the deactivated state. if (!ThreadData::InitializeAndSetTrackingStatus(ThreadData::DEACTIVATED)) return; const char kFunction[] = "DeactivatedBirthOnlyToSnapshotMainThread"; Location location(kFunction, kFile, kLineNumber, NULL); TallyABirth(location, kMainThreadName); ProcessDataSnapshot process_data; ThreadData::Snapshot(false, &process_data); EXPECT_EQ(0u, process_data.tasks.size()); EXPECT_EQ(0u, process_data.descendants.size()); EXPECT_EQ(base::GetCurrentProcId(), process_data.process_id); } TEST_F(TrackedObjectsTest, BirthOnlyToSnapshotWorkerThread) { if (!ThreadData::InitializeAndSetTrackingStatus( ThreadData::PROFILING_CHILDREN_ACTIVE)) return; const char kFunction[] = "BirthOnlyToSnapshotWorkerThread"; Location location(kFunction, kFile, kLineNumber, NULL); TallyABirth(location, std::string()); ProcessDataSnapshot process_data; ThreadData::Snapshot(false, &process_data); ExpectSimpleProcessData(process_data, kFunction, kWorkerThreadName, kStillAlive, 1, 0, 0); } TEST_F(TrackedObjectsTest, BirthOnlyToSnapshotMainThread) { if (!ThreadData::InitializeAndSetTrackingStatus( ThreadData::PROFILING_CHILDREN_ACTIVE)) return; const char kFunction[] = "BirthOnlyToSnapshotMainThread"; Location location(kFunction, kFile, kLineNumber, NULL); TallyABirth(location, kMainThreadName); ProcessDataSnapshot process_data; ThreadData::Snapshot(false, &process_data); ExpectSimpleProcessData(process_data, kFunction, kMainThreadName, kStillAlive, 1, 0, 0); } TEST_F(TrackedObjectsTest, LifeCycleToSnapshotMainThread) { if (!ThreadData::InitializeAndSetTrackingStatus( ThreadData::PROFILING_CHILDREN_ACTIVE)) return; const char kFunction[] = "LifeCycleToSnapshotMainThread"; Location location(kFunction, kFile, kLineNumber, NULL); TallyABirth(location, kMainThreadName); const base::TimeTicks kTimePosted = base::TimeTicks() + base::TimeDelta::FromMilliseconds(1); const base::TimeTicks kDelayedStartTime = base::TimeTicks(); // TrackingInfo will call TallyABirth() during construction. base::TrackingInfo pending_task(location, kDelayedStartTime); pending_task.time_posted = kTimePosted; // Overwrite implied Now(). const TrackedTime kStartOfRun = TrackedTime() + Duration::FromMilliseconds(5); const TrackedTime kEndOfRun = TrackedTime() + Duration::FromMilliseconds(7); ThreadData::TallyRunOnNamedThreadIfTracking(pending_task, kStartOfRun, kEndOfRun); ProcessDataSnapshot process_data; ThreadData::Snapshot(false, &process_data); ExpectSimpleProcessData(process_data, kFunction, kMainThreadName, kMainThreadName, 1, 2, 4); } // We will deactivate tracking after the birth, and before the death, and // demonstrate that the lifecycle is completely tallied. This ensures that // our tallied births are matched by tallied deaths (except for when the // task is still running, or is queued). TEST_F(TrackedObjectsTest, LifeCycleMidDeactivatedToSnapshotMainThread) { if (!ThreadData::InitializeAndSetTrackingStatus( ThreadData::PROFILING_CHILDREN_ACTIVE)) return; const char kFunction[] = "LifeCycleMidDeactivatedToSnapshotMainThread"; Location location(kFunction, kFile, kLineNumber, NULL); TallyABirth(location, kMainThreadName); const base::TimeTicks kTimePosted = base::TimeTicks() + base::TimeDelta::FromMilliseconds(1); const base::TimeTicks kDelayedStartTime = base::TimeTicks(); // TrackingInfo will call TallyABirth() during construction. base::TrackingInfo pending_task(location, kDelayedStartTime); pending_task.time_posted = kTimePosted; // Overwrite implied Now(). // Turn off tracking now that we have births. EXPECT_TRUE(ThreadData::InitializeAndSetTrackingStatus( ThreadData::DEACTIVATED)); const TrackedTime kStartOfRun = TrackedTime() + Duration::FromMilliseconds(5); const TrackedTime kEndOfRun = TrackedTime() + Duration::FromMilliseconds(7); ThreadData::TallyRunOnNamedThreadIfTracking(pending_task, kStartOfRun, kEndOfRun); ProcessDataSnapshot process_data; ThreadData::Snapshot(false, &process_data); ExpectSimpleProcessData(process_data, kFunction, kMainThreadName, kMainThreadName, 1, 2, 4); } // We will deactivate tracking before starting a life cycle, and neither // the birth nor the death will be recorded. TEST_F(TrackedObjectsTest, LifeCyclePreDeactivatedToSnapshotMainThread) { // Start in the deactivated state. if (!ThreadData::InitializeAndSetTrackingStatus(ThreadData::DEACTIVATED)) return; const char kFunction[] = "LifeCyclePreDeactivatedToSnapshotMainThread"; Location location(kFunction, kFile, kLineNumber, NULL); TallyABirth(location, kMainThreadName); const base::TimeTicks kTimePosted = base::TimeTicks() + base::TimeDelta::FromMilliseconds(1); const base::TimeTicks kDelayedStartTime = base::TimeTicks(); // TrackingInfo will call TallyABirth() during construction. base::TrackingInfo pending_task(location, kDelayedStartTime); pending_task.time_posted = kTimePosted; // Overwrite implied Now(). const TrackedTime kStartOfRun = TrackedTime() + Duration::FromMilliseconds(5); const TrackedTime kEndOfRun = TrackedTime() + Duration::FromMilliseconds(7); ThreadData::TallyRunOnNamedThreadIfTracking(pending_task, kStartOfRun, kEndOfRun); ProcessDataSnapshot process_data; ThreadData::Snapshot(false, &process_data); EXPECT_EQ(0u, process_data.tasks.size()); EXPECT_EQ(0u, process_data.descendants.size()); EXPECT_EQ(base::GetCurrentProcId(), process_data.process_id); } TEST_F(TrackedObjectsTest, LifeCycleToSnapshotWorkerThread) { if (!ThreadData::InitializeAndSetTrackingStatus( ThreadData::PROFILING_CHILDREN_ACTIVE)) return; const char kFunction[] = "LifeCycleToSnapshotWorkerThread"; Location location(kFunction, kFile, kLineNumber, NULL); // Do not delete |birth|. We don't own it. Births* birth = ThreadData::TallyABirthIfActive(location); EXPECT_NE(reinterpret_cast(NULL), birth); const TrackedTime kTimePosted = TrackedTime() + Duration::FromMilliseconds(1); const TrackedTime kStartOfRun = TrackedTime() + Duration::FromMilliseconds(5); const TrackedTime kEndOfRun = TrackedTime() + Duration::FromMilliseconds(7); ThreadData::TallyRunOnWorkerThreadIfTracking(birth, kTimePosted, kStartOfRun, kEndOfRun); // Call for the ToSnapshot, but tell it to not reset the maxes after scanning. ProcessDataSnapshot process_data; ThreadData::Snapshot(false, &process_data); ExpectSimpleProcessData(process_data, kFunction, kWorkerThreadName, kWorkerThreadName, 1, 2, 4); // Call for the ToSnapshot, but tell it to reset the maxes after scanning. // We'll still get the same values, but the data will be reset (which we'll // see in a moment). ProcessDataSnapshot process_data_pre_reset; ThreadData::Snapshot(true, &process_data_pre_reset); ExpectSimpleProcessData(process_data, kFunction, kWorkerThreadName, kWorkerThreadName, 1, 2, 4); // Call for the ToSnapshot, and now we'll see the result of the last // translation, as the max will have been pushed back to zero. ProcessDataSnapshot process_data_post_reset; ThreadData::Snapshot(true, &process_data_post_reset); ASSERT_EQ(1u, process_data_post_reset.tasks.size()); EXPECT_EQ(kFile, process_data_post_reset.tasks[0].birth.location.file_name); EXPECT_EQ(kFunction, process_data_post_reset.tasks[0].birth.location.function_name); EXPECT_EQ(kLineNumber, process_data_post_reset.tasks[0].birth.location.line_number); EXPECT_EQ(kWorkerThreadName, process_data_post_reset.tasks[0].birth.thread_name); EXPECT_EQ(1, process_data_post_reset.tasks[0].death_data.count); EXPECT_EQ(2, process_data_post_reset.tasks[0].death_data.run_duration_sum); EXPECT_EQ(0, process_data_post_reset.tasks[0].death_data.run_duration_max); EXPECT_EQ(2, process_data_post_reset.tasks[0].death_data.run_duration_sample); EXPECT_EQ(4, process_data_post_reset.tasks[0].death_data.queue_duration_sum); EXPECT_EQ(0, process_data_post_reset.tasks[0].death_data.queue_duration_max); EXPECT_EQ(4, process_data_post_reset.tasks[0].death_data.queue_duration_sample); EXPECT_EQ(kWorkerThreadName, process_data_post_reset.tasks[0].death_thread_name); EXPECT_EQ(0u, process_data_post_reset.descendants.size()); EXPECT_EQ(base::GetCurrentProcId(), process_data_post_reset.process_id); } TEST_F(TrackedObjectsTest, TwoLives) { if (!ThreadData::InitializeAndSetTrackingStatus( ThreadData::PROFILING_CHILDREN_ACTIVE)) return; const char kFunction[] = "TwoLives"; Location location(kFunction, kFile, kLineNumber, NULL); TallyABirth(location, kMainThreadName); const base::TimeTicks kTimePosted = base::TimeTicks() + base::TimeDelta::FromMilliseconds(1); const base::TimeTicks kDelayedStartTime = base::TimeTicks(); // TrackingInfo will call TallyABirth() during construction. base::TrackingInfo pending_task(location, kDelayedStartTime); pending_task.time_posted = kTimePosted; // Overwrite implied Now(). const TrackedTime kStartOfRun = TrackedTime() + Duration::FromMilliseconds(5); const TrackedTime kEndOfRun = TrackedTime() + Duration::FromMilliseconds(7); ThreadData::TallyRunOnNamedThreadIfTracking(pending_task, kStartOfRun, kEndOfRun); // TrackingInfo will call TallyABirth() during construction. base::TrackingInfo pending_task2(location, kDelayedStartTime); pending_task2.time_posted = kTimePosted; // Overwrite implied Now(). ThreadData::TallyRunOnNamedThreadIfTracking(pending_task2, kStartOfRun, kEndOfRun); ProcessDataSnapshot process_data; ThreadData::Snapshot(false, &process_data); ExpectSimpleProcessData(process_data, kFunction, kMainThreadName, kMainThreadName, 2, 2, 4); } TEST_F(TrackedObjectsTest, DifferentLives) { if (!ThreadData::InitializeAndSetTrackingStatus( ThreadData::PROFILING_CHILDREN_ACTIVE)) return; // Use a well named thread. ThreadData::InitializeThreadContext(kMainThreadName); const char kFunction[] = "DifferentLives"; Location location(kFunction, kFile, kLineNumber, NULL); const base::TimeTicks kTimePosted = base::TimeTicks() + base::TimeDelta::FromMilliseconds(1); const base::TimeTicks kDelayedStartTime = base::TimeTicks(); // TrackingInfo will call TallyABirth() during construction. base::TrackingInfo pending_task(location, kDelayedStartTime); pending_task.time_posted = kTimePosted; // Overwrite implied Now(). const TrackedTime kStartOfRun = TrackedTime() + Duration::FromMilliseconds(5); const TrackedTime kEndOfRun = TrackedTime() + Duration::FromMilliseconds(7); ThreadData::TallyRunOnNamedThreadIfTracking(pending_task, kStartOfRun, kEndOfRun); const int kSecondFakeLineNumber = 999; Location second_location(kFunction, kFile, kSecondFakeLineNumber, NULL); // TrackingInfo will call TallyABirth() during construction. base::TrackingInfo pending_task2(second_location, kDelayedStartTime); pending_task2.time_posted = kTimePosted; // Overwrite implied Now(). ProcessDataSnapshot process_data; ThreadData::Snapshot(false, &process_data); ASSERT_EQ(2u, process_data.tasks.size()); EXPECT_EQ(kFile, process_data.tasks[0].birth.location.file_name); EXPECT_EQ(kFunction, process_data.tasks[0].birth.location.function_name); EXPECT_EQ(kLineNumber, process_data.tasks[0].birth.location.line_number); EXPECT_EQ(kMainThreadName, process_data.tasks[0].birth.thread_name); EXPECT_EQ(1, process_data.tasks[0].death_data.count); EXPECT_EQ(2, process_data.tasks[0].death_data.run_duration_sum); EXPECT_EQ(2, process_data.tasks[0].death_data.run_duration_max); EXPECT_EQ(2, process_data.tasks[0].death_data.run_duration_sample); EXPECT_EQ(4, process_data.tasks[0].death_data.queue_duration_sum); EXPECT_EQ(4, process_data.tasks[0].death_data.queue_duration_max); EXPECT_EQ(4, process_data.tasks[0].death_data.queue_duration_sample); EXPECT_EQ(kMainThreadName, process_data.tasks[0].death_thread_name); EXPECT_EQ(kFile, process_data.tasks[1].birth.location.file_name); EXPECT_EQ(kFunction, process_data.tasks[1].birth.location.function_name); EXPECT_EQ(kSecondFakeLineNumber, process_data.tasks[1].birth.location.line_number); EXPECT_EQ(kMainThreadName, process_data.tasks[1].birth.thread_name); EXPECT_EQ(1, process_data.tasks[1].death_data.count); EXPECT_EQ(0, process_data.tasks[1].death_data.run_duration_sum); EXPECT_EQ(0, process_data.tasks[1].death_data.run_duration_max); EXPECT_EQ(0, process_data.tasks[1].death_data.run_duration_sample); EXPECT_EQ(0, process_data.tasks[1].death_data.queue_duration_sum); EXPECT_EQ(0, process_data.tasks[1].death_data.queue_duration_max); EXPECT_EQ(0, process_data.tasks[1].death_data.queue_duration_sample); EXPECT_EQ(kStillAlive, process_data.tasks[1].death_thread_name); EXPECT_EQ(0u, process_data.descendants.size()); EXPECT_EQ(base::GetCurrentProcId(), process_data.process_id); } } // namespace tracked_objects