services/inputflinger/tests/EventHub_test.cpp - third_party/android/platform/frameworks/native - Git at Google

 /*
  * Copyright (C) 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.
  */

 #include "EventHub.h"

 #include "UinputDevice.h"

 #include <gtest/gtest.h>
 #include <inttypes.h>
 #include <linux/uinput.h>
 #include <log/log.h>
 #include <chrono>

 #define TAG "EventHub_test"

 using android::createUinputDevice;
 using android::EventHub;
 using android::EventHubInterface;
 using android::InputDeviceIdentifier;
 using android::RawEvent;
 using android::sp;
 using android::UinputHomeKey;
 using std::chrono_literals::operator""ms;
 using std::chrono_literals::operator""s;

 static constexpr bool DEBUG = false;

 static void dumpEvents(const std::vector<RawEvent>& events) {
     for (const RawEvent& event : events) {
         if (event.type >= EventHubInterface::FIRST_SYNTHETIC_EVENT) {
             switch (event.type) {
                 case EventHubInterface::DEVICE_ADDED:
                     ALOGI("Device added: %i", event.deviceId);
                     break;
                 case EventHubInterface::DEVICE_REMOVED:
                     ALOGI("Device removed: %i", event.deviceId);
                     break;
                 case EventHubInterface::FINISHED_DEVICE_SCAN:
                     ALOGI("Finished device scan.");
                     break;
             }
         } else {
             ALOGI("Device %" PRId32 " : time = %" PRId64 ", type %i, code %i, value %i",
                   event.deviceId, event.when, event.type, event.code, event.value);
         }
     }
 }

 // --- EventHubTest ---
 class EventHubTest : public testing::Test {
 protected:
     std::unique_ptr<EventHubInterface> mEventHub;
     // We are only going to emulate a single input device currently.
     std::unique_ptr<UinputHomeKey> mKeyboard;
     int32_t mDeviceId;

     virtual void SetUp() override {
         mEventHub = std::make_unique<EventHub>();
         consumeInitialDeviceAddedEvents();
         mKeyboard = createUinputDevice<UinputHomeKey>();
         ASSERT_NO_FATAL_FAILURE(mDeviceId = waitForDeviceCreation());
     }
     virtual void TearDown() override {
         mKeyboard.reset();
         waitForDeviceClose(mDeviceId);
         assertNoMoreEvents();
     }

     /**
      * Return the device id of the created device.
      */
     int32_t waitForDeviceCreation();
     void waitForDeviceClose(int32_t deviceId);
     void consumeInitialDeviceAddedEvents();
     void assertNoMoreEvents();
     /**
      * Read events from the EventHub.
      *
      * If expectedEvents is set, wait for a significant period of time to try and ensure that
      * the expected number of events has been read. The number of returned events
      * may be smaller (if timeout has been reached) or larger than expectedEvents.
      *
      * If expectedEvents is not set, return all of the immediately available events.
      */
     std::vector<RawEvent> getEvents(std::optional<size_t> expectedEvents = std::nullopt);
 };

 std::vector<RawEvent> EventHubTest::getEvents(std::optional<size_t> expectedEvents) {
     static constexpr size_t EVENT_BUFFER_SIZE = 256;
     std::array<RawEvent, EVENT_BUFFER_SIZE> eventBuffer;
     std::vector<RawEvent> events;

     while (true) {
         std::chrono::milliseconds timeout = 0s;
         if (expectedEvents) {
             timeout = 2s;
         }
         const size_t count =
                 mEventHub->getEvents(timeout.count(), eventBuffer.data(), eventBuffer.size());
         if (count == 0) {
             break;
         }
         events.insert(events.end(), eventBuffer.begin(), eventBuffer.begin() + count);
         if (expectedEvents && events.size() >= *expectedEvents) {
             break;
         }
     }
     if (DEBUG) {
         dumpEvents(events);
     }
     return events;
 }

 /**
  * Since the test runs on a real platform, there will be existing devices
  * in addition to the test devices being added. Therefore, when EventHub is first created,
  * it will return a lot of "device added" type of events.
  */
 void EventHubTest::consumeInitialDeviceAddedEvents() {
     std::vector<RawEvent> events = getEvents();
     std::set<int32_t /*deviceId*/> existingDevices;
     // All of the events should be DEVICE_ADDED type, except the last one.
     for (size_t i = 0; i < events.size() - 1; i++) {
         const RawEvent& event = events[i];
         EXPECT_EQ(EventHubInterface::DEVICE_ADDED, event.type);
         existingDevices.insert(event.deviceId);
     }
     // None of the existing system devices should be changing while this test is run.
     // Check that the returned device ids are unique for all of the existing devices.
     EXPECT_EQ(existingDevices.size(), events.size() - 1);
     // The last event should be "finished device scan"
     EXPECT_EQ(EventHubInterface::FINISHED_DEVICE_SCAN, events[events.size() - 1].type);
 }

 int32_t EventHubTest::waitForDeviceCreation() {
     // Wait a little longer than usual, to ensure input device has time to be created
     std::vector<RawEvent> events = getEvents(2);
     if (events.size() != 2) {
         ADD_FAILURE() << "Instead of 2 events, received " << events.size();
         return 0; // this value is unused
     }
     const RawEvent& deviceAddedEvent = events[0];
     EXPECT_EQ(static_cast<int32_t>(EventHubInterface::DEVICE_ADDED), deviceAddedEvent.type);
     InputDeviceIdentifier identifier = mEventHub->getDeviceIdentifier(deviceAddedEvent.deviceId);
     const int32_t deviceId = deviceAddedEvent.deviceId;
     EXPECT_EQ(identifier.name, mKeyboard->getName());
     const RawEvent& finishedDeviceScanEvent = events[1];
     EXPECT_EQ(static_cast<int32_t>(EventHubInterface::FINISHED_DEVICE_SCAN),
               finishedDeviceScanEvent.type);
     return deviceId;
 }

 void EventHubTest::waitForDeviceClose(int32_t deviceId) {
     std::vector<RawEvent> events = getEvents(2);
     ASSERT_EQ(2U, events.size());
     const RawEvent& deviceRemovedEvent = events[0];
     EXPECT_EQ(static_cast<int32_t>(EventHubInterface::DEVICE_REMOVED), deviceRemovedEvent.type);
     EXPECT_EQ(deviceId, deviceRemovedEvent.deviceId);
     const RawEvent& finishedDeviceScanEvent = events[1];
     EXPECT_EQ(static_cast<int32_t>(EventHubInterface::FINISHED_DEVICE_SCAN),
               finishedDeviceScanEvent.type);
 }

 void EventHubTest::assertNoMoreEvents() {
     std::vector<RawEvent> events = getEvents();
     ASSERT_TRUE(events.empty());
 }

 /**
  * Ensure that input_events are generated with monotonic clock.
  * That means input_event should receive a timestamp that is in the future of the time
  * before the event was sent.
  * Input system uses CLOCK_MONOTONIC everywhere in the code base.
  */
 TEST_F(EventHubTest, InputEvent_TimestampIsMonotonic) {
     nsecs_t lastEventTime = systemTime(SYSTEM_TIME_MONOTONIC);
     ASSERT_NO_FATAL_FAILURE(mKeyboard->pressAndReleaseHomeKey());

     std::vector<RawEvent> events = getEvents(4);
     ASSERT_EQ(4U, events.size()) << "Expected to receive 2 keys and 2 syncs, total of 4 events";
     for (const RawEvent& event : events) {
         // Cannot use strict comparison because the events may happen too quickly
         ASSERT_LE(lastEventTime, event.when) << "Event must have occurred after the key was sent";
         ASSERT_LT(std::chrono::nanoseconds(event.when - lastEventTime), 100ms)
                 << "Event times are too far apart";
         lastEventTime = event.when; // Ensure all returned events are monotonic
     }
 }

 // --- BitArrayTest ---
 class BitArrayTest : public testing::Test {
 protected:
     static constexpr size_t SINGLE_ELE_BITS = 32UL;
     static constexpr size_t MULTI_ELE_BITS = 256UL;

     virtual void SetUp() override {
         mBitmaskSingle.loadFromBuffer(mBufferSingle);
         mBitmaskMulti.loadFromBuffer(mBufferMulti);
     }

     android::BitArray<SINGLE_ELE_BITS> mBitmaskSingle;
     android::BitArray<MULTI_ELE_BITS> mBitmaskMulti;

 private:
     const typename android::BitArray<SINGLE_ELE_BITS>::Buffer mBufferSingle = {
             0x800F0F0FUL // bit 0 - 31
     };
     const typename android::BitArray<MULTI_ELE_BITS>::Buffer mBufferMulti = {
             0xFFFFFFFFUL, // bit 0 - 31
             0x01000001UL, // bit 32 - 63
             0x00000000UL, // bit 64 - 95
             0x80000000UL, // bit 96 - 127
             0x00000000UL, // bit 128 - 159
             0x00000000UL, // bit 160 - 191
             0x80000008UL, // bit 192 - 223
             0x00000000UL, // bit 224 - 255
     };
 };

 TEST_F(BitArrayTest, SetBit) {
     ASSERT_TRUE(mBitmaskSingle.test(0));
     ASSERT_TRUE(mBitmaskSingle.test(31));
     ASSERT_FALSE(mBitmaskSingle.test(7));

     ASSERT_TRUE(mBitmaskMulti.test(32));
     ASSERT_TRUE(mBitmaskMulti.test(56));
     ASSERT_FALSE(mBitmaskMulti.test(192));
     ASSERT_TRUE(mBitmaskMulti.test(223));
     ASSERT_FALSE(mBitmaskMulti.test(255));
 }

 TEST_F(BitArrayTest, AnyBit) {
     ASSERT_TRUE(mBitmaskSingle.any(31, 32));
     ASSERT_FALSE(mBitmaskSingle.any(12, 16));

     ASSERT_TRUE(mBitmaskMulti.any(31, 32));
     ASSERT_FALSE(mBitmaskMulti.any(33, 33));
     ASSERT_TRUE(mBitmaskMulti.any(32, 55));
     ASSERT_TRUE(mBitmaskMulti.any(33, 57));
     ASSERT_FALSE(mBitmaskMulti.any(33, 55));
     ASSERT_FALSE(mBitmaskMulti.any(130, 190));

     ASSERT_FALSE(mBitmaskMulti.any(128, 195));
     ASSERT_TRUE(mBitmaskMulti.any(128, 196));
     ASSERT_TRUE(mBitmaskMulti.any(128, 224));
     ASSERT_FALSE(mBitmaskMulti.any(255, 256));
 }

 TEST_F(BitArrayTest, SetBit_InvalidBitIndex) {
     ASSERT_FALSE(mBitmaskSingle.test(32));
     ASSERT_FALSE(mBitmaskMulti.test(256));
 }

 TEST_F(BitArrayTest, AnyBit_InvalidBitIndex) {
     ASSERT_FALSE(mBitmaskSingle.any(32, 32));
     ASSERT_FALSE(mBitmaskSingle.any(33, 34));

     ASSERT_FALSE(mBitmaskMulti.any(256, 256));
     ASSERT_FALSE(mBitmaskMulti.any(257, 258));
     ASSERT_FALSE(mBitmaskMulti.any(0, 0));
 }
	/*
	* Copyright (C) 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.
	*/

	#include "EventHub.h"

	#include "UinputDevice.h"

	#include <gtest/gtest.h>
	#include <inttypes.h>
	#include <linux/uinput.h>
	#include <log/log.h>
	#include <chrono>

	#define TAG "EventHub_test"

	using android::createUinputDevice;
	using android::EventHub;
	using android::EventHubInterface;
	using android::InputDeviceIdentifier;
	using android::RawEvent;
	using android::sp;
	using android::UinputHomeKey;
	using std::chrono_literals::operator""ms;
	using std::chrono_literals::operator""s;

	static constexpr bool DEBUG = false;

	static void dumpEvents(const std::vector<RawEvent>& events) {
	for (const RawEvent& event : events) {
	if (event.type >= EventHubInterface::FIRST_SYNTHETIC_EVENT) {
	switch (event.type) {
	case EventHubInterface::DEVICE_ADDED:
	ALOGI("Device added: %i", event.deviceId);
	break;
	case EventHubInterface::DEVICE_REMOVED:
	ALOGI("Device removed: %i", event.deviceId);
	break;
	case EventHubInterface::FINISHED_DEVICE_SCAN:
	ALOGI("Finished device scan.");
	break;
	}
	} else {
	ALOGI("Device %" PRId32 " : time = %" PRId64 ", type %i, code %i, value %i",
	event.deviceId, event.when, event.type, event.code, event.value);
	}
	}
	}

	// --- EventHubTest ---
	class EventHubTest : public testing::Test {
	protected:
	std::unique_ptr<EventHubInterface> mEventHub;
	// We are only going to emulate a single input device currently.
	std::unique_ptr<UinputHomeKey> mKeyboard;
	int32_t mDeviceId;

	virtual void SetUp() override {
	mEventHub = std::make_unique<EventHub>();
	consumeInitialDeviceAddedEvents();
	mKeyboard = createUinputDevice<UinputHomeKey>();
	ASSERT_NO_FATAL_FAILURE(mDeviceId = waitForDeviceCreation());
	}
	virtual void TearDown() override {
	mKeyboard.reset();
	waitForDeviceClose(mDeviceId);
	assertNoMoreEvents();
	}

	/**
	* Return the device id of the created device.
	*/
	int32_t waitForDeviceCreation();
	void waitForDeviceClose(int32_t deviceId);
	void consumeInitialDeviceAddedEvents();
	void assertNoMoreEvents();
	/**
	* Read events from the EventHub.
	*
	* If expectedEvents is set, wait for a significant period of time to try and ensure that
	* the expected number of events has been read. The number of returned events
	* may be smaller (if timeout has been reached) or larger than expectedEvents.
	*
	* If expectedEvents is not set, return all of the immediately available events.
	*/
	std::vector<RawEvent> getEvents(std::optional<size_t> expectedEvents = std::nullopt);
	};

	std::vector<RawEvent> EventHubTest::getEvents(std::optional<size_t> expectedEvents) {
	static constexpr size_t EVENT_BUFFER_SIZE = 256;
	std::array<RawEvent, EVENT_BUFFER_SIZE> eventBuffer;
	std::vector<RawEvent> events;

	while (true) {
	std::chrono::milliseconds timeout = 0s;
	if (expectedEvents) {
	timeout = 2s;
	}
	const size_t count =
	mEventHub->getEvents(timeout.count(), eventBuffer.data(), eventBuffer.size());
	if (count == 0) {
	break;
	}
	events.insert(events.end(), eventBuffer.begin(), eventBuffer.begin() + count);
	if (expectedEvents && events.size() >= *expectedEvents) {
	break;
	}
	}
	if (DEBUG) {
	dumpEvents(events);
	}
	return events;
	}

	/**
	* Since the test runs on a real platform, there will be existing devices
	* in addition to the test devices being added. Therefore, when EventHub is first created,
	* it will return a lot of "device added" type of events.
	*/
	void EventHubTest::consumeInitialDeviceAddedEvents() {
	std::vector<RawEvent> events = getEvents();
	std::set<int32_t /deviceId/> existingDevices;
	// All of the events should be DEVICE_ADDED type, except the last one.
	for (size_t i = 0; i < events.size() - 1; i++) {
	const RawEvent& event = events[i];
	EXPECT_EQ(EventHubInterface::DEVICE_ADDED, event.type);
	existingDevices.insert(event.deviceId);
	}
	// None of the existing system devices should be changing while this test is run.
	// Check that the returned device ids are unique for all of the existing devices.
	EXPECT_EQ(existingDevices.size(), events.size() - 1);
	// The last event should be "finished device scan"
	EXPECT_EQ(EventHubInterface::FINISHED_DEVICE_SCAN, events[events.size() - 1].type);
	}

	int32_t EventHubTest::waitForDeviceCreation() {
	// Wait a little longer than usual, to ensure input device has time to be created
	std::vector<RawEvent> events = getEvents(2);
	if (events.size() != 2) {
	ADD_FAILURE() << "Instead of 2 events, received " << events.size();
	return 0; // this value is unused
	}
	const RawEvent& deviceAddedEvent = events[0];
	EXPECT_EQ(static_cast<int32_t>(EventHubInterface::DEVICE_ADDED), deviceAddedEvent.type);
	InputDeviceIdentifier identifier = mEventHub->getDeviceIdentifier(deviceAddedEvent.deviceId);
	const int32_t deviceId = deviceAddedEvent.deviceId;
	EXPECT_EQ(identifier.name, mKeyboard->getName());
	const RawEvent& finishedDeviceScanEvent = events[1];
	EXPECT_EQ(static_cast<int32_t>(EventHubInterface::FINISHED_DEVICE_SCAN),
	finishedDeviceScanEvent.type);
	return deviceId;
	}

	void EventHubTest::waitForDeviceClose(int32_t deviceId) {
	std::vector<RawEvent> events = getEvents(2);
	ASSERT_EQ(2U, events.size());
	const RawEvent& deviceRemovedEvent = events[0];
	EXPECT_EQ(static_cast<int32_t>(EventHubInterface::DEVICE_REMOVED), deviceRemovedEvent.type);
	EXPECT_EQ(deviceId, deviceRemovedEvent.deviceId);
	const RawEvent& finishedDeviceScanEvent = events[1];
	EXPECT_EQ(static_cast<int32_t>(EventHubInterface::FINISHED_DEVICE_SCAN),
	finishedDeviceScanEvent.type);
	}

	void EventHubTest::assertNoMoreEvents() {
	std::vector<RawEvent> events = getEvents();
	ASSERT_TRUE(events.empty());
	}

	/**
	* Ensure that input_events are generated with monotonic clock.
	* That means input_event should receive a timestamp that is in the future of the time
	* before the event was sent.
	* Input system uses CLOCK_MONOTONIC everywhere in the code base.
	*/
	TEST_F(EventHubTest, InputEvent_TimestampIsMonotonic) {
	nsecs_t lastEventTime = systemTime(SYSTEM_TIME_MONOTONIC);
	ASSERT_NO_FATAL_FAILURE(mKeyboard->pressAndReleaseHomeKey());

	std::vector<RawEvent> events = getEvents(4);
	ASSERT_EQ(4U, events.size()) << "Expected to receive 2 keys and 2 syncs, total of 4 events";
	for (const RawEvent& event : events) {
	// Cannot use strict comparison because the events may happen too quickly
	ASSERT_LE(lastEventTime, event.when) << "Event must have occurred after the key was sent";
	ASSERT_LT(std::chrono::nanoseconds(event.when - lastEventTime), 100ms)
	<< "Event times are too far apart";
	lastEventTime = event.when; // Ensure all returned events are monotonic
	}
	}

	// --- BitArrayTest ---
	class BitArrayTest : public testing::Test {
	protected:
	static constexpr size_t SINGLE_ELE_BITS = 32UL;
	static constexpr size_t MULTI_ELE_BITS = 256UL;

	virtual void SetUp() override {
	mBitmaskSingle.loadFromBuffer(mBufferSingle);
	mBitmaskMulti.loadFromBuffer(mBufferMulti);
	}

	android::BitArray<SINGLE_ELE_BITS> mBitmaskSingle;
	android::BitArray<MULTI_ELE_BITS> mBitmaskMulti;

	private:
	const typename android::BitArray<SINGLE_ELE_BITS>::Buffer mBufferSingle = {
	0x800F0F0FUL // bit 0 - 31
	};
	const typename android::BitArray<MULTI_ELE_BITS>::Buffer mBufferMulti = {
	0xFFFFFFFFUL, // bit 0 - 31
	0x01000001UL, // bit 32 - 63
	0x00000000UL, // bit 64 - 95
	0x80000000UL, // bit 96 - 127
	0x00000000UL, // bit 128 - 159
	0x00000000UL, // bit 160 - 191
	0x80000008UL, // bit 192 - 223
	0x00000000UL, // bit 224 - 255
	};
	};

	TEST_F(BitArrayTest, SetBit) {
	ASSERT_TRUE(mBitmaskSingle.test(0));
	ASSERT_TRUE(mBitmaskSingle.test(31));
	ASSERT_FALSE(mBitmaskSingle.test(7));

	ASSERT_TRUE(mBitmaskMulti.test(32));
	ASSERT_TRUE(mBitmaskMulti.test(56));
	ASSERT_FALSE(mBitmaskMulti.test(192));
	ASSERT_TRUE(mBitmaskMulti.test(223));
	ASSERT_FALSE(mBitmaskMulti.test(255));
	}

	TEST_F(BitArrayTest, AnyBit) {
	ASSERT_TRUE(mBitmaskSingle.any(31, 32));
	ASSERT_FALSE(mBitmaskSingle.any(12, 16));

	ASSERT_TRUE(mBitmaskMulti.any(31, 32));
	ASSERT_FALSE(mBitmaskMulti.any(33, 33));
	ASSERT_TRUE(mBitmaskMulti.any(32, 55));
	ASSERT_TRUE(mBitmaskMulti.any(33, 57));
	ASSERT_FALSE(mBitmaskMulti.any(33, 55));
	ASSERT_FALSE(mBitmaskMulti.any(130, 190));

	ASSERT_FALSE(mBitmaskMulti.any(128, 195));
	ASSERT_TRUE(mBitmaskMulti.any(128, 196));
	ASSERT_TRUE(mBitmaskMulti.any(128, 224));
	ASSERT_FALSE(mBitmaskMulti.any(255, 256));
	}

	TEST_F(BitArrayTest, SetBit_InvalidBitIndex) {
	ASSERT_FALSE(mBitmaskSingle.test(32));
	ASSERT_FALSE(mBitmaskMulti.test(256));
	}

	TEST_F(BitArrayTest, AnyBit_InvalidBitIndex) {
	ASSERT_FALSE(mBitmaskSingle.any(32, 32));
	ASSERT_FALSE(mBitmaskSingle.any(33, 34));

	ASSERT_FALSE(mBitmaskMulti.any(256, 256));
	ASSERT_FALSE(mBitmaskMulti.any(257, 258));
	ASSERT_FALSE(mBitmaskMulti.any(0, 0));
	}