| /* |
| * Copyright 2019 The Android Open Source Project |
| * |
| * Licensed under the Apache License, Version 2.0 (the "License"); |
| * you may not use this file except in compliance with the License. |
| * You may obtain a copy of the License at |
| * |
| * http://www.apache.org/licenses/LICENSE-2.0 |
| * |
| * Unless required by applicable law or agreed to in writing, software |
| * distributed under the License is distributed on an "AS IS" BASIS, |
| * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. |
| * See the License for the specific language governing permissions and |
| * limitations under the License. |
| */ |
| |
| // TODO(b/129481165): remove the #pragma below and fix conversion issues |
| #pragma clang diagnostic push |
| #pragma clang diagnostic ignored "-Wconversion" |
| #pragma clang diagnostic ignored "-Wextra" |
| |
| #undef LOG_TAG |
| #define LOG_TAG "LibSurfaceFlingerUnittests" |
| #define LOG_NDEBUG 0 |
| |
| #include <thread> |
| |
| #include <gmock/gmock.h> |
| #include <gtest/gtest.h> |
| |
| #include <scheduler/TimeKeeper.h> |
| |
| #include "FlagUtils.h" |
| #include "Scheduler/VSyncDispatchTimerQueue.h" |
| #include "Scheduler/VSyncTracker.h" |
| |
| #include <com_android_graphics_surfaceflinger_flags.h> |
| |
| using namespace testing; |
| using namespace std::literals; |
| |
| namespace android::scheduler { |
| using namespace com::android::graphics::surfaceflinger; |
| |
| class MockVSyncTracker : public VSyncTracker { |
| public: |
| MockVSyncTracker(nsecs_t period) : mPeriod{period} { |
| ON_CALL(*this, nextAnticipatedVSyncTimeFrom(_)) |
| .WillByDefault(Invoke(this, &MockVSyncTracker::nextVSyncTime)); |
| ON_CALL(*this, addVsyncTimestamp(_)).WillByDefault(Return(true)); |
| ON_CALL(*this, currentPeriod()) |
| .WillByDefault(Invoke(this, &MockVSyncTracker::getCurrentPeriod)); |
| } |
| |
| MOCK_METHOD1(addVsyncTimestamp, bool(nsecs_t)); |
| MOCK_CONST_METHOD1(nextAnticipatedVSyncTimeFrom, nsecs_t(nsecs_t)); |
| MOCK_CONST_METHOD0(currentPeriod, nsecs_t()); |
| MOCK_METHOD1(setPeriod, void(nsecs_t)); |
| MOCK_METHOD0(resetModel, void()); |
| MOCK_CONST_METHOD0(needsMoreSamples, bool()); |
| MOCK_CONST_METHOD2(isVSyncInPhase, bool(nsecs_t, Fps)); |
| MOCK_METHOD(void, setRenderRate, (Fps), (override)); |
| MOCK_CONST_METHOD1(dump, void(std::string&)); |
| |
| nsecs_t nextVSyncTime(nsecs_t timePoint) const { |
| if (timePoint % mPeriod == 0) { |
| return timePoint; |
| } |
| return (timePoint - (timePoint % mPeriod) + mPeriod); |
| } |
| |
| nsecs_t getCurrentPeriod() const { return mPeriod; } |
| |
| protected: |
| nsecs_t const mPeriod; |
| }; |
| |
| class ControllableClock : public TimeKeeper { |
| public: |
| ControllableClock() { |
| ON_CALL(*this, alarmAt(_, _)) |
| .WillByDefault(Invoke(this, &ControllableClock::alarmAtDefaultBehavior)); |
| ON_CALL(*this, now()).WillByDefault(Invoke(this, &ControllableClock::fakeTime)); |
| } |
| |
| MOCK_METHOD(nsecs_t, now, (), (const)); |
| MOCK_METHOD(void, alarmAt, (std::function<void()>, nsecs_t), (override)); |
| MOCK_METHOD(void, alarmCancel, (), (override)); |
| MOCK_METHOD(void, dump, (std::string&), (const, override)); |
| |
| void alarmAtDefaultBehavior(std::function<void()> const& callback, nsecs_t time) { |
| mCallback = callback; |
| mNextCallbackTime = time; |
| } |
| |
| nsecs_t fakeTime() const { return mCurrentTime; } |
| |
| void advanceToNextCallback() { |
| mCurrentTime = mNextCallbackTime; |
| if (mCallback) { |
| mCallback(); |
| } |
| } |
| |
| void advanceBy(nsecs_t advancement) { |
| mCurrentTime += advancement; |
| if (mCurrentTime >= (mNextCallbackTime + mLag) && mCallback) { |
| mCallback(); |
| } |
| }; |
| |
| void setLag(nsecs_t lag) { mLag = lag; } |
| |
| private: |
| std::function<void()> mCallback; |
| nsecs_t mNextCallbackTime = 0; |
| nsecs_t mCurrentTime = 0; |
| nsecs_t mLag = 0; |
| }; |
| |
| class CountingCallback { |
| public: |
| CountingCallback(std::shared_ptr<VSyncDispatch> dispatch) |
| : mDispatch(std::move(dispatch)), |
| mToken(mDispatch->registerCallback(std::bind(&CountingCallback::counter, this, |
| std::placeholders::_1, |
| std::placeholders::_2, |
| std::placeholders::_3), |
| "test")) {} |
| ~CountingCallback() { mDispatch->unregisterCallback(mToken); } |
| |
| operator VSyncDispatch::CallbackToken() const { return mToken; } |
| |
| void counter(nsecs_t time, nsecs_t wakeup_time, nsecs_t readyTime) { |
| mCalls.push_back(time); |
| mWakeupTime.push_back(wakeup_time); |
| mReadyTime.push_back(readyTime); |
| } |
| |
| std::shared_ptr<VSyncDispatch> mDispatch; |
| VSyncDispatch::CallbackToken mToken; |
| std::vector<nsecs_t> mCalls; |
| std::vector<nsecs_t> mWakeupTime; |
| std::vector<nsecs_t> mReadyTime; |
| }; |
| |
| class PausingCallback { |
| public: |
| PausingCallback(std::shared_ptr<VSyncDispatch> dispatch, std::chrono::milliseconds pauseAmount) |
| : mDispatch(std::move(dispatch)), |
| mToken(mDispatch->registerCallback(std::bind(&PausingCallback::pause, this, |
| std::placeholders::_1, |
| std::placeholders::_2), |
| "test")), |
| mRegistered(true), |
| mPauseAmount(pauseAmount) {} |
| ~PausingCallback() { unregister(); } |
| |
| operator VSyncDispatch::CallbackToken() const { return mToken; } |
| |
| void pause(nsecs_t, nsecs_t) { |
| std::unique_lock lock(mMutex); |
| mPause = true; |
| mCv.notify_all(); |
| |
| mCv.wait_for(lock, mPauseAmount, [this] { return !mPause; }); |
| |
| mResourcePresent = (mResource.lock() != nullptr); |
| } |
| |
| bool waitForPause() { |
| std::unique_lock lock(mMutex); |
| auto waiting = mCv.wait_for(lock, 10s, [this] { return mPause; }); |
| return waiting; |
| } |
| |
| void stashResource(std::weak_ptr<void> const& resource) { mResource = resource; } |
| |
| bool resourcePresent() { return mResourcePresent; } |
| |
| void unpause() { |
| std::unique_lock lock(mMutex); |
| mPause = false; |
| mCv.notify_all(); |
| } |
| |
| void unregister() { |
| if (mRegistered) { |
| mDispatch->unregisterCallback(mToken); |
| mRegistered = false; |
| } |
| } |
| |
| std::shared_ptr<VSyncDispatch> mDispatch; |
| VSyncDispatch::CallbackToken mToken; |
| bool mRegistered = true; |
| |
| std::mutex mMutex; |
| std::condition_variable mCv; |
| bool mPause = false; |
| std::weak_ptr<void> mResource; |
| bool mResourcePresent = false; |
| std::chrono::milliseconds const mPauseAmount; |
| }; |
| |
| class VSyncDispatchTimerQueueTest : public testing::Test { |
| protected: |
| std::unique_ptr<TimeKeeper> createTimeKeeper() { |
| class TimeKeeperWrapper : public TimeKeeper { |
| public: |
| TimeKeeperWrapper(TimeKeeper& control) : mControllableClock(control) {} |
| |
| nsecs_t now() const final { return mControllableClock.now(); } |
| |
| void alarmAt(std::function<void()> callback, nsecs_t time) final { |
| mControllableClock.alarmAt(std::move(callback), time); |
| } |
| |
| void alarmCancel() final { mControllableClock.alarmCancel(); } |
| void dump(std::string&) const final {} |
| |
| private: |
| TimeKeeper& mControllableClock; |
| }; |
| return std::make_unique<TimeKeeperWrapper>(mMockClock); |
| } |
| |
| ~VSyncDispatchTimerQueueTest() { |
| // destructor of dispatch will cancelAlarm(). Ignore final cancel in common test. |
| Mock::VerifyAndClearExpectations(&mMockClock); |
| } |
| |
| void advanceToNextCallback() { mMockClock.advanceToNextCallback(); } |
| |
| NiceMock<ControllableClock> mMockClock; |
| static nsecs_t constexpr mDispatchGroupThreshold = 5; |
| nsecs_t const mPeriod = 1000; |
| nsecs_t const mVsyncMoveThreshold = 300; |
| std::shared_ptr<NiceMock<MockVSyncTracker>> mStubTracker = |
| std::make_shared<NiceMock<MockVSyncTracker>>(mPeriod); |
| std::shared_ptr<VSyncDispatch> mDispatch = |
| std::make_shared<VSyncDispatchTimerQueue>(createTimeKeeper(), mStubTracker, |
| mDispatchGroupThreshold, mVsyncMoveThreshold); |
| }; |
| |
| TEST_F(VSyncDispatchTimerQueueTest, unregistersSetAlarmOnDestruction) { |
| EXPECT_CALL(mMockClock, alarmAt(_, 900)); |
| EXPECT_CALL(mMockClock, alarmCancel()); |
| { |
| std::shared_ptr<VSyncDispatch> mDispatch = |
| std::make_shared<VSyncDispatchTimerQueue>(createTimeKeeper(), mStubTracker, |
| mDispatchGroupThreshold, |
| mVsyncMoveThreshold); |
| CountingCallback cb(mDispatch); |
| const auto result = mDispatch->schedule(cb, |
| {.workDuration = 100, |
| .readyDuration = 0, |
| .earliestVsync = 1000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(900, *result); |
| } |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, basicAlarmSettingFuture) { |
| auto intended = mPeriod - 230; |
| EXPECT_CALL(mMockClock, alarmAt(_, 900)); |
| |
| CountingCallback cb(mDispatch); |
| const auto result = mDispatch->schedule(cb, |
| {.workDuration = 100, |
| .readyDuration = 0, |
| .earliestVsync = intended}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(900, *result); |
| |
| advanceToNextCallback(); |
| |
| ASSERT_THAT(cb.mCalls.size(), Eq(1)); |
| EXPECT_THAT(cb.mCalls[0], Eq(mPeriod)); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, updateAlarmSettingFuture) { |
| auto intended = mPeriod - 230; |
| Sequence seq; |
| EXPECT_CALL(mMockClock, alarmAt(_, 900)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 700)).InSequence(seq); |
| |
| CountingCallback cb(mDispatch); |
| auto result = mDispatch->schedule(cb, |
| {.workDuration = 100, |
| .readyDuration = 0, |
| .earliestVsync = intended}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(900, *result); |
| |
| result = |
| mDispatch->update(cb, |
| {.workDuration = 300, .readyDuration = 0, .earliestVsync = intended}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(700, *result); |
| |
| advanceToNextCallback(); |
| |
| ASSERT_THAT(cb.mCalls.size(), Eq(1)); |
| EXPECT_THAT(cb.mCalls[0], Eq(mPeriod)); |
| EXPECT_THAT(cb.mWakeupTime[0], Eq(700)); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, updateDoesntSchedule) { |
| auto intended = mPeriod - 230; |
| EXPECT_CALL(mMockClock, alarmAt(_, _)).Times(0); |
| |
| CountingCallback cb(mDispatch); |
| const auto result = |
| mDispatch->update(cb, |
| {.workDuration = 300, .readyDuration = 0, .earliestVsync = intended}); |
| EXPECT_FALSE(result.has_value()); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, basicAlarmSettingFutureWithAdjustmentToTrueVsync) { |
| EXPECT_CALL(*mStubTracker.get(), nextAnticipatedVSyncTimeFrom(1000)).WillOnce(Return(1150)); |
| EXPECT_CALL(mMockClock, alarmAt(_, 1050)); |
| |
| CountingCallback cb(mDispatch); |
| mDispatch->schedule(cb, {.workDuration = 100, .readyDuration = 0, .earliestVsync = mPeriod}); |
| advanceToNextCallback(); |
| |
| ASSERT_THAT(cb.mCalls.size(), Eq(1)); |
| EXPECT_THAT(cb.mCalls[0], Eq(1150)); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, basicAlarmSettingAdjustmentPast) { |
| auto const now = 234; |
| mMockClock.advanceBy(234); |
| auto const workDuration = 10 * mPeriod; |
| EXPECT_CALL(*mStubTracker.get(), nextAnticipatedVSyncTimeFrom(now + workDuration)) |
| .WillOnce(Return(mPeriod * 11)); |
| EXPECT_CALL(mMockClock, alarmAt(_, mPeriod)); |
| |
| CountingCallback cb(mDispatch); |
| const auto result = mDispatch->schedule(cb, |
| {.workDuration = workDuration, |
| .readyDuration = 0, |
| .earliestVsync = mPeriod}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(mPeriod, *result); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, basicAlarmCancel) { |
| EXPECT_CALL(mMockClock, alarmAt(_, 900)); |
| EXPECT_CALL(mMockClock, alarmCancel()); |
| |
| CountingCallback cb(mDispatch); |
| const auto result = mDispatch->schedule(cb, |
| {.workDuration = 100, |
| .readyDuration = 0, |
| .earliestVsync = mPeriod}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(mPeriod - 100, *result); |
| EXPECT_EQ(mDispatch->cancel(cb), CancelResult::Cancelled); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, basicAlarmCancelTooLate) { |
| EXPECT_CALL(mMockClock, alarmAt(_, 900)); |
| EXPECT_CALL(mMockClock, alarmCancel()); |
| |
| CountingCallback cb(mDispatch); |
| const auto result = mDispatch->schedule(cb, |
| {.workDuration = 100, |
| .readyDuration = 0, |
| .earliestVsync = mPeriod}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(mPeriod - 100, *result); |
| mMockClock.advanceBy(950); |
| EXPECT_EQ(mDispatch->cancel(cb), CancelResult::TooLate); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, basicAlarmCancelTooLateWhenRunning) { |
| EXPECT_CALL(mMockClock, alarmAt(_, 900)); |
| EXPECT_CALL(mMockClock, alarmCancel()); |
| |
| PausingCallback cb(mDispatch, std::chrono::duration_cast<std::chrono::milliseconds>(1s)); |
| const auto result = mDispatch->schedule(cb, |
| {.workDuration = 100, |
| .readyDuration = 0, |
| .earliestVsync = mPeriod}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(mPeriod - 100, *result); |
| |
| std::thread pausingThread([&] { mMockClock.advanceToNextCallback(); }); |
| EXPECT_TRUE(cb.waitForPause()); |
| EXPECT_EQ(mDispatch->cancel(cb), CancelResult::TooLate); |
| cb.unpause(); |
| pausingThread.join(); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, unregisterSynchronizes) { |
| EXPECT_CALL(mMockClock, alarmAt(_, 900)); |
| EXPECT_CALL(mMockClock, alarmCancel()); |
| |
| auto resource = std::make_shared<int>(110); |
| |
| PausingCallback cb(mDispatch, 50ms); |
| cb.stashResource(resource); |
| const auto result = mDispatch->schedule(cb, |
| {.workDuration = 100, |
| .readyDuration = 0, |
| .earliestVsync = mPeriod}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(mPeriod - 100, *result); |
| |
| std::thread pausingThread([&] { mMockClock.advanceToNextCallback(); }); |
| EXPECT_TRUE(cb.waitForPause()); |
| |
| cb.unregister(); |
| resource.reset(); |
| |
| cb.unpause(); |
| pausingThread.join(); |
| |
| EXPECT_TRUE(cb.resourcePresent()); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, basicTwoAlarmSetting) { |
| EXPECT_CALL(*mStubTracker.get(), nextAnticipatedVSyncTimeFrom(1000)) |
| .Times(4) |
| .WillOnce(Return(1055)) |
| .WillOnce(Return(1063)) |
| .WillOnce(Return(1063)) |
| .WillOnce(Return(1075)); |
| |
| Sequence seq; |
| EXPECT_CALL(mMockClock, alarmAt(_, 955)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 813)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 975)).InSequence(seq); |
| |
| CountingCallback cb0(mDispatch); |
| CountingCallback cb1(mDispatch); |
| |
| mDispatch->schedule(cb0, {.workDuration = 100, .readyDuration = 0, .earliestVsync = mPeriod}); |
| mDispatch->schedule(cb1, {.workDuration = 250, .readyDuration = 0, .earliestVsync = mPeriod}); |
| |
| advanceToNextCallback(); |
| advanceToNextCallback(); |
| |
| ASSERT_THAT(cb0.mCalls.size(), Eq(1)); |
| EXPECT_THAT(cb0.mCalls[0], Eq(1075)); |
| ASSERT_THAT(cb1.mCalls.size(), Eq(1)); |
| EXPECT_THAT(cb1.mCalls[0], Eq(1063)); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, noCloseCallbacksAfterPeriodChange) { |
| EXPECT_CALL(*mStubTracker.get(), nextAnticipatedVSyncTimeFrom(_)) |
| .Times(4) |
| .WillOnce(Return(1000)) |
| .WillOnce(Return(2000)) |
| .WillOnce(Return(2500)) |
| .WillOnce(Return(4000)); |
| |
| Sequence seq; |
| EXPECT_CALL(mMockClock, alarmAt(_, 900)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 1900)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 3900)).InSequence(seq); |
| |
| CountingCallback cb(mDispatch); |
| |
| mDispatch->schedule(cb, {.workDuration = 100, .readyDuration = 0, .earliestVsync = 0}); |
| |
| advanceToNextCallback(); |
| |
| ASSERT_THAT(cb.mCalls.size(), Eq(1)); |
| EXPECT_THAT(cb.mCalls[0], Eq(1000)); |
| |
| mDispatch->schedule(cb, {.workDuration = 100, .readyDuration = 0, .earliestVsync = 1000}); |
| |
| advanceToNextCallback(); |
| |
| ASSERT_THAT(cb.mCalls.size(), Eq(2)); |
| EXPECT_THAT(cb.mCalls[1], Eq(2000)); |
| |
| mDispatch->schedule(cb, {.workDuration = 100, .readyDuration = 0, .earliestVsync = 2000}); |
| |
| advanceToNextCallback(); |
| |
| ASSERT_THAT(cb.mCalls.size(), Eq(3)); |
| EXPECT_THAT(cb.mCalls[2], Eq(4000)); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, rearmsFaroutTimeoutWhenCancellingCloseOne) { |
| EXPECT_CALL(*mStubTracker.get(), nextAnticipatedVSyncTimeFrom(_)) |
| .Times(4) |
| .WillOnce(Return(10000)) |
| .WillOnce(Return(1000)) |
| .WillOnce(Return(10000)) |
| .WillOnce(Return(10000)); |
| |
| Sequence seq; |
| EXPECT_CALL(mMockClock, alarmAt(_, 9900)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 750)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 9900)).InSequence(seq); |
| |
| CountingCallback cb0(mDispatch); |
| CountingCallback cb1(mDispatch); |
| |
| mDispatch->schedule(cb0, |
| {.workDuration = 100, .readyDuration = 0, .earliestVsync = mPeriod * 10}); |
| mDispatch->schedule(cb1, {.workDuration = 250, .readyDuration = 0, .earliestVsync = mPeriod}); |
| mDispatch->cancel(cb1); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, noUnnecessaryRearmsWhenRescheduling) { |
| Sequence seq; |
| EXPECT_CALL(mMockClock, alarmAt(_, 600)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 700)).InSequence(seq); |
| |
| CountingCallback cb0(mDispatch); |
| CountingCallback cb1(mDispatch); |
| |
| mDispatch->schedule(cb0, {.workDuration = 400, .readyDuration = 0, .earliestVsync = 1000}); |
| mDispatch->schedule(cb1, {.workDuration = 200, .readyDuration = 0, .earliestVsync = 1000}); |
| mDispatch->schedule(cb1, {.workDuration = 300, .readyDuration = 0, .earliestVsync = 1000}); |
| advanceToNextCallback(); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, necessaryRearmsWhenModifying) { |
| Sequence seq; |
| EXPECT_CALL(mMockClock, alarmAt(_, 600)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 500)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 600)).InSequence(seq); |
| |
| CountingCallback cb0(mDispatch); |
| CountingCallback cb1(mDispatch); |
| |
| mDispatch->schedule(cb0, {.workDuration = 400, .readyDuration = 0, .earliestVsync = 1000}); |
| mDispatch->schedule(cb1, {.workDuration = 200, .readyDuration = 0, .earliestVsync = 1000}); |
| mDispatch->schedule(cb1, {.workDuration = 500, .readyDuration = 0, .earliestVsync = 1000}); |
| advanceToNextCallback(); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, modifyIntoGroup) { |
| Sequence seq; |
| EXPECT_CALL(mMockClock, alarmAt(_, 600)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 1600)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 1590)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 1600)).InSequence(seq); |
| |
| auto offset = 400; |
| auto closeOffset = offset + mDispatchGroupThreshold - 1; |
| auto notCloseOffset = offset + 2 * mDispatchGroupThreshold; |
| |
| CountingCallback cb0(mDispatch); |
| CountingCallback cb1(mDispatch); |
| |
| mDispatch->schedule(cb0, {.workDuration = 400, .readyDuration = 0, .earliestVsync = 1000}); |
| mDispatch->schedule(cb1, {.workDuration = 200, .readyDuration = 0, .earliestVsync = 1000}); |
| mDispatch->schedule(cb1, |
| {.workDuration = closeOffset, .readyDuration = 0, .earliestVsync = 1000}); |
| |
| advanceToNextCallback(); |
| ASSERT_THAT(cb0.mCalls.size(), Eq(1)); |
| EXPECT_THAT(cb0.mCalls[0], Eq(mPeriod)); |
| ASSERT_THAT(cb1.mCalls.size(), Eq(1)); |
| EXPECT_THAT(cb1.mCalls[0], Eq(mPeriod)); |
| |
| mDispatch->schedule(cb0, {.workDuration = 400, .readyDuration = 0, .earliestVsync = 2000}); |
| mDispatch->schedule(cb1, |
| {.workDuration = notCloseOffset, |
| .readyDuration = 0, |
| .earliestVsync = 2000}); |
| advanceToNextCallback(); |
| ASSERT_THAT(cb1.mCalls.size(), Eq(2)); |
| EXPECT_THAT(cb1.mCalls[1], Eq(2000)); |
| |
| advanceToNextCallback(); |
| ASSERT_THAT(cb0.mCalls.size(), Eq(2)); |
| EXPECT_THAT(cb0.mCalls[1], Eq(2000)); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, rearmsWhenEndingAndDoesntCancel) { |
| Sequence seq; |
| EXPECT_CALL(mMockClock, alarmAt(_, 900)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 800)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 900)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmCancel()); |
| |
| CountingCallback cb0(mDispatch); |
| CountingCallback cb1(mDispatch); |
| |
| mDispatch->schedule(cb0, {.workDuration = 100, .readyDuration = 0, .earliestVsync = 1000}); |
| mDispatch->schedule(cb1, {.workDuration = 200, .readyDuration = 0, .earliestVsync = 1000}); |
| advanceToNextCallback(); |
| EXPECT_EQ(mDispatch->cancel(cb0), CancelResult::Cancelled); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, setAlarmCallsAtCorrectTimeWithChangingVsync) { |
| EXPECT_CALL(*mStubTracker.get(), nextAnticipatedVSyncTimeFrom(_)) |
| .Times(3) |
| .WillOnce(Return(950)) |
| .WillOnce(Return(1975)) |
| .WillOnce(Return(2950)); |
| |
| CountingCallback cb(mDispatch); |
| mDispatch->schedule(cb, {.workDuration = 100, .readyDuration = 0, .earliestVsync = 920}); |
| |
| mMockClock.advanceBy(850); |
| EXPECT_THAT(cb.mCalls.size(), Eq(1)); |
| |
| mDispatch->schedule(cb, {.workDuration = 100, .readyDuration = 0, .earliestVsync = 1900}); |
| mMockClock.advanceBy(900); |
| EXPECT_THAT(cb.mCalls.size(), Eq(1)); |
| mMockClock.advanceBy(125); |
| EXPECT_THAT(cb.mCalls.size(), Eq(2)); |
| |
| mDispatch->schedule(cb, {.workDuration = 100, .readyDuration = 0, .earliestVsync = 2900}); |
| mMockClock.advanceBy(975); |
| EXPECT_THAT(cb.mCalls.size(), Eq(3)); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, callbackReentrancy) { |
| Sequence seq; |
| EXPECT_CALL(mMockClock, alarmAt(_, 900)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 1900)).InSequence(seq); |
| |
| VSyncDispatch::CallbackToken tmp; |
| tmp = mDispatch->registerCallback( |
| [&](auto, auto, auto) { |
| mDispatch->schedule(tmp, |
| {.workDuration = 100, |
| .readyDuration = 0, |
| .earliestVsync = 2000}); |
| }, |
| "o.o"); |
| |
| mDispatch->schedule(tmp, {.workDuration = 100, .readyDuration = 0, .earliestVsync = 1000}); |
| advanceToNextCallback(); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, callbackReentrantWithPastWakeup) { |
| VSyncDispatch::CallbackToken tmp; |
| std::optional<nsecs_t> lastTarget; |
| tmp = mDispatch->registerCallback( |
| [&](auto timestamp, auto, auto) { |
| auto result = |
| mDispatch->schedule(tmp, |
| {.workDuration = 400, |
| .readyDuration = 0, |
| .earliestVsync = timestamp - mVsyncMoveThreshold}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(mPeriod + timestamp - 400, *result); |
| result = mDispatch->schedule(tmp, |
| {.workDuration = 400, |
| .readyDuration = 0, |
| .earliestVsync = timestamp}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(mPeriod + timestamp - 400, *result); |
| result = mDispatch->schedule(tmp, |
| {.workDuration = 400, |
| .readyDuration = 0, |
| .earliestVsync = timestamp + mVsyncMoveThreshold}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(mPeriod + timestamp - 400, *result); |
| lastTarget = timestamp; |
| }, |
| "oo"); |
| |
| mDispatch->schedule(tmp, {.workDuration = 999, .readyDuration = 0, .earliestVsync = 1000}); |
| advanceToNextCallback(); |
| EXPECT_THAT(lastTarget, Eq(1000)); |
| |
| advanceToNextCallback(); |
| EXPECT_THAT(lastTarget, Eq(2000)); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, modificationsAroundVsyncTime) { |
| Sequence seq; |
| EXPECT_CALL(mMockClock, alarmAt(_, 1000)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 950)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 1950)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 1900)).InSequence(seq); |
| |
| CountingCallback cb(mDispatch); |
| mDispatch->schedule(cb, {.workDuration = 0, .readyDuration = 0, .earliestVsync = 1000}); |
| |
| mMockClock.advanceBy(750); |
| mDispatch->schedule(cb, {.workDuration = 50, .readyDuration = 0, .earliestVsync = 1000}); |
| |
| advanceToNextCallback(); |
| mDispatch->schedule(cb, {.workDuration = 50, .readyDuration = 0, .earliestVsync = 2000}); |
| |
| mMockClock.advanceBy(800); |
| mDispatch->schedule(cb, {.workDuration = 100, .readyDuration = 0, .earliestVsync = 2000}); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, lateModifications) { |
| Sequence seq; |
| EXPECT_CALL(mMockClock, alarmAt(_, 500)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 900)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 850)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 1800)).InSequence(seq); |
| |
| CountingCallback cb0(mDispatch); |
| CountingCallback cb1(mDispatch); |
| |
| mDispatch->schedule(cb0, {.workDuration = 500, .readyDuration = 0, .earliestVsync = 1000}); |
| mDispatch->schedule(cb1, {.workDuration = 100, .readyDuration = 0, .earliestVsync = 1000}); |
| |
| advanceToNextCallback(); |
| mDispatch->schedule(cb0, {.workDuration = 200, .readyDuration = 0, .earliestVsync = 2000}); |
| mDispatch->schedule(cb1, {.workDuration = 150, .readyDuration = 0, .earliestVsync = 1000}); |
| |
| advanceToNextCallback(); |
| advanceToNextCallback(); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, doesntCancelPriorValidTimerForFutureMod) { |
| Sequence seq; |
| EXPECT_CALL(mMockClock, alarmAt(_, 500)).InSequence(seq); |
| |
| CountingCallback cb0(mDispatch); |
| CountingCallback cb1(mDispatch); |
| mDispatch->schedule(cb0, {.workDuration = 500, .readyDuration = 0, .earliestVsync = 1000}); |
| mDispatch->schedule(cb1, {.workDuration = 500, .readyDuration = 0, .earliestVsync = 20000}); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, setsTimerAfterCancellation) { |
| Sequence seq; |
| EXPECT_CALL(mMockClock, alarmAt(_, 500)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmCancel()).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 900)).InSequence(seq); |
| |
| CountingCallback cb0(mDispatch); |
| mDispatch->schedule(cb0, {.workDuration = 500, .readyDuration = 0, .earliestVsync = 1000}); |
| mDispatch->cancel(cb0); |
| mDispatch->schedule(cb0, {.workDuration = 100, .readyDuration = 0, .earliestVsync = 1000}); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, makingUpIdsError) { |
| VSyncDispatch::CallbackToken token(100); |
| EXPECT_FALSE( |
| mDispatch |
| ->schedule(token, |
| {.workDuration = 100, .readyDuration = 0, .earliestVsync = 1000}) |
| .has_value()); |
| EXPECT_THAT(mDispatch->cancel(token), Eq(CancelResult::Error)); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, canMoveCallbackBackwardsInTime) { |
| CountingCallback cb0(mDispatch); |
| auto result = |
| mDispatch->schedule(cb0, |
| {.workDuration = 500, .readyDuration = 0, .earliestVsync = 1000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(500, *result); |
| result = mDispatch->schedule(cb0, |
| {.workDuration = 100, .readyDuration = 0, .earliestVsync = 1000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(900, *result); |
| } |
| |
| // b/1450138150 |
| TEST_F(VSyncDispatchTimerQueueTest, doesNotMoveCallbackBackwardsAndSkipAScheduledTargetVSync) { |
| EXPECT_CALL(mMockClock, alarmAt(_, 500)); |
| CountingCallback cb(mDispatch); |
| auto result = |
| mDispatch->schedule(cb, |
| {.workDuration = 500, .readyDuration = 0, .earliestVsync = 1000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(500, *result); |
| mMockClock.advanceBy(400); |
| |
| result = mDispatch->schedule(cb, |
| {.workDuration = 800, .readyDuration = 0, .earliestVsync = 1000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(1200, *result); |
| advanceToNextCallback(); |
| ASSERT_THAT(cb.mCalls.size(), Eq(1)); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, targetOffsetMovingBackALittleCanStillSchedule) { |
| EXPECT_CALL(*mStubTracker.get(), nextAnticipatedVSyncTimeFrom(1000)) |
| .Times(2) |
| .WillOnce(Return(1000)) |
| .WillOnce(Return(1002)); |
| CountingCallback cb(mDispatch); |
| auto result = |
| mDispatch->schedule(cb, |
| {.workDuration = 500, .readyDuration = 0, .earliestVsync = 1000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(500, *result); |
| mMockClock.advanceBy(400); |
| result = mDispatch->schedule(cb, |
| {.workDuration = 400, .readyDuration = 0, .earliestVsync = 1000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(602, *result); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, canScheduleNegativeOffsetAgainstDifferentPeriods) { |
| CountingCallback cb0(mDispatch); |
| auto result = |
| mDispatch->schedule(cb0, |
| {.workDuration = 500, .readyDuration = 0, .earliestVsync = 1000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(500, *result); |
| advanceToNextCallback(); |
| result = mDispatch->schedule(cb0, |
| {.workDuration = 1100, .readyDuration = 0, .earliestVsync = 2000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(900, *result); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, canScheduleLargeNegativeOffset) { |
| Sequence seq; |
| EXPECT_CALL(mMockClock, alarmAt(_, 500)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 1100)).InSequence(seq); |
| CountingCallback cb0(mDispatch); |
| auto result = |
| mDispatch->schedule(cb0, |
| {.workDuration = 500, .readyDuration = 0, .earliestVsync = 1000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(500, *result); |
| advanceToNextCallback(); |
| result = mDispatch->schedule(cb0, |
| {.workDuration = 1900, .readyDuration = 0, .earliestVsync = 2000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(1100, *result); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, scheduleUpdatesDoesNotAffectSchedulingState) { |
| EXPECT_CALL(mMockClock, alarmAt(_, 600)); |
| |
| CountingCallback cb(mDispatch); |
| auto result = |
| mDispatch->schedule(cb, |
| {.workDuration = 400, .readyDuration = 0, .earliestVsync = 1000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(600, *result); |
| |
| result = mDispatch->schedule(cb, |
| {.workDuration = 1400, .readyDuration = 0, .earliestVsync = 1000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(600, *result); |
| |
| advanceToNextCallback(); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, helperMove) { |
| EXPECT_CALL(mMockClock, alarmAt(_, 500)).Times(1); |
| EXPECT_CALL(mMockClock, alarmCancel()).Times(1); |
| |
| VSyncCallbackRegistration cb( |
| mDispatch, [](auto, auto, auto) {}, ""); |
| VSyncCallbackRegistration cb1(std::move(cb)); |
| cb.schedule({.workDuration = 100, .readyDuration = 0, .earliestVsync = 1000}); |
| cb.cancel(); |
| |
| cb1.schedule({.workDuration = 500, .readyDuration = 0, .earliestVsync = 1000}); |
| cb1.cancel(); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, helperMoveAssign) { |
| EXPECT_CALL(mMockClock, alarmAt(_, 500)).Times(1); |
| EXPECT_CALL(mMockClock, alarmCancel()).Times(1); |
| |
| VSyncCallbackRegistration cb( |
| mDispatch, [](auto, auto, auto) {}, ""); |
| VSyncCallbackRegistration cb1( |
| mDispatch, [](auto, auto, auto) {}, ""); |
| cb1 = std::move(cb); |
| cb.schedule({.workDuration = 100, .readyDuration = 0, .earliestVsync = 1000}); |
| cb.cancel(); |
| |
| cb1.schedule({.workDuration = 500, .readyDuration = 0, .earliestVsync = 1000}); |
| cb1.cancel(); |
| } |
| |
| // b/154303580 |
| TEST_F(VSyncDispatchTimerQueueTest, skipsSchedulingIfTimerReschedulingIsImminent) { |
| Sequence seq; |
| EXPECT_CALL(mMockClock, alarmAt(_, 600)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 1900)).InSequence(seq); |
| CountingCallback cb1(mDispatch); |
| CountingCallback cb2(mDispatch); |
| |
| auto result = |
| mDispatch->schedule(cb1, |
| {.workDuration = 400, .readyDuration = 0, .earliestVsync = 1000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(600, *result); |
| |
| mMockClock.setLag(100); |
| mMockClock.advanceBy(620); |
| |
| result = mDispatch->schedule(cb2, |
| {.workDuration = 100, .readyDuration = 0, .earliestVsync = 2000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(1900, *result); |
| mMockClock.advanceBy(80); |
| |
| EXPECT_THAT(cb1.mCalls.size(), Eq(1)); |
| EXPECT_THAT(cb2.mCalls.size(), Eq(0)); |
| } |
| |
| // b/154303580. |
| // If the same callback tries to reschedule itself after it's too late, timer opts to apply the |
| // update later, as opposed to blocking the calling thread. |
| TEST_F(VSyncDispatchTimerQueueTest, skipsSchedulingIfTimerReschedulingIsImminentSameCallback) { |
| Sequence seq; |
| EXPECT_CALL(mMockClock, alarmAt(_, 600)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 1630)).InSequence(seq); |
| CountingCallback cb(mDispatch); |
| |
| auto result = |
| mDispatch->schedule(cb, |
| {.workDuration = 400, .readyDuration = 0, .earliestVsync = 1000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(600, *result); |
| |
| mMockClock.setLag(100); |
| mMockClock.advanceBy(620); |
| |
| result = mDispatch->schedule(cb, |
| {.workDuration = 370, .readyDuration = 0, .earliestVsync = 2000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(1630, *result); |
| mMockClock.advanceBy(80); |
| |
| EXPECT_THAT(cb.mCalls.size(), Eq(1)); |
| } |
| |
| // b/154303580. |
| TEST_F(VSyncDispatchTimerQueueTest, skipsRearmingWhenNotNextScheduled) { |
| Sequence seq; |
| EXPECT_CALL(mMockClock, alarmAt(_, 600)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmCancel()).InSequence(seq); |
| CountingCallback cb1(mDispatch); |
| CountingCallback cb2(mDispatch); |
| |
| auto result = |
| mDispatch->schedule(cb1, |
| {.workDuration = 400, .readyDuration = 0, .earliestVsync = 1000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(600, *result); |
| result = mDispatch->schedule(cb2, |
| {.workDuration = 100, .readyDuration = 0, .earliestVsync = 2000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(1900, *result); |
| |
| mMockClock.setLag(100); |
| mMockClock.advanceBy(620); |
| |
| EXPECT_EQ(mDispatch->cancel(cb2), CancelResult::Cancelled); |
| |
| mMockClock.advanceBy(80); |
| |
| EXPECT_THAT(cb1.mCalls.size(), Eq(1)); |
| EXPECT_THAT(cb2.mCalls.size(), Eq(0)); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, rearmsWhenCancelledAndIsNextScheduled) { |
| Sequence seq; |
| EXPECT_CALL(mMockClock, alarmAt(_, 600)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmAt(_, 1900)).InSequence(seq); |
| EXPECT_CALL(mMockClock, alarmCancel()).InSequence(seq); |
| CountingCallback cb1(mDispatch); |
| CountingCallback cb2(mDispatch); |
| |
| auto result = |
| mDispatch->schedule(cb1, |
| {.workDuration = 400, .readyDuration = 0, .earliestVsync = 1000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(600, *result); |
| result = mDispatch->schedule(cb2, |
| {.workDuration = 100, .readyDuration = 0, .earliestVsync = 2000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(1900, *result); |
| |
| mMockClock.setLag(100); |
| mMockClock.advanceBy(620); |
| |
| EXPECT_EQ(mDispatch->cancel(cb1), CancelResult::Cancelled); |
| |
| EXPECT_THAT(cb1.mCalls.size(), Eq(0)); |
| EXPECT_THAT(cb2.mCalls.size(), Eq(0)); |
| mMockClock.advanceToNextCallback(); |
| |
| EXPECT_THAT(cb1.mCalls.size(), Eq(0)); |
| EXPECT_THAT(cb2.mCalls.size(), Eq(1)); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, laggedTimerGroupsCallbacksWithinLag) { |
| CountingCallback cb1(mDispatch); |
| CountingCallback cb2(mDispatch); |
| |
| Sequence seq; |
| EXPECT_CALL(*mStubTracker.get(), nextAnticipatedVSyncTimeFrom(1000)) |
| .InSequence(seq) |
| .WillOnce(Return(1000)); |
| EXPECT_CALL(mMockClock, alarmAt(_, 600)).InSequence(seq); |
| EXPECT_CALL(*mStubTracker.get(), nextAnticipatedVSyncTimeFrom(1000)) |
| .InSequence(seq) |
| .WillOnce(Return(1000)); |
| |
| auto result = |
| mDispatch->schedule(cb1, |
| {.workDuration = 400, .readyDuration = 0, .earliestVsync = 1000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(600, *result); |
| result = mDispatch->schedule(cb2, |
| {.workDuration = 390, .readyDuration = 0, .earliestVsync = 1000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(610, *result); |
| |
| mMockClock.setLag(100); |
| mMockClock.advanceBy(700); |
| |
| ASSERT_THAT(cb1.mWakeupTime.size(), Eq(1)); |
| EXPECT_THAT(cb1.mWakeupTime[0], Eq(600)); |
| ASSERT_THAT(cb1.mReadyTime.size(), Eq(1)); |
| EXPECT_THAT(cb1.mReadyTime[0], Eq(1000)); |
| ASSERT_THAT(cb2.mWakeupTime.size(), Eq(1)); |
| EXPECT_THAT(cb2.mWakeupTime[0], Eq(610)); |
| ASSERT_THAT(cb2.mReadyTime.size(), Eq(1)); |
| EXPECT_THAT(cb2.mReadyTime[0], Eq(1000)); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, basicAlarmSettingFutureWithReadyDuration) { |
| auto intended = mPeriod - 230; |
| EXPECT_CALL(mMockClock, alarmAt(_, 900)); |
| |
| CountingCallback cb(mDispatch); |
| const auto result = mDispatch->schedule(cb, |
| {.workDuration = 70, |
| .readyDuration = 30, |
| .earliestVsync = intended}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(900, *result); |
| advanceToNextCallback(); |
| |
| ASSERT_THAT(cb.mCalls.size(), Eq(1)); |
| EXPECT_THAT(cb.mCalls[0], Eq(mPeriod)); |
| ASSERT_THAT(cb.mWakeupTime.size(), Eq(1)); |
| EXPECT_THAT(cb.mWakeupTime[0], 900); |
| ASSERT_THAT(cb.mReadyTime.size(), Eq(1)); |
| EXPECT_THAT(cb.mReadyTime[0], 970); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, updatesVsyncTimeForCloseWakeupTime) { |
| Sequence seq; |
| EXPECT_CALL(mMockClock, alarmAt(_, 600)).InSequence(seq); |
| |
| CountingCallback cb(mDispatch); |
| |
| mDispatch->schedule(cb, {.workDuration = 400, .readyDuration = 0, .earliestVsync = 1000}); |
| mDispatch->schedule(cb, {.workDuration = 1400, .readyDuration = 0, .earliestVsync = 1000}); |
| |
| advanceToNextCallback(); |
| |
| advanceToNextCallback(); |
| |
| ASSERT_THAT(cb.mCalls.size(), Eq(1)); |
| EXPECT_THAT(cb.mCalls[0], Eq(2000)); |
| ASSERT_THAT(cb.mWakeupTime.size(), Eq(1)); |
| EXPECT_THAT(cb.mWakeupTime[0], Eq(600)); |
| ASSERT_THAT(cb.mReadyTime.size(), Eq(1)); |
| EXPECT_THAT(cb.mReadyTime[0], Eq(2000)); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, skipAVsyc) { |
| SET_FLAG_FOR_TEST(flags::dont_skip_on_early, false); |
| |
| EXPECT_CALL(mMockClock, alarmAt(_, 500)); |
| CountingCallback cb(mDispatch); |
| auto result = |
| mDispatch->schedule(cb, |
| {.workDuration = 500, .readyDuration = 0, .earliestVsync = 1000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(500, *result); |
| mMockClock.advanceBy(300); |
| |
| result = mDispatch->schedule(cb, |
| {.workDuration = 800, .readyDuration = 0, .earliestVsync = 1000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(1200, *result); |
| |
| advanceToNextCallback(); |
| ASSERT_THAT(cb.mCalls.size(), Eq(1)); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueTest, dontskipAVsyc) { |
| SET_FLAG_FOR_TEST(flags::dont_skip_on_early, true); |
| |
| EXPECT_CALL(mMockClock, alarmAt(_, 500)); |
| CountingCallback cb(mDispatch); |
| auto result = |
| mDispatch->schedule(cb, |
| {.workDuration = 500, .readyDuration = 0, .earliestVsync = 1000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(500, *result); |
| mMockClock.advanceBy(300); |
| |
| result = mDispatch->schedule(cb, |
| {.workDuration = 800, .readyDuration = 0, .earliestVsync = 1000}); |
| EXPECT_TRUE(result.has_value()); |
| EXPECT_EQ(200, *result); |
| |
| advanceToNextCallback(); |
| ASSERT_THAT(cb.mCalls.size(), Eq(1)); |
| } |
| |
| class VSyncDispatchTimerQueueEntryTest : public testing::Test { |
| protected: |
| nsecs_t const mPeriod = 1000; |
| nsecs_t const mVsyncMoveThreshold = 200; |
| std::shared_ptr<NiceMock<MockVSyncTracker>> mStubTracker = |
| std::make_shared<NiceMock<MockVSyncTracker>>(mPeriod); |
| }; |
| |
| TEST_F(VSyncDispatchTimerQueueEntryTest, stateAfterInitialization) { |
| std::string name("basicname"); |
| VSyncDispatchTimerQueueEntry entry( |
| name, [](auto, auto, auto) {}, mVsyncMoveThreshold); |
| EXPECT_THAT(entry.name(), Eq(name)); |
| EXPECT_FALSE(entry.lastExecutedVsyncTarget()); |
| EXPECT_FALSE(entry.wakeupTime()); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueEntryTest, stateScheduling) { |
| VSyncDispatchTimerQueueEntry entry( |
| "test", [](auto, auto, auto) {}, mVsyncMoveThreshold); |
| |
| EXPECT_FALSE(entry.wakeupTime()); |
| EXPECT_TRUE(entry.schedule({.workDuration = 100, .readyDuration = 0, .earliestVsync = 500}, |
| *mStubTracker.get(), 0) |
| .has_value()); |
| auto const wakeup = entry.wakeupTime(); |
| ASSERT_TRUE(wakeup); |
| EXPECT_THAT(*wakeup, Eq(900)); |
| |
| entry.disarm(); |
| EXPECT_FALSE(entry.wakeupTime()); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueEntryTest, stateSchedulingReallyLongWakeupLatency) { |
| auto const duration = 500; |
| auto const now = 8750; |
| |
| EXPECT_CALL(*mStubTracker.get(), nextAnticipatedVSyncTimeFrom(now + duration)) |
| .Times(1) |
| .WillOnce(Return(10000)); |
| VSyncDispatchTimerQueueEntry entry( |
| "test", [](auto, auto, auto) {}, mVsyncMoveThreshold); |
| |
| EXPECT_FALSE(entry.wakeupTime()); |
| EXPECT_TRUE(entry.schedule({.workDuration = 500, .readyDuration = 0, .earliestVsync = 994}, |
| *mStubTracker.get(), now) |
| .has_value()); |
| auto const wakeup = entry.wakeupTime(); |
| ASSERT_TRUE(wakeup); |
| EXPECT_THAT(*wakeup, Eq(9500)); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueEntryTest, runCallback) { |
| auto callCount = 0; |
| auto vsyncCalledTime = 0; |
| auto wakeupCalledTime = 0; |
| auto readyCalledTime = 0; |
| VSyncDispatchTimerQueueEntry entry( |
| "test", |
| [&](auto vsyncTime, auto wakeupTime, auto readyTime) { |
| callCount++; |
| vsyncCalledTime = vsyncTime; |
| wakeupCalledTime = wakeupTime; |
| readyCalledTime = readyTime; |
| }, |
| mVsyncMoveThreshold); |
| |
| EXPECT_TRUE(entry.schedule({.workDuration = 100, .readyDuration = 0, .earliestVsync = 500}, |
| *mStubTracker.get(), 0) |
| .has_value()); |
| auto const wakeup = entry.wakeupTime(); |
| ASSERT_TRUE(wakeup); |
| EXPECT_THAT(*wakeup, Eq(900)); |
| |
| auto const ready = entry.readyTime(); |
| ASSERT_TRUE(ready); |
| EXPECT_THAT(*ready, Eq(1000)); |
| |
| entry.callback(entry.executing(), *wakeup, *ready); |
| |
| EXPECT_THAT(callCount, Eq(1)); |
| EXPECT_THAT(vsyncCalledTime, Eq(mPeriod)); |
| EXPECT_THAT(wakeupCalledTime, Eq(*wakeup)); |
| EXPECT_FALSE(entry.wakeupTime()); |
| auto lastCalledTarget = entry.lastExecutedVsyncTarget(); |
| ASSERT_TRUE(lastCalledTarget); |
| EXPECT_THAT(*lastCalledTarget, Eq(mPeriod)); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueEntryTest, updateCallback) { |
| EXPECT_CALL(*mStubTracker.get(), nextAnticipatedVSyncTimeFrom(_)) |
| .Times(2) |
| .WillOnce(Return(1000)) |
| .WillOnce(Return(1020)); |
| |
| VSyncDispatchTimerQueueEntry entry( |
| "test", [](auto, auto, auto) {}, mVsyncMoveThreshold); |
| |
| EXPECT_FALSE(entry.wakeupTime()); |
| entry.update(*mStubTracker.get(), 0); |
| EXPECT_FALSE(entry.wakeupTime()); |
| |
| EXPECT_TRUE(entry.schedule({.workDuration = 100, .readyDuration = 0, .earliestVsync = 500}, |
| *mStubTracker.get(), 0) |
| .has_value()); |
| auto wakeup = entry.wakeupTime(); |
| ASSERT_TRUE(wakeup); |
| EXPECT_THAT(wakeup, Eq(900)); |
| |
| entry.update(*mStubTracker.get(), 0); |
| wakeup = entry.wakeupTime(); |
| ASSERT_TRUE(wakeup); |
| EXPECT_THAT(*wakeup, Eq(920)); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueEntryTest, skipsUpdateIfJustScheduled) { |
| VSyncDispatchTimerQueueEntry entry( |
| "test", [](auto, auto, auto) {}, mVsyncMoveThreshold); |
| EXPECT_TRUE(entry.schedule({.workDuration = 100, .readyDuration = 0, .earliestVsync = 500}, |
| *mStubTracker.get(), 0) |
| .has_value()); |
| entry.update(*mStubTracker.get(), 0); |
| |
| auto const wakeup = entry.wakeupTime(); |
| ASSERT_TRUE(wakeup); |
| EXPECT_THAT(*wakeup, Eq(wakeup)); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueEntryTest, willSnapToNextTargettableVSync) { |
| VSyncDispatchTimerQueueEntry entry( |
| "test", [](auto, auto, auto) {}, mVsyncMoveThreshold); |
| EXPECT_TRUE(entry.schedule({.workDuration = 100, .readyDuration = 0, .earliestVsync = 500}, |
| *mStubTracker.get(), 0) |
| .has_value()); |
| entry.executing(); // 1000 is executing |
| // had 1000 not been executing, this could have been scheduled for time 800. |
| EXPECT_TRUE(entry.schedule({.workDuration = 200, .readyDuration = 0, .earliestVsync = 500}, |
| *mStubTracker.get(), 0) |
| .has_value()); |
| EXPECT_THAT(*entry.wakeupTime(), Eq(1800)); |
| EXPECT_THAT(*entry.readyTime(), Eq(2000)); |
| |
| EXPECT_TRUE(entry.schedule({.workDuration = 50, .readyDuration = 0, .earliestVsync = 500}, |
| *mStubTracker.get(), 0) |
| .has_value()); |
| EXPECT_THAT(*entry.wakeupTime(), Eq(1950)); |
| EXPECT_THAT(*entry.readyTime(), Eq(2000)); |
| |
| EXPECT_TRUE(entry.schedule({.workDuration = 200, .readyDuration = 0, .earliestVsync = 1001}, |
| *mStubTracker.get(), 0) |
| .has_value()); |
| EXPECT_THAT(*entry.wakeupTime(), Eq(1800)); |
| EXPECT_THAT(*entry.readyTime(), Eq(2000)); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueEntryTest, |
| willRequestNextEstimateWhenSnappingToNextTargettableVSync) { |
| VSyncDispatchTimerQueueEntry entry( |
| "test", [](auto, auto, auto) {}, mVsyncMoveThreshold); |
| |
| Sequence seq; |
| EXPECT_CALL(*mStubTracker.get(), nextAnticipatedVSyncTimeFrom(500)) |
| .InSequence(seq) |
| .WillOnce(Return(1000)); |
| EXPECT_CALL(*mStubTracker.get(), nextAnticipatedVSyncTimeFrom(500)) |
| .InSequence(seq) |
| .WillOnce(Return(1000)); |
| EXPECT_CALL(*mStubTracker.get(), nextAnticipatedVSyncTimeFrom(1000 + mVsyncMoveThreshold)) |
| .InSequence(seq) |
| .WillOnce(Return(2000)); |
| |
| EXPECT_TRUE(entry.schedule({.workDuration = 100, .readyDuration = 0, .earliestVsync = 500}, |
| *mStubTracker.get(), 0) |
| .has_value()); |
| |
| entry.executing(); // 1000 is executing |
| |
| EXPECT_TRUE(entry.schedule({.workDuration = 200, .readyDuration = 0, .earliestVsync = 500}, |
| *mStubTracker.get(), 0) |
| .has_value()); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueEntryTest, reportsScheduledIfStillTime) { |
| VSyncDispatchTimerQueueEntry entry( |
| "test", [](auto, auto, auto) {}, mVsyncMoveThreshold); |
| EXPECT_TRUE(entry.schedule({.workDuration = 100, .readyDuration = 0, .earliestVsync = 500}, |
| *mStubTracker.get(), 0) |
| .has_value()); |
| EXPECT_TRUE(entry.schedule({.workDuration = 200, .readyDuration = 0, .earliestVsync = 500}, |
| *mStubTracker.get(), 0) |
| .has_value()); |
| EXPECT_TRUE(entry.schedule({.workDuration = 50, .readyDuration = 0, .earliestVsync = 500}, |
| *mStubTracker.get(), 0) |
| .has_value()); |
| EXPECT_TRUE(entry.schedule({.workDuration = 1200, .readyDuration = 0, .earliestVsync = 500}, |
| *mStubTracker.get(), 0) |
| .has_value()); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueEntryTest, storesPendingUpdatesUntilUpdate) { |
| static constexpr auto effectualOffset = 200; |
| VSyncDispatchTimerQueueEntry entry( |
| "test", [](auto, auto, auto) {}, mVsyncMoveThreshold); |
| EXPECT_FALSE(entry.hasPendingWorkloadUpdate()); |
| entry.addPendingWorkloadUpdate({.workDuration = 100, .readyDuration = 0, .earliestVsync = 400}); |
| entry.addPendingWorkloadUpdate( |
| {.workDuration = effectualOffset, .readyDuration = 0, .earliestVsync = 400}); |
| EXPECT_TRUE(entry.hasPendingWorkloadUpdate()); |
| entry.update(*mStubTracker.get(), 0); |
| EXPECT_FALSE(entry.hasPendingWorkloadUpdate()); |
| EXPECT_THAT(*entry.wakeupTime(), Eq(mPeriod - effectualOffset)); |
| } |
| |
| TEST_F(VSyncDispatchTimerQueueEntryTest, runCallbackWithReadyDuration) { |
| auto callCount = 0; |
| auto vsyncCalledTime = 0; |
| auto wakeupCalledTime = 0; |
| auto readyCalledTime = 0; |
| VSyncDispatchTimerQueueEntry entry( |
| "test", |
| [&](auto vsyncTime, auto wakeupTime, auto readyTime) { |
| callCount++; |
| vsyncCalledTime = vsyncTime; |
| wakeupCalledTime = wakeupTime; |
| readyCalledTime = readyTime; |
| }, |
| mVsyncMoveThreshold); |
| |
| EXPECT_TRUE(entry.schedule({.workDuration = 70, .readyDuration = 30, .earliestVsync = 500}, |
| *mStubTracker.get(), 0) |
| .has_value()); |
| auto const wakeup = entry.wakeupTime(); |
| ASSERT_TRUE(wakeup); |
| EXPECT_THAT(*wakeup, Eq(900)); |
| |
| auto const ready = entry.readyTime(); |
| ASSERT_TRUE(ready); |
| EXPECT_THAT(*ready, Eq(970)); |
| |
| entry.callback(entry.executing(), *wakeup, *ready); |
| |
| EXPECT_THAT(callCount, Eq(1)); |
| EXPECT_THAT(vsyncCalledTime, Eq(mPeriod)); |
| EXPECT_THAT(wakeupCalledTime, Eq(*wakeup)); |
| EXPECT_FALSE(entry.wakeupTime()); |
| auto lastCalledTarget = entry.lastExecutedVsyncTarget(); |
| ASSERT_TRUE(lastCalledTarget); |
| EXPECT_THAT(*lastCalledTarget, Eq(mPeriod)); |
| } |
| |
| } // namespace android::scheduler |
| |
| // TODO(b/129481165): remove the #pragma below and fix conversion issues |
| #pragma clang diagnostic pop // ignored "-Wconversion -Wextra" |
