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chromium / chromium / src / 0046768337a62af8352abe1196be5c4c9fd23a7c / . / net / socket / udp_socket_unittest.cc
blob: 1208b19b54ccff2648c69bf5612956e81eb036a0 [file] [log] [blame]
// Copyright (c) 2012 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "net/socket/udp_socket.h"
#include <algorithm>
#include "base/bind.h"
#include "base/containers/circular_deque.h"
#include "base/location.h"
#include "base/macros.h"
#include "base/memory/weak_ptr.h"
#include "base/run_loop.h"
#include "base/scoped_clear_last_error.h"
#include "base/single_thread_task_runner.h"
#include "base/threading/thread_task_runner_handle.h"
#include "build/build_config.h"
#include "net/base/io_buffer.h"
#include "net/base/ip_address.h"
#include "net/base/ip_endpoint.h"
#include "net/base/net_errors.h"
#include "net/base/network_interfaces.h"
#include "net/base/test_completion_callback.h"
#include "net/log/net_log_event_type.h"
#include "net/log/net_log_source.h"
#include "net/log/test_net_log.h"
#include "net/log/test_net_log_entry.h"
#include "net/log/test_net_log_util.h"
#include "net/socket/socket_test_util.h"
#include "net/socket/udp_client_socket.h"
#include "net/socket/udp_server_socket.h"
#include "net/test/gtest_util.h"
#include "net/test/test_with_scoped_task_environment.h"
#include "net/traffic_annotation/network_traffic_annotation_test_helper.h"
#include "testing/gmock/include/gmock/gmock.h"
#include "testing/gtest/include/gtest/gtest.h"
#include "testing/platform_test.h"
#if defined(OS_ANDROID)
#include "base/android/build_info.h"
#include "net/android/network_change_notifier_factory_android.h"
#include "net/base/network_change_notifier.h"
#endif
#if defined(OS_IOS)
#include <TargetConditionals.h>
#endif
using net::test::IsError;
using net::test::IsOk;
using testing::Not;
namespace net {
namespace {
// Creates an address from ip address and port and writes it to |*address|.
bool CreateUDPAddress(const std::string& ip_str,
uint16_t port,
IPEndPoint* address) {
IPAddress ip_address;
if (!ip_address.AssignFromIPLiteral(ip_str))
return false;
*address = IPEndPoint(ip_address, port);
return true;
}
class UDPSocketTest : public PlatformTest, public WithScopedTaskEnvironment {
public:
UDPSocketTest() : buffer_(base::MakeRefCounted<IOBufferWithSize>(kMaxRead)) {}
// Blocks until data is read from the socket.
std::string RecvFromSocket(UDPServerSocket* socket) {
TestCompletionCallback callback;
int rv = socket->RecvFrom(buffer_.get(), kMaxRead, &recv_from_address_,
callback.callback());
rv = callback.GetResult(rv);
if (rv < 0)
return std::string();
return std::string(buffer_->data(), rv);
}
// Sends UDP packet.
// If |address| is specified, then it is used for the destination
// to send to. Otherwise, will send to the last socket this server
// received from.
int SendToSocket(UDPServerSocket* socket, const std::string& msg) {
return SendToSocket(socket, msg, recv_from_address_);
}
int SendToSocket(UDPServerSocket* socket,
std::string msg,
const IPEndPoint& address) {
scoped_refptr<StringIOBuffer> io_buffer =
base::MakeRefCounted<StringIOBuffer>(msg);
TestCompletionCallback callback;
int rv = socket->SendTo(io_buffer.get(), io_buffer->size(), address,
callback.callback());
return callback.GetResult(rv);
}
std::string ReadSocket(UDPClientSocket* socket) {
TestCompletionCallback callback;
int rv = socket->Read(buffer_.get(), kMaxRead, callback.callback());
rv = callback.GetResult(rv);
if (rv < 0)
return std::string();
return std::string(buffer_->data(), rv);
}
// Writes specified message to the socket.
int WriteSocket(UDPClientSocket* socket, const std::string& msg) {
scoped_refptr<StringIOBuffer> io_buffer =
base::MakeRefCounted<StringIOBuffer>(msg);
TestCompletionCallback callback;
int rv = socket->Write(io_buffer.get(), io_buffer->size(),
callback.callback(), TRAFFIC_ANNOTATION_FOR_TESTS);
return callback.GetResult(rv);
}
void WriteSocketIgnoreResult(UDPClientSocket* socket,
const std::string& msg) {
WriteSocket(socket, msg);
}
// And again for a bare socket
int SendToSocket(UDPSocket* socket,
std::string msg,
const IPEndPoint& address) {
scoped_refptr<StringIOBuffer> io_buffer = new StringIOBuffer(msg);
TestCompletionCallback callback;
int rv = socket->SendTo(io_buffer.get(), io_buffer->size(), address,
callback.callback());
return callback.GetResult(rv);
}
// Run unit test for a connection test.
// |use_nonblocking_io| is used to switch between overlapped and non-blocking
// IO on Windows. It has no effect in other ports.
void ConnectTest(bool use_nonblocking_io);
protected:
static const int kMaxRead = 1024;
scoped_refptr<IOBufferWithSize> buffer_;
IPEndPoint recv_from_address_;
};
const int UDPSocketTest::kMaxRead;
void ReadCompleteCallback(int* result_out, base::Closure callback, int result) {
*result_out = result;
callback.Run();
}
void UDPSocketTest::ConnectTest(bool use_nonblocking_io) {
const uint16_t kPort = 9999;
std::string simple_message("hello world!");
// Setup the server to listen.
IPEndPoint server_address(IPAddress::IPv4Localhost(), kPort);
TestNetLog server_log;
std::unique_ptr<UDPServerSocket> server(
new UDPServerSocket(&server_log, NetLogSource()));
if (use_nonblocking_io)
server->UseNonBlockingIO();
server->AllowAddressReuse();
int rv = server->Listen(server_address);
ASSERT_THAT(rv, IsOk());
// Setup the client.
TestNetLog client_log;
auto client = std::make_unique<UDPClientSocket>(DatagramSocket::DEFAULT_BIND,
&client_log, NetLogSource());
if (use_nonblocking_io)
client->UseNonBlockingIO();
rv = client->Connect(server_address);
EXPECT_THAT(rv, IsOk());
// Client sends to the server.
rv = WriteSocket(client.get(), simple_message);
EXPECT_EQ(simple_message.length(), static_cast<size_t>(rv));
// Server waits for message.
std::string str = RecvFromSocket(server.get());
EXPECT_EQ(simple_message, str);
// Server echoes reply.
rv = SendToSocket(server.get(), simple_message);
EXPECT_EQ(simple_message.length(), static_cast<size_t>(rv));
// Client waits for response.
str = ReadSocket(client.get());
EXPECT_EQ(simple_message, str);
// Test asynchronous read. Server waits for message.
base::RunLoop run_loop;
int read_result = 0;
rv = server->RecvFrom(
buffer_.get(), kMaxRead, &recv_from_address_,
base::Bind(&ReadCompleteCallback, &read_result, run_loop.QuitClosure()));
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
// Client sends to the server.
base::ThreadTaskRunnerHandle::Get()->PostTask(
FROM_HERE,
base::Bind(&UDPSocketTest::WriteSocketIgnoreResult,
base::Unretained(this), client.get(), simple_message));
run_loop.Run();
EXPECT_EQ(simple_message.length(), static_cast<size_t>(read_result));
EXPECT_EQ(simple_message, std::string(buffer_->data(), read_result));
// Delete sockets so they log their final events.
server.reset();
client.reset();
// Check the server's log.
TestNetLogEntry::List server_entries;
server_log.GetEntries(&server_entries);
EXPECT_EQ(5u, server_entries.size());
EXPECT_TRUE(
LogContainsBeginEvent(server_entries, 0, NetLogEventType::SOCKET_ALIVE));
EXPECT_TRUE(LogContainsEvent(server_entries, 1,
NetLogEventType::UDP_BYTES_RECEIVED,
NetLogEventPhase::NONE));
EXPECT_TRUE(LogContainsEvent(server_entries, 2,
NetLogEventType::UDP_BYTES_SENT,
NetLogEventPhase::NONE));
EXPECT_TRUE(LogContainsEvent(server_entries, 3,
NetLogEventType::UDP_BYTES_RECEIVED,
NetLogEventPhase::NONE));
EXPECT_TRUE(
LogContainsEndEvent(server_entries, 4, NetLogEventType::SOCKET_ALIVE));
// Check the client's log.
TestNetLogEntry::List client_entries;
client_log.GetEntries(&client_entries);
EXPECT_EQ(7u, client_entries.size());
EXPECT_TRUE(
LogContainsBeginEvent(client_entries, 0, NetLogEventType::SOCKET_ALIVE));
EXPECT_TRUE(
LogContainsBeginEvent(client_entries, 1, NetLogEventType::UDP_CONNECT));
EXPECT_TRUE(
LogContainsEndEvent(client_entries, 2, NetLogEventType::UDP_CONNECT));
EXPECT_TRUE(LogContainsEvent(client_entries, 3,
NetLogEventType::UDP_BYTES_SENT,
NetLogEventPhase::NONE));
EXPECT_TRUE(LogContainsEvent(client_entries, 4,
NetLogEventType::UDP_BYTES_RECEIVED,
NetLogEventPhase::NONE));
EXPECT_TRUE(LogContainsEvent(client_entries, 5,
NetLogEventType::UDP_BYTES_SENT,
NetLogEventPhase::NONE));
EXPECT_TRUE(
LogContainsEndEvent(client_entries, 6, NetLogEventType::SOCKET_ALIVE));
}
TEST_F(UDPSocketTest, Connect) {
// The variable |use_nonblocking_io| has no effect in non-Windows ports.
ConnectTest(false);
}
#if defined(OS_WIN)
TEST_F(UDPSocketTest, ConnectNonBlocking) {
ConnectTest(true);
}
#endif
TEST_F(UDPSocketTest, PartialRecv) {
UDPServerSocket server_socket(nullptr, NetLogSource());
ASSERT_THAT(server_socket.Listen(IPEndPoint(IPAddress::IPv4Localhost(), 0)),
IsOk());
IPEndPoint server_address;
ASSERT_THAT(server_socket.GetLocalAddress(&server_address), IsOk());
UDPClientSocket client_socket(DatagramSocket::DEFAULT_BIND, nullptr,
NetLogSource());
ASSERT_THAT(client_socket.Connect(server_address), IsOk());
std::string test_packet("hello world!");
ASSERT_EQ(static_cast<int>(test_packet.size()),
WriteSocket(&client_socket, test_packet));
TestCompletionCallback recv_callback;
// Read just 2 bytes. Read() is expected to return the first 2 bytes from the
// packet and discard the rest.
const int kPartialReadSize = 2;
scoped_refptr<IOBuffer> buffer =
base::MakeRefCounted<IOBuffer>(kPartialReadSize);
int rv =
server_socket.RecvFrom(buffer.get(), kPartialReadSize,
&recv_from_address_, recv_callback.callback());
rv = recv_callback.GetResult(rv);
EXPECT_EQ(rv, ERR_MSG_TOO_BIG);
// Send a different message again.
std::string second_packet("Second packet");
ASSERT_EQ(static_cast<int>(second_packet.size()),
WriteSocket(&client_socket, second_packet));
// Read whole packet now.
std::string received = RecvFromSocket(&server_socket);
EXPECT_EQ(second_packet, received);
}
#if defined(OS_MACOSX) || defined(OS_ANDROID) || defined(OS_FUCHSIA)
// - MacOS: requires root permissions on OSX 10.7+.
// - Android: devices attached to testbots don't have default network, so
// broadcasting to 255.255.255.255 returns error -109 (Address not reachable).
// crbug.com/139144.
// - Fuchsia: TODO(fuchsia): broadcast support is not implemented yet.
#define MAYBE_LocalBroadcast DISABLED_LocalBroadcast
#else
#define MAYBE_LocalBroadcast LocalBroadcast
#endif
TEST_F(UDPSocketTest, MAYBE_LocalBroadcast) {
const uint16_t kPort = 9999;
std::string first_message("first message"), second_message("second message");
IPEndPoint broadcast_address;
ASSERT_TRUE(CreateUDPAddress("127.255.255.255", kPort, &broadcast_address));
IPEndPoint listen_address;
ASSERT_TRUE(CreateUDPAddress("0.0.0.0", kPort, &listen_address));
TestNetLog server1_log, server2_log;
std::unique_ptr<UDPServerSocket> server1(
new UDPServerSocket(&server1_log, NetLogSource()));
std::unique_ptr<UDPServerSocket> server2(
new UDPServerSocket(&server2_log, NetLogSource()));
server1->AllowAddressReuse();
server1->AllowBroadcast();
server2->AllowAddressReuse();
server2->AllowBroadcast();
int rv = server1->Listen(listen_address);
EXPECT_THAT(rv, IsOk());
rv = server2->Listen(listen_address);
EXPECT_THAT(rv, IsOk());
rv = SendToSocket(server1.get(), first_message, broadcast_address);
ASSERT_EQ(static_cast<int>(first_message.size()), rv);
std::string str = RecvFromSocket(server1.get());
ASSERT_EQ(first_message, str);
str = RecvFromSocket(server2.get());
ASSERT_EQ(first_message, str);
rv = SendToSocket(server2.get(), second_message, broadcast_address);
ASSERT_EQ(static_cast<int>(second_message.size()), rv);
str = RecvFromSocket(server1.get());
ASSERT_EQ(second_message, str);
str = RecvFromSocket(server2.get());
ASSERT_EQ(second_message, str);
}
// ConnectRandomBind verifies RANDOM_BIND is handled correctly. It connects
// 1000 sockets and then verifies that the allocated port numbers satisfy the
// following 2 conditions:
// 1. Range from min port value to max is greater than 10000.
// 2. There is at least one port in the 5 buckets in the [min, max] range.
//
// These conditions are not enough to verify that the port numbers are truly
// random, but they are enough to protect from most common non-random port
// allocation strategies (e.g. counter, pool of available ports, etc.) False
// positive result is theoretically possible, but its probability is negligible.
TEST_F(UDPSocketTest, ConnectRandomBind) {
const int kIterations = 1000;
std::vector<int> used_ports;
for (int i = 0; i < kIterations; ++i) {
UDPClientSocket socket(DatagramSocket::RANDOM_BIND, nullptr,
NetLogSource());
EXPECT_THAT(socket.Connect(IPEndPoint(IPAddress::IPv4Localhost(), 53)),
IsOk());
IPEndPoint client_address;
EXPECT_THAT(socket.GetLocalAddress(&client_address), IsOk());
used_ports.push_back(client_address.port());
}
int min_port = *std::min_element(used_ports.begin(), used_ports.end());
int max_port = *std::max_element(used_ports.begin(), used_ports.end());
int range = max_port - min_port + 1;
// Verify that the range of ports used by the random port allocator is wider
// than 10k. Assuming that socket implementation limits port range to 16k
// ports (default on Fuchsia) probability of false negative is below
// 10^-200.
static int kMinRange = 10000;
EXPECT_GT(range, kMinRange);
static int kBuckets = 5;
std::vector<int> bucket_sizes(kBuckets, 0);
for (int port : used_ports) {
bucket_sizes[(port - min_port) * kBuckets / range] += 1;
}
// Verify that there is at least one value in each bucket. Probability of
// false negative is below (kBuckets * (1 - 1 / kBuckets) ^ kIterations),
// which is less than 10^-96.
for (int size : bucket_sizes) {
EXPECT_GT(size, 0);
}
}
#if defined(OS_FUCHSIA)
// Currently the test fails on Fuchsia because netstack allows to connect IPv4
// socket to IPv6 address. This issue is tracked by NET-596.
#define MAYBE_ConnectFail DISABLED_ConnectFail
#else
#define MAYBE_ConnectFail ConnectFail
#endif
TEST_F(UDPSocketTest, MAYBE_ConnectFail) {
UDPSocket socket(DatagramSocket::DEFAULT_BIND, nullptr, NetLogSource());
EXPECT_THAT(socket.Open(ADDRESS_FAMILY_IPV4), IsOk());
// Connect to an IPv6 address should fail since the socket was created for
// IPv4.
EXPECT_THAT(socket.Connect(net::IPEndPoint(IPAddress::IPv6Localhost(), 53)),
Not(IsOk()));
// Make sure that UDPSocket actually closed the socket.
EXPECT_FALSE(socket.is_connected());
}
// In this test, we verify that connect() on a socket will have the effect
// of filtering reads on this socket only to data read from the destination
// we connected to.
//
// The purpose of this test is that some documentation indicates that connect
// binds the client's sends to send to a particular server endpoint, but does
// not bind the client's reads to only be from that endpoint, and that we need
// to always use recvfrom() to disambiguate.
TEST_F(UDPSocketTest, VerifyConnectBindsAddr) {
const uint16_t kPort1 = 9999;
const uint16_t kPort2 = 10000;
std::string simple_message("hello world!");
std::string foreign_message("BAD MESSAGE TO GET!!");
// Setup the first server to listen.
IPEndPoint server1_address(IPAddress::IPv4Localhost(), kPort1);
UDPServerSocket server1(nullptr, NetLogSource());
server1.AllowAddressReuse();
int rv = server1.Listen(server1_address);
ASSERT_THAT(rv, IsOk());
// Setup the second server to listen.
IPEndPoint server2_address(IPAddress::IPv4Localhost(), kPort2);
UDPServerSocket server2(nullptr, NetLogSource());
server2.AllowAddressReuse();
rv = server2.Listen(server2_address);
ASSERT_THAT(rv, IsOk());
// Setup the client, connected to server 1.
UDPClientSocket client(DatagramSocket::DEFAULT_BIND, nullptr, NetLogSource());
rv = client.Connect(server1_address);
EXPECT_THAT(rv, IsOk());
// Client sends to server1.
rv = WriteSocket(&client, simple_message);
EXPECT_EQ(simple_message.length(), static_cast<size_t>(rv));
// Server1 waits for message.
std::string str = RecvFromSocket(&server1);
EXPECT_EQ(simple_message, str);
// Get the client's address.
IPEndPoint client_address;
rv = client.GetLocalAddress(&client_address);
EXPECT_THAT(rv, IsOk());
// Server2 sends reply.
rv = SendToSocket(&server2, foreign_message, client_address);
EXPECT_EQ(foreign_message.length(), static_cast<size_t>(rv));
// Server1 sends reply.
rv = SendToSocket(&server1, simple_message, client_address);
EXPECT_EQ(simple_message.length(), static_cast<size_t>(rv));
// Client waits for response.
str = ReadSocket(&client);
EXPECT_EQ(simple_message, str);
}
TEST_F(UDPSocketTest, ClientGetLocalPeerAddresses) {
struct TestData {
std::string remote_address;
std::string local_address;
bool may_fail;
} tests[] = {
{"127.0.00.1", "127.0.0.1", false},
{"::1", "::1", true},
#if !defined(OS_ANDROID) && !defined(OS_IOS)
// Addresses below are disabled on Android. See crbug.com/161248
// They are also disabled on iOS. See https://crbug.com/523225
{"192.168.1.1", "127.0.0.1", false},
{"2001:db8:0::42", "::1", true},
#endif
};
for (size_t i = 0; i < arraysize(tests); i++) {
SCOPED_TRACE(std::string("Connecting from ") + tests[i].local_address +
std::string(" to ") + tests[i].remote_address);
IPAddress ip_address;
EXPECT_TRUE(ip_address.AssignFromIPLiteral(tests[i].remote_address));
IPEndPoint remote_address(ip_address, 80);
EXPECT_TRUE(ip_address.AssignFromIPLiteral(tests[i].local_address));
IPEndPoint local_address(ip_address, 80);
UDPClientSocket client(DatagramSocket::DEFAULT_BIND, nullptr,
NetLogSource());
int rv = client.Connect(remote_address);
if (tests[i].may_fail && rv == ERR_ADDRESS_UNREACHABLE) {
// Connect() may return ERR_ADDRESS_UNREACHABLE for IPv6
// addresses if IPv6 is not configured.
continue;
}
EXPECT_LE(ERR_IO_PENDING, rv);
IPEndPoint fetched_local_address;
rv = client.GetLocalAddress(&fetched_local_address);
EXPECT_THAT(rv, IsOk());
// TODO(mbelshe): figure out how to verify the IP and port.
// The port is dynamically generated by the udp stack.
// The IP is the real IP of the client, not necessarily
// loopback.
// EXPECT_EQ(local_address.address(), fetched_local_address.address());
IPEndPoint fetched_remote_address;
rv = client.GetPeerAddress(&fetched_remote_address);
EXPECT_THAT(rv, IsOk());
EXPECT_EQ(remote_address, fetched_remote_address);
}
}
TEST_F(UDPSocketTest, ServerGetLocalAddress) {
IPEndPoint bind_address(IPAddress::IPv4Localhost(), 0);
UDPServerSocket server(NULL, NetLogSource());
int rv = server.Listen(bind_address);
EXPECT_THAT(rv, IsOk());
IPEndPoint local_address;
rv = server.GetLocalAddress(&local_address);
EXPECT_EQ(rv, 0);
// Verify that port was allocated.
EXPECT_GT(local_address.port(), 0);
EXPECT_EQ(local_address.address(), bind_address.address());
}
TEST_F(UDPSocketTest, ServerGetPeerAddress) {
IPEndPoint bind_address(IPAddress::IPv4Localhost(), 0);
UDPServerSocket server(NULL, NetLogSource());
int rv = server.Listen(bind_address);
EXPECT_THAT(rv, IsOk());
IPEndPoint peer_address;
rv = server.GetPeerAddress(&peer_address);
EXPECT_EQ(rv, ERR_SOCKET_NOT_CONNECTED);
}
TEST_F(UDPSocketTest, ClientSetDoNotFragment) {
for (std::string ip : {"127.0.0.1", "::1"}) {
UDPClientSocket client(DatagramSocket::DEFAULT_BIND, nullptr,
NetLogSource());
IPAddress ip_address;
EXPECT_TRUE(ip_address.AssignFromIPLiteral(ip));
IPEndPoint remote_address(ip_address, 80);
int rv = client.Connect(remote_address);
// May fail on IPv6 is IPv6 is not configured.
if (ip_address.IsIPv6() && rv == ERR_ADDRESS_UNREACHABLE)
return;
EXPECT_THAT(rv, IsOk());
#if defined(OS_MACOSX)
EXPECT_EQ(ERR_NOT_IMPLEMENTED, client.SetDoNotFragment());
#else
rv = client.SetDoNotFragment();
EXPECT_THAT(rv, IsOk());
#endif
}
}
TEST_F(UDPSocketTest, ServerSetDoNotFragment) {
for (std::string ip : {"127.0.0.1", "::1"}) {
IPEndPoint bind_address;
ASSERT_TRUE(CreateUDPAddress(ip, 0, &bind_address));
UDPServerSocket server(nullptr, NetLogSource());
int rv = server.Listen(bind_address);
// May fail on IPv6 is IPv6 is not configure
if (bind_address.address().IsIPv6() &&
(rv == ERR_ADDRESS_INVALID || rv == ERR_ADDRESS_UNREACHABLE))
return;
EXPECT_THAT(rv, IsOk());
#if defined(OS_MACOSX)
EXPECT_EQ(ERR_NOT_IMPLEMENTED, server.SetDoNotFragment());
#else
rv = server.SetDoNotFragment();
EXPECT_THAT(rv, IsOk());
#endif
}
}
// Close the socket while read is pending.
TEST_F(UDPSocketTest, CloseWithPendingRead) {
IPEndPoint bind_address(IPAddress::IPv4Localhost(), 0);
UDPServerSocket server(NULL, NetLogSource());
int rv = server.Listen(bind_address);
EXPECT_THAT(rv, IsOk());
TestCompletionCallback callback;
IPEndPoint from;
rv = server.RecvFrom(buffer_.get(), kMaxRead, &from, callback.callback());
EXPECT_EQ(rv, ERR_IO_PENDING);
server.Close();
EXPECT_FALSE(callback.have_result());
}
// Some Android devices do not support multicast socket.
// The ones supporting multicast need WifiManager.MulitcastLock to enable it.
// http://goo.gl/jjAk9
#if !defined(OS_ANDROID)
TEST_F(UDPSocketTest, JoinMulticastGroup) {
const uint16_t kPort = 9999;
const char kGroup[] = "237.132.100.17";
IPAddress group_ip;
EXPECT_TRUE(group_ip.AssignFromIPLiteral(kGroup));
#if defined(OS_WIN) || defined(OS_FUCHSIA)
IPEndPoint bind_address(IPAddress::AllZeros(group_ip.size()), kPort);
#else
IPEndPoint bind_address(group_ip, kPort);
#endif // defined(OS_WIN) || defined(OS_FUCHSIA)
UDPSocket socket(DatagramSocket::DEFAULT_BIND, nullptr, NetLogSource());
EXPECT_THAT(socket.Open(bind_address.GetFamily()), IsOk());
#if defined(OS_FUCHSIA)
// Fuchsia currently doesn't support automatic interface selection for
// multicast, so interface index needs to be set explicitly.
// See https://fuchsia.atlassian.net/browse/NET-195 .
NetworkInterfaceList interfaces;
ASSERT_TRUE(GetNetworkList(&interfaces, 0));
ASSERT_FALSE(interfaces.empty());
EXPECT_THAT(socket.SetMulticastInterface(interfaces[0].interface_index),
IsOk());
#endif // defined(OS_FUCHSIA)
EXPECT_THAT(socket.Bind(bind_address), IsOk());
EXPECT_THAT(socket.JoinGroup(group_ip), IsOk());
// Joining group multiple times.
EXPECT_NE(OK, socket.JoinGroup(group_ip));
EXPECT_THAT(socket.LeaveGroup(group_ip), IsOk());
// Leaving group multiple times.
EXPECT_NE(OK, socket.LeaveGroup(group_ip));
socket.Close();
}
#if !defined(OS_FUCHSIA)
// TODO(https://crbug.com/900709): SO_REUSEPORT doesn't work on Fuchsia.
TEST_F(UDPSocketTest, SharedMulticastAddress) {
const uint16_t kPort = 9999;
const char kGroup[] = "224.0.0.251";
IPAddress group_ip;
ASSERT_TRUE(group_ip.AssignFromIPLiteral(kGroup));
IPEndPoint send_address(group_ip, kPort);
#if defined(OS_WIN) || defined(OS_FUCHSIA)
IPEndPoint receive_address(IPAddress::AllZeros(group_ip.size()), kPort);
#else
IPEndPoint receive_address(send_address);
#endif // defined(OS_WIN) || defined(OS_FUCHSIA)
NetworkInterfaceList interfaces;
ASSERT_TRUE(GetNetworkList(&interfaces, 0));
ASSERT_FALSE(interfaces.empty());
// Setup first receiving socket.
UDPServerSocket socket1(nullptr, NetLogSource());
socket1.AllowAddressSharingForMulticast();
ASSERT_THAT(socket1.SetMulticastInterface(interfaces[0].interface_index),
IsOk());
ASSERT_THAT(socket1.Listen(receive_address), IsOk());
ASSERT_THAT(socket1.JoinGroup(group_ip), IsOk());
// Setup second receiving socket.
UDPServerSocket socket2(nullptr, NetLogSource());
socket2.AllowAddressSharingForMulticast(), IsOk();
ASSERT_THAT(socket2.SetMulticastInterface(interfaces[0].interface_index),
IsOk());
ASSERT_THAT(socket2.Listen(receive_address), IsOk());
ASSERT_THAT(socket2.JoinGroup(group_ip), IsOk());
// Setup client socket.
UDPClientSocket client_socket(DatagramSocket::DEFAULT_BIND, nullptr,
NetLogSource());
ASSERT_THAT(client_socket.Connect(send_address), IsOk());
#if !defined(OS_CHROMEOS)
// Send a message via the multicast group. That message is expected be be
// received by both receving sockets.
//
// Skip on ChromeOS where it's known to sometimes not work.
// TODO(crbug.com/898964): If possible, fix and reenable.
const char kMessage[] = "hello!";
ASSERT_GE(WriteSocket(&client_socket, kMessage), 0);
EXPECT_EQ(kMessage, RecvFromSocket(&socket1));
EXPECT_EQ(kMessage, RecvFromSocket(&socket2));
#endif // !defined(OS_CHROMEOS)
}
#endif // !defined(OS_FUCHSIA)
#endif // !defined(OS_ANDROID)
TEST_F(UDPSocketTest, MulticastOptions) {
const uint16_t kPort = 9999;
IPEndPoint bind_address;
ASSERT_TRUE(CreateUDPAddress("0.0.0.0", kPort, &bind_address));
UDPSocket socket(DatagramSocket::DEFAULT_BIND, nullptr, NetLogSource());
// Before binding.
EXPECT_THAT(socket.SetMulticastLoopbackMode(false), IsOk());
EXPECT_THAT(socket.SetMulticastLoopbackMode(true), IsOk());
EXPECT_THAT(socket.SetMulticastTimeToLive(0), IsOk());
EXPECT_THAT(socket.SetMulticastTimeToLive(3), IsOk());
EXPECT_NE(OK, socket.SetMulticastTimeToLive(-1));
EXPECT_THAT(socket.SetMulticastInterface(0), IsOk());
EXPECT_THAT(socket.Open(bind_address.GetFamily()), IsOk());
EXPECT_THAT(socket.Bind(bind_address), IsOk());
EXPECT_NE(OK, socket.SetMulticastLoopbackMode(false));
EXPECT_NE(OK, socket.SetMulticastTimeToLive(0));
EXPECT_NE(OK, socket.SetMulticastInterface(0));
socket.Close();
}
// Checking that DSCP bits are set correctly is difficult,
// but let's check that the code doesn't crash at least.
TEST_F(UDPSocketTest, SetDSCP) {
// Setup the server to listen.
IPEndPoint bind_address;
UDPSocket client(DatagramSocket::DEFAULT_BIND, nullptr, NetLogSource());
// We need a real IP, but we won't actually send anything to it.
ASSERT_TRUE(CreateUDPAddress("8.8.8.8", 9999, &bind_address));
int rv = client.Open(bind_address.GetFamily());
EXPECT_THAT(rv, IsOk());
rv = client.Connect(bind_address);
if (rv != OK) {
// Let's try localhost then.
bind_address = IPEndPoint(IPAddress::IPv4Localhost(), 9999);
rv = client.Connect(bind_address);
}
EXPECT_THAT(rv, IsOk());
client.SetDiffServCodePoint(DSCP_NO_CHANGE);
client.SetDiffServCodePoint(DSCP_AF41);
client.SetDiffServCodePoint(DSCP_DEFAULT);
client.SetDiffServCodePoint(DSCP_CS2);
client.SetDiffServCodePoint(DSCP_NO_CHANGE);
client.SetDiffServCodePoint(DSCP_DEFAULT);
client.Close();
}
TEST_F(UDPSocketTest, TestBindToNetwork) {
UDPSocket socket(DatagramSocket::RANDOM_BIND, nullptr, NetLogSource());
#if defined(OS_ANDROID)
NetworkChangeNotifierFactoryAndroid ncn_factory;
NetworkChangeNotifier::DisableForTest ncn_disable_for_test;
std::unique_ptr<NetworkChangeNotifier> ncn(ncn_factory.CreateInstance());
#endif
ASSERT_EQ(OK, socket.Open(ADDRESS_FAMILY_IPV4));
// Test unsuccessful binding, by attempting to bind to a bogus NetworkHandle.
int rv = socket.BindToNetwork(65536);
#if !defined(OS_ANDROID)
EXPECT_EQ(ERR_NOT_IMPLEMENTED, rv);
#else
if (base::android::BuildInfo::GetInstance()->sdk_int() <
base::android::SDK_VERSION_LOLLIPOP) {
EXPECT_EQ(ERR_NOT_IMPLEMENTED, rv);
} else if (base::android::BuildInfo::GetInstance()->sdk_int() >=
base::android::SDK_VERSION_LOLLIPOP &&
base::android::BuildInfo::GetInstance()->sdk_int() <
base::android::SDK_VERSION_MARSHMALLOW) {
// On Lollipop, we assume if the user has a NetworkHandle that they must
// have gotten it from a legitimate source, so if binding to the network
// fails it's assumed to be because the network went away so
// ERR_NETWORK_CHANGED is returned. In this test the network never existed
// anyhow. ConnectivityService.MAX_NET_ID is 65535, so 65536 won't be used.
EXPECT_EQ(ERR_NETWORK_CHANGED, rv);
} else if (base::android::BuildInfo::GetInstance()->sdk_int() >=
base::android::SDK_VERSION_MARSHMALLOW) {
// On Marshmallow and newer releases, the NetworkHandle is munged by
// Network.getNetworkHandle() and 65536 isn't munged so it's rejected.
EXPECT_EQ(ERR_INVALID_ARGUMENT, rv);
}
if (base::android::BuildInfo::GetInstance()->sdk_int() >=
base::android::SDK_VERSION_LOLLIPOP) {
EXPECT_EQ(
ERR_INVALID_ARGUMENT,
socket.BindToNetwork(NetworkChangeNotifier::kInvalidNetworkHandle));
// Test successful binding, if possible.
EXPECT_TRUE(NetworkChangeNotifier::AreNetworkHandlesSupported());
NetworkChangeNotifier::NetworkHandle network_handle =
NetworkChangeNotifier::GetDefaultNetwork();
if (network_handle != NetworkChangeNotifier::kInvalidNetworkHandle) {
EXPECT_EQ(OK, socket.BindToNetwork(network_handle));
}
}
#endif
}
} // namespace
#if defined(OS_WIN)
namespace {
const HANDLE kFakeHandle1 = (HANDLE)12;
const HANDLE kFakeHandle2 = (HANDLE)13;
const QOS_FLOWID kFakeFlowId1 = (QOS_FLOWID)27;
const QOS_FLOWID kFakeFlowId2 = (QOS_FLOWID)38;
class TestUDPSocketWin : public UDPSocketWin {
public:
TestUDPSocketWin(QwaveApi* qos,
DatagramSocket::BindType bind_type,
net::NetLog* net_log,
const net::NetLogSource& source)
: UDPSocketWin(bind_type, net_log, source), qos_(qos) {}
// Overriding GetQwaveApi causes the test class to use the injected mock
// QwaveApi instance instead of the singleton.
QwaveApi* GetQwaveApi() const override { return qos_; }
private:
QwaveApi* qos_;
DISALLOW_COPY_AND_ASSIGN(TestUDPSocketWin);
};
class MockQwaveApi : public QwaveApi {
public:
MOCK_CONST_METHOD0(qwave_supported, bool());
MOCK_METHOD0(OnFatalError, void());
MOCK_METHOD2(CreateHandle, BOOL(PQOS_VERSION version, PHANDLE handle));
MOCK_METHOD1(CloseHandle, BOOL(HANDLE handle));
MOCK_METHOD6(AddSocketToFlow,
BOOL(HANDLE handle,
SOCKET socket,
PSOCKADDR addr,
QOS_TRAFFIC_TYPE traffic_type,
DWORD flags,
PQOS_FLOWID flow_id));
MOCK_METHOD4(
RemoveSocketFromFlow,
BOOL(HANDLE handle, SOCKET socket, QOS_FLOWID flow_id, DWORD reserved));
MOCK_METHOD7(SetFlow,
BOOL(HANDLE handle,
QOS_FLOWID flow_id,
QOS_SET_FLOW op,
ULONG size,
PVOID data,
DWORD reserved,
LPOVERLAPPED overlapped));
};
std::unique_ptr<UDPSocket> OpenedDscpTestClient(QwaveApi* api,
IPEndPoint bind_address) {
auto client = std::make_unique<TestUDPSocketWin>(
api, DatagramSocket::DEFAULT_BIND, nullptr, NetLogSource());
int rv = client->Open(bind_address.GetFamily());
EXPECT_THAT(rv, IsOk());
return client;
}
std::unique_ptr<UDPSocket> ConnectedDscpTestClient(QwaveApi* api) {
IPEndPoint bind_address;
// We need a real IP, but we won't actually send anything to it.
EXPECT_TRUE(CreateUDPAddress("8.8.8.8", 9999, &bind_address));
auto client = OpenedDscpTestClient(api, bind_address);
EXPECT_THAT(client->Connect(bind_address), IsOk());
return client;
}
std::unique_ptr<UDPSocket> UnconnectedDscpTestClient(QwaveApi* api) {
IPEndPoint bind_address;
EXPECT_TRUE(CreateUDPAddress("0.0.0.0", 9999, &bind_address));
auto client = OpenedDscpTestClient(api, bind_address);
EXPECT_THAT(client->Bind(bind_address), IsOk());
return client;
}
} // namespace
using ::testing::Return;
using ::testing::SetArgPointee;
using ::testing::_;
TEST_F(UDPSocketTest, SetDSCPNoopIfPassedNoChange) {
MockQwaveApi api;
EXPECT_CALL(api, qwave_supported()).WillRepeatedly(Return(true));
EXPECT_CALL(api, AddSocketToFlow(_, _, _, _, _, _)).Times(0);
std::unique_ptr<UDPSocket> client = ConnectedDscpTestClient(&api);
EXPECT_THAT(client->SetDiffServCodePoint(DSCP_NO_CHANGE), IsOk());
}
TEST_F(UDPSocketTest, SetDSCPFailsIfQOSDoesntLink) {
MockQwaveApi api;
EXPECT_CALL(api, qwave_supported()).WillRepeatedly(Return(false));
EXPECT_CALL(api, CreateHandle(_, _)).Times(0);
std::unique_ptr<UDPSocket> client = ConnectedDscpTestClient(&api);
EXPECT_EQ(ERR_NOT_IMPLEMENTED, client->SetDiffServCodePoint(DSCP_AF41));
}
TEST_F(UDPSocketTest, SetDSCPFailsIfHandleCantBeCreated) {
MockQwaveApi api;
EXPECT_CALL(api, qwave_supported()).WillRepeatedly(Return(true));
EXPECT_CALL(api, CreateHandle(_, _)).WillOnce(Return(false));
EXPECT_CALL(api, OnFatalError()).Times(1);
std::unique_ptr<UDPSocket> client = ConnectedDscpTestClient(&api);
EXPECT_EQ(ERR_INVALID_HANDLE, client->SetDiffServCodePoint(DSCP_AF41));
RunUntilIdle();
EXPECT_CALL(api, qwave_supported()).WillRepeatedly(Return(false));
EXPECT_EQ(ERR_NOT_IMPLEMENTED, client->SetDiffServCodePoint(DSCP_AF41));
}
MATCHER_P(DscpPointee, dscp, "") {
return *(DWORD*)arg == (DWORD)dscp;
}
TEST_F(UDPSocketTest, ConnectedSocketDelayedInitAndUpdate) {
MockQwaveApi api;
std::unique_ptr<UDPSocket> client = ConnectedDscpTestClient(&api);
EXPECT_CALL(api, qwave_supported()).WillRepeatedly(Return(true));
EXPECT_CALL(api, CreateHandle(_, _))
.WillOnce(DoAll(SetArgPointee<1>(kFakeHandle1), Return(true)));
EXPECT_CALL(api, AddSocketToFlow(_, _, _, _, _, _))
.WillOnce(DoAll(SetArgPointee<5>(kFakeFlowId1), Return(true)));
EXPECT_CALL(api, SetFlow(_, _, _, _, _, _, _));
// First set on connected sockets will fail since init is async and
// we haven't given the runloop a chance to execute the callback.
EXPECT_EQ(ERR_INVALID_HANDLE, client->SetDiffServCodePoint(DSCP_AF41));
RunUntilIdle();
EXPECT_THAT(client->SetDiffServCodePoint(DSCP_AF41), IsOk());
// New dscp value should reset the flow.
EXPECT_CALL(api, RemoveSocketFromFlow(_, _, kFakeFlowId1, _));
EXPECT_CALL(api, AddSocketToFlow(_, _, _, QOSTrafficTypeBestEffort, _, _))
.WillOnce(DoAll(SetArgPointee<5>(kFakeFlowId2), Return(true)));
EXPECT_CALL(api, SetFlow(_, _, QOSSetOutgoingDSCPValue, _,
DscpPointee(DSCP_DEFAULT), _, _));
EXPECT_THAT(client->SetDiffServCodePoint(DSCP_DEFAULT), IsOk());
// Called from DscpManager destructor.
EXPECT_CALL(api, RemoveSocketFromFlow(_, _, kFakeFlowId2, _));
EXPECT_CALL(api, CloseHandle(kFakeHandle1));
}
TEST_F(UDPSocketTest, UnonnectedSocketDelayedInitAndUpdate) {
MockQwaveApi api;
EXPECT_CALL(api, qwave_supported()).WillRepeatedly(Return(true));
EXPECT_CALL(api, CreateHandle(_, _))
.WillOnce(DoAll(SetArgPointee<1>(kFakeHandle1), Return(true)));
// CreateHandle won't have completed yet. Set passes.
std::unique_ptr<UDPSocket> client = UnconnectedDscpTestClient(&api);
EXPECT_THAT(client->SetDiffServCodePoint(DSCP_AF41), IsOk());
RunUntilIdle();
EXPECT_THAT(client->SetDiffServCodePoint(DSCP_AF42), IsOk());
// Called from DscpManager destructor.
EXPECT_CALL(api, CloseHandle(kFakeHandle1));
}
// TODO(zstein): Mocking out DscpManager might be simpler here
// (just verify that DscpManager::Set and DscpManager::PrepareForSend are
// called).
TEST_F(UDPSocketTest, SendToCallsQwaveApis) {
MockQwaveApi api;
std::unique_ptr<UDPSocket> client = UnconnectedDscpTestClient(&api);
EXPECT_CALL(api, qwave_supported()).WillRepeatedly(Return(true));
EXPECT_CALL(api, CreateHandle(_, _))
.WillOnce(DoAll(SetArgPointee<1>(kFakeHandle1), Return(true)));
EXPECT_THAT(client->SetDiffServCodePoint(DSCP_AF41), IsOk());
RunUntilIdle();
EXPECT_CALL(api, AddSocketToFlow(_, _, _, _, _, _))
.WillOnce(DoAll(SetArgPointee<5>(kFakeFlowId1), Return(true)));
EXPECT_CALL(api, SetFlow(_, _, _, _, _, _, _));
std::string simple_message("hello world");
IPEndPoint server_address(IPAddress::IPv4Localhost(), 9438);
int rv = SendToSocket(client.get(), simple_message, server_address);
EXPECT_EQ(simple_message.length(), static_cast<size_t>(rv));
// TODO(zstein): Move to second test case (Qwave APIs called once per address)
rv = SendToSocket(client.get(), simple_message, server_address);
EXPECT_EQ(simple_message.length(), static_cast<size_t>(rv));
// TODO(zstein): Move to third test case (Qwave APIs called for each
// destination address).
EXPECT_CALL(api, AddSocketToFlow(_, _, _, _, _, _)).WillOnce(Return(true));
IPEndPoint server_address2(IPAddress::IPv4Localhost(), 9439);
rv = SendToSocket(client.get(), simple_message, server_address2);
EXPECT_EQ(simple_message.length(), static_cast<size_t>(rv));
// Called from DscpManager destructor.
EXPECT_CALL(api, RemoveSocketFromFlow(_, _, _, _));
EXPECT_CALL(api, CloseHandle(kFakeHandle1));
}
TEST_F(UDPSocketTest, SendToCallsApisAfterDeferredInit) {
MockQwaveApi api;
std::unique_ptr<UDPSocket> client = UnconnectedDscpTestClient(&api);
EXPECT_CALL(api, qwave_supported()).WillRepeatedly(Return(true));
EXPECT_CALL(api, CreateHandle(_, _))
.WillOnce(DoAll(SetArgPointee<1>(kFakeHandle1), Return(true)));
// SetDiffServCodepoint works even if qos api hasn't finished initing.
EXPECT_THAT(client->SetDiffServCodePoint(DSCP_CS7), IsOk());
std::string simple_message("hello world");
IPEndPoint server_address(IPAddress::IPv4Localhost(), 9438);
// SendTo works, but doesn't yet apply TOS
EXPECT_CALL(api, AddSocketToFlow(_, _, _, _, _, _)).Times(0);
int rv = SendToSocket(client.get(), simple_message, server_address);
EXPECT_EQ(simple_message.length(), static_cast<size_t>(rv));
RunUntilIdle();
// Now we're initialized, SendTo triggers qos calls with correct codepoint.
EXPECT_CALL(api, AddSocketToFlow(_, _, _, QOSTrafficTypeControl, _, _))
.WillOnce(DoAll(SetArgPointee<5>(kFakeFlowId1), Return(true)));
EXPECT_CALL(api, SetFlow(_, _, _, _, _, _, _)).WillOnce(Return(true));
rv = SendToSocket(client.get(), simple_message, server_address);
EXPECT_EQ(simple_message.length(), static_cast<size_t>(rv));
// Called from DscpManager destructor.
EXPECT_CALL(api, RemoveSocketFromFlow(_, _, kFakeFlowId1, _));
EXPECT_CALL(api, CloseHandle(kFakeHandle1));
}
class DscpManagerTest : public TestWithScopedTaskEnvironment {
protected:
DscpManagerTest() {
EXPECT_CALL(api_, qwave_supported()).WillRepeatedly(Return(true));
EXPECT_CALL(api_, CreateHandle(_, _))
.WillOnce(DoAll(SetArgPointee<1>(kFakeHandle1), Return(true)));
dscp_manager_ = std::make_unique<DscpManager>(&api_, INVALID_SOCKET);
CreateUDPAddress("1.2.3.4", 9001, &address1_);
CreateUDPAddress("1234:5678:90ab:cdef:1234:5678:90ab:cdef", 9002,
&address2_);
}
MockQwaveApi api_;
std::unique_ptr<DscpManager> dscp_manager_;
IPEndPoint address1_;
IPEndPoint address2_;
};
TEST_F(DscpManagerTest, PrepareForSendIsNoopIfNoSet) {
RunUntilIdle();
dscp_manager_->PrepareForSend(address1_);
}
TEST_F(DscpManagerTest, PrepareForSendCallsQwaveApisAfterSet) {
RunUntilIdle();
dscp_manager_->Set(DSCP_CS2);
// AddSocketToFlow should be called for each address.
// SetFlow should only be called when the flow is first created.
EXPECT_CALL(api_, AddSocketToFlow(_, _, _, _, _, _))
.WillOnce(DoAll(SetArgPointee<5>(kFakeFlowId1), Return(true)));
EXPECT_CALL(api_, SetFlow(_, kFakeFlowId1, _, _, _, _, _));
dscp_manager_->PrepareForSend(address1_);
EXPECT_CALL(api_, AddSocketToFlow(_, _, _, _, _, _))
.WillOnce(DoAll(SetArgPointee<5>(kFakeFlowId1), Return(true)));
EXPECT_CALL(api_, SetFlow(_, _, _, _, _, _, _)).Times(0);
dscp_manager_->PrepareForSend(address2_);
// Called from DscpManager destructor.
EXPECT_CALL(api_, RemoveSocketFromFlow(_, _, kFakeFlowId1, _));
EXPECT_CALL(api_, CloseHandle(kFakeHandle1));
}
TEST_F(DscpManagerTest, PrepareForSendCallsQwaveApisOncePerAddress) {
RunUntilIdle();
dscp_manager_->Set(DSCP_CS2);
EXPECT_CALL(api_, AddSocketToFlow(_, _, _, _, _, _))
.WillOnce(DoAll(SetArgPointee<5>(kFakeFlowId1), Return(true)));
EXPECT_CALL(api_, SetFlow(_, kFakeFlowId1, _, _, _, _, _));
dscp_manager_->PrepareForSend(address1_);
EXPECT_CALL(api_, AddSocketToFlow(_, _, _, _, _, _)).Times(0);
EXPECT_CALL(api_, SetFlow(_, _, _, _, _, _, _)).Times(0);
dscp_manager_->PrepareForSend(address1_);
// Called from DscpManager destructor.
EXPECT_CALL(api_, RemoveSocketFromFlow(_, _, kFakeFlowId1, _));
EXPECT_CALL(api_, CloseHandle(kFakeHandle1));
}
TEST_F(DscpManagerTest, SetDestroysExistingFlow) {
RunUntilIdle();
dscp_manager_->Set(DSCP_CS2);
EXPECT_CALL(api_, AddSocketToFlow(_, _, _, _, _, _))
.WillOnce(DoAll(SetArgPointee<5>(kFakeFlowId1), Return(true)));
EXPECT_CALL(api_, SetFlow(_, kFakeFlowId1, _, _, _, _, _));
dscp_manager_->PrepareForSend(address1_);
// Calling Set should destroy the existing flow.
// TODO(zstein): Verify that RemoveSocketFromFlow with no address
// destroys the flow for all destinations.
EXPECT_CALL(api_, RemoveSocketFromFlow(_, NULL, kFakeFlowId1, _));
dscp_manager_->Set(DSCP_CS5);
EXPECT_CALL(api_, AddSocketToFlow(_, _, _, _, _, _))
.WillOnce(DoAll(SetArgPointee<5>(kFakeFlowId2), Return(true)));
EXPECT_CALL(api_, SetFlow(_, kFakeFlowId2, _, _, _, _, _));
dscp_manager_->PrepareForSend(address1_);
// Called from DscpManager destructor.
EXPECT_CALL(api_, RemoveSocketFromFlow(_, _, kFakeFlowId2, _));
EXPECT_CALL(api_, CloseHandle(kFakeHandle1));
}
TEST_F(DscpManagerTest, SocketReAddedOnRecreateHandle) {
RunUntilIdle();
dscp_manager_->Set(DSCP_CS2);
// First Set and Send work fine.
EXPECT_CALL(api_, AddSocketToFlow(_, _, _, _, _, _))
.WillOnce(DoAll(SetArgPointee<5>(kFakeFlowId1), Return(true)));
EXPECT_CALL(api_, SetFlow(_, kFakeFlowId1, _, _, _, _, _))
.WillOnce(Return(true));
EXPECT_THAT(dscp_manager_->PrepareForSend(address1_), IsOk());
// Make Second flow operation fail (requires resetting the codepoint).
EXPECT_CALL(api_, RemoveSocketFromFlow(_, _, kFakeFlowId1, _))
.WillOnce(Return(true));
dscp_manager_->Set(DSCP_CS7);
auto error = std::make_unique<base::internal::ScopedClearLastError>();
::SetLastError(ERROR_DEVICE_REINITIALIZATION_NEEDED);
EXPECT_CALL(api_, AddSocketToFlow(_, _, _, _, _, _)).WillOnce(Return(false));
EXPECT_CALL(api_, SetFlow(_, _, _, _, _, _, _)).Times(0);
EXPECT_CALL(api_, CloseHandle(kFakeHandle1));
EXPECT_CALL(api_, CreateHandle(_, _))
.WillOnce(DoAll(SetArgPointee<1>(kFakeHandle2), Return(true)));
EXPECT_EQ(ERR_INVALID_HANDLE, dscp_manager_->PrepareForSend(address1_));
error = nullptr;
RunUntilIdle();
// Next Send should work fine, without requiring another Set
EXPECT_CALL(api_, AddSocketToFlow(_, _, _, QOSTrafficTypeControl, _, _))
.WillOnce(DoAll(SetArgPointee<5>(kFakeFlowId2), Return(true)));
EXPECT_CALL(api_, SetFlow(_, kFakeFlowId2, _, _, _, _, _))
.WillOnce(Return(true));
EXPECT_THAT(dscp_manager_->PrepareForSend(address1_), IsOk());
// Called from DscpManager destructor.
EXPECT_CALL(api_, RemoveSocketFromFlow(_, _, kFakeFlowId2, _));
EXPECT_CALL(api_, CloseHandle(kFakeHandle2));
}
#endif
TEST_F(UDPSocketTest, ReadWithSocketOptimization) {
const uint16_t kPort = 10000;
std::string simple_message("hello world!");
// Setup the server to listen.
IPEndPoint server_address(IPAddress::IPv4Localhost(), kPort);
UDPServerSocket server(NULL, NetLogSource());
server.AllowAddressReuse();
int rv = server.Listen(server_address);
ASSERT_THAT(rv, IsOk());
// Setup the client, enable experimental optimization and connected to the
// server.
UDPClientSocket client(DatagramSocket::DEFAULT_BIND, nullptr, NetLogSource());
client.EnableRecvOptimization();
rv = client.Connect(server_address);
EXPECT_THAT(rv, IsOk());
// Get the client's address.
IPEndPoint client_address;
rv = client.GetLocalAddress(&client_address);
EXPECT_THAT(rv, IsOk());
// Server sends the message to the client.
rv = SendToSocket(&server, simple_message, client_address);
EXPECT_EQ(simple_message.length(), static_cast<size_t>(rv));
// Client receives the message.
std::string str = ReadSocket(&client);
EXPECT_EQ(simple_message, str);
server.Close();
client.Close();
}
// Tests that read from a socket correctly returns
// |ERR_MSG_TOO_BIG| when the buffer is too small and
// returns the actual message when it fits the buffer.
// For the optimized path, the buffer size should be at least
// 1 byte greater than the message.
TEST_F(UDPSocketTest, ReadWithSocketOptimizationTruncation) {
const uint16_t kPort = 10000;
std::string too_long_message(kMaxRead + 1, 'A');
std::string right_length_message(kMaxRead - 1, 'B');
std::string exact_length_message(kMaxRead, 'C');
// Setup the server to listen.
IPEndPoint server_address(IPAddress::IPv4Localhost(), kPort);
UDPServerSocket server(NULL, NetLogSource());
server.AllowAddressReuse();
int rv = server.Listen(server_address);
ASSERT_THAT(rv, IsOk());
// Setup the client, enable experimental optimization and connected to the
// server.
UDPClientSocket client(DatagramSocket::DEFAULT_BIND, nullptr, NetLogSource());
client.EnableRecvOptimization();
rv = client.Connect(server_address);
EXPECT_THAT(rv, IsOk());
// Get the client's address.
IPEndPoint client_address;
rv = client.GetLocalAddress(&client_address);
EXPECT_THAT(rv, IsOk());
// Send messages to the client.
rv = SendToSocket(&server, too_long_message, client_address);
EXPECT_EQ(too_long_message.length(), static_cast<size_t>(rv));
rv = SendToSocket(&server, right_length_message, client_address);
EXPECT_EQ(right_length_message.length(), static_cast<size_t>(rv));
rv = SendToSocket(&server, exact_length_message, client_address);
EXPECT_EQ(exact_length_message.length(), static_cast<size_t>(rv));
// Client receives the messages.
// 1. The first message is |too_long_message|. Its size exceeds the buffer.
// In that case, the client is expected to get |ERR_MSG_TOO_BIG| when the
// data is read.
TestCompletionCallback callback;
rv = client.Read(buffer_.get(), kMaxRead, callback.callback());
rv = callback.GetResult(rv);
EXPECT_EQ(ERR_MSG_TOO_BIG, rv);
// 2. The second message is |right_length_message|. Its size is
// one byte smaller than the size of the buffer. In that case, the client
// is expected to read the whole message successfully.
rv = client.Read(buffer_.get(), kMaxRead, callback.callback());
rv = callback.GetResult(rv);
EXPECT_EQ(static_cast<int>(right_length_message.length()), rv);
EXPECT_EQ(right_length_message, std::string(buffer_->data(), rv));
// 3. The third message is |exact_length_message|. Its size is equal to
// the read buffer size. In that case, the client expects to get
// |ERR_MSG_TOO_BIG| when the socket is read. Internally, the optimized
// path uses read() system call that requires one extra byte to detect
// truncated messages; therefore, messages that fill the buffer exactly
// are considered truncated.
// The optimization is only enabled on POSIX platforms. On Windows,
// the optimization is turned off; therefore, the client
// should be able to read the whole message without encountering
// |ERR_MSG_TOO_BIG|.
rv = client.Read(buffer_.get(), kMaxRead, callback.callback());
rv = callback.GetResult(rv);
#if defined(OS_POSIX)
EXPECT_EQ(ERR_MSG_TOO_BIG, rv);
#else
EXPECT_EQ(static_cast<int>(exact_length_message.length()), rv);
EXPECT_EQ(exact_length_message, std::string(buffer_->data(), rv));
#endif
server.Close();
client.Close();
}
// On Android, where socket tagging is supported, verify that UDPSocket::Tag
// works as expected.
#if defined(OS_ANDROID)
TEST_F(UDPSocketTest, Tag) {
UDPServerSocket server(nullptr, NetLogSource());
ASSERT_THAT(server.Listen(IPEndPoint(IPAddress::IPv4Localhost(), 0)), IsOk());
IPEndPoint server_address;
ASSERT_THAT(server.GetLocalAddress(&server_address), IsOk());
UDPClientSocket client(DatagramSocket::DEFAULT_BIND, nullptr, NetLogSource());
ASSERT_THAT(client.Connect(server_address), IsOk());
// Verify UDP packets are tagged and counted properly.
int32_t tag_val1 = 0x12345678;
uint64_t old_traffic = GetTaggedBytes(tag_val1);
SocketTag tag1(SocketTag::UNSET_UID, tag_val1);
client.ApplySocketTag(tag1);
// Client sends to the server.
std::string simple_message("hello world!");
int rv = WriteSocket(&client, simple_message);
EXPECT_EQ(simple_message.length(), static_cast<size_t>(rv));
// Server waits for message.
std::string str = RecvFromSocket(&server);
EXPECT_EQ(simple_message, str);
// Server echoes reply.
rv = SendToSocket(&server, simple_message);
EXPECT_EQ(simple_message.length(), static_cast<size_t>(rv));
// Client waits for response.
str = ReadSocket(&client);
EXPECT_EQ(simple_message, str);
EXPECT_GT(GetTaggedBytes(tag_val1), old_traffic);
// Verify socket can be retagged with a new value and the current process's
// UID.
int32_t tag_val2 = 0x87654321;
old_traffic = GetTaggedBytes(tag_val2);
SocketTag tag2(getuid(), tag_val2);
client.ApplySocketTag(tag2);
// Client sends to the server.
rv = WriteSocket(&client, simple_message);
EXPECT_EQ(simple_message.length(), static_cast<size_t>(rv));
// Server waits for message.
str = RecvFromSocket(&server);
EXPECT_EQ(simple_message, str);
// Server echoes reply.
rv = SendToSocket(&server, simple_message);
EXPECT_EQ(simple_message.length(), static_cast<size_t>(rv));
// Client waits for response.
str = ReadSocket(&client);
EXPECT_EQ(simple_message, str);
EXPECT_GT(GetTaggedBytes(tag_val2), old_traffic);
// Verify socket can be retagged with a new value and the current process's
// UID.
old_traffic = GetTaggedBytes(tag_val1);
client.ApplySocketTag(tag1);
// Client sends to the server.
rv = WriteSocket(&client, simple_message);
EXPECT_EQ(simple_message.length(), static_cast<size_t>(rv));
// Server waits for message.
str = RecvFromSocket(&server);
EXPECT_EQ(simple_message, str);
// Server echoes reply.
rv = SendToSocket(&server, simple_message);
EXPECT_EQ(simple_message.length(), static_cast<size_t>(rv));
// Client waits for response.
str = ReadSocket(&client);
EXPECT_EQ(simple_message, str);
EXPECT_GT(GetTaggedBytes(tag_val1), old_traffic);
}
#endif
} // namespace net