/* * Copyright (C) 2010 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 #include "TestHelpers.h" #include #include #include #include #include #include #include #include #include #include namespace android { class InputChannelTest : public testing::Test { }; TEST_F(InputChannelTest, ConstructorAndDestructor_TakesOwnershipOfFileDescriptors) { // Our purpose here is to verify that the input channel destructor closes the // file descriptor provided to it. One easy way is to provide it with one end // of a pipe and to check for EPIPE on the other end after the channel is destroyed. Pipe pipe; android::base::unique_fd sendFd(pipe.sendFd); std::unique_ptr inputChannel = InputChannel::create("channel name", std::move(sendFd), new BBinder()); EXPECT_NE(inputChannel, nullptr) << "channel should be successfully created"; EXPECT_STREQ("channel name", inputChannel->getName().c_str()) << "channel should have provided name"; EXPECT_NE(-1, inputChannel->getFd()) << "channel should have valid fd"; // InputChannel should be the owner of the file descriptor now ASSERT_FALSE(sendFd.ok()); } TEST_F(InputChannelTest, SetAndGetToken) { Pipe pipe; sp token = new BBinder(); std::unique_ptr channel = InputChannel::create("test channel", android::base::unique_fd(pipe.sendFd), token); EXPECT_EQ(token, channel->getConnectionToken()); } TEST_F(InputChannelTest, OpenInputChannelPair_ReturnsAPairOfConnectedChannels) { std::unique_ptr serverChannel, clientChannel; status_t result = InputChannel::openInputChannelPair("channel name", serverChannel, clientChannel); ASSERT_EQ(OK, result) << "should have successfully opened a channel pair"; // Name EXPECT_STREQ("channel name (server)", serverChannel->getName().c_str()) << "server channel should have suffixed name"; EXPECT_STREQ("channel name (client)", clientChannel->getName().c_str()) << "client channel should have suffixed name"; // Server->Client communication InputMessage serverMsg; memset(&serverMsg, 0, sizeof(InputMessage)); serverMsg.header.type = InputMessage::Type::KEY; serverMsg.body.key.action = AKEY_EVENT_ACTION_DOWN; EXPECT_EQ(OK, serverChannel->sendMessage(&serverMsg)) << "server channel should be able to send message to client channel"; InputMessage clientMsg; EXPECT_EQ(OK, clientChannel->receiveMessage(&clientMsg)) << "client channel should be able to receive message from server channel"; EXPECT_EQ(serverMsg.header.type, clientMsg.header.type) << "client channel should receive the correct message from server channel"; EXPECT_EQ(serverMsg.body.key.action, clientMsg.body.key.action) << "client channel should receive the correct message from server channel"; // Client->Server communication InputMessage clientReply; memset(&clientReply, 0, sizeof(InputMessage)); clientReply.header.type = InputMessage::Type::FINISHED; clientReply.header.seq = 0x11223344; clientReply.body.finished.handled = true; EXPECT_EQ(OK, clientChannel->sendMessage(&clientReply)) << "client channel should be able to send message to server channel"; InputMessage serverReply; EXPECT_EQ(OK, serverChannel->receiveMessage(&serverReply)) << "server channel should be able to receive message from client channel"; EXPECT_EQ(clientReply.header.type, serverReply.header.type) << "server channel should receive the correct message from client channel"; EXPECT_EQ(clientReply.header.seq, serverReply.header.seq) << "server channel should receive the correct message from client channel"; EXPECT_EQ(clientReply.body.finished.handled, serverReply.body.finished.handled) << "server channel should receive the correct message from client channel"; } TEST_F(InputChannelTest, ReceiveSignal_WhenNoSignalPresent_ReturnsAnError) { std::unique_ptr serverChannel, clientChannel; status_t result = InputChannel::openInputChannelPair("channel name", serverChannel, clientChannel); ASSERT_EQ(OK, result) << "should have successfully opened a channel pair"; InputMessage msg; EXPECT_EQ(WOULD_BLOCK, clientChannel->receiveMessage(&msg)) << "receiveMessage should have returned WOULD_BLOCK"; } TEST_F(InputChannelTest, ReceiveSignal_WhenPeerClosed_ReturnsAnError) { std::unique_ptr serverChannel, clientChannel; status_t result = InputChannel::openInputChannelPair("channel name", serverChannel, clientChannel); ASSERT_EQ(OK, result) << "should have successfully opened a channel pair"; serverChannel.reset(); // close server channel InputMessage msg; EXPECT_EQ(DEAD_OBJECT, clientChannel->receiveMessage(&msg)) << "receiveMessage should have returned DEAD_OBJECT"; } TEST_F(InputChannelTest, SendSignal_WhenPeerClosed_ReturnsAnError) { std::unique_ptr serverChannel, clientChannel; status_t result = InputChannel::openInputChannelPair("channel name", serverChannel, clientChannel); ASSERT_EQ(OK, result) << "should have successfully opened a channel pair"; serverChannel.reset(); // close server channel InputMessage msg; msg.header.type = InputMessage::Type::KEY; EXPECT_EQ(DEAD_OBJECT, clientChannel->sendMessage(&msg)) << "sendMessage should have returned DEAD_OBJECT"; } TEST_F(InputChannelTest, SendAndReceive_MotionClassification) { std::unique_ptr serverChannel, clientChannel; status_t result = InputChannel::openInputChannelPair("channel name", serverChannel, clientChannel); ASSERT_EQ(OK, result) << "should have successfully opened a channel pair"; std::array classifications = { MotionClassification::NONE, MotionClassification::AMBIGUOUS_GESTURE, MotionClassification::DEEP_PRESS, }; InputMessage serverMsg = {}, clientMsg; serverMsg.header.type = InputMessage::Type::MOTION; serverMsg.header.seq = 1; serverMsg.body.motion.pointerCount = 1; for (MotionClassification classification : classifications) { // Send and receive a message with classification serverMsg.body.motion.classification = classification; EXPECT_EQ(OK, serverChannel->sendMessage(&serverMsg)) << "server channel should be able to send message to client channel"; EXPECT_EQ(OK, clientChannel->receiveMessage(&clientMsg)) << "client channel should be able to receive message from server channel"; EXPECT_EQ(serverMsg.header.type, clientMsg.header.type); EXPECT_EQ(classification, clientMsg.body.motion.classification) << "Expected to receive " << motionClassificationToString(classification); } } TEST_F(InputChannelTest, InputChannelParcelAndUnparcel) { std::unique_ptr serverChannel, clientChannel; status_t result = InputChannel::openInputChannelPair("channel parceling", serverChannel, clientChannel); ASSERT_EQ(OK, result) << "should have successfully opened a channel pair"; InputChannel chan; Parcel parcel; ASSERT_EQ(OK, serverChannel->writeToParcel(&parcel)); parcel.setDataPosition(0); chan.readFromParcel(&parcel); EXPECT_EQ(chan == *serverChannel, true) << "inputchannel should be equal after parceling and unparceling.\n" << "name " << chan.getName() << " name " << serverChannel->getName(); } TEST_F(InputChannelTest, DuplicateChannelAndAssertEqual) { std::unique_ptr serverChannel, clientChannel; status_t result = InputChannel::openInputChannelPair("channel dup", serverChannel, clientChannel); ASSERT_EQ(OK, result) << "should have successfully opened a channel pair"; std::unique_ptr dupChan = serverChannel->dup(); EXPECT_EQ(*serverChannel == *dupChan, true) << "inputchannel should be equal after duplication"; } } // namespace android