fastboot/udp_test.cpp - third_party/android/platform/system/core - Git at Google

 /*
  * Copyright (C) 2015 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 "udp.h"

 #include <gtest/gtest.h>

 #include "socket.h"
 #include "socket_mock.h"

 using namespace udp;
 using namespace udp::internal;

 // Some possible corner case sequence numbers we want to check.
 static const uint16_t kTestSequenceNumbers[] = {0x0000, 0x0001, 0x00FF, 0x0100,
                                                 0x7FFF, 0x8000, 0xFFFF};

 // Converts |value| to a binary big-endian string.
 static std::string PacketValue(uint16_t value) {
     return std::string{static_cast<char>(value >> 8), static_cast<char>(value)};
 }

 // Returns an Error packet.
 static std::string ErrorPacket(uint16_t sequence, const std::string& message = "",
                                char flags = kFlagNone) {
     return std::string{kIdError, flags} + PacketValue(sequence) + message;
 }

 // Returns a Query packet with no data.
 static std::string QueryPacket(uint16_t sequence) {
     return std::string{kIdDeviceQuery, kFlagNone} + PacketValue(sequence);
 }

 // Returns a Query packet with a 2-byte |new_sequence|.
 static std::string QueryPacket(uint16_t sequence, uint16_t new_sequence) {
     return std::string{kIdDeviceQuery, kFlagNone} + PacketValue(sequence) +
            PacketValue(new_sequence);
 }

 // Returns an Init packet with a 2-byte |version| and |max_packet_size|.
 static std::string InitPacket(uint16_t sequence, uint16_t version, uint16_t max_packet_size) {
     return std::string{kIdInitialization, kFlagNone} + PacketValue(sequence) +
            PacketValue(version) + PacketValue(max_packet_size);
 }

 // Returns a Fastboot packet with |data|.
 static std::string FastbootPacket(uint16_t sequence, const std::string& data = "",
                                   char flags = kFlagNone) {
     return std::string{kIdFastboot, flags} + PacketValue(sequence) + data;
 }

 // Fixture class to test protocol initialization. Usage is to set up the expected calls to the
 // SocketMock object then call UdpConnect() and check the result.
 class UdpConnectTest : public ::testing::Test {
   public:
     UdpConnectTest() : mock_socket_(new SocketMock) {}

     // Run the initialization, return whether it was successful or not. This passes ownership of
     // the current |mock_socket_| but allocates a new one for re-use.
     bool UdpConnect(std::string* error = nullptr) {
         std::string local_error;
         if (error == nullptr) {
             error = &local_error;
         }
         std::unique_ptr<Transport> transport(Connect(std::move(mock_socket_), error));
         mock_socket_.reset(new SocketMock);
         return transport != nullptr && error->empty();
     }

   protected:
     std::unique_ptr<SocketMock> mock_socket_;
 };

 // Tests a successful protocol initialization with various starting sequence numbers.
 TEST_F(UdpConnectTest, InitializationSuccess) {
     for (uint16_t seq : kTestSequenceNumbers) {
         mock_socket_->ExpectSend(QueryPacket(0));
         mock_socket_->AddReceive(QueryPacket(0, seq));
         mock_socket_->ExpectSend(InitPacket(seq, kProtocolVersion, kHostMaxPacketSize));
         mock_socket_->AddReceive(InitPacket(seq, kProtocolVersion, 1024));

         EXPECT_TRUE(UdpConnect());
     }
 }

 // Tests continuation packets during initialization.
 TEST_F(UdpConnectTest, InitializationContinuationSuccess) {
     mock_socket_->ExpectSend(QueryPacket(0));
     mock_socket_->AddReceive(std::string{kIdDeviceQuery, kFlagContinuation, 0, 0, 0x44});
     mock_socket_->ExpectSend(std::string{kIdDeviceQuery, kFlagNone, 0, 1});
     mock_socket_->AddReceive(std::string{kIdDeviceQuery, kFlagNone, 0, 1, 0x55});

     mock_socket_->ExpectSend(InitPacket(0x4455, kProtocolVersion, kHostMaxPacketSize));
     mock_socket_->AddReceive(std::string{kIdInitialization, kFlagContinuation, 0x44, 0x55, 0});
     mock_socket_->ExpectSend(std::string{kIdInitialization, kFlagNone, 0x44, 0x56});
     mock_socket_->AddReceive(std::string{kIdInitialization, kFlagContinuation, 0x44, 0x56, 1});
     mock_socket_->ExpectSend(std::string{kIdInitialization, kFlagNone, 0x44, 0x57});
     mock_socket_->AddReceive(std::string{kIdInitialization, kFlagContinuation, 0x44, 0x57, 2});
     mock_socket_->ExpectSend(std::string{kIdInitialization, kFlagNone, 0x44, 0x58});
     mock_socket_->AddReceive(std::string{kIdInitialization, kFlagNone, 0x44, 0x58, 0});

     EXPECT_TRUE(UdpConnect());
 }


 // Tests a mismatched version number; as long as the minimum of the two versions is supported
 // we should allow the connection.
 TEST_F(UdpConnectTest, InitializationVersionMismatch) {
     mock_socket_->ExpectSend(QueryPacket(0));
     mock_socket_->AddReceive(QueryPacket(0, 0));
     mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
     mock_socket_->AddReceive(InitPacket(0, 2, 1024));

     EXPECT_TRUE(UdpConnect());

     mock_socket_->ExpectSend(QueryPacket(0));
     mock_socket_->AddReceive(QueryPacket(0, 0));
     mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
     mock_socket_->AddReceive(InitPacket(0, 0, 1024));

     EXPECT_FALSE(UdpConnect());
 }

 TEST_F(UdpConnectTest, QueryResponseTimeoutFailure) {
     for (int i = 0; i < kMaxConnectAttempts; ++i) {
         mock_socket_->ExpectSend(QueryPacket(0));
         mock_socket_->AddReceiveTimeout();
     }

     EXPECT_FALSE(UdpConnect());
 }

 TEST_F(UdpConnectTest, QueryResponseReceiveFailure) {
     mock_socket_->ExpectSend(QueryPacket(0));
     mock_socket_->AddReceiveFailure();

     EXPECT_FALSE(UdpConnect());
 }

 TEST_F(UdpConnectTest, InitResponseTimeoutFailure) {
     mock_socket_->ExpectSend(QueryPacket(0));
     mock_socket_->AddReceive(QueryPacket(0, 0));
     for (int i = 0; i < kMaxTransmissionAttempts; ++i) {
         mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
         mock_socket_->AddReceiveTimeout();
     }

     EXPECT_FALSE(UdpConnect());
 }

 TEST_F(UdpConnectTest, InitResponseReceiveFailure) {
     mock_socket_->ExpectSend(QueryPacket(0));
     mock_socket_->AddReceive(QueryPacket(0, 0));
     mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
     mock_socket_->AddReceiveFailure();

     EXPECT_FALSE(UdpConnect());
 }

 // Tests that we can recover up to the maximum number of allowed retries.
 TEST_F(UdpConnectTest, ResponseRecovery) {
     // The device query packet can recover from up to (kMaxConnectAttempts - 1) timeouts.
     for (int i = 0; i < kMaxConnectAttempts - 1; ++i) {
         mock_socket_->ExpectSend(QueryPacket(0));
         mock_socket_->AddReceiveTimeout();
     }
     mock_socket_->ExpectSend(QueryPacket(0));
     mock_socket_->AddReceive(QueryPacket(0, 0));

     // Subsequent packets try up to (kMaxTransmissionAttempts - 1) times.
     for (int i = 0; i < kMaxTransmissionAttempts - 1; ++i) {
         mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
         mock_socket_->AddReceiveTimeout();
     }
     mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
     mock_socket_->AddReceive(InitPacket(0, kProtocolVersion, 1024));

     EXPECT_TRUE(UdpConnect());
 }

 // Tests that the host can handle receiving additional bytes for forward compatibility.
 TEST_F(UdpConnectTest, ExtraResponseDataSuccess) {
     mock_socket_->ExpectSend(QueryPacket(0));
     mock_socket_->AddReceive(QueryPacket(0, 0) + "foo");
     mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
     mock_socket_->AddReceive(InitPacket(0, kProtocolVersion, 1024) + "bar");

     EXPECT_TRUE(UdpConnect());
 }

 // Tests mismatched response sequence numbers. A wrong sequence number is interpreted as a previous
 // retransmission and just ignored so we should be able to recover.
 TEST_F(UdpConnectTest, WrongSequenceRecovery) {
     mock_socket_->ExpectSend(QueryPacket(0));
     mock_socket_->AddReceive(QueryPacket(1, 0));
     mock_socket_->AddReceive(QueryPacket(0, 0));

     mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
     mock_socket_->AddReceive(InitPacket(1, kProtocolVersion, 1024));
     mock_socket_->AddReceive(InitPacket(0, kProtocolVersion, 1024));

     EXPECT_TRUE(UdpConnect());
 }

 // Tests mismatched response IDs. This should also be interpreted as a retransmission and ignored.
 TEST_F(UdpConnectTest, WrongIdRecovery) {
     mock_socket_->ExpectSend(QueryPacket(0));
     mock_socket_->AddReceive(FastbootPacket(0));
     mock_socket_->AddReceive(QueryPacket(0, 0));

     mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
     mock_socket_->AddReceive(FastbootPacket(0));
     mock_socket_->AddReceive(InitPacket(0, kProtocolVersion, 1024));

     EXPECT_TRUE(UdpConnect());
 }

 // Tests an invalid query response. Query responses must have at least 2 bytes of data.
 TEST_F(UdpConnectTest, InvalidQueryResponseFailure) {
     std::string error;

     mock_socket_->ExpectSend(QueryPacket(0));
     mock_socket_->AddReceive(QueryPacket(0));

     EXPECT_FALSE(UdpConnect(&error));
     EXPECT_EQ("invalid query response from target", error);

     mock_socket_->ExpectSend(QueryPacket(0));
     mock_socket_->AddReceive(QueryPacket(0) + std::string{0x00});

     EXPECT_FALSE(UdpConnect(&error));
     EXPECT_EQ("invalid query response from target", error);
 }

 // Tests an invalid initialization response. Max packet size must be at least 512 bytes.
 TEST_F(UdpConnectTest, InvalidInitResponseFailure) {
     std::string error;

     mock_socket_->ExpectSend(QueryPacket(0));
     mock_socket_->AddReceive(QueryPacket(0, 0));
     mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
     mock_socket_->AddReceive(InitPacket(0, kProtocolVersion, 511));

     EXPECT_FALSE(UdpConnect(&error));
     EXPECT_EQ("target reported invalid packet size 511", error);

     mock_socket_->ExpectSend(QueryPacket(0));
     mock_socket_->AddReceive(QueryPacket(0, 0));
     mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
     mock_socket_->AddReceive(InitPacket(0, 0, 1024));

     EXPECT_FALSE(UdpConnect(&error));
     EXPECT_EQ("target reported invalid protocol version 0", error);
 }

 TEST_F(UdpConnectTest, ErrorResponseFailure) {
     std::string error;

     mock_socket_->ExpectSend(QueryPacket(0));
     mock_socket_->AddReceive(ErrorPacket(0, "error1"));

     EXPECT_FALSE(UdpConnect(&error));
     EXPECT_NE(std::string::npos, error.find("error1"));

     mock_socket_->ExpectSend(QueryPacket(0));
     mock_socket_->AddReceive(QueryPacket(0, 0));
     mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
     mock_socket_->AddReceive(ErrorPacket(0, "error2"));

     EXPECT_FALSE(UdpConnect(&error));
     EXPECT_NE(std::string::npos, error.find("error2"));
 }

 // Tests an error response with continuation flag.
 TEST_F(UdpConnectTest, ErrorContinuationFailure) {
     std::string error;

     mock_socket_->ExpectSend(QueryPacket(0));
     mock_socket_->AddReceive(ErrorPacket(0, "error1", kFlagContinuation));
     mock_socket_->ExpectSend(ErrorPacket(1));
     mock_socket_->AddReceive(ErrorPacket(1, " ", kFlagContinuation));
     mock_socket_->ExpectSend(ErrorPacket(2));
     mock_socket_->AddReceive(ErrorPacket(2, "error2"));

     EXPECT_FALSE(UdpConnect(&error));
     EXPECT_NE(std::string::npos, error.find("error1 error2"));
 }

 // Fixture class to test UDP Transport read/write functionality.
 class UdpTest : public ::testing::Test {
   public:
     void SetUp() override {
         // Create |transport_| starting at sequence 0 with 512 byte max packet size. Tests can call
         // InitializeTransport() again to change settings.
         ASSERT_TRUE(InitializeTransport(0, 512));
     }

     // Sets up |mock_socket_| to correctly initialize the protocol and creates |transport_|. This
     // can be called multiple times in a test if needed.
     bool InitializeTransport(uint16_t starting_sequence, int device_max_packet_size = 512) {
         mock_socket_ = new SocketMock;
         mock_socket_->ExpectSend(QueryPacket(0));
         mock_socket_->AddReceive(QueryPacket(0, starting_sequence));
         mock_socket_->ExpectSend(
                 InitPacket(starting_sequence, kProtocolVersion, kHostMaxPacketSize));
         mock_socket_->AddReceive(
                 InitPacket(starting_sequence, kProtocolVersion, device_max_packet_size));

         std::string error;
         transport_ = Connect(std::unique_ptr<Socket>(mock_socket_), &error);
         return transport_ != nullptr && error.empty();
     }

     // Writes |message| to |transport_|, returns true on success.
     bool Write(const std::string& message) {
         return transport_->Write(message.data(), message.length()) ==
                 static_cast<ssize_t>(message.length());
     }

     // Reads from |transport_|, returns true if it matches |message|.
     bool Read(const std::string& message) {
         std::string buffer(message.length(), '\0');
         return transport_->Read(&buffer[0], buffer.length()) ==
                 static_cast<ssize_t>(message.length()) && buffer == message;
     }

   protected:
     // |mock_socket_| is a raw pointer here because we transfer ownership to |transport_| but we
     // need to retain a pointer to set send and receive expectations.
     SocketMock* mock_socket_ = nullptr;
     std::unique_ptr<Transport> transport_;
 };

 // Tests sequence behavior with various starting sequence numbers.
 TEST_F(UdpTest, SequenceIncrementCheck) {
     for (uint16_t seq : kTestSequenceNumbers) {
         ASSERT_TRUE(InitializeTransport(seq));

         for (int i = 0; i < 10; ++i) {
             mock_socket_->ExpectSend(FastbootPacket(++seq, "foo"));
             mock_socket_->AddReceive(FastbootPacket(seq, ""));
             mock_socket_->ExpectSend(FastbootPacket(++seq, ""));
             mock_socket_->AddReceive(FastbootPacket(seq, "bar"));

             EXPECT_TRUE(Write("foo"));
             EXPECT_TRUE(Read("bar"));
         }
     }
 }

 // Tests sending and receiving a few small packets.
 TEST_F(UdpTest, ReadAndWriteSmallPackets) {
     mock_socket_->ExpectSend(FastbootPacket(1, "foo"));
     mock_socket_->AddReceive(FastbootPacket(1, ""));
     mock_socket_->ExpectSend(FastbootPacket(2, ""));
     mock_socket_->AddReceive(FastbootPacket(2, "bar"));

     EXPECT_TRUE(Write("foo"));
     EXPECT_TRUE(Read("bar"));

     mock_socket_->ExpectSend(FastbootPacket(3, "12345 67890"));
     mock_socket_->AddReceive(FastbootPacket(3));
     mock_socket_->ExpectSend(FastbootPacket(4, "\x01\x02\x03\x04\x05"));
     mock_socket_->AddReceive(FastbootPacket(4));

     EXPECT_TRUE(Write("12345 67890"));
     EXPECT_TRUE(Write("\x01\x02\x03\x04\x05"));

     // Reads are done by sending empty packets.
     mock_socket_->ExpectSend(FastbootPacket(5));
     mock_socket_->AddReceive(FastbootPacket(5, "foo bar baz"));
     mock_socket_->ExpectSend(FastbootPacket(6));
     mock_socket_->AddReceive(FastbootPacket(6, "\x01\x02\x03\x04\x05"));

     EXPECT_TRUE(Read("foo bar baz"));
     EXPECT_TRUE(Read("\x01\x02\x03\x04\x05"));
 }

 TEST_F(UdpTest, ResponseTimeoutFailure) {
     for (int i = 0; i < kMaxTransmissionAttempts; ++i) {
         mock_socket_->ExpectSend(FastbootPacket(1, "foo"));
         mock_socket_->AddReceiveTimeout();
     }

     EXPECT_FALSE(Write("foo"));
 }

 TEST_F(UdpTest, ResponseReceiveFailure) {
     mock_socket_->ExpectSend(FastbootPacket(1, "foo"));
     mock_socket_->AddReceiveFailure();

     EXPECT_FALSE(Write("foo"));
 }

 TEST_F(UdpTest, ResponseTimeoutRecovery) {
     for (int i = 0; i < kMaxTransmissionAttempts - 1; ++i) {
         mock_socket_->ExpectSend(FastbootPacket(1, "foo"));
         mock_socket_->AddReceiveTimeout();
     }
     mock_socket_->ExpectSend(FastbootPacket(1, "foo"));
     mock_socket_->AddReceive(FastbootPacket(1, ""));

     EXPECT_TRUE(Write("foo"));
 }

 // Tests continuation packets for various max packet sizes.
 // The important part of this test is that regardless of what kind of packet fragmentation happens
 // at the socket layer, a single call to Transport::Read() and Transport::Write() is all the
 // fastboot code needs to do.
 TEST_F(UdpTest, ContinuationPackets) {
     for (uint16_t max_packet_size : {512, 1024, 1200}) {
         ASSERT_TRUE(InitializeTransport(0, max_packet_size));

         // Initialize the data we want to send. Use (size - 4) to leave room for the header.
         size_t max_data_size = max_packet_size - 4;
         std::string data(max_data_size * 3, '\0');
         for (size_t i = 0; i < data.length(); ++i) {
             data[i] = i;
         }
         std::string chunks[] = {data.substr(0, max_data_size),
                                 data.substr(max_data_size, max_data_size),
                                 data.substr(max_data_size * 2, max_data_size)};

         // Write data: split into 3 UDP packets, each of which will be ACKed.
         mock_socket_->ExpectSend(FastbootPacket(1, chunks[0], kFlagContinuation));
         mock_socket_->AddReceive(FastbootPacket(1));
         mock_socket_->ExpectSend(FastbootPacket(2, chunks[1], kFlagContinuation));
         mock_socket_->AddReceive(FastbootPacket(2));
         mock_socket_->ExpectSend(FastbootPacket(3, chunks[2]));
         mock_socket_->AddReceive(FastbootPacket(3));
         EXPECT_TRUE(Write(data));

         // Same thing for reading the data.
         mock_socket_->ExpectSend(FastbootPacket(4));
         mock_socket_->AddReceive(FastbootPacket(4, chunks[0], kFlagContinuation));
         mock_socket_->ExpectSend(FastbootPacket(5));
         mock_socket_->AddReceive(FastbootPacket(5, chunks[1], kFlagContinuation));
         mock_socket_->ExpectSend(FastbootPacket(6));
         mock_socket_->AddReceive(FastbootPacket(6, chunks[2]));
         EXPECT_TRUE(Read(data));
     }
 }

 // Tests that the continuation bit is respected even if the packet isn't max size.
 TEST_F(UdpTest, SmallContinuationPackets) {
     mock_socket_->ExpectSend(FastbootPacket(1));
     mock_socket_->AddReceive(FastbootPacket(1, "foo", kFlagContinuation));
     mock_socket_->ExpectSend(FastbootPacket(2));
     mock_socket_->AddReceive(FastbootPacket(2, "bar"));

     EXPECT_TRUE(Read("foobar"));
 }

 // Tests receiving an error packet mid-continuation.
 TEST_F(UdpTest, ContinuationPacketError) {
     mock_socket_->ExpectSend(FastbootPacket(1));
     mock_socket_->AddReceive(FastbootPacket(1, "foo", kFlagContinuation));
     mock_socket_->ExpectSend(FastbootPacket(2));
     mock_socket_->AddReceive(ErrorPacket(2, "test error"));

     EXPECT_FALSE(Read("foo"));
 }

 // Tests timeout during a continuation sequence.
 TEST_F(UdpTest, ContinuationTimeoutRecovery) {
     mock_socket_->ExpectSend(FastbootPacket(1));
     mock_socket_->AddReceive(FastbootPacket(1, "foo", kFlagContinuation));
     mock_socket_->ExpectSend(FastbootPacket(2));
     mock_socket_->AddReceiveTimeout();
     mock_socket_->ExpectSend(FastbootPacket(2));
     mock_socket_->AddReceive(FastbootPacket(2, "bar"));

     EXPECT_TRUE(Read("foobar"));
 }

 // Tests read overflow returns -1 to indicate the failure.
 TEST_F(UdpTest, MultipleReadPacket) {
     mock_socket_->ExpectSend(FastbootPacket(1));
     mock_socket_->AddReceive(FastbootPacket(1, "foobarbaz"));

     char buffer[3];
     EXPECT_EQ(-1, transport_->Read(buffer, 3));
 }

 // Tests that packets arriving out-of-order are ignored.
 TEST_F(UdpTest, IgnoreOutOfOrderPackets) {
     mock_socket_->ExpectSend(FastbootPacket(1));
     mock_socket_->AddReceive(FastbootPacket(0, "sequence too low"));
     mock_socket_->AddReceive(FastbootPacket(2, "sequence too high"));
     mock_socket_->AddReceive(QueryPacket(1));
     mock_socket_->AddReceive(FastbootPacket(1, "correct"));

     EXPECT_TRUE(Read("correct"));
 }

 // Tests that an error response with the correct sequence number causes immediate failure.
 TEST_F(UdpTest, ErrorResponse) {
     // Error packets with the wrong sequence number should be ignored like any other packet.
     mock_socket_->ExpectSend(FastbootPacket(1, "foo"));
     mock_socket_->AddReceive(ErrorPacket(0, "ignored error"));
     mock_socket_->AddReceive(FastbootPacket(1));

     EXPECT_TRUE(Write("foo"));

     // Error packets with the correct sequence should abort immediately without retransmission.
     mock_socket_->ExpectSend(FastbootPacket(2, "foo"));
     mock_socket_->AddReceive(ErrorPacket(2, "test error"));

     EXPECT_FALSE(Write("foo"));
 }

 // Tests that attempting to use a closed transport returns -1 without making any socket calls.
 TEST_F(UdpTest, CloseTransport) {
     char buffer[32];
     EXPECT_EQ(0, transport_->Close());
     EXPECT_EQ(-1, transport_->Write("foo", 3));
     EXPECT_EQ(-1, transport_->Read(buffer, sizeof(buffer)));
 }
	/*
	* Copyright (C) 2015 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 "udp.h"

	#include <gtest/gtest.h>

	#include "socket.h"
	#include "socket_mock.h"

	using namespace udp;
	using namespace udp::internal;

	// Some possible corner case sequence numbers we want to check.
	static const uint16_t kTestSequenceNumbers[] = {0x0000, 0x0001, 0x00FF, 0x0100,
	0x7FFF, 0x8000, 0xFFFF};

	// Converts \|value\| to a binary big-endian string.
	static std::string PacketValue(uint16_t value) {
	return std::string{static_cast<char>(value >> 8), static_cast<char>(value)};
	}

	// Returns an Error packet.
	static std::string ErrorPacket(uint16_t sequence, const std::string& message = "",
	char flags = kFlagNone) {
	return std::string{kIdError, flags} + PacketValue(sequence) + message;
	}

	// Returns a Query packet with no data.
	static std::string QueryPacket(uint16_t sequence) {
	return std::string{kIdDeviceQuery, kFlagNone} + PacketValue(sequence);
	}

	// Returns a Query packet with a 2-byte \|new_sequence\|.
	static std::string QueryPacket(uint16_t sequence, uint16_t new_sequence) {
	return std::string{kIdDeviceQuery, kFlagNone} + PacketValue(sequence) +
	PacketValue(new_sequence);
	}

	// Returns an Init packet with a 2-byte \|version\| and \|max_packet_size\|.
	static std::string InitPacket(uint16_t sequence, uint16_t version, uint16_t max_packet_size) {
	return std::string{kIdInitialization, kFlagNone} + PacketValue(sequence) +
	PacketValue(version) + PacketValue(max_packet_size);
	}

	// Returns a Fastboot packet with \|data\|.
	static std::string FastbootPacket(uint16_t sequence, const std::string& data = "",
	char flags = kFlagNone) {
	return std::string{kIdFastboot, flags} + PacketValue(sequence) + data;
	}

	// Fixture class to test protocol initialization. Usage is to set up the expected calls to the
	// SocketMock object then call UdpConnect() and check the result.
	class UdpConnectTest : public ::testing::Test {
	public:
	UdpConnectTest() : mock_socket_(new SocketMock) {}

	// Run the initialization, return whether it was successful or not. This passes ownership of
	// the current \|mock_socket_\| but allocates a new one for re-use.
	bool UdpConnect(std::string* error = nullptr) {
	std::string local_error;
	if (error == nullptr) {
	error = &local_error;
	}
	std::unique_ptr<Transport> transport(Connect(std::move(mock_socket_), error));
	mock_socket_.reset(new SocketMock);
	return transport != nullptr && error->empty();
	}

	protected:
	std::unique_ptr<SocketMock> mock_socket_;
	};

	// Tests a successful protocol initialization with various starting sequence numbers.
	TEST_F(UdpConnectTest, InitializationSuccess) {
	for (uint16_t seq : kTestSequenceNumbers) {
	mock_socket_->ExpectSend(QueryPacket(0));
	mock_socket_->AddReceive(QueryPacket(0, seq));
	mock_socket_->ExpectSend(InitPacket(seq, kProtocolVersion, kHostMaxPacketSize));
	mock_socket_->AddReceive(InitPacket(seq, kProtocolVersion, 1024));

	EXPECT_TRUE(UdpConnect());
	}
	}

	// Tests continuation packets during initialization.
	TEST_F(UdpConnectTest, InitializationContinuationSuccess) {
	mock_socket_->ExpectSend(QueryPacket(0));
	mock_socket_->AddReceive(std::string{kIdDeviceQuery, kFlagContinuation, 0, 0, 0x44});
	mock_socket_->ExpectSend(std::string{kIdDeviceQuery, kFlagNone, 0, 1});
	mock_socket_->AddReceive(std::string{kIdDeviceQuery, kFlagNone, 0, 1, 0x55});

	mock_socket_->ExpectSend(InitPacket(0x4455, kProtocolVersion, kHostMaxPacketSize));
	mock_socket_->AddReceive(std::string{kIdInitialization, kFlagContinuation, 0x44, 0x55, 0});
	mock_socket_->ExpectSend(std::string{kIdInitialization, kFlagNone, 0x44, 0x56});
	mock_socket_->AddReceive(std::string{kIdInitialization, kFlagContinuation, 0x44, 0x56, 1});
	mock_socket_->ExpectSend(std::string{kIdInitialization, kFlagNone, 0x44, 0x57});
	mock_socket_->AddReceive(std::string{kIdInitialization, kFlagContinuation, 0x44, 0x57, 2});
	mock_socket_->ExpectSend(std::string{kIdInitialization, kFlagNone, 0x44, 0x58});
	mock_socket_->AddReceive(std::string{kIdInitialization, kFlagNone, 0x44, 0x58, 0});

	EXPECT_TRUE(UdpConnect());
	}


	// Tests a mismatched version number; as long as the minimum of the two versions is supported
	// we should allow the connection.
	TEST_F(UdpConnectTest, InitializationVersionMismatch) {
	mock_socket_->ExpectSend(QueryPacket(0));
	mock_socket_->AddReceive(QueryPacket(0, 0));
	mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
	mock_socket_->AddReceive(InitPacket(0, 2, 1024));

	EXPECT_TRUE(UdpConnect());

	mock_socket_->ExpectSend(QueryPacket(0));
	mock_socket_->AddReceive(QueryPacket(0, 0));
	mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
	mock_socket_->AddReceive(InitPacket(0, 0, 1024));

	EXPECT_FALSE(UdpConnect());
	}

	TEST_F(UdpConnectTest, QueryResponseTimeoutFailure) {
	for (int i = 0; i < kMaxConnectAttempts; ++i) {
	mock_socket_->ExpectSend(QueryPacket(0));
	mock_socket_->AddReceiveTimeout();
	}

	EXPECT_FALSE(UdpConnect());
	}

	TEST_F(UdpConnectTest, QueryResponseReceiveFailure) {
	mock_socket_->ExpectSend(QueryPacket(0));
	mock_socket_->AddReceiveFailure();

	EXPECT_FALSE(UdpConnect());
	}

	TEST_F(UdpConnectTest, InitResponseTimeoutFailure) {
	mock_socket_->ExpectSend(QueryPacket(0));
	mock_socket_->AddReceive(QueryPacket(0, 0));
	for (int i = 0; i < kMaxTransmissionAttempts; ++i) {
	mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
	mock_socket_->AddReceiveTimeout();
	}

	EXPECT_FALSE(UdpConnect());
	}

	TEST_F(UdpConnectTest, InitResponseReceiveFailure) {
	mock_socket_->ExpectSend(QueryPacket(0));
	mock_socket_->AddReceive(QueryPacket(0, 0));
	mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
	mock_socket_->AddReceiveFailure();

	EXPECT_FALSE(UdpConnect());
	}

	// Tests that we can recover up to the maximum number of allowed retries.
	TEST_F(UdpConnectTest, ResponseRecovery) {
	// The device query packet can recover from up to (kMaxConnectAttempts - 1) timeouts.
	for (int i = 0; i < kMaxConnectAttempts - 1; ++i) {
	mock_socket_->ExpectSend(QueryPacket(0));
	mock_socket_->AddReceiveTimeout();
	}
	mock_socket_->ExpectSend(QueryPacket(0));
	mock_socket_->AddReceive(QueryPacket(0, 0));

	// Subsequent packets try up to (kMaxTransmissionAttempts - 1) times.
	for (int i = 0; i < kMaxTransmissionAttempts - 1; ++i) {
	mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
	mock_socket_->AddReceiveTimeout();
	}
	mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
	mock_socket_->AddReceive(InitPacket(0, kProtocolVersion, 1024));

	EXPECT_TRUE(UdpConnect());
	}

	// Tests that the host can handle receiving additional bytes for forward compatibility.
	TEST_F(UdpConnectTest, ExtraResponseDataSuccess) {
	mock_socket_->ExpectSend(QueryPacket(0));
	mock_socket_->AddReceive(QueryPacket(0, 0) + "foo");
	mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
	mock_socket_->AddReceive(InitPacket(0, kProtocolVersion, 1024) + "bar");

	EXPECT_TRUE(UdpConnect());
	}

	// Tests mismatched response sequence numbers. A wrong sequence number is interpreted as a previous
	// retransmission and just ignored so we should be able to recover.
	TEST_F(UdpConnectTest, WrongSequenceRecovery) {
	mock_socket_->ExpectSend(QueryPacket(0));
	mock_socket_->AddReceive(QueryPacket(1, 0));
	mock_socket_->AddReceive(QueryPacket(0, 0));

	mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
	mock_socket_->AddReceive(InitPacket(1, kProtocolVersion, 1024));
	mock_socket_->AddReceive(InitPacket(0, kProtocolVersion, 1024));

	EXPECT_TRUE(UdpConnect());
	}

	// Tests mismatched response IDs. This should also be interpreted as a retransmission and ignored.
	TEST_F(UdpConnectTest, WrongIdRecovery) {
	mock_socket_->ExpectSend(QueryPacket(0));
	mock_socket_->AddReceive(FastbootPacket(0));
	mock_socket_->AddReceive(QueryPacket(0, 0));

	mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
	mock_socket_->AddReceive(FastbootPacket(0));
	mock_socket_->AddReceive(InitPacket(0, kProtocolVersion, 1024));

	EXPECT_TRUE(UdpConnect());
	}

	// Tests an invalid query response. Query responses must have at least 2 bytes of data.
	TEST_F(UdpConnectTest, InvalidQueryResponseFailure) {
	std::string error;

	mock_socket_->ExpectSend(QueryPacket(0));
	mock_socket_->AddReceive(QueryPacket(0));

	EXPECT_FALSE(UdpConnect(&error));
	EXPECT_EQ("invalid query response from target", error);

	mock_socket_->ExpectSend(QueryPacket(0));
	mock_socket_->AddReceive(QueryPacket(0) + std::string{0x00});

	EXPECT_FALSE(UdpConnect(&error));
	EXPECT_EQ("invalid query response from target", error);
	}

	// Tests an invalid initialization response. Max packet size must be at least 512 bytes.
	TEST_F(UdpConnectTest, InvalidInitResponseFailure) {
	std::string error;

	mock_socket_->ExpectSend(QueryPacket(0));
	mock_socket_->AddReceive(QueryPacket(0, 0));
	mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
	mock_socket_->AddReceive(InitPacket(0, kProtocolVersion, 511));

	EXPECT_FALSE(UdpConnect(&error));
	EXPECT_EQ("target reported invalid packet size 511", error);

	mock_socket_->ExpectSend(QueryPacket(0));
	mock_socket_->AddReceive(QueryPacket(0, 0));
	mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
	mock_socket_->AddReceive(InitPacket(0, 0, 1024));

	EXPECT_FALSE(UdpConnect(&error));
	EXPECT_EQ("target reported invalid protocol version 0", error);
	}

	TEST_F(UdpConnectTest, ErrorResponseFailure) {
	std::string error;

	mock_socket_->ExpectSend(QueryPacket(0));
	mock_socket_->AddReceive(ErrorPacket(0, "error1"));

	EXPECT_FALSE(UdpConnect(&error));
	EXPECT_NE(std::string::npos, error.find("error1"));

	mock_socket_->ExpectSend(QueryPacket(0));
	mock_socket_->AddReceive(QueryPacket(0, 0));
	mock_socket_->ExpectSend(InitPacket(0, kProtocolVersion, kHostMaxPacketSize));
	mock_socket_->AddReceive(ErrorPacket(0, "error2"));

	EXPECT_FALSE(UdpConnect(&error));
	EXPECT_NE(std::string::npos, error.find("error2"));
	}

	// Tests an error response with continuation flag.
	TEST_F(UdpConnectTest, ErrorContinuationFailure) {
	std::string error;

	mock_socket_->ExpectSend(QueryPacket(0));
	mock_socket_->AddReceive(ErrorPacket(0, "error1", kFlagContinuation));
	mock_socket_->ExpectSend(ErrorPacket(1));
	mock_socket_->AddReceive(ErrorPacket(1, " ", kFlagContinuation));
	mock_socket_->ExpectSend(ErrorPacket(2));
	mock_socket_->AddReceive(ErrorPacket(2, "error2"));

	EXPECT_FALSE(UdpConnect(&error));
	EXPECT_NE(std::string::npos, error.find("error1 error2"));
	}

	// Fixture class to test UDP Transport read/write functionality.
	class UdpTest : public ::testing::Test {
	public:
	void SetUp() override {
	// Create \|transport_\| starting at sequence 0 with 512 byte max packet size. Tests can call
	// InitializeTransport() again to change settings.
	ASSERT_TRUE(InitializeTransport(0, 512));
	}

	// Sets up \|mock_socket_\| to correctly initialize the protocol and creates \|transport_\|. This
	// can be called multiple times in a test if needed.
	bool InitializeTransport(uint16_t starting_sequence, int device_max_packet_size = 512) {
	mock_socket_ = new SocketMock;
	mock_socket_->ExpectSend(QueryPacket(0));
	mock_socket_->AddReceive(QueryPacket(0, starting_sequence));
	mock_socket_->ExpectSend(
	InitPacket(starting_sequence, kProtocolVersion, kHostMaxPacketSize));
	mock_socket_->AddReceive(
	InitPacket(starting_sequence, kProtocolVersion, device_max_packet_size));

	std::string error;
	transport_ = Connect(std::unique_ptr<Socket>(mock_socket_), &error);
	return transport_ != nullptr && error.empty();
	}

	// Writes \|message\| to \|transport_\|, returns true on success.
	bool Write(const std::string& message) {
	return transport_->Write(message.data(), message.length()) ==
	static_cast<ssize_t>(message.length());
	}

	// Reads from \|transport_\|, returns true if it matches \|message\|.
	bool Read(const std::string& message) {
	std::string buffer(message.length(), '\0');
	return transport_->Read(&buffer[0], buffer.length()) ==
	static_cast<ssize_t>(message.length()) && buffer == message;
	}

	protected:
	// \|mock_socket_\| is a raw pointer here because we transfer ownership to \|transport_\| but we
	// need to retain a pointer to set send and receive expectations.
	SocketMock* mock_socket_ = nullptr;
	std::unique_ptr<Transport> transport_;
	};

	// Tests sequence behavior with various starting sequence numbers.
	TEST_F(UdpTest, SequenceIncrementCheck) {
	for (uint16_t seq : kTestSequenceNumbers) {
	ASSERT_TRUE(InitializeTransport(seq));

	for (int i = 0; i < 10; ++i) {
	mock_socket_->ExpectSend(FastbootPacket(++seq, "foo"));
	mock_socket_->AddReceive(FastbootPacket(seq, ""));
	mock_socket_->ExpectSend(FastbootPacket(++seq, ""));
	mock_socket_->AddReceive(FastbootPacket(seq, "bar"));

	EXPECT_TRUE(Write("foo"));
	EXPECT_TRUE(Read("bar"));
	}
	}
	}

	// Tests sending and receiving a few small packets.
	TEST_F(UdpTest, ReadAndWriteSmallPackets) {
	mock_socket_->ExpectSend(FastbootPacket(1, "foo"));
	mock_socket_->AddReceive(FastbootPacket(1, ""));
	mock_socket_->ExpectSend(FastbootPacket(2, ""));
	mock_socket_->AddReceive(FastbootPacket(2, "bar"));

	EXPECT_TRUE(Write("foo"));
	EXPECT_TRUE(Read("bar"));

	mock_socket_->ExpectSend(FastbootPacket(3, "12345 67890"));
	mock_socket_->AddReceive(FastbootPacket(3));
	mock_socket_->ExpectSend(FastbootPacket(4, "\x01\x02\x03\x04\x05"));
	mock_socket_->AddReceive(FastbootPacket(4));

	EXPECT_TRUE(Write("12345 67890"));
	EXPECT_TRUE(Write("\x01\x02\x03\x04\x05"));

	// Reads are done by sending empty packets.
	mock_socket_->ExpectSend(FastbootPacket(5));
	mock_socket_->AddReceive(FastbootPacket(5, "foo bar baz"));
	mock_socket_->ExpectSend(FastbootPacket(6));
	mock_socket_->AddReceive(FastbootPacket(6, "\x01\x02\x03\x04\x05"));

	EXPECT_TRUE(Read("foo bar baz"));
	EXPECT_TRUE(Read("\x01\x02\x03\x04\x05"));
	}

	TEST_F(UdpTest, ResponseTimeoutFailure) {
	for (int i = 0; i < kMaxTransmissionAttempts; ++i) {
	mock_socket_->ExpectSend(FastbootPacket(1, "foo"));
	mock_socket_->AddReceiveTimeout();
	}

	EXPECT_FALSE(Write("foo"));
	}

	TEST_F(UdpTest, ResponseReceiveFailure) {
	mock_socket_->ExpectSend(FastbootPacket(1, "foo"));
	mock_socket_->AddReceiveFailure();

	EXPECT_FALSE(Write("foo"));
	}

	TEST_F(UdpTest, ResponseTimeoutRecovery) {
	for (int i = 0; i < kMaxTransmissionAttempts - 1; ++i) {
	mock_socket_->ExpectSend(FastbootPacket(1, "foo"));
	mock_socket_->AddReceiveTimeout();
	}
	mock_socket_->ExpectSend(FastbootPacket(1, "foo"));
	mock_socket_->AddReceive(FastbootPacket(1, ""));

	EXPECT_TRUE(Write("foo"));
	}

	// Tests continuation packets for various max packet sizes.
	// The important part of this test is that regardless of what kind of packet fragmentation happens
	// at the socket layer, a single call to Transport::Read() and Transport::Write() is all the
	// fastboot code needs to do.
	TEST_F(UdpTest, ContinuationPackets) {
	for (uint16_t max_packet_size : {512, 1024, 1200}) {
	ASSERT_TRUE(InitializeTransport(0, max_packet_size));

	// Initialize the data we want to send. Use (size - 4) to leave room for the header.
	size_t max_data_size = max_packet_size - 4;
	std::string data(max_data_size * 3, '\0');
	for (size_t i = 0; i < data.length(); ++i) {
	data[i] = i;
	}
	std::string chunks[] = {data.substr(0, max_data_size),
	data.substr(max_data_size, max_data_size),
	data.substr(max_data_size * 2, max_data_size)};

	// Write data: split into 3 UDP packets, each of which will be ACKed.
	mock_socket_->ExpectSend(FastbootPacket(1, chunks[0], kFlagContinuation));
	mock_socket_->AddReceive(FastbootPacket(1));
	mock_socket_->ExpectSend(FastbootPacket(2, chunks[1], kFlagContinuation));
	mock_socket_->AddReceive(FastbootPacket(2));
	mock_socket_->ExpectSend(FastbootPacket(3, chunks[2]));
	mock_socket_->AddReceive(FastbootPacket(3));
	EXPECT_TRUE(Write(data));

	// Same thing for reading the data.
	mock_socket_->ExpectSend(FastbootPacket(4));
	mock_socket_->AddReceive(FastbootPacket(4, chunks[0], kFlagContinuation));
	mock_socket_->ExpectSend(FastbootPacket(5));
	mock_socket_->AddReceive(FastbootPacket(5, chunks[1], kFlagContinuation));
	mock_socket_->ExpectSend(FastbootPacket(6));
	mock_socket_->AddReceive(FastbootPacket(6, chunks[2]));
	EXPECT_TRUE(Read(data));
	}
	}

	// Tests that the continuation bit is respected even if the packet isn't max size.
	TEST_F(UdpTest, SmallContinuationPackets) {
	mock_socket_->ExpectSend(FastbootPacket(1));
	mock_socket_->AddReceive(FastbootPacket(1, "foo", kFlagContinuation));
	mock_socket_->ExpectSend(FastbootPacket(2));
	mock_socket_->AddReceive(FastbootPacket(2, "bar"));

	EXPECT_TRUE(Read("foobar"));
	}

	// Tests receiving an error packet mid-continuation.
	TEST_F(UdpTest, ContinuationPacketError) {
	mock_socket_->ExpectSend(FastbootPacket(1));
	mock_socket_->AddReceive(FastbootPacket(1, "foo", kFlagContinuation));
	mock_socket_->ExpectSend(FastbootPacket(2));
	mock_socket_->AddReceive(ErrorPacket(2, "test error"));

	EXPECT_FALSE(Read("foo"));
	}

	// Tests timeout during a continuation sequence.
	TEST_F(UdpTest, ContinuationTimeoutRecovery) {
	mock_socket_->ExpectSend(FastbootPacket(1));
	mock_socket_->AddReceive(FastbootPacket(1, "foo", kFlagContinuation));
	mock_socket_->ExpectSend(FastbootPacket(2));
	mock_socket_->AddReceiveTimeout();
	mock_socket_->ExpectSend(FastbootPacket(2));
	mock_socket_->AddReceive(FastbootPacket(2, "bar"));

	EXPECT_TRUE(Read("foobar"));
	}

	// Tests read overflow returns -1 to indicate the failure.
	TEST_F(UdpTest, MultipleReadPacket) {
	mock_socket_->ExpectSend(FastbootPacket(1));
	mock_socket_->AddReceive(FastbootPacket(1, "foobarbaz"));

	char buffer[3];
	EXPECT_EQ(-1, transport_->Read(buffer, 3));
	}

	// Tests that packets arriving out-of-order are ignored.
	TEST_F(UdpTest, IgnoreOutOfOrderPackets) {
	mock_socket_->ExpectSend(FastbootPacket(1));
	mock_socket_->AddReceive(FastbootPacket(0, "sequence too low"));
	mock_socket_->AddReceive(FastbootPacket(2, "sequence too high"));
	mock_socket_->AddReceive(QueryPacket(1));
	mock_socket_->AddReceive(FastbootPacket(1, "correct"));

	EXPECT_TRUE(Read("correct"));
	}

	// Tests that an error response with the correct sequence number causes immediate failure.
	TEST_F(UdpTest, ErrorResponse) {
	// Error packets with the wrong sequence number should be ignored like any other packet.
	mock_socket_->ExpectSend(FastbootPacket(1, "foo"));
	mock_socket_->AddReceive(ErrorPacket(0, "ignored error"));
	mock_socket_->AddReceive(FastbootPacket(1));

	EXPECT_TRUE(Write("foo"));

	// Error packets with the correct sequence should abort immediately without retransmission.
	mock_socket_->ExpectSend(FastbootPacket(2, "foo"));
	mock_socket_->AddReceive(ErrorPacket(2, "test error"));

	EXPECT_FALSE(Write("foo"));
	}

	// Tests that attempting to use a closed transport returns -1 without making any socket calls.
	TEST_F(UdpTest, CloseTransport) {
	char buffer[32];
	EXPECT_EQ(0, transport_->Close());
	EXPECT_EQ(-1, transport_->Write("foo", 3));
	EXPECT_EQ(-1, transport_->Read(buffer, sizeof(buffer)));
	}