/* * Copyright (C) 2021 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. */ #include "../dispatcher/LatencyTracker.h" #include #include #include #include #define TAG "LatencyTracker_test" using android::inputdispatcher::InputEventTimeline; using android::inputdispatcher::LatencyTracker; namespace android::inputdispatcher { InputEventTimeline getTestTimeline() { InputEventTimeline t( /*isDown*/ true, /*eventTime*/ 2, /*readTime*/ 3); ConnectionTimeline expectedCT(/*deliveryTime*/ 6, /* consumeTime*/ 7, /*finishTime*/ 8); std::array graphicsTimeline; graphicsTimeline[GraphicsTimeline::GPU_COMPLETED_TIME] = 9; graphicsTimeline[GraphicsTimeline::PRESENT_TIME] = 10; expectedCT.setGraphicsTimeline(std::move(graphicsTimeline)); t.connectionTimelines.emplace(new BBinder(), std::move(expectedCT)); return t; } // --- LatencyTrackerTest --- class LatencyTrackerTest : public testing::Test, public InputEventTimelineProcessor { protected: std::unique_ptr mTracker; sp connection1; sp connection2; void SetUp() override { connection1 = new BBinder(); connection2 = new BBinder(); mTracker = std::make_unique(this); } void TearDown() override {} void assertReceivedTimeline(const InputEventTimeline& timeline); /** * Timelines can be received in any order (order is not guaranteed). So if we are expecting more * than 1 timeline, use this function to check that the set of received timelines matches * what we expected. */ void assertReceivedTimelines(const std::vector& timelines); private: void processTimeline(const InputEventTimeline& timeline) override { mReceivedTimelines.push_back(timeline); } std::deque mReceivedTimelines; }; void LatencyTrackerTest::assertReceivedTimeline(const InputEventTimeline& timeline) { mTracker->reportNow(); ASSERT_FALSE(mReceivedTimelines.empty()); const InputEventTimeline& t = mReceivedTimelines.front(); ASSERT_EQ(timeline, t); mReceivedTimelines.pop_front(); } /** * We are essentially comparing two multisets, but without constructing them. * This comparison is inefficient, but it avoids having to construct a set, and also avoids the * declaration of copy constructor for ConnectionTimeline. * We ensure that collections A and B have the same size, that for every element in A, there is an * equal element in B, and for every element in B there is an equal element in A. */ void LatencyTrackerTest::assertReceivedTimelines(const std::vector& timelines) { mTracker->reportNow(); ASSERT_EQ(timelines.size(), mReceivedTimelines.size()); for (const InputEventTimeline& expectedTimeline : timelines) { bool found = false; for (const InputEventTimeline& receivedTimeline : mReceivedTimelines) { if (receivedTimeline == expectedTimeline) { found = true; break; } } ASSERT_TRUE(found) << "Could not find expected timeline with eventTime=" << expectedTimeline.eventTime; } for (const InputEventTimeline& receivedTimeline : mReceivedTimelines) { bool found = false; for (const InputEventTimeline& expectedTimeline : timelines) { if (receivedTimeline == expectedTimeline) { found = true; break; } } ASSERT_TRUE(found) << "Could not find received timeline with eventTime=" << receivedTimeline.eventTime; } mReceivedTimelines.clear(); } /** * Ensure that calling 'trackListener' in isolation only creates an inputflinger timeline, without * any additional ConnectionTimeline's. */ TEST_F(LatencyTrackerTest, TrackListener_DoesNotTriggerReporting) { mTracker->trackListener(1 /*inputEventId*/, false /*isDown*/, 2 /*eventTime*/, 3 /*readTime*/); assertReceivedTimeline(InputEventTimeline{false, 2, 3}); } /** * A single call to trackFinishedEvent should not cause a timeline to be reported. */ TEST_F(LatencyTrackerTest, TrackFinishedEvent_DoesNotTriggerReporting) { mTracker->trackFinishedEvent(1 /*inputEventId*/, connection1, 2 /*deliveryTime*/, 3 /*consumeTime*/, 4 /*finishTime*/); assertReceivedTimelines({}); } /** * A single call to trackGraphicsLatency should not cause a timeline to be reported. */ TEST_F(LatencyTrackerTest, TrackGraphicsLatency_DoesNotTriggerReporting) { std::array graphicsTimeline; graphicsTimeline[GraphicsTimeline::GPU_COMPLETED_TIME] = 2; graphicsTimeline[GraphicsTimeline::PRESENT_TIME] = 3; mTracker->trackGraphicsLatency(1 /*inputEventId*/, connection2, graphicsTimeline); assertReceivedTimelines({}); } TEST_F(LatencyTrackerTest, TrackAllParameters_ReportsFullTimeline) { constexpr int32_t inputEventId = 1; InputEventTimeline expected = getTestTimeline(); const auto& [connectionToken, expectedCT] = *expected.connectionTimelines.begin(); mTracker->trackListener(inputEventId, expected.isDown, expected.eventTime, expected.readTime); mTracker->trackFinishedEvent(inputEventId, connectionToken, expectedCT.deliveryTime, expectedCT.consumeTime, expectedCT.finishTime); mTracker->trackGraphicsLatency(inputEventId, connectionToken, expectedCT.graphicsTimeline); assertReceivedTimeline(expected); } TEST_F(LatencyTrackerTest, MultipleEvents_AreReportedConsistently) { constexpr int32_t inputEventId1 = 1; InputEventTimeline timeline1( /*isDown*/ true, /*eventTime*/ 2, /*readTime*/ 3); timeline1.connectionTimelines.emplace(connection1, ConnectionTimeline(/*deliveryTime*/ 6, /*consumeTime*/ 7, /*finishTime*/ 8)); ConnectionTimeline& connectionTimeline1 = timeline1.connectionTimelines.begin()->second; std::array graphicsTimeline1; graphicsTimeline1[GraphicsTimeline::GPU_COMPLETED_TIME] = 9; graphicsTimeline1[GraphicsTimeline::PRESENT_TIME] = 10; connectionTimeline1.setGraphicsTimeline(std::move(graphicsTimeline1)); constexpr int32_t inputEventId2 = 10; InputEventTimeline timeline2( /*isDown*/ false, /*eventTime*/ 20, /*readTime*/ 30); timeline2.connectionTimelines.emplace(connection2, ConnectionTimeline(/*deliveryTime*/ 60, /*consumeTime*/ 70, /*finishTime*/ 80)); ConnectionTimeline& connectionTimeline2 = timeline2.connectionTimelines.begin()->second; std::array graphicsTimeline2; graphicsTimeline2[GraphicsTimeline::GPU_COMPLETED_TIME] = 90; graphicsTimeline2[GraphicsTimeline::PRESENT_TIME] = 100; connectionTimeline2.setGraphicsTimeline(std::move(graphicsTimeline2)); // Start processing first event mTracker->trackListener(inputEventId1, timeline1.isDown, timeline1.eventTime, timeline1.readTime); // Start processing second event mTracker->trackListener(inputEventId2, timeline2.isDown, timeline2.eventTime, timeline2.readTime); mTracker->trackFinishedEvent(inputEventId1, connection1, connectionTimeline1.deliveryTime, connectionTimeline1.consumeTime, connectionTimeline1.finishTime); mTracker->trackFinishedEvent(inputEventId2, connection2, connectionTimeline2.deliveryTime, connectionTimeline2.consumeTime, connectionTimeline2.finishTime); mTracker->trackGraphicsLatency(inputEventId1, connection1, connectionTimeline1.graphicsTimeline); mTracker->trackGraphicsLatency(inputEventId2, connection2, connectionTimeline2.graphicsTimeline); // Now both events should be completed assertReceivedTimelines({timeline1, timeline2}); } /** * Check that LatencyTracker consistently tracks events even if there are many incomplete events. */ TEST_F(LatencyTrackerTest, IncompleteEvents_AreHandledConsistently) { InputEventTimeline timeline = getTestTimeline(); std::vector expectedTimelines; const ConnectionTimeline& expectedCT = timeline.connectionTimelines.begin()->second; const sp& token = timeline.connectionTimelines.begin()->first; for (size_t i = 1; i <= 100; i++) { mTracker->trackListener(i /*inputEventId*/, timeline.isDown, timeline.eventTime, timeline.readTime); expectedTimelines.push_back( InputEventTimeline{timeline.isDown, timeline.eventTime, timeline.readTime}); } // Now, complete the first event that was sent. mTracker->trackFinishedEvent(1 /*inputEventId*/, token, expectedCT.deliveryTime, expectedCT.consumeTime, expectedCT.finishTime); mTracker->trackGraphicsLatency(1 /*inputEventId*/, token, expectedCT.graphicsTimeline); expectedTimelines[0].connectionTimelines.emplace(token, std::move(expectedCT)); assertReceivedTimelines(expectedTimelines); } /** * For simplicity of the implementation, LatencyTracker only starts tracking an event when * 'trackListener' is invoked. * Both 'trackFinishedEvent' and 'trackGraphicsLatency' should not start a new event. * If they are received before 'trackListener' (which should not be possible), they are ignored. */ TEST_F(LatencyTrackerTest, EventsAreTracked_WhenTrackListenerIsCalledFirst) { constexpr int32_t inputEventId = 1; InputEventTimeline expected = getTestTimeline(); const ConnectionTimeline& expectedCT = expected.connectionTimelines.begin()->second; mTracker->trackFinishedEvent(inputEventId, connection1, expectedCT.deliveryTime, expectedCT.consumeTime, expectedCT.finishTime); mTracker->trackGraphicsLatency(inputEventId, connection1, expectedCT.graphicsTimeline); mTracker->trackListener(inputEventId, expected.isDown, expected.eventTime, expected.readTime); assertReceivedTimeline( InputEventTimeline{expected.isDown, expected.eventTime, expected.readTime}); } } // namespace android::inputdispatcher