/* * Copyright (C) 2017 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 "perfetto/ext/base/unix_socket.h" #include #include #include #include #if !PERFETTO_BUILDFLAG(PERFETTO_OS_WIN) #include #include #include #endif #include "perfetto/base/build_config.h" #include "perfetto/base/logging.h" #include "perfetto/ext/base/file_utils.h" #include "perfetto/ext/base/pipe.h" #include "perfetto/ext/base/temp_file.h" #include "perfetto/ext/base/utils.h" #include "src/base/test/test_task_runner.h" #include "src/ipc/test/test_socket.h" #include "test/gtest_and_gmock.h" namespace perfetto { namespace base { namespace { using ::testing::_; using ::testing::AtLeast; using ::testing::Invoke; using ::testing::InvokeWithoutArgs; using ::testing::Mock; ipc::TestSocket kTestSocket{"unix_socket_unittest"}; class MockEventListener : public UnixSocket::EventListener { public: MOCK_METHOD2(OnNewIncomingConnection, void(UnixSocket*, UnixSocket*)); MOCK_METHOD2(OnConnect, void(UnixSocket*, bool)); MOCK_METHOD1(OnDisconnect, void(UnixSocket*)); MOCK_METHOD1(OnDataAvailable, void(UnixSocket*)); // GMock doesn't support mocking methods with non-copiable args. void OnNewIncomingConnection( UnixSocket* self, std::unique_ptr new_connection) override { incoming_connections_.emplace_back(std::move(new_connection)); OnNewIncomingConnection(self, incoming_connections_.back().get()); } std::unique_ptr GetIncomingConnection() { if (incoming_connections_.empty()) return nullptr; std::unique_ptr sock = std::move(incoming_connections_.front()); incoming_connections_.pop_front(); return sock; } private: std::list> incoming_connections_; }; class UnixSocketTest : public ::testing::Test { protected: void SetUp() override { kTestSocket.Destroy(); } void TearDown() override { kTestSocket.Destroy(); } TestTaskRunner task_runner_; MockEventListener event_listener_; }; TEST_F(UnixSocketTest, ConnectionFailureIfUnreachable) { auto cli = UnixSocket::Connect(kTestSocket.name(), &event_listener_, &task_runner_, kTestSocket.family(), SockType::kStream); ASSERT_FALSE(cli->is_connected()); auto checkpoint = task_runner_.CreateCheckpoint("failure"); EXPECT_CALL(event_listener_, OnConnect(cli.get(), false)) .WillOnce(InvokeWithoutArgs(checkpoint)); task_runner_.RunUntilCheckpoint("failure"); } // Both server and client should see an OnDisconnect() if the server drops // incoming connections immediately as they are created. TEST_F(UnixSocketTest, ConnectionImmediatelyDroppedByServer) { auto srv = UnixSocket::Listen(kTestSocket.name(), &event_listener_, &task_runner_, kTestSocket.family(), SockType::kStream); ASSERT_TRUE(srv->is_listening()); // The server will immediately shutdown the connection upon // OnNewIncomingConnection(). auto srv_did_shutdown = task_runner_.CreateCheckpoint("srv_did_shutdown"); EXPECT_CALL(event_listener_, OnNewIncomingConnection(srv.get(), _)) .WillOnce( Invoke([this, srv_did_shutdown](UnixSocket*, UnixSocket* new_conn) { EXPECT_CALL(event_listener_, OnDisconnect(new_conn)); new_conn->Shutdown(true); srv_did_shutdown(); })); auto checkpoint = task_runner_.CreateCheckpoint("cli_connected"); auto cli = UnixSocket::Connect(kTestSocket.name(), &event_listener_, &task_runner_, kTestSocket.family(), SockType::kStream); EXPECT_CALL(event_listener_, OnConnect(cli.get(), true)) .WillOnce(InvokeWithoutArgs(checkpoint)); task_runner_.RunUntilCheckpoint("cli_connected"); task_runner_.RunUntilCheckpoint("srv_did_shutdown"); // Trying to send something will trigger the disconnection notification. auto cli_disconnected = task_runner_.CreateCheckpoint("cli_disconnected"); EXPECT_CALL(event_listener_, OnDisconnect(cli.get())) .WillOnce(InvokeWithoutArgs(cli_disconnected)); // On Windows the first send immediately after the disconnection succeeds, the // kernel will detect the disconnection only later. cli->Send("."); EXPECT_FALSE(cli->Send("should_fail_both_on_win_and_unix")); task_runner_.RunUntilCheckpoint("cli_disconnected"); } TEST_F(UnixSocketTest, ClientAndServerExchangeData) { auto srv = UnixSocket::Listen(kTestSocket.name(), &event_listener_, &task_runner_, kTestSocket.family(), SockType::kStream); ASSERT_TRUE(srv->is_listening()); auto cli = UnixSocket::Connect(kTestSocket.name(), &event_listener_, &task_runner_, kTestSocket.family(), SockType::kStream); auto cli_connected = task_runner_.CreateCheckpoint("cli_connected"); EXPECT_CALL(event_listener_, OnConnect(cli.get(), true)) .WillOnce(InvokeWithoutArgs(cli_connected)); auto srv_conn_seen = task_runner_.CreateCheckpoint("srv_conn_seen"); auto srv_disconnected = task_runner_.CreateCheckpoint("srv_disconnected"); EXPECT_CALL(event_listener_, OnNewIncomingConnection(srv.get(), _)) .WillOnce(Invoke([this, srv_conn_seen, srv_disconnected]( UnixSocket*, UnixSocket* srv_conn) { EXPECT_CALL(event_listener_, OnDisconnect(srv_conn)) .WillOnce(InvokeWithoutArgs(srv_disconnected)); srv_conn_seen(); })); task_runner_.RunUntilCheckpoint("srv_conn_seen"); task_runner_.RunUntilCheckpoint("cli_connected"); auto srv_conn = event_listener_.GetIncomingConnection(); ASSERT_TRUE(srv_conn); ASSERT_TRUE(cli->is_connected()); auto cli_did_recv = task_runner_.CreateCheckpoint("cli_did_recv"); EXPECT_CALL(event_listener_, OnDataAvailable(cli.get())) .WillOnce(Invoke([cli_did_recv](UnixSocket* s) { ASSERT_EQ("srv>cli", s->ReceiveString()); cli_did_recv(); })); auto srv_did_recv = task_runner_.CreateCheckpoint("srv_did_recv"); EXPECT_CALL(event_listener_, OnDataAvailable(srv_conn.get())) .WillOnce(Invoke([srv_did_recv](UnixSocket* s) { ASSERT_EQ("cli>srv", s->ReceiveString()); srv_did_recv(); })); ASSERT_TRUE(cli->Send("cli>srv")); ASSERT_TRUE(srv_conn->Send("srv>cli")); task_runner_.RunUntilCheckpoint("cli_did_recv"); task_runner_.RunUntilCheckpoint("srv_did_recv"); // Check that Send/Receive() fails gracefully once the socket is closed. auto cli_disconnected = task_runner_.CreateCheckpoint("cli_disconnected"); EXPECT_CALL(event_listener_, OnDisconnect(cli.get())) .WillOnce(InvokeWithoutArgs(cli_disconnected)); cli->Shutdown(true); char msg[4]; ASSERT_EQ(0u, cli->Receive(&msg, sizeof(msg))); ASSERT_EQ("", cli->ReceiveString()); ASSERT_EQ(0u, srv_conn->Receive(&msg, sizeof(msg))); ASSERT_EQ("", srv_conn->ReceiveString()); ASSERT_FALSE(cli->Send("foo")); ASSERT_FALSE(srv_conn->Send("bar")); srv->Shutdown(true); task_runner_.RunUntilCheckpoint("cli_disconnected"); task_runner_.RunUntilCheckpoint("srv_disconnected"); } TEST_F(UnixSocketTest, ListenWithPassedSocketHandle) { auto sock_raw = UnixSocketRaw::CreateMayFail(kTestSocket.family(), SockType::kStream); ASSERT_TRUE(sock_raw.Bind(kTestSocket.name())); auto fd = sock_raw.ReleaseFd(); auto srv = UnixSocket::Listen(std::move(fd), &event_listener_, &task_runner_, kTestSocket.family(), SockType::kStream); ASSERT_TRUE(srv->is_listening()); auto cli_connected = task_runner_.CreateCheckpoint("cli_connected"); auto cli = UnixSocket::Connect(kTestSocket.name(), &event_listener_, &task_runner_, kTestSocket.family(), SockType::kStream); EXPECT_CALL(event_listener_, OnConnect(cli.get(), true)) .WillOnce(InvokeWithoutArgs(cli_connected)); auto srv_connected = task_runner_.CreateCheckpoint("srv_connected"); auto srv_disconnected = task_runner_.CreateCheckpoint("srv_disconnected"); EXPECT_CALL(event_listener_, OnNewIncomingConnection(srv.get(), _)) .WillOnce(Invoke([this, srv_connected, srv_disconnected]( UnixSocket*, UnixSocket* srv_conn) { // An empty OnDataAvailable might be raised to signal the EOF state. EXPECT_CALL(event_listener_, OnDataAvailable(srv_conn)) .WillRepeatedly( InvokeWithoutArgs([srv_conn] { srv_conn->ReceiveString(); })); EXPECT_CALL(event_listener_, OnDisconnect(srv_conn)) .WillOnce(InvokeWithoutArgs(srv_disconnected)); srv_connected(); })); task_runner_.RunUntilCheckpoint("srv_connected"); task_runner_.RunUntilCheckpoint("cli_connected"); ASSERT_TRUE(cli->is_connected()); cli.reset(); task_runner_.RunUntilCheckpoint("srv_disconnected"); } // Mostly a stress tests. Connects kNumClients clients to the same server and // tests that all can exchange data and can see the expected sequence of events. TEST_F(UnixSocketTest, SeveralClients) { auto srv = UnixSocket::Listen(kTestSocket.name(), &event_listener_, &task_runner_, kTestSocket.family(), SockType::kStream); ASSERT_TRUE(srv->is_listening()); constexpr size_t kNumClients = 32; std::unique_ptr cli[kNumClients]; EXPECT_CALL(event_listener_, OnNewIncomingConnection(srv.get(), _)) .Times(kNumClients) .WillRepeatedly(Invoke([this](UnixSocket*, UnixSocket* s) { EXPECT_CALL(event_listener_, OnDataAvailable(s)) .WillOnce(Invoke([](UnixSocket* t) { ASSERT_EQ("PING", t->ReceiveString()); ASSERT_TRUE(t->Send("PONG")); })); })); for (size_t i = 0; i < kNumClients; i++) { cli[i] = UnixSocket::Connect(kTestSocket.name(), &event_listener_, &task_runner_, kTestSocket.family(), SockType::kStream); EXPECT_CALL(event_listener_, OnConnect(cli[i].get(), true)) .WillOnce(Invoke([](UnixSocket* s, bool success) { ASSERT_TRUE(success); ASSERT_TRUE(s->Send("PING")); })); auto checkpoint = task_runner_.CreateCheckpoint(std::to_string(i)); EXPECT_CALL(event_listener_, OnDataAvailable(cli[i].get())) .WillOnce(Invoke([checkpoint](UnixSocket* s) { ASSERT_EQ("PONG", s->ReceiveString()); checkpoint(); })); } for (size_t i = 0; i < kNumClients; i++) { task_runner_.RunUntilCheckpoint(std::to_string(i)); ASSERT_TRUE(Mock::VerifyAndClearExpectations(cli[i].get())); } } TEST_F(UnixSocketTest, BlockingSend) { auto srv = UnixSocket::Listen(kTestSocket.name(), &event_listener_, &task_runner_, kTestSocket.family(), SockType::kStream); ASSERT_TRUE(srv->is_listening()); auto all_frames_done = task_runner_.CreateCheckpoint("all_frames_done"); size_t total_bytes_received = 0; static constexpr size_t kTotalBytes = 1024 * 1024 * 4; EXPECT_CALL(event_listener_, OnNewIncomingConnection(srv.get(), _)) .WillOnce(Invoke([this, &total_bytes_received, all_frames_done]( UnixSocket*, UnixSocket* srv_conn) { EXPECT_CALL(event_listener_, OnDataAvailable(srv_conn)) .WillRepeatedly( Invoke([&total_bytes_received, all_frames_done](UnixSocket* s) { char buf[1024]; size_t res = s->Receive(buf, sizeof(buf)); total_bytes_received += res; if (total_bytes_received == kTotalBytes) all_frames_done(); })); })); // Override default timeout as this test can take time on the emulator. static constexpr int kTimeoutMs = 60000 * 3; // Perform the blocking send form another thread. std::thread tx_thread([] { TestTaskRunner tx_task_runner; MockEventListener tx_events; auto cli = UnixSocket::Connect(kTestSocket.name(), &tx_events, &tx_task_runner, kTestSocket.family(), SockType::kStream); auto cli_connected = tx_task_runner.CreateCheckpoint("cli_connected"); EXPECT_CALL(tx_events, OnConnect(cli.get(), true)) .WillOnce(InvokeWithoutArgs(cli_connected)); tx_task_runner.RunUntilCheckpoint("cli_connected"); auto all_sent = tx_task_runner.CreateCheckpoint("all_sent"); char buf[1024 * 32] = {}; tx_task_runner.PostTask([&cli, &buf, all_sent] { for (size_t i = 0; i < kTotalBytes / sizeof(buf); i++) cli->Send(buf, sizeof(buf)); all_sent(); }); tx_task_runner.RunUntilCheckpoint("all_sent", kTimeoutMs); }); task_runner_.RunUntilCheckpoint("all_frames_done", kTimeoutMs); tx_thread.join(); } // Regression test for b/76155349 . If the receiver end disconnects while the // sender is in the middle of a large send(), the socket should gracefully give // up (i.e. Shutdown()) but not crash. TEST_F(UnixSocketTest, ReceiverDisconnectsDuringSend) { auto srv = UnixSocket::Listen(kTestSocket.name(), &event_listener_, &task_runner_, kTestSocket.family(), SockType::kStream); ASSERT_TRUE(srv->is_listening()); static constexpr int kTimeoutMs = 30000; auto receive_done = task_runner_.CreateCheckpoint("receive_done"); EXPECT_CALL(event_listener_, OnNewIncomingConnection(srv.get(), _)) .WillOnce(Invoke([this, receive_done](UnixSocket*, UnixSocket* srv_conn) { EXPECT_CALL(event_listener_, OnDataAvailable(srv_conn)) .WillOnce(Invoke([receive_done](UnixSocket* s) { char buf[1024]; size_t res = s->Receive(buf, sizeof(buf)); ASSERT_EQ(1024u, res); s->Shutdown(false /*notify*/); receive_done(); })); })); // Perform the blocking send form another thread. std::thread tx_thread([] { TestTaskRunner tx_task_runner; MockEventListener tx_events; auto cli = UnixSocket::Connect(kTestSocket.name(), &tx_events, &tx_task_runner, kTestSocket.family(), SockType::kStream); auto cli_connected = tx_task_runner.CreateCheckpoint("cli_connected"); EXPECT_CALL(tx_events, OnConnect(cli.get(), true)) .WillOnce(InvokeWithoutArgs(cli_connected)); tx_task_runner.RunUntilCheckpoint("cli_connected"); auto send_done = tx_task_runner.CreateCheckpoint("send_done"); static constexpr size_t kBufSize = 32 * 1024 * 1024; std::unique_ptr buf(new char[kBufSize]()); tx_task_runner.PostTask([&cli, &buf, send_done] { cli->Send(buf.get(), kBufSize); send_done(); }); tx_task_runner.RunUntilCheckpoint("send_done", kTimeoutMs); }); task_runner_.RunUntilCheckpoint("receive_done", kTimeoutMs); tx_thread.join(); } TEST_F(UnixSocketTest, ReleaseSocket) { auto srv = UnixSocket::Listen(kTestSocket.name(), &event_listener_, &task_runner_, kTestSocket.family(), SockType::kStream); ASSERT_TRUE(srv->is_listening()); auto srv_connected = task_runner_.CreateCheckpoint("srv_connected"); UnixSocket* peer = nullptr; EXPECT_CALL(event_listener_, OnNewIncomingConnection(srv.get(), _)) .WillOnce( Invoke([srv_connected, &peer](UnixSocket*, UnixSocket* new_conn) { peer = new_conn; srv_connected(); })); auto cli = UnixSocket::Connect(kTestSocket.name(), &event_listener_, &task_runner_, kTestSocket.family(), SockType::kStream); auto cli_connected = task_runner_.CreateCheckpoint("cli_connected"); EXPECT_CALL(event_listener_, OnConnect(cli.get(), true)) .WillOnce(InvokeWithoutArgs(cli_connected)); task_runner_.RunUntilCheckpoint("srv_connected"); task_runner_.RunUntilCheckpoint("cli_connected"); srv->Shutdown(true); cli->Send("test"); ASSERT_NE(peer, nullptr); auto raw_sock = peer->ReleaseSocket(); EXPECT_CALL(event_listener_, OnDataAvailable(_)).Times(0); task_runner_.RunUntilIdle(); char buf[sizeof("test")]; ASSERT_TRUE(raw_sock); ASSERT_EQ(raw_sock.Receive(buf, sizeof(buf)), static_cast(sizeof(buf))); ASSERT_STREQ(buf, "test"); } TEST_F(UnixSocketTest, TcpStream) { char host_and_port[32]; int attempt = 0; std::unique_ptr srv; // Try listening on a random port. Some ports might be taken by other syste // services. Do a bunch of attempts on different ports before giving up. do { sprintf(host_and_port, "127.0.0.1:%d", 10000 + (rand() % 10000)); srv = UnixSocket::Listen(host_and_port, &event_listener_, &task_runner_, SockFamily::kInet, SockType::kStream); } while ((!srv || !srv->is_listening()) && attempt++ < 10); ASSERT_TRUE(srv->is_listening()); constexpr size_t kNumClients = 3; std::unique_ptr cli[kNumClients]; EXPECT_CALL(event_listener_, OnNewIncomingConnection(srv.get(), _)) .Times(kNumClients) .WillRepeatedly(Invoke([&](UnixSocket*, UnixSocket* s) { // OnDisconnect() might spuriously happen depending on the dtor order. EXPECT_CALL(event_listener_, OnDisconnect(s)).Times(AtLeast(0)); EXPECT_CALL(event_listener_, OnDataAvailable(s)) .WillRepeatedly(Invoke([](UnixSocket* cli_sock) { cli_sock->ReceiveString(); // Read connection EOF; })); ASSERT_TRUE(s->Send("welcome")); })); for (size_t i = 0; i < kNumClients; i++) { cli[i] = UnixSocket::Connect(host_and_port, &event_listener_, &task_runner_, SockFamily::kInet, SockType::kStream); auto checkpoint = task_runner_.CreateCheckpoint(std::to_string(i)); EXPECT_CALL(event_listener_, OnDisconnect(cli[i].get())).Times(AtLeast(0)); EXPECT_CALL(event_listener_, OnConnect(cli[i].get(), true)); EXPECT_CALL(event_listener_, OnDataAvailable(cli[i].get())) .WillRepeatedly(Invoke([checkpoint](UnixSocket* s) { auto str = s->ReceiveString(); if (str == "") return; // Connection EOF. ASSERT_EQ("welcome", str); checkpoint(); })); } for (size_t i = 0; i < kNumClients; i++) { task_runner_.RunUntilCheckpoint(std::to_string(i)); ASSERT_TRUE(Mock::VerifyAndClearExpectations(cli[i].get())); } } // --------------------------------- // Posix-only tests below this point // --------------------------------- #if !PERFETTO_BUILDFLAG(PERFETTO_OS_WIN) // Tests the SockPeerCredMode::kIgnore logic. TEST_F(UnixSocketTest, IgnorePeerCredentials) { auto srv = UnixSocket::Listen(kTestSocket.name(), &event_listener_, &task_runner_, kTestSocket.family(), SockType::kStream); ASSERT_TRUE(srv->is_listening()); auto cli1_connected = task_runner_.CreateCheckpoint("cli1_connected"); auto cli1 = UnixSocket::Connect(kTestSocket.name(), &event_listener_, &task_runner_, kTestSocket.family(), SockType::kStream, SockPeerCredMode::kIgnore); EXPECT_CALL(event_listener_, OnConnect(cli1.get(), true)) .WillOnce(InvokeWithoutArgs(cli1_connected)); auto cli2_connected = task_runner_.CreateCheckpoint("cli2_connected"); auto cli2 = UnixSocket::Connect( kTestSocket.name(), &event_listener_, &task_runner_, kTestSocket.family(), SockType::kStream, SockPeerCredMode::kReadOnConnect); EXPECT_CALL(event_listener_, OnConnect(cli2.get(), true)) .WillOnce(InvokeWithoutArgs(cli2_connected)); task_runner_.RunUntilCheckpoint("cli1_connected"); task_runner_.RunUntilCheckpoint("cli2_connected"); ASSERT_EQ(cli1->peer_uid_posix(/*skip_check_for_testing=*/true), kInvalidUid); ASSERT_EQ(cli2->peer_uid_posix(), geteuid()); #if PERFETTO_BUILDFLAG(PERFETTO_OS_LINUX) || \ PERFETTO_BUILDFLAG(PERFETTO_OS_ANDROID) ASSERT_EQ(cli1->peer_pid_linux(/*skip_check_for_testing=*/true), kInvalidPid); ASSERT_EQ(cli2->peer_pid_linux(), getpid()); #endif } // Checks that the peer_uid() is retained after the client disconnects. The IPC // layer needs to rely on this to validate messages received immediately before // a client disconnects. TEST_F(UnixSocketTest, PeerCredentialsRetainedAfterDisconnect) { auto srv = UnixSocket::Listen(kTestSocket.name(), &event_listener_, &task_runner_, kTestSocket.family(), SockType::kStream); ASSERT_TRUE(srv->is_listening()); UnixSocket* srv_client_conn = nullptr; auto srv_connected = task_runner_.CreateCheckpoint("srv_connected"); EXPECT_CALL(event_listener_, OnNewIncomingConnection(srv.get(), _)) .WillOnce(Invoke([&srv_client_conn, srv_connected](UnixSocket*, UnixSocket* srv_conn) { srv_client_conn = srv_conn; EXPECT_EQ(geteuid(), static_cast(srv_conn->peer_uid_posix())); #if PERFETTO_BUILDFLAG(PERFETTO_OS_LINUX) || \ PERFETTO_BUILDFLAG(PERFETTO_OS_ANDROID) EXPECT_EQ(getpid(), static_cast(srv_conn->peer_pid_linux())); #endif srv_connected(); })); auto cli_connected = task_runner_.CreateCheckpoint("cli_connected"); auto cli = UnixSocket::Connect(kTestSocket.name(), &event_listener_, &task_runner_, kTestSocket.family(), SockType::kStream); EXPECT_CALL(event_listener_, OnConnect(cli.get(), true)) .WillOnce(InvokeWithoutArgs(cli_connected)); task_runner_.RunUntilCheckpoint("cli_connected"); task_runner_.RunUntilCheckpoint("srv_connected"); ASSERT_NE(nullptr, srv_client_conn); ASSERT_TRUE(srv_client_conn->is_connected()); auto cli_disconnected = task_runner_.CreateCheckpoint("cli_disconnected"); EXPECT_CALL(event_listener_, OnDisconnect(srv_client_conn)) .WillOnce(InvokeWithoutArgs(cli_disconnected)); // TODO(primiano): when the a peer disconnects, the other end receives a // spurious OnDataAvailable() that needs to be acked with a Receive() to read // the EOF. See b/69536434. EXPECT_CALL(event_listener_, OnDataAvailable(srv_client_conn)) .WillOnce(Invoke([](UnixSocket* sock) { sock->ReceiveString(); })); cli.reset(); task_runner_.RunUntilCheckpoint("cli_disconnected"); ASSERT_FALSE(srv_client_conn->is_connected()); EXPECT_EQ(geteuid(), static_cast(srv_client_conn->peer_uid_posix())); #if PERFETTO_BUILDFLAG(PERFETTO_OS_LINUX) || \ PERFETTO_BUILDFLAG(PERFETTO_OS_ANDROID) EXPECT_EQ(getpid(), static_cast(srv_client_conn->peer_pid_linux())); #endif } TEST_F(UnixSocketTest, ClientAndServerExchangeFDs) { static constexpr char cli_str[] = "cli>srv"; static constexpr char srv_str[] = "srv>cli"; auto srv = UnixSocket::Listen(kTestSocket.name(), &event_listener_, &task_runner_, kTestSocket.family(), SockType::kStream); ASSERT_TRUE(srv->is_listening()); auto cli = UnixSocket::Connect(kTestSocket.name(), &event_listener_, &task_runner_, kTestSocket.family(), SockType::kStream); EXPECT_CALL(event_listener_, OnConnect(cli.get(), true)); auto cli_connected = task_runner_.CreateCheckpoint("cli_connected"); auto srv_disconnected = task_runner_.CreateCheckpoint("srv_disconnected"); EXPECT_CALL(event_listener_, OnNewIncomingConnection(srv.get(), _)) .WillOnce(Invoke([this, cli_connected, srv_disconnected]( UnixSocket*, UnixSocket* srv_conn) { EXPECT_CALL(event_listener_, OnDisconnect(srv_conn)) .WillOnce(InvokeWithoutArgs(srv_disconnected)); cli_connected(); })); task_runner_.RunUntilCheckpoint("cli_connected"); auto srv_conn = event_listener_.GetIncomingConnection(); ASSERT_TRUE(srv_conn); ASSERT_TRUE(cli->is_connected()); ScopedFile null_fd(base::OpenFile("/dev/null", O_RDONLY)); ScopedFile zero_fd(base::OpenFile("/dev/zero", O_RDONLY)); auto cli_did_recv = task_runner_.CreateCheckpoint("cli_did_recv"); EXPECT_CALL(event_listener_, OnDataAvailable(cli.get())) .WillRepeatedly(Invoke([cli_did_recv](UnixSocket* s) { ScopedFile fd_buf[3]; char buf[sizeof(cli_str)]; if (!s->Receive(buf, sizeof(buf), fd_buf, ArraySize(fd_buf))) return; ASSERT_STREQ(srv_str, buf); ASSERT_NE(*fd_buf[0], -1); ASSERT_NE(*fd_buf[1], -1); ASSERT_EQ(*fd_buf[2], -1); char rd_buf[1]; // /dev/null ASSERT_EQ(read(*fd_buf[0], rd_buf, sizeof(rd_buf)), 0); // /dev/zero ASSERT_EQ(read(*fd_buf[1], rd_buf, sizeof(rd_buf)), 1); cli_did_recv(); })); auto srv_did_recv = task_runner_.CreateCheckpoint("srv_did_recv"); EXPECT_CALL(event_listener_, OnDataAvailable(srv_conn.get())) .WillRepeatedly(Invoke([srv_did_recv](UnixSocket* s) { ScopedFile fd_buf[3]; char buf[sizeof(srv_str)]; if (!s->Receive(buf, sizeof(buf), fd_buf, ArraySize(fd_buf))) return; ASSERT_STREQ(cli_str, buf); ASSERT_NE(*fd_buf[0], -1); ASSERT_NE(*fd_buf[1], -1); ASSERT_EQ(*fd_buf[2], -1); char rd_buf[1]; // /dev/null ASSERT_EQ(read(*fd_buf[0], rd_buf, sizeof(rd_buf)), 0); // /dev/zero ASSERT_EQ(read(*fd_buf[1], rd_buf, sizeof(rd_buf)), 1); srv_did_recv(); })); int buf_fd[2] = {null_fd.get(), zero_fd.get()}; ASSERT_TRUE( cli->Send(cli_str, sizeof(cli_str), buf_fd, base::ArraySize(buf_fd))); ASSERT_TRUE(srv_conn->Send(srv_str, sizeof(srv_str), buf_fd, base::ArraySize(buf_fd))); task_runner_.RunUntilCheckpoint("srv_did_recv"); task_runner_.RunUntilCheckpoint("cli_did_recv"); auto cli_disconnected = task_runner_.CreateCheckpoint("cli_disconnected"); EXPECT_CALL(event_listener_, OnDisconnect(cli.get())) .WillOnce(InvokeWithoutArgs(cli_disconnected)); cli->Shutdown(true); srv->Shutdown(true); task_runner_.RunUntilCheckpoint("srv_disconnected"); task_runner_.RunUntilCheckpoint("cli_disconnected"); } // Creates two processes. The server process creates a file and passes it over // the socket to the client. Both processes mmap the file in shared mode and // check that they see the same contents. TEST_F(UnixSocketTest, SharedMemory) { Pipe pipe = Pipe::Create(); pid_t pid = fork(); ASSERT_GE(pid, 0); constexpr size_t kTmpSize = 4096; if (pid == 0) { // Child process. TempFile scoped_tmp = TempFile::CreateUnlinked(); int tmp_fd = scoped_tmp.fd(); ASSERT_FALSE(ftruncate(tmp_fd, kTmpSize)); char* mem = reinterpret_cast( mmap(nullptr, kTmpSize, PROT_READ | PROT_WRITE, MAP_SHARED, tmp_fd, 0)); ASSERT_NE(nullptr, mem); memcpy(mem, "shm rocks", 10); auto srv = UnixSocket::Listen(kTestSocket.name(), &event_listener_, &task_runner_, kTestSocket.family(), SockType::kStream); ASSERT_TRUE(srv->is_listening()); // Signal the other process that it can connect. ASSERT_EQ(1, base::WriteAll(*pipe.wr, ".", 1)); auto checkpoint = task_runner_.CreateCheckpoint("change_seen_by_server"); EXPECT_CALL(event_listener_, OnNewIncomingConnection(srv.get(), _)) .WillOnce(Invoke( [this, tmp_fd, checkpoint, mem](UnixSocket*, UnixSocket* new_conn) { ASSERT_EQ(geteuid(), static_cast(new_conn->peer_uid_posix())); ASSERT_TRUE(new_conn->Send("txfd", 5, tmp_fd)); // Wait for the client to change this again. EXPECT_CALL(event_listener_, OnDataAvailable(new_conn)) .WillOnce(Invoke([checkpoint, mem](UnixSocket* s) { ASSERT_EQ("change notify", s->ReceiveString()); ASSERT_STREQ("rock more", mem); checkpoint(); })); })); task_runner_.RunUntilCheckpoint("change_seen_by_server"); ASSERT_TRUE(Mock::VerifyAndClearExpectations(&event_listener_)); _exit(0); } else { char sync_cmd = '\0'; ASSERT_EQ(1, PERFETTO_EINTR(read(*pipe.rd, &sync_cmd, 1))); ASSERT_EQ('.', sync_cmd); auto cli = UnixSocket::Connect(kTestSocket.name(), &event_listener_, &task_runner_, kTestSocket.family(), SockType::kStream); EXPECT_CALL(event_listener_, OnConnect(cli.get(), true)); auto checkpoint = task_runner_.CreateCheckpoint("change_seen_by_client"); EXPECT_CALL(event_listener_, OnDataAvailable(cli.get())) .WillOnce(Invoke([checkpoint](UnixSocket* s) { char msg[32]; ScopedFile fd; ASSERT_EQ(5u, s->Receive(msg, sizeof(msg), &fd)); ASSERT_STREQ("txfd", msg); ASSERT_TRUE(fd); char* mem = reinterpret_cast(mmap( nullptr, kTmpSize, PROT_READ | PROT_WRITE, MAP_SHARED, *fd, 0)); ASSERT_NE(nullptr, mem); mem[9] = '\0'; // Just to get a clean error in case of test failure. ASSERT_STREQ("shm rocks", mem); // Now change the shared memory and ping the other process. memcpy(mem, "rock more", 10); ASSERT_TRUE(s->Send("change notify")); checkpoint(); })); task_runner_.RunUntilCheckpoint("change_seen_by_client"); int st = 0; PERFETTO_EINTR(waitpid(pid, &st, 0)); ASSERT_FALSE(WIFSIGNALED(st)) << "Server died with signal " << WTERMSIG(st); EXPECT_TRUE(WIFEXITED(st)); ASSERT_EQ(0, WEXITSTATUS(st)); } } TEST_F(UnixSocketTest, ShiftMsgHdrSendPartialFirst) { // Send a part of the first iov, then send the rest. struct iovec iov[2] = {}; char hello[] = "hello"; char world[] = "world"; iov[0].iov_base = &hello[0]; iov[0].iov_len = base::ArraySize(hello); iov[1].iov_base = &world[0]; iov[1].iov_len = base::ArraySize(world); struct msghdr hdr = {}; hdr.msg_iov = iov; hdr.msg_iovlen = base::ArraySize(iov); UnixSocketRaw::ShiftMsgHdrPosix(1, &hdr); EXPECT_NE(hdr.msg_iov, nullptr); EXPECT_EQ(hdr.msg_iov[0].iov_base, &hello[1]); EXPECT_EQ(hdr.msg_iov[1].iov_base, &world[0]); EXPECT_EQ(static_cast(hdr.msg_iovlen), 2); EXPECT_STREQ(reinterpret_cast(hdr.msg_iov[0].iov_base), "ello"); EXPECT_EQ(iov[0].iov_len, base::ArraySize(hello) - 1); UnixSocketRaw::ShiftMsgHdrPosix(base::ArraySize(hello) - 1, &hdr); EXPECT_EQ(hdr.msg_iov, &iov[1]); EXPECT_EQ(static_cast(hdr.msg_iovlen), 1); EXPECT_STREQ(reinterpret_cast(hdr.msg_iov[0].iov_base), world); EXPECT_EQ(hdr.msg_iov[0].iov_len, base::ArraySize(world)); UnixSocketRaw::ShiftMsgHdrPosix(base::ArraySize(world), &hdr); EXPECT_EQ(hdr.msg_iov, nullptr); EXPECT_EQ(static_cast(hdr.msg_iovlen), 0); } TEST_F(UnixSocketTest, ShiftMsgHdrSendFirstAndPartial) { // Send first iov and part of the second iov, then send the rest. struct iovec iov[2] = {}; char hello[] = "hello"; char world[] = "world"; iov[0].iov_base = &hello[0]; iov[0].iov_len = base::ArraySize(hello); iov[1].iov_base = &world[0]; iov[1].iov_len = base::ArraySize(world); struct msghdr hdr = {}; hdr.msg_iov = iov; hdr.msg_iovlen = base::ArraySize(iov); UnixSocketRaw::ShiftMsgHdrPosix(base::ArraySize(hello) + 1, &hdr); EXPECT_NE(hdr.msg_iov, nullptr); EXPECT_EQ(static_cast(hdr.msg_iovlen), 1); EXPECT_STREQ(reinterpret_cast(hdr.msg_iov[0].iov_base), "orld"); EXPECT_EQ(hdr.msg_iov[0].iov_len, base::ArraySize(world) - 1); UnixSocketRaw::ShiftMsgHdrPosix(base::ArraySize(world) - 1, &hdr); EXPECT_EQ(hdr.msg_iov, nullptr); EXPECT_EQ(static_cast(hdr.msg_iovlen), 0); } TEST_F(UnixSocketTest, ShiftMsgHdrSendEverything) { // Send everything at once. struct iovec iov[2] = {}; char hello[] = "hello"; char world[] = "world"; iov[0].iov_base = &hello[0]; iov[0].iov_len = base::ArraySize(hello); iov[1].iov_base = &world[0]; iov[1].iov_len = base::ArraySize(world); struct msghdr hdr = {}; hdr.msg_iov = iov; hdr.msg_iovlen = base::ArraySize(iov); UnixSocketRaw::ShiftMsgHdrPosix( base::ArraySize(world) + base::ArraySize(hello), &hdr); EXPECT_EQ(hdr.msg_iov, nullptr); EXPECT_EQ(static_cast(hdr.msg_iovlen), 0); } // For use in PartialSendMsgAll template argument. Cannot be a lambda. int RollbackSigaction(const struct sigaction* act) { return sigaction(SIGWINCH, act, nullptr); } TEST_F(UnixSocketTest, PartialSendMsgAll) { UnixSocketRaw send_sock; UnixSocketRaw recv_sock; std::tie(send_sock, recv_sock) = UnixSocketRaw::CreatePairPosix(kTestSocket.family(), SockType::kStream); ASSERT_TRUE(send_sock); ASSERT_TRUE(recv_sock); // Set bufsize to minimum. int bufsize = 1024; ASSERT_EQ(setsockopt(send_sock.fd(), SOL_SOCKET, SO_SNDBUF, &bufsize, sizeof(bufsize)), 0); ASSERT_EQ(setsockopt(recv_sock.fd(), SOL_SOCKET, SO_RCVBUF, &bufsize, sizeof(bufsize)), 0); // Send something larger than send + recv kernel buffers combined to make // sendmsg block. char send_buf[8192]; // Make MSAN happy. for (size_t i = 0; i < sizeof(send_buf); ++i) send_buf[i] = static_cast(i % 256); char recv_buf[sizeof(send_buf)]; // Need to install signal handler to cause the interrupt to happen. // man 3 pthread_kill: // Signal dispositions are process-wide: if a signal handler is // installed, the handler will be invoked in the thread thread, but if // the disposition of the signal is "stop", "continue", or "terminate", // this action will affect the whole process. struct sigaction oldact; struct sigaction newact = {}; newact.sa_handler = [](int) {}; ASSERT_EQ(sigaction(SIGWINCH, &newact, &oldact), 0); base::ScopedResource rollback(&oldact); auto blocked_thread = pthread_self(); std::thread th([blocked_thread, &recv_sock, &recv_buf] { ssize_t rd = PERFETTO_EINTR(read(recv_sock.fd(), recv_buf, 1)); ASSERT_EQ(rd, 1); // We are now sure the other thread is in sendmsg, interrupt send. ASSERT_EQ(pthread_kill(blocked_thread, SIGWINCH), 0); // Drain the socket to allow SendMsgAllPosix to succeed. size_t offset = 1; while (offset < sizeof(recv_buf)) { rd = PERFETTO_EINTR( read(recv_sock.fd(), recv_buf + offset, sizeof(recv_buf) - offset)); ASSERT_GE(rd, 0); offset += static_cast(rd); } }); // Test sending the send_buf in several chunks as an iov to exercise the // more complicated code-paths of SendMsgAllPosix. struct msghdr hdr = {}; struct iovec iov[4]; static_assert(sizeof(send_buf) % base::ArraySize(iov) == 0, "Cannot split buffer into even pieces."); constexpr size_t kChunkSize = sizeof(send_buf) / base::ArraySize(iov); for (size_t i = 0; i < base::ArraySize(iov); ++i) { iov[i].iov_base = send_buf + i * kChunkSize; iov[i].iov_len = kChunkSize; } hdr.msg_iov = iov; hdr.msg_iovlen = base::ArraySize(iov); ASSERT_EQ(send_sock.SendMsgAllPosix(&hdr), static_cast(sizeof(send_buf))); send_sock.Shutdown(); th.join(); // Make sure the re-entry logic was actually triggered. ASSERT_EQ(hdr.msg_iov, nullptr); ASSERT_EQ(memcmp(send_buf, recv_buf, sizeof(send_buf)), 0); } #endif // !OS_WIN } // namespace } // namespace base } // namespace perfetto