// Copyright 2018 The gVisor Authors. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #include #include #include #include #include #ifdef __linux__ #include #include #endif // __linux__ #include #include #include #include #include #include "absl/strings/str_format.h" #ifndef SIOCGSTAMP #include #endif #include "gtest/gtest.h" #include "absl/base/macros.h" #include "absl/time/clock.h" #include "absl/time/time.h" #include "test/syscalls/linux/ip_socket_test_util.h" #include "test/syscalls/linux/socket_test_util.h" #include "test/syscalls/linux/unix_domain_socket_test_util.h" #include "test/util/file_descriptor.h" #include "test/util/posix_error.h" #include "test/util/test_util.h" #include "test/util/thread_util.h" namespace gvisor { namespace testing { namespace { // Fixture for tests parameterized by the address family to use (AF_INET and // AF_INET6) when creating sockets. class UdpSocketTest : public ::testing::TestWithParam { protected: // Creates two sockets that will be used by test cases. void SetUp() override; // Binds the socket bind_ to the loopback and updates bind_addr_. PosixError BindLoopback(); // Binds the socket bind_ to Any and updates bind_addr_. PosixError BindAny(); // Binds given socket to address addr and updates. PosixError BindSocket(int socket, struct sockaddr* addr); // Return initialized Any address to port 0. struct sockaddr_storage InetAnyAddr(); // Return initialized Loopback address to port 0. struct sockaddr_storage InetLoopbackAddr(); // Disconnects socket sockfd. void Disconnect(int sockfd); // Get family for the test. int GetFamily(); // Socket used by Bind methods FileDescriptor bind_; // Second socket used for tests. FileDescriptor sock_; // Address for bind_ socket. struct sockaddr* bind_addr_; // Initialized to the length based on GetFamily(). socklen_t addrlen_; // Storage for bind_addr_. struct sockaddr_storage bind_addr_storage_; private: // Helper to initialize addrlen_ for the test case. socklen_t GetAddrLength(); }; // Gets a pointer to the port component of the given address. uint16_t* Port(struct sockaddr_storage* addr) { switch (addr->ss_family) { case AF_INET: { auto sin = reinterpret_cast(addr); return &sin->sin_port; } case AF_INET6: { auto sin6 = reinterpret_cast(addr); return &sin6->sin6_port; } } return nullptr; } // Sets addr port to "port". void SetPort(struct sockaddr_storage* addr, uint16_t port) { switch (addr->ss_family) { case AF_INET: { auto sin = reinterpret_cast(addr); sin->sin_port = port; break; } case AF_INET6: { auto sin6 = reinterpret_cast(addr); sin6->sin6_port = port; break; } } } void UdpSocketTest::SetUp() { addrlen_ = GetAddrLength(); bind_ = ASSERT_NO_ERRNO_AND_VALUE(Socket(GetFamily(), SOCK_DGRAM, IPPROTO_UDP)); memset(&bind_addr_storage_, 0, sizeof(bind_addr_storage_)); bind_addr_ = reinterpret_cast(&bind_addr_storage_); sock_ = ASSERT_NO_ERRNO_AND_VALUE(Socket(GetFamily(), SOCK_DGRAM, IPPROTO_UDP)); } int UdpSocketTest::GetFamily() { if (GetParam() == AddressFamily::kIpv4) { return AF_INET; } return AF_INET6; } PosixError UdpSocketTest::BindLoopback() { bind_addr_storage_ = InetLoopbackAddr(); struct sockaddr* bind_addr_ = reinterpret_cast(&bind_addr_storage_); return BindSocket(bind_.get(), bind_addr_); } PosixError UdpSocketTest::BindAny() { bind_addr_storage_ = InetAnyAddr(); struct sockaddr* bind_addr_ = reinterpret_cast(&bind_addr_storage_); return BindSocket(bind_.get(), bind_addr_); } PosixError UdpSocketTest::BindSocket(int socket, struct sockaddr* addr) { socklen_t len = sizeof(bind_addr_storage_); // Bind, then check that we get the right address. RETURN_ERROR_IF_SYSCALL_FAIL(bind(socket, addr, addrlen_)); RETURN_ERROR_IF_SYSCALL_FAIL(getsockname(socket, addr, &len)); if (addrlen_ != len) { return PosixError( EINVAL, absl::StrFormat("getsockname len: %u expected: %u", len, addrlen_)); } return PosixError(0); } socklen_t UdpSocketTest::GetAddrLength() { struct sockaddr_storage addr; if (GetFamily() == AF_INET) { auto sin = reinterpret_cast(&addr); return sizeof(*sin); } auto sin6 = reinterpret_cast(&addr); return sizeof(*sin6); } sockaddr_storage UdpSocketTest::InetAnyAddr() { struct sockaddr_storage addr; memset(&addr, 0, sizeof(addr)); reinterpret_cast(&addr)->sa_family = GetFamily(); if (GetFamily() == AF_INET) { auto sin = reinterpret_cast(&addr); sin->sin_addr.s_addr = htonl(INADDR_ANY); sin->sin_port = htons(0); return addr; } auto sin6 = reinterpret_cast(&addr); sin6->sin6_addr = IN6ADDR_ANY_INIT; sin6->sin6_port = htons(0); return addr; } sockaddr_storage UdpSocketTest::InetLoopbackAddr() { struct sockaddr_storage addr; memset(&addr, 0, sizeof(addr)); reinterpret_cast(&addr)->sa_family = GetFamily(); if (GetFamily() == AF_INET) { auto sin = reinterpret_cast(&addr); sin->sin_addr.s_addr = htonl(INADDR_LOOPBACK); sin->sin_port = htons(0); return addr; } auto sin6 = reinterpret_cast(&addr); sin6->sin6_addr = in6addr_loopback; sin6->sin6_port = htons(0); return addr; } void UdpSocketTest::Disconnect(int sockfd) { sockaddr_storage addr_storage = InetAnyAddr(); sockaddr* addr = reinterpret_cast(&addr_storage); socklen_t addrlen = sizeof(addr_storage); addr->sa_family = AF_UNSPEC; ASSERT_THAT(connect(sockfd, addr, addrlen), SyscallSucceeds()); // Check that after disconnect the socket is bound to the ANY address. EXPECT_THAT(getsockname(sockfd, addr, &addrlen), SyscallSucceeds()); if (GetParam() == AddressFamily::kIpv4) { auto addr_out = reinterpret_cast(addr); EXPECT_EQ(addrlen, sizeof(*addr_out)); EXPECT_EQ(addr_out->sin_addr.s_addr, htonl(INADDR_ANY)); } else { auto addr_out = reinterpret_cast(addr); EXPECT_EQ(addrlen, sizeof(*addr_out)); struct in6_addr loopback = IN6ADDR_ANY_INIT; EXPECT_EQ(memcmp(&addr_out->sin6_addr, &loopback, sizeof(in6_addr)), 0); } } TEST_P(UdpSocketTest, Creation) { FileDescriptor sock = ASSERT_NO_ERRNO_AND_VALUE(Socket(GetFamily(), SOCK_DGRAM, IPPROTO_UDP)); EXPECT_THAT(close(sock.release()), SyscallSucceeds()); sock = ASSERT_NO_ERRNO_AND_VALUE(Socket(GetFamily(), SOCK_DGRAM, 0)); EXPECT_THAT(close(sock.release()), SyscallSucceeds()); ASSERT_THAT(socket(GetFamily(), SOCK_STREAM, IPPROTO_UDP), SyscallFails()); } TEST_P(UdpSocketTest, Getsockname) { // Check that we're not bound. struct sockaddr_storage addr; socklen_t addrlen = sizeof(addr); EXPECT_THAT( getsockname(bind_.get(), reinterpret_cast(&addr), &addrlen), SyscallSucceeds()); EXPECT_EQ(addrlen, addrlen_); struct sockaddr_storage any = InetAnyAddr(); EXPECT_EQ(memcmp(&addr, reinterpret_cast(&any), addrlen_), 0); ASSERT_NO_ERRNO(BindLoopback()); EXPECT_THAT( getsockname(bind_.get(), reinterpret_cast(&addr), &addrlen), SyscallSucceeds()); EXPECT_EQ(addrlen, addrlen_); EXPECT_EQ(memcmp(&addr, bind_addr_, addrlen_), 0); } TEST_P(UdpSocketTest, Getpeername) { ASSERT_NO_ERRNO(BindLoopback()); // Check that we're not connected. struct sockaddr_storage addr; socklen_t addrlen = sizeof(addr); EXPECT_THAT( getpeername(sock_.get(), reinterpret_cast(&addr), &addrlen), SyscallFailsWithErrno(ENOTCONN)); // Connect, then check that we get the right address. ASSERT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); addrlen = sizeof(addr); EXPECT_THAT( getpeername(sock_.get(), reinterpret_cast(&addr), &addrlen), SyscallSucceeds()); EXPECT_EQ(addrlen, addrlen_); EXPECT_EQ(memcmp(&addr, bind_addr_, addrlen_), 0); } TEST_P(UdpSocketTest, SendNotConnected) { ASSERT_NO_ERRNO(BindLoopback()); // Do send & write, they must fail. char buf[512]; EXPECT_THAT(send(sock_.get(), buf, sizeof(buf), 0), SyscallFailsWithErrno(EDESTADDRREQ)); EXPECT_THAT(write(sock_.get(), buf, sizeof(buf)), SyscallFailsWithErrno(EDESTADDRREQ)); // Use sendto. ASSERT_THAT(sendto(sock_.get(), buf, sizeof(buf), 0, bind_addr_, addrlen_), SyscallSucceedsWithValue(sizeof(buf))); // Check that we're bound now. struct sockaddr_storage addr; socklen_t addrlen = sizeof(addr); EXPECT_THAT( getsockname(sock_.get(), reinterpret_cast(&addr), &addrlen), SyscallSucceeds()); EXPECT_EQ(addrlen, addrlen_); EXPECT_NE(*Port(&addr), 0); } TEST_P(UdpSocketTest, ConnectBinds) { ASSERT_NO_ERRNO(BindLoopback()); // Connect the socket. ASSERT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); // Check that we're bound now. struct sockaddr_storage addr; socklen_t addrlen = sizeof(addr); EXPECT_THAT( getsockname(sock_.get(), reinterpret_cast(&addr), &addrlen), SyscallSucceeds()); EXPECT_EQ(addrlen, addrlen_); EXPECT_NE(*Port(&addr), 0); } TEST_P(UdpSocketTest, ReceiveNotBound) { char buf[512]; EXPECT_THAT(recv(sock_.get(), buf, sizeof(buf), MSG_DONTWAIT), SyscallFailsWithErrno(EWOULDBLOCK)); } TEST_P(UdpSocketTest, Bind) { ASSERT_NO_ERRNO(BindLoopback()); // Try to bind again. EXPECT_THAT(bind(bind_.get(), bind_addr_, addrlen_), SyscallFailsWithErrno(EINVAL)); // Check that we're still bound to the original address. struct sockaddr_storage addr; socklen_t addrlen = sizeof(addr); EXPECT_THAT( getsockname(bind_.get(), reinterpret_cast(&addr), &addrlen), SyscallSucceeds()); EXPECT_EQ(addrlen, addrlen_); EXPECT_EQ(memcmp(&addr, bind_addr_, addrlen_), 0); } TEST_P(UdpSocketTest, BindInUse) { ASSERT_NO_ERRNO(BindLoopback()); // Try to bind again. EXPECT_THAT(bind(sock_.get(), bind_addr_, addrlen_), SyscallFailsWithErrno(EADDRINUSE)); } TEST_P(UdpSocketTest, ConnectWriteToInvalidPort) { // Discover a free unused port by creating a new UDP socket, binding it // recording the just bound port and closing it. This is not guaranteed as it // can still race with other port UDP sockets trying to bind a port at the // same time. struct sockaddr_storage addr_storage = InetLoopbackAddr(); socklen_t addrlen = sizeof(addr_storage); struct sockaddr* addr = reinterpret_cast(&addr_storage); FileDescriptor s = ASSERT_NO_ERRNO_AND_VALUE(Socket(GetFamily(), SOCK_DGRAM, IPPROTO_UDP)); ASSERT_THAT(bind(s.get(), addr, addrlen), SyscallSucceeds()); ASSERT_THAT(getsockname(s.get(), addr, &addrlen), SyscallSucceeds()); EXPECT_EQ(addrlen, addrlen_); EXPECT_NE(*Port(&addr_storage), 0); ASSERT_THAT(close(s.release()), SyscallSucceeds()); // Now connect to the port that we just released. This should generate an // ECONNREFUSED error. ASSERT_THAT(connect(sock_.get(), addr, addrlen_), SyscallSucceeds()); char buf[512]; RandomizeBuffer(buf, sizeof(buf)); // Send from sock_ to an unbound port. ASSERT_THAT(sendto(sock_.get(), buf, sizeof(buf), 0, addr, addrlen_), SyscallSucceedsWithValue(sizeof(buf))); // Now verify that we got an ICMP error back of ECONNREFUSED. int err; socklen_t optlen = sizeof(err); ASSERT_THAT(getsockopt(sock_.get(), SOL_SOCKET, SO_ERROR, &err, &optlen), SyscallSucceeds()); ASSERT_EQ(err, ECONNREFUSED); ASSERT_EQ(optlen, sizeof(err)); } TEST_P(UdpSocketTest, ConnectSimultaneousWriteToInvalidPort) { // Discover a free unused port by creating a new UDP socket, binding it // recording the just bound port and closing it. This is not guaranteed as it // can still race with other port UDP sockets trying to bind a port at the // same time. struct sockaddr_storage addr_storage = InetLoopbackAddr(); socklen_t addrlen = sizeof(addr_storage); struct sockaddr* addr = reinterpret_cast(&addr_storage); FileDescriptor s = ASSERT_NO_ERRNO_AND_VALUE(Socket(GetFamily(), SOCK_DGRAM, IPPROTO_UDP)); ASSERT_THAT(bind(s.get(), addr, addrlen), SyscallSucceeds()); ASSERT_THAT(getsockname(s.get(), addr, &addrlen), SyscallSucceeds()); EXPECT_EQ(addrlen, addrlen_); EXPECT_NE(*Port(&addr_storage), 0); ASSERT_THAT(close(s.release()), SyscallSucceeds()); // Now connect to the port that we just released. ScopedThread t([&] { ASSERT_THAT(connect(sock_.get(), addr, addrlen_), SyscallSucceeds()); }); char buf[512]; RandomizeBuffer(buf, sizeof(buf)); // Send from sock_ to an unbound port. ASSERT_THAT(sendto(sock_.get(), buf, sizeof(buf), 0, addr, addrlen_), SyscallSucceedsWithValue(sizeof(buf))); t.Join(); } TEST_P(UdpSocketTest, ReceiveAfterConnect) { ASSERT_NO_ERRNO(BindLoopback()); ASSERT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); // Send from sock_ to bind_ char buf[512]; RandomizeBuffer(buf, sizeof(buf)); ASSERT_THAT(sendto(sock_.get(), buf, sizeof(buf), 0, bind_addr_, addrlen_), SyscallSucceedsWithValue(sizeof(buf))); // Receive the data. char received[sizeof(buf)]; EXPECT_THAT(recv(bind_.get(), received, sizeof(received), 0), SyscallSucceedsWithValue(sizeof(received))); EXPECT_EQ(memcmp(buf, received, sizeof(buf)), 0); } TEST_P(UdpSocketTest, ReceiveAfterDisconnect) { ASSERT_NO_ERRNO(BindLoopback()); for (int i = 0; i < 2; i++) { // Connet sock_ to bound address. ASSERT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); struct sockaddr_storage addr; socklen_t addrlen = sizeof(addr); EXPECT_THAT( getsockname(sock_.get(), reinterpret_cast(&addr), &addrlen), SyscallSucceeds()); EXPECT_EQ(addrlen, addrlen_); // Send from sock to bind_. char buf[512]; RandomizeBuffer(buf, sizeof(buf)); ASSERT_THAT(sendto(bind_.get(), buf, sizeof(buf), 0, reinterpret_cast(&addr), addrlen), SyscallSucceedsWithValue(sizeof(buf))); // Receive the data. char received[sizeof(buf)]; EXPECT_THAT(recv(sock_.get(), received, sizeof(received), 0), SyscallSucceedsWithValue(sizeof(received))); EXPECT_EQ(memcmp(buf, received, sizeof(buf)), 0); // Disconnect sock_. struct sockaddr unspec = {}; unspec.sa_family = AF_UNSPEC; ASSERT_THAT(connect(sock_.get(), &unspec, sizeof(unspec.sa_family)), SyscallSucceeds()); } } TEST_P(UdpSocketTest, Connect) { ASSERT_NO_ERRNO(BindLoopback()); ASSERT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); // Check that we're connected to the right peer. struct sockaddr_storage peer; socklen_t peerlen = sizeof(peer); EXPECT_THAT( getpeername(sock_.get(), reinterpret_cast(&peer), &peerlen), SyscallSucceeds()); EXPECT_EQ(peerlen, addrlen_); EXPECT_EQ(memcmp(&peer, bind_addr_, addrlen_), 0); // Try to bind after connect. struct sockaddr_storage any = InetAnyAddr(); EXPECT_THAT( bind(sock_.get(), reinterpret_cast(&any), addrlen_), SyscallFailsWithErrno(EINVAL)); struct sockaddr_storage bind2_storage = InetLoopbackAddr(); struct sockaddr* bind2_addr = reinterpret_cast(&bind2_storage); FileDescriptor bind2 = ASSERT_NO_ERRNO_AND_VALUE(Socket(GetFamily(), SOCK_DGRAM, IPPROTO_UDP)); ASSERT_NO_ERRNO(BindSocket(bind2.get(), bind2_addr)); // Try to connect again. EXPECT_THAT(connect(sock_.get(), bind2_addr, addrlen_), SyscallSucceeds()); // Check that peer name changed. peerlen = sizeof(peer); EXPECT_THAT( getpeername(sock_.get(), reinterpret_cast(&peer), &peerlen), SyscallSucceeds()); EXPECT_EQ(peerlen, addrlen_); EXPECT_EQ(memcmp(&peer, bind2_addr, addrlen_), 0); } TEST_P(UdpSocketTest, ConnectAnyZero) { // TODO(138658473): Enable when we can connect to port 0 with gVisor. SKIP_IF(IsRunningOnGvisor()); struct sockaddr_storage any = InetAnyAddr(); EXPECT_THAT( connect(sock_.get(), reinterpret_cast(&any), addrlen_), SyscallSucceeds()); struct sockaddr_storage addr; socklen_t addrlen = sizeof(addr); EXPECT_THAT( getpeername(sock_.get(), reinterpret_cast(&addr), &addrlen), SyscallFailsWithErrno(ENOTCONN)); } TEST_P(UdpSocketTest, ConnectAnyWithPort) { ASSERT_NO_ERRNO(BindAny()); ASSERT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); struct sockaddr_storage addr; socklen_t addrlen = sizeof(addr); EXPECT_THAT( getpeername(sock_.get(), reinterpret_cast(&addr), &addrlen), SyscallSucceeds()); } TEST_P(UdpSocketTest, DisconnectAfterConnectAny) { // TODO(138658473): Enable when we can connect to port 0 with gVisor. SKIP_IF(IsRunningOnGvisor()); struct sockaddr_storage any = InetAnyAddr(); EXPECT_THAT( connect(sock_.get(), reinterpret_cast(&any), addrlen_), SyscallSucceeds()); struct sockaddr_storage addr; socklen_t addrlen = sizeof(addr); EXPECT_THAT( getpeername(sock_.get(), reinterpret_cast(&addr), &addrlen), SyscallFailsWithErrno(ENOTCONN)); Disconnect(sock_.get()); } TEST_P(UdpSocketTest, DisconnectAfterConnectAnyWithPort) { ASSERT_NO_ERRNO(BindAny()); EXPECT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); struct sockaddr_storage addr; socklen_t addrlen = sizeof(addr); EXPECT_THAT( getpeername(sock_.get(), reinterpret_cast(&addr), &addrlen), SyscallSucceeds()); EXPECT_EQ(addrlen, addrlen_); EXPECT_EQ(*Port(&bind_addr_storage_), *Port(&addr)); Disconnect(sock_.get()); } TEST_P(UdpSocketTest, DisconnectAfterBind) { ASSERT_NO_ERRNO(BindLoopback()); // Bind to the next port above bind_. struct sockaddr_storage addr_storage = InetLoopbackAddr(); struct sockaddr* addr = reinterpret_cast(&addr_storage); SetPort(&addr_storage, *Port(&bind_addr_storage_) + 1); ASSERT_NO_ERRNO(BindSocket(sock_.get(), addr)); // Connect the socket. ASSERT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); struct sockaddr_storage unspec = {}; unspec.ss_family = AF_UNSPEC; EXPECT_THAT(connect(sock_.get(), reinterpret_cast(&unspec), sizeof(unspec.ss_family)), SyscallSucceeds()); // Check that we're still bound. socklen_t addrlen = sizeof(unspec); EXPECT_THAT( getsockname(sock_.get(), reinterpret_cast(&unspec), &addrlen), SyscallSucceeds()); EXPECT_EQ(addrlen, addrlen_); EXPECT_EQ(memcmp(addr, &unspec, addrlen_), 0); addrlen = sizeof(addr); EXPECT_THAT(getpeername(sock_.get(), addr, &addrlen), SyscallFailsWithErrno(ENOTCONN)); } TEST_P(UdpSocketTest, BindToAnyConnnectToLocalhost) { ASSERT_NO_ERRNO(BindAny()); struct sockaddr_storage addr_storage = InetLoopbackAddr(); struct sockaddr* addr = reinterpret_cast(&addr_storage); SetPort(&addr_storage, *Port(&bind_addr_storage_) + 1); socklen_t addrlen = sizeof(addr); // Connect the socket. ASSERT_THAT(connect(bind_.get(), addr, addrlen_), SyscallSucceeds()); EXPECT_THAT(getsockname(bind_.get(), addr, &addrlen), SyscallSucceeds()); // If the socket is bound to ANY and connected to a loopback address, // getsockname() has to return the loopback address. if (GetParam() == AddressFamily::kIpv4) { auto addr_out = reinterpret_cast(addr); EXPECT_EQ(addrlen, sizeof(*addr_out)); EXPECT_EQ(addr_out->sin_addr.s_addr, htonl(INADDR_LOOPBACK)); } else { auto addr_out = reinterpret_cast(addr); struct in6_addr loopback = IN6ADDR_LOOPBACK_INIT; EXPECT_EQ(addrlen, sizeof(*addr_out)); EXPECT_EQ(memcmp(&addr_out->sin6_addr, &loopback, sizeof(in6_addr)), 0); } } TEST_P(UdpSocketTest, DisconnectAfterBindToAny) { ASSERT_NO_ERRNO(BindLoopback()); struct sockaddr_storage any_storage = InetAnyAddr(); struct sockaddr* any = reinterpret_cast(&any_storage); SetPort(&any_storage, *Port(&bind_addr_storage_) + 1); ASSERT_NO_ERRNO(BindSocket(sock_.get(), any)); // Connect the socket. ASSERT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); Disconnect(sock_.get()); // Check that we're still bound. struct sockaddr_storage addr; socklen_t addrlen = sizeof(addr); EXPECT_THAT( getsockname(sock_.get(), reinterpret_cast(&addr), &addrlen), SyscallSucceeds()); EXPECT_EQ(addrlen, addrlen_); EXPECT_EQ(memcmp(&addr, any, addrlen), 0); addrlen = sizeof(addr); EXPECT_THAT( getpeername(sock_.get(), reinterpret_cast(&addr), &addrlen), SyscallFailsWithErrno(ENOTCONN)); } TEST_P(UdpSocketTest, Disconnect) { ASSERT_NO_ERRNO(BindLoopback()); struct sockaddr_storage any_storage = InetAnyAddr(); struct sockaddr* any = reinterpret_cast(&any_storage); SetPort(&any_storage, *Port(&bind_addr_storage_) + 1); ASSERT_NO_ERRNO(BindSocket(sock_.get(), any)); for (int i = 0; i < 2; i++) { // Try to connect again. EXPECT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); // Check that we're connected to the right peer. struct sockaddr_storage peer; socklen_t peerlen = sizeof(peer); EXPECT_THAT( getpeername(sock_.get(), reinterpret_cast(&peer), &peerlen), SyscallSucceeds()); EXPECT_EQ(peerlen, addrlen_); EXPECT_EQ(memcmp(&peer, bind_addr_, addrlen_), 0); // Try to disconnect. struct sockaddr_storage addr = {}; addr.ss_family = AF_UNSPEC; EXPECT_THAT(connect(sock_.get(), reinterpret_cast(&addr), sizeof(addr.ss_family)), SyscallSucceeds()); peerlen = sizeof(peer); EXPECT_THAT( getpeername(sock_.get(), reinterpret_cast(&peer), &peerlen), SyscallFailsWithErrno(ENOTCONN)); // Check that we're still bound. socklen_t addrlen = sizeof(addr); EXPECT_THAT( getsockname(sock_.get(), reinterpret_cast(&addr), &addrlen), SyscallSucceeds()); EXPECT_EQ(addrlen, addrlen_); EXPECT_EQ(*Port(&addr), *Port(&any_storage)); } } TEST_P(UdpSocketTest, ConnectBadAddress) { struct sockaddr addr = {}; addr.sa_family = GetFamily(); ASSERT_THAT(connect(sock_.get(), &addr, sizeof(addr.sa_family)), SyscallFailsWithErrno(EINVAL)); } TEST_P(UdpSocketTest, SendToAddressOtherThanConnected) { ASSERT_NO_ERRNO(BindLoopback()); struct sockaddr_storage addr_storage = InetAnyAddr(); struct sockaddr* addr = reinterpret_cast(&addr_storage); SetPort(&addr_storage, *Port(&bind_addr_storage_) + 1); ASSERT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); // Send to a different destination than we're connected to. char buf[512]; EXPECT_THAT(sendto(sock_.get(), buf, sizeof(buf), 0, addr, addrlen_), SyscallSucceedsWithValue(sizeof(buf))); } TEST_P(UdpSocketTest, ConnectAndSendNoReceiver) { ASSERT_NO_ERRNO(BindLoopback()); // Close the socket to release the port so that we get an ICMP error. ASSERT_THAT(close(bind_.release()), SyscallSucceeds()); // Connect to loopback:bind_addr_ which should *hopefully* not be bound by an // UDP socket. There is no easy way to ensure that the UDP port is not bound // by another conncurrently running test. *This is potentially flaky*. ASSERT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); char buf[512]; EXPECT_THAT(send(sock_.get(), buf, sizeof(buf), 0), SyscallSucceedsWithValue(sizeof(buf))); constexpr int kTimeout = 1000; // Poll to make sure we get the ICMP error back before issuing more writes. struct pollfd pfd = {sock_.get(), POLLERR, 0}; ASSERT_THAT(RetryEINTR(poll)(&pfd, 1, kTimeout), SyscallSucceedsWithValue(1)); // Next write should fail with ECONNREFUSED due to the ICMP error generated in // response to the previous write. ASSERT_THAT(send(sock_.get(), buf, sizeof(buf), 0), SyscallFailsWithErrno(ECONNREFUSED)); // The next write should succeed again since the last write call would have // retrieved and cleared the socket error. ASSERT_THAT(send(sock_.get(), buf, sizeof(buf), 0), SyscallSucceeds()); // Poll to make sure we get the ICMP error back before issuing more writes. ASSERT_THAT(RetryEINTR(poll)(&pfd, 1, kTimeout), SyscallSucceedsWithValue(1)); // Next write should fail with ECONNREFUSED due to the ICMP error generated in // response to the previous write. ASSERT_THAT(send(sock_.get(), buf, sizeof(buf), 0), SyscallFailsWithErrno(ECONNREFUSED)); } #ifdef __linux__ TEST_P(UdpSocketTest, RecvErrorConnRefused) { // We will simulate an ICMP error and verify that we do receive that error via // recvmsg(MSG_ERRQUEUE). ASSERT_NO_ERRNO(BindLoopback()); // Close the socket to release the port so that we get an ICMP error. ASSERT_THAT(close(bind_.release()), SyscallSucceeds()); // Set IP_RECVERR socket option to enable error queueing. int v = kSockOptOn; socklen_t optlen = sizeof(v); int opt_level = SOL_IP; int opt_type = IP_RECVERR; if (GetParam() != AddressFamily::kIpv4) { opt_level = SOL_IPV6; opt_type = IPV6_RECVERR; } ASSERT_THAT(setsockopt(sock_.get(), opt_level, opt_type, &v, optlen), SyscallSucceeds()); // Connect to loopback:bind_addr_ which should *hopefully* not be bound by an // UDP socket. There is no easy way to ensure that the UDP port is not bound // by another conncurrently running test. *This is potentially flaky*. const int kBufLen = 300; ASSERT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); char buf[kBufLen]; RandomizeBuffer(buf, sizeof(buf)); // Send from sock_ to an unbound port. This should cause ECONNREFUSED. EXPECT_THAT(send(sock_.get(), buf, sizeof(buf), 0), SyscallSucceedsWithValue(sizeof(buf))); // Dequeue error using recvmsg(MSG_ERRQUEUE). char got[kBufLen]; struct iovec iov; iov.iov_base = reinterpret_cast(got); iov.iov_len = kBufLen; size_t control_buf_len = CMSG_SPACE(sizeof(sock_extended_err) + addrlen_); char* control_buf = static_cast(calloc(1, control_buf_len)); struct sockaddr_storage remote; memset(&remote, 0, sizeof(remote)); struct msghdr msg = {}; msg.msg_iov = &iov; msg.msg_iovlen = 1; msg.msg_flags = 0; msg.msg_control = control_buf; msg.msg_controllen = control_buf_len; msg.msg_name = reinterpret_cast(&remote); msg.msg_namelen = addrlen_; ASSERT_THAT(recvmsg(sock_.get(), &msg, MSG_ERRQUEUE), SyscallSucceedsWithValue(kBufLen)); // Check the contents of msg. EXPECT_EQ(memcmp(got, buf, sizeof(buf)), 0); // iovec check // TODO(b/176251997): The next check fails on the gvisor platform due to the // kernel bug. if (!IsRunningWithHostinet() || GvisorPlatform() == Platform::kPtrace || GvisorPlatform() == Platform::kKVM || GvisorPlatform() == Platform::kNative) EXPECT_NE(msg.msg_flags & MSG_ERRQUEUE, 0); EXPECT_EQ(memcmp(&remote, bind_addr_, addrlen_), 0); // Check the contents of the control message. struct cmsghdr* cmsg = CMSG_FIRSTHDR(&msg); ASSERT_NE(cmsg, nullptr); EXPECT_EQ(CMSG_NXTHDR(&msg, cmsg), nullptr); EXPECT_EQ(cmsg->cmsg_level, opt_level); EXPECT_EQ(cmsg->cmsg_type, opt_type); // Check the contents of socket error. struct sock_extended_err* sock_err = (struct sock_extended_err*)CMSG_DATA(cmsg); EXPECT_EQ(sock_err->ee_errno, ECONNREFUSED); if (GetParam() == AddressFamily::kIpv4) { EXPECT_EQ(sock_err->ee_origin, SO_EE_ORIGIN_ICMP); EXPECT_EQ(sock_err->ee_type, ICMP_DEST_UNREACH); EXPECT_EQ(sock_err->ee_code, ICMP_PORT_UNREACH); } else { EXPECT_EQ(sock_err->ee_origin, SO_EE_ORIGIN_ICMP6); EXPECT_EQ(sock_err->ee_type, ICMP6_DST_UNREACH); EXPECT_EQ(sock_err->ee_code, ICMP6_DST_UNREACH_NOPORT); } // Now verify that the socket error was cleared by recvmsg(MSG_ERRQUEUE). int err; optlen = sizeof(err); ASSERT_THAT(getsockopt(sock_.get(), SOL_SOCKET, SO_ERROR, &err, &optlen), SyscallSucceeds()); ASSERT_EQ(err, 0); ASSERT_EQ(optlen, sizeof(err)); } #endif // __linux__ TEST_P(UdpSocketTest, ZerolengthWriteAllowed) { // TODO(gvisor.dev/issue/1202): Hostinet does not support zero length writes. SKIP_IF(IsRunningWithHostinet()); ASSERT_NO_ERRNO(BindLoopback()); // Connect to loopback:bind_addr_+1. struct sockaddr_storage addr_storage = InetLoopbackAddr(); struct sockaddr* addr = reinterpret_cast(&addr_storage); SetPort(&addr_storage, *Port(&bind_addr_storage_) + 1); ASSERT_THAT(connect(bind_.get(), addr, addrlen_), SyscallSucceeds()); // Bind sock to loopback:bind_addr_+1. ASSERT_THAT(bind(sock_.get(), addr, addrlen_), SyscallSucceeds()); char buf[3]; // Send zero length packet from bind_ to sock_. ASSERT_THAT(write(bind_.get(), buf, 0), SyscallSucceedsWithValue(0)); struct pollfd pfd = {sock_.get(), POLLIN, 0}; ASSERT_THAT(RetryEINTR(poll)(&pfd, 1, /*timeout*/ 1000), SyscallSucceedsWithValue(1)); // Receive the packet. char received[3]; EXPECT_THAT(read(sock_.get(), received, sizeof(received)), SyscallSucceedsWithValue(0)); } TEST_P(UdpSocketTest, ZerolengthWriteAllowedNonBlockRead) { // TODO(gvisor.dev/issue/1202): Hostinet does not support zero length writes. SKIP_IF(IsRunningWithHostinet()); ASSERT_NO_ERRNO(BindLoopback()); // Connect to loopback:bind_addr_port+1. struct sockaddr_storage addr_storage = InetLoopbackAddr(); struct sockaddr* addr = reinterpret_cast(&addr_storage); SetPort(&addr_storage, *Port(&bind_addr_storage_) + 1); ASSERT_THAT(connect(bind_.get(), addr, addrlen_), SyscallSucceeds()); // Bind sock to loopback:bind_addr_port+1. ASSERT_THAT(bind(sock_.get(), addr, addrlen_), SyscallSucceeds()); // Set sock to non-blocking. int opts = 0; ASSERT_THAT(opts = fcntl(sock_.get(), F_GETFL), SyscallSucceeds()); ASSERT_THAT(fcntl(sock_.get(), F_SETFL, opts | O_NONBLOCK), SyscallSucceeds()); char buf[3]; // Send zero length packet from bind_ to sock_. ASSERT_THAT(write(bind_.get(), buf, 0), SyscallSucceedsWithValue(0)); struct pollfd pfd = {sock_.get(), POLLIN, 0}; ASSERT_THAT(RetryEINTR(poll)(&pfd, 1, /*timeout=*/1000), SyscallSucceedsWithValue(1)); // Receive the packet. char received[3]; EXPECT_THAT(read(sock_.get(), received, sizeof(received)), SyscallSucceedsWithValue(0)); EXPECT_THAT(read(sock_.get(), received, sizeof(received)), SyscallFailsWithErrno(EAGAIN)); } TEST_P(UdpSocketTest, SendAndReceiveNotConnected) { ASSERT_NO_ERRNO(BindLoopback()); // Send some data to bind_. char buf[512]; RandomizeBuffer(buf, sizeof(buf)); ASSERT_THAT(sendto(sock_.get(), buf, sizeof(buf), 0, bind_addr_, addrlen_), SyscallSucceedsWithValue(sizeof(buf))); // Receive the data. char received[sizeof(buf)]; EXPECT_THAT(recv(bind_.get(), received, sizeof(received), 0), SyscallSucceedsWithValue(sizeof(received))); EXPECT_EQ(memcmp(buf, received, sizeof(buf)), 0); } TEST_P(UdpSocketTest, SendAndReceiveConnected) { ASSERT_NO_ERRNO(BindLoopback()); // Connect to loopback:bind_addr_port+1. struct sockaddr_storage addr_storage = InetLoopbackAddr(); struct sockaddr* addr = reinterpret_cast(&addr_storage); SetPort(&addr_storage, *Port(&bind_addr_storage_) + 1); ASSERT_THAT(connect(bind_.get(), addr, addrlen_), SyscallSucceeds()); // Bind sock to loopback:bind_addr_port+1. ASSERT_THAT(bind(sock_.get(), addr, addrlen_), SyscallSucceeds()); // Send some data from sock to bind_. char buf[512]; RandomizeBuffer(buf, sizeof(buf)); ASSERT_THAT(sendto(sock_.get(), buf, sizeof(buf), 0, bind_addr_, addrlen_), SyscallSucceedsWithValue(sizeof(buf))); // Receive the data. char received[sizeof(buf)]; EXPECT_THAT(recv(bind_.get(), received, sizeof(received), 0), SyscallSucceedsWithValue(sizeof(received))); EXPECT_EQ(memcmp(buf, received, sizeof(buf)), 0); } TEST_P(UdpSocketTest, ReceiveFromNotConnected) { ASSERT_NO_ERRNO(BindLoopback()); // Connect to loopback:bind_addr_port+1. struct sockaddr_storage addr_storage = InetLoopbackAddr(); struct sockaddr* addr = reinterpret_cast(&addr_storage); SetPort(&addr_storage, *Port(&bind_addr_storage_) + 1); ASSERT_THAT(connect(bind_.get(), addr, addrlen_), SyscallSucceeds()); // Bind sock to loopback:bind_addr_port+2. struct sockaddr_storage addr2_storage = InetLoopbackAddr(); struct sockaddr* addr2 = reinterpret_cast(&addr2_storage); SetPort(&addr2_storage, *Port(&bind_addr_storage_) + 2); ASSERT_THAT(bind(sock_.get(), addr2, addrlen_), SyscallSucceeds()); // Send some data from sock to bind_. char buf[512]; ASSERT_THAT(sendto(sock_.get(), buf, sizeof(buf), 0, bind_addr_, addrlen_), SyscallSucceedsWithValue(sizeof(buf))); // Check that the data isn't received because it was sent from a different // address than we're connected. EXPECT_THAT(recv(sock_.get(), buf, sizeof(buf), MSG_DONTWAIT), SyscallFailsWithErrno(EWOULDBLOCK)); } TEST_P(UdpSocketTest, ReceiveBeforeConnect) { ASSERT_NO_ERRNO(BindLoopback()); // Bind sock to loopback:bind_addr_port+2. struct sockaddr_storage addr2_storage = InetLoopbackAddr(); struct sockaddr* addr2 = reinterpret_cast(&addr2_storage); SetPort(&addr2_storage, *Port(&bind_addr_storage_) + 2); ASSERT_THAT(bind(sock_.get(), addr2, addrlen_), SyscallSucceeds()); // Send some data from sock to bind_. char buf[512]; RandomizeBuffer(buf, sizeof(buf)); ASSERT_THAT(sendto(sock_.get(), buf, sizeof(buf), 0, bind_addr_, addrlen_), SyscallSucceedsWithValue(sizeof(buf))); // Connect to loopback:bind_addr_port+1. struct sockaddr_storage addr_storage = InetLoopbackAddr(); struct sockaddr* addr = reinterpret_cast(&addr_storage); SetPort(&addr_storage, *Port(&bind_addr_storage_) + 1); ASSERT_THAT(connect(bind_.get(), addr, addrlen_), SyscallSucceeds()); // Receive the data. It works because it was sent before the connect. char received[sizeof(buf)]; EXPECT_THAT( RecvTimeout(bind_.get(), received, sizeof(received), 1 /*timeout*/), IsPosixErrorOkAndHolds(sizeof(received))); EXPECT_EQ(memcmp(buf, received, sizeof(buf)), 0); // Send again. This time it should not be received. ASSERT_THAT(sendto(sock_.get(), buf, sizeof(buf), 0, bind_addr_, addrlen_), SyscallSucceedsWithValue(sizeof(buf))); EXPECT_THAT(recv(bind_.get(), buf, sizeof(buf), MSG_DONTWAIT), SyscallFailsWithErrno(EWOULDBLOCK)); } TEST_P(UdpSocketTest, ReceiveFrom) { ASSERT_NO_ERRNO(BindLoopback()); // Connect to loopback:bind_addr_port+1. struct sockaddr_storage addr_storage = InetLoopbackAddr(); struct sockaddr* addr = reinterpret_cast(&addr_storage); SetPort(&addr_storage, *Port(&bind_addr_storage_) + 1); ASSERT_THAT(connect(bind_.get(), addr, addrlen_), SyscallSucceeds()); // Bind sock to loopback:bind_addr_port+1. ASSERT_THAT(bind(sock_.get(), addr, addrlen_), SyscallSucceeds()); // Send some data from sock to bind_. char buf[512]; RandomizeBuffer(buf, sizeof(buf)); ASSERT_THAT(sendto(sock_.get(), buf, sizeof(buf), 0, bind_addr_, addrlen_), SyscallSucceedsWithValue(sizeof(buf))); // Receive the data and sender address. char received[sizeof(buf)]; struct sockaddr_storage addr2; socklen_t addr2len = sizeof(addr2); EXPECT_THAT(recvfrom(bind_.get(), received, sizeof(received), 0, reinterpret_cast(&addr2), &addr2len), SyscallSucceedsWithValue(sizeof(received))); EXPECT_EQ(memcmp(buf, received, sizeof(buf)), 0); EXPECT_EQ(addr2len, addrlen_); EXPECT_EQ(memcmp(addr, &addr2, addrlen_), 0); } TEST_P(UdpSocketTest, Listen) { ASSERT_THAT(listen(sock_.get(), SOMAXCONN), SyscallFailsWithErrno(EOPNOTSUPP)); } TEST_P(UdpSocketTest, Accept) { ASSERT_THAT(accept(sock_.get(), nullptr, nullptr), SyscallFailsWithErrno(EOPNOTSUPP)); } // This test validates that a read shutdown with pending data allows the read // to proceed with the data before returning EAGAIN. TEST_P(UdpSocketTest, ReadShutdownNonblockPendingData) { ASSERT_NO_ERRNO(BindLoopback()); // Connect to loopback:bind_addr_port+1. struct sockaddr_storage addr_storage = InetLoopbackAddr(); struct sockaddr* addr = reinterpret_cast(&addr_storage); SetPort(&addr_storage, *Port(&bind_addr_storage_) + 1); ASSERT_THAT(connect(bind_.get(), addr, addrlen_), SyscallSucceeds()); // Bind to loopback:bind_addr_port+1 and connect to bind_addr_. ASSERT_THAT(bind(sock_.get(), addr, addrlen_), SyscallSucceeds()); ASSERT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); // Verify that we get EWOULDBLOCK when there is nothing to read. char received[512]; EXPECT_THAT(recv(bind_.get(), received, sizeof(received), MSG_DONTWAIT), SyscallFailsWithErrno(EWOULDBLOCK)); const char* buf = "abc"; EXPECT_THAT(write(sock_.get(), buf, 3), SyscallSucceedsWithValue(3)); int opts = 0; ASSERT_THAT(opts = fcntl(bind_.get(), F_GETFL), SyscallSucceeds()); ASSERT_THAT(fcntl(bind_.get(), F_SETFL, opts | O_NONBLOCK), SyscallSucceeds()); ASSERT_THAT(opts = fcntl(bind_.get(), F_GETFL), SyscallSucceeds()); ASSERT_NE(opts & O_NONBLOCK, 0); EXPECT_THAT(shutdown(bind_.get(), SHUT_RD), SyscallSucceeds()); struct pollfd pfd = {bind_.get(), POLLIN, 0}; ASSERT_THAT(RetryEINTR(poll)(&pfd, 1, /*timeout=*/1000), SyscallSucceedsWithValue(1)); // We should get the data even though read has been shutdown. EXPECT_THAT(RecvTimeout(bind_.get(), received, 2 /*buf_size*/, 1 /*timeout*/), IsPosixErrorOkAndHolds(2)); // Because we read less than the entire packet length, since it's a packet // based socket any subsequent reads should return EWOULDBLOCK. EXPECT_THAT(recv(bind_.get(), received, 1, 0), SyscallFailsWithErrno(EWOULDBLOCK)); } // This test is validating that even after a socket is shutdown if it's // reconnected it will reset the shutdown state. TEST_P(UdpSocketTest, ReadShutdownSameSocketResetsShutdownState) { char received[512]; EXPECT_THAT(recv(bind_.get(), received, sizeof(received), MSG_DONTWAIT), SyscallFailsWithErrno(EWOULDBLOCK)); EXPECT_THAT(shutdown(bind_.get(), SHUT_RD), SyscallFailsWithErrno(ENOTCONN)); EXPECT_THAT(recv(bind_.get(), received, sizeof(received), MSG_DONTWAIT), SyscallFailsWithErrno(EWOULDBLOCK)); // Connect the socket, then try to shutdown again. ASSERT_NO_ERRNO(BindLoopback()); // Connect to loopback:bind_addr_port+1. struct sockaddr_storage addr_storage = InetLoopbackAddr(); struct sockaddr* addr = reinterpret_cast(&addr_storage); SetPort(&addr_storage, *Port(&bind_addr_storage_) + 1); ASSERT_THAT(connect(bind_.get(), addr, addrlen_), SyscallSucceeds()); EXPECT_THAT(recv(bind_.get(), received, sizeof(received), MSG_DONTWAIT), SyscallFailsWithErrno(EWOULDBLOCK)); } TEST_P(UdpSocketTest, ReadShutdown) { // TODO(gvisor.dev/issue/1202): Calling recv() after shutdown without // MSG_DONTWAIT blocks indefinitely. SKIP_IF(IsRunningWithHostinet()); ASSERT_NO_ERRNO(BindLoopback()); char received[512]; EXPECT_THAT(recv(sock_.get(), received, sizeof(received), MSG_DONTWAIT), SyscallFailsWithErrno(EWOULDBLOCK)); EXPECT_THAT(shutdown(sock_.get(), SHUT_RD), SyscallFailsWithErrno(ENOTCONN)); EXPECT_THAT(recv(sock_.get(), received, sizeof(received), MSG_DONTWAIT), SyscallFailsWithErrno(EWOULDBLOCK)); // Connect the socket, then try to shutdown again. ASSERT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); EXPECT_THAT(recv(sock_.get(), received, sizeof(received), MSG_DONTWAIT), SyscallFailsWithErrno(EWOULDBLOCK)); EXPECT_THAT(shutdown(sock_.get(), SHUT_RD), SyscallSucceeds()); EXPECT_THAT(recv(sock_.get(), received, sizeof(received), 0), SyscallSucceedsWithValue(0)); } TEST_P(UdpSocketTest, ReadShutdownDifferentThread) { // TODO(gvisor.dev/issue/1202): Calling recv() after shutdown without // MSG_DONTWAIT blocks indefinitely. SKIP_IF(IsRunningWithHostinet()); ASSERT_NO_ERRNO(BindLoopback()); char received[512]; EXPECT_THAT(recv(sock_.get(), received, sizeof(received), MSG_DONTWAIT), SyscallFailsWithErrno(EWOULDBLOCK)); // Connect the socket, then shutdown from another thread. ASSERT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); EXPECT_THAT(recv(sock_.get(), received, sizeof(received), MSG_DONTWAIT), SyscallFailsWithErrno(EWOULDBLOCK)); ScopedThread t([&] { absl::SleepFor(absl::Milliseconds(200)); EXPECT_THAT(shutdown(sock_.get(), SHUT_RD), SyscallSucceeds()); }); EXPECT_THAT(RetryEINTR(recv)(sock_.get(), received, sizeof(received), 0), SyscallSucceedsWithValue(0)); t.Join(); EXPECT_THAT(RetryEINTR(recv)(sock_.get(), received, sizeof(received), 0), SyscallSucceedsWithValue(0)); } TEST_P(UdpSocketTest, WriteShutdown) { ASSERT_NO_ERRNO(BindLoopback()); EXPECT_THAT(shutdown(sock_.get(), SHUT_WR), SyscallFailsWithErrno(ENOTCONN)); ASSERT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); EXPECT_THAT(shutdown(sock_.get(), SHUT_WR), SyscallSucceeds()); } TEST_P(UdpSocketTest, SynchronousReceive) { ASSERT_NO_ERRNO(BindLoopback()); // Send some data to bind_ from another thread. char buf[512]; RandomizeBuffer(buf, sizeof(buf)); // Receive the data prior to actually starting the other thread. char received[512]; EXPECT_THAT( RetryEINTR(recv)(bind_.get(), received, sizeof(received), MSG_DONTWAIT), SyscallFailsWithErrno(EWOULDBLOCK)); // Start the thread. ScopedThread t([&] { absl::SleepFor(absl::Milliseconds(200)); ASSERT_THAT(sendto(sock_.get(), buf, sizeof(buf), 0, this->bind_addr_, this->addrlen_), SyscallSucceedsWithValue(sizeof(buf))); }); EXPECT_THAT(RetryEINTR(recv)(bind_.get(), received, sizeof(received), 0), SyscallSucceedsWithValue(512)); EXPECT_EQ(memcmp(buf, received, sizeof(buf)), 0); } TEST_P(UdpSocketTest, BoundaryPreserved_SendRecv) { ASSERT_NO_ERRNO(BindLoopback()); // Send 3 packets from sock to bind_. constexpr int psize = 100; char buf[3 * psize]; RandomizeBuffer(buf, sizeof(buf)); for (int i = 0; i < 3; ++i) { ASSERT_THAT( sendto(sock_.get(), buf + i * psize, psize, 0, bind_addr_, addrlen_), SyscallSucceedsWithValue(psize)); } // Receive the data as 3 separate packets. char received[6 * psize]; for (int i = 0; i < 3; ++i) { EXPECT_THAT(recv(bind_.get(), received + i * psize, 3 * psize, 0), SyscallSucceedsWithValue(psize)); } EXPECT_EQ(memcmp(buf, received, 3 * psize), 0); } TEST_P(UdpSocketTest, BoundaryPreserved_WritevReadv) { ASSERT_NO_ERRNO(BindLoopback()); // Direct writes from sock to bind_. ASSERT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); // Send 2 packets from sock to bind_, where each packet's data consists of // 2 discontiguous iovecs. constexpr size_t kPieceSize = 100; char buf[4 * kPieceSize]; RandomizeBuffer(buf, sizeof(buf)); for (int i = 0; i < 2; i++) { struct iovec iov[2]; for (int j = 0; j < 2; j++) { iov[j].iov_base = reinterpret_cast( reinterpret_cast(buf) + (i + 2 * j) * kPieceSize); iov[j].iov_len = kPieceSize; } ASSERT_THAT(writev(sock_.get(), iov, 2), SyscallSucceedsWithValue(2 * kPieceSize)); } // Receive the data as 2 separate packets. char received[6 * kPieceSize]; for (int i = 0; i < 2; i++) { struct iovec iov[3]; for (int j = 0; j < 3; j++) { iov[j].iov_base = reinterpret_cast( reinterpret_cast(received) + (i + 2 * j) * kPieceSize); iov[j].iov_len = kPieceSize; } ASSERT_THAT(readv(bind_.get(), iov, 3), SyscallSucceedsWithValue(2 * kPieceSize)); } EXPECT_EQ(memcmp(buf, received, 4 * kPieceSize), 0); } TEST_P(UdpSocketTest, BoundaryPreserved_SendMsgRecvMsg) { ASSERT_NO_ERRNO(BindLoopback()); // Send 2 packets from sock to bind_, where each packet's data consists of // 2 discontiguous iovecs. constexpr size_t kPieceSize = 100; char buf[4 * kPieceSize]; RandomizeBuffer(buf, sizeof(buf)); for (int i = 0; i < 2; i++) { struct iovec iov[2]; for (int j = 0; j < 2; j++) { iov[j].iov_base = reinterpret_cast( reinterpret_cast(buf) + (i + 2 * j) * kPieceSize); iov[j].iov_len = kPieceSize; } struct msghdr msg = {}; msg.msg_name = bind_addr_; msg.msg_namelen = addrlen_; msg.msg_iov = iov; msg.msg_iovlen = 2; ASSERT_THAT(sendmsg(sock_.get(), &msg, 0), SyscallSucceedsWithValue(2 * kPieceSize)); } // Receive the data as 2 separate packets. char received[6 * kPieceSize]; for (int i = 0; i < 2; i++) { struct iovec iov[3]; for (int j = 0; j < 3; j++) { iov[j].iov_base = reinterpret_cast( reinterpret_cast(received) + (i + 2 * j) * kPieceSize); iov[j].iov_len = kPieceSize; } struct msghdr msg = {}; msg.msg_iov = iov; msg.msg_iovlen = 3; ASSERT_THAT(recvmsg(bind_.get(), &msg, 0), SyscallSucceedsWithValue(2 * kPieceSize)); } EXPECT_EQ(memcmp(buf, received, 4 * kPieceSize), 0); } TEST_P(UdpSocketTest, FIONREADShutdown) { ASSERT_NO_ERRNO(BindLoopback()); int n = -1; EXPECT_THAT(ioctl(sock_.get(), FIONREAD, &n), SyscallSucceedsWithValue(0)); EXPECT_EQ(n, 0); // A UDP socket must be connected before it can be shutdown. ASSERT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); n = -1; EXPECT_THAT(ioctl(sock_.get(), FIONREAD, &n), SyscallSucceedsWithValue(0)); EXPECT_EQ(n, 0); EXPECT_THAT(shutdown(sock_.get(), SHUT_RD), SyscallSucceeds()); n = -1; EXPECT_THAT(ioctl(sock_.get(), FIONREAD, &n), SyscallSucceedsWithValue(0)); EXPECT_EQ(n, 0); } TEST_P(UdpSocketTest, FIONREADWriteShutdown) { int n = -1; EXPECT_THAT(ioctl(bind_.get(), FIONREAD, &n), SyscallSucceedsWithValue(0)); EXPECT_EQ(n, 0); ASSERT_NO_ERRNO(BindLoopback()); // A UDP socket must be connected before it can be shutdown. ASSERT_THAT(connect(bind_.get(), bind_addr_, addrlen_), SyscallSucceeds()); n = -1; EXPECT_THAT(ioctl(bind_.get(), FIONREAD, &n), SyscallSucceedsWithValue(0)); EXPECT_EQ(n, 0); const char str[] = "abc"; ASSERT_THAT(send(bind_.get(), str, sizeof(str), 0), SyscallSucceedsWithValue(sizeof(str))); struct pollfd pfd = {bind_.get(), POLLIN, 0}; ASSERT_THAT(RetryEINTR(poll)(&pfd, 1, /*timeout=*/1000), SyscallSucceedsWithValue(1)); n = -1; EXPECT_THAT(ioctl(bind_.get(), FIONREAD, &n), SyscallSucceedsWithValue(0)); EXPECT_EQ(n, sizeof(str)); EXPECT_THAT(shutdown(bind_.get(), SHUT_RD), SyscallSucceeds()); n = -1; EXPECT_THAT(ioctl(bind_.get(), FIONREAD, &n), SyscallSucceedsWithValue(0)); EXPECT_EQ(n, sizeof(str)); } // NOTE: Do not use `FIONREAD` as test name because it will be replaced by the // corresponding macro and become `0x541B`. TEST_P(UdpSocketTest, Fionread) { ASSERT_NO_ERRNO(BindLoopback()); // Check that the bound socket with an empty buffer reports an empty first // packet. int n = -1; EXPECT_THAT(ioctl(bind_.get(), FIONREAD, &n), SyscallSucceedsWithValue(0)); EXPECT_EQ(n, 0); // Send 3 packets from sock to bind_. constexpr int psize = 100; char buf[3 * psize]; RandomizeBuffer(buf, sizeof(buf)); struct pollfd pfd = {bind_.get(), POLLIN, 0}; for (int i = 0; i < 3; ++i) { ASSERT_THAT( sendto(sock_.get(), buf + i * psize, psize, 0, bind_addr_, addrlen_), SyscallSucceedsWithValue(psize)); ASSERT_THAT(RetryEINTR(poll)(&pfd, 1, /*timeout=*/1000), SyscallSucceedsWithValue(1)); // Check that regardless of how many packets are in the queue, the size // reported is that of a single packet. n = -1; EXPECT_THAT(ioctl(bind_.get(), FIONREAD, &n), SyscallSucceedsWithValue(0)); EXPECT_EQ(n, psize); } } TEST_P(UdpSocketTest, FIONREADZeroLengthPacket) { ASSERT_NO_ERRNO(BindLoopback()); // Check that the bound socket with an empty buffer reports an empty first // packet. int n = -1; EXPECT_THAT(ioctl(bind_.get(), FIONREAD, &n), SyscallSucceedsWithValue(0)); EXPECT_EQ(n, 0); // Send 3 packets from sock to bind_. constexpr int psize = 100; char buf[3 * psize]; RandomizeBuffer(buf, sizeof(buf)); struct pollfd pfd = {bind_.get(), POLLIN, 0}; for (int i = 0; i < 3; ++i) { ASSERT_THAT( sendto(sock_.get(), buf + i * psize, 0, 0, bind_addr_, addrlen_), SyscallSucceedsWithValue(0)); // TODO(gvisor.dev/issue/2726): sending a zero-length message to a hostinet // socket does not cause a poll event to be triggered. if (!IsRunningWithHostinet()) { ASSERT_THAT(RetryEINTR(poll)(&pfd, 1, /*timeout=*/1000), SyscallSucceedsWithValue(1)); } // Check that regardless of how many packets are in the queue, the size // reported is that of a single packet. n = -1; EXPECT_THAT(ioctl(bind_.get(), FIONREAD, &n), SyscallSucceedsWithValue(0)); EXPECT_EQ(n, 0); } } TEST_P(UdpSocketTest, FIONREADZeroLengthWriteShutdown) { int n = -1; EXPECT_THAT(ioctl(bind_.get(), FIONREAD, &n), SyscallSucceedsWithValue(0)); EXPECT_EQ(n, 0); ASSERT_NO_ERRNO(BindLoopback()); // A UDP socket must be connected before it can be shutdown. ASSERT_THAT(connect(bind_.get(), bind_addr_, addrlen_), SyscallSucceeds()); n = -1; EXPECT_THAT(ioctl(bind_.get(), FIONREAD, &n), SyscallSucceedsWithValue(0)); EXPECT_EQ(n, 0); const char str[] = "abc"; ASSERT_THAT(send(bind_.get(), str, 0, 0), SyscallSucceedsWithValue(0)); n = -1; EXPECT_THAT(ioctl(bind_.get(), FIONREAD, &n), SyscallSucceedsWithValue(0)); EXPECT_EQ(n, 0); EXPECT_THAT(shutdown(bind_.get(), SHUT_RD), SyscallSucceeds()); n = -1; EXPECT_THAT(ioctl(bind_.get(), FIONREAD, &n), SyscallSucceedsWithValue(0)); EXPECT_EQ(n, 0); } TEST_P(UdpSocketTest, SoNoCheckOffByDefault) { // TODO(gvisor.dev/issue/1202): SO_NO_CHECK socket option not supported by // hostinet. SKIP_IF(IsRunningWithHostinet()); int v = -1; socklen_t optlen = sizeof(v); ASSERT_THAT(getsockopt(bind_.get(), SOL_SOCKET, SO_NO_CHECK, &v, &optlen), SyscallSucceeds()); ASSERT_EQ(v, kSockOptOff); ASSERT_EQ(optlen, sizeof(v)); } TEST_P(UdpSocketTest, SoNoCheck) { // TODO(gvisor.dev/issue/1202): SO_NO_CHECK socket option not supported by // hostinet. SKIP_IF(IsRunningWithHostinet()); int v = kSockOptOn; socklen_t optlen = sizeof(v); ASSERT_THAT(setsockopt(bind_.get(), SOL_SOCKET, SO_NO_CHECK, &v, optlen), SyscallSucceeds()); v = -1; ASSERT_THAT(getsockopt(bind_.get(), SOL_SOCKET, SO_NO_CHECK, &v, &optlen), SyscallSucceeds()); ASSERT_EQ(v, kSockOptOn); ASSERT_EQ(optlen, sizeof(v)); v = kSockOptOff; ASSERT_THAT(setsockopt(bind_.get(), SOL_SOCKET, SO_NO_CHECK, &v, optlen), SyscallSucceeds()); v = -1; ASSERT_THAT(getsockopt(bind_.get(), SOL_SOCKET, SO_NO_CHECK, &v, &optlen), SyscallSucceeds()); ASSERT_EQ(v, kSockOptOff); ASSERT_EQ(optlen, sizeof(v)); } #ifdef __linux__ TEST_P(UdpSocketTest, ErrorQueue) { char cmsgbuf[CMSG_SPACE(sizeof(sock_extended_err))]; msghdr msg; memset(&msg, 0, sizeof(msg)); iovec iov; memset(&iov, 0, sizeof(iov)); msg.msg_iov = &iov; msg.msg_iovlen = 1; msg.msg_control = cmsgbuf; msg.msg_controllen = sizeof(cmsgbuf); // recv*(MSG_ERRQUEUE) never blocks, even without MSG_DONTWAIT. EXPECT_THAT(RetryEINTR(recvmsg)(bind_.get(), &msg, MSG_ERRQUEUE), SyscallFailsWithErrno(EAGAIN)); } #endif // __linux__ TEST_P(UdpSocketTest, SoTimestampOffByDefault) { // TODO(gvisor.dev/issue/1202): SO_TIMESTAMP socket option not supported by // hostinet. SKIP_IF(IsRunningWithHostinet()); int v = -1; socklen_t optlen = sizeof(v); ASSERT_THAT(getsockopt(bind_.get(), SOL_SOCKET, SO_TIMESTAMP, &v, &optlen), SyscallSucceeds()); ASSERT_EQ(v, kSockOptOff); ASSERT_EQ(optlen, sizeof(v)); } TEST_P(UdpSocketTest, SoTimestamp) { // TODO(gvisor.dev/issue/1202): ioctl() and SO_TIMESTAMP socket option are not // supported by hostinet. SKIP_IF(IsRunningWithHostinet()); ASSERT_NO_ERRNO(BindLoopback()); ASSERT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); int v = 1; ASSERT_THAT(setsockopt(bind_.get(), SOL_SOCKET, SO_TIMESTAMP, &v, sizeof(v)), SyscallSucceeds()); char buf[3]; // Send zero length packet from sock to bind_. ASSERT_THAT(RetryEINTR(write)(sock_.get(), buf, 0), SyscallSucceedsWithValue(0)); struct pollfd pfd = {bind_.get(), POLLIN, 0}; ASSERT_THAT(RetryEINTR(poll)(&pfd, 1, /*timeout=*/1000), SyscallSucceedsWithValue(1)); char cmsgbuf[CMSG_SPACE(sizeof(struct timeval))]; msghdr msg; memset(&msg, 0, sizeof(msg)); iovec iov; memset(&iov, 0, sizeof(iov)); msg.msg_iov = &iov; msg.msg_iovlen = 1; msg.msg_control = cmsgbuf; msg.msg_controllen = sizeof(cmsgbuf); ASSERT_THAT(RetryEINTR(recvmsg)(bind_.get(), &msg, 0), SyscallSucceedsWithValue(0)); struct cmsghdr* cmsg = CMSG_FIRSTHDR(&msg); ASSERT_NE(cmsg, nullptr); ASSERT_EQ(cmsg->cmsg_level, SOL_SOCKET); ASSERT_EQ(cmsg->cmsg_type, SO_TIMESTAMP); ASSERT_EQ(cmsg->cmsg_len, CMSG_LEN(sizeof(struct timeval))); struct timeval tv = {}; memcpy(&tv, CMSG_DATA(cmsg), sizeof(struct timeval)); ASSERT_TRUE(tv.tv_sec != 0 || tv.tv_usec != 0); // There should be nothing to get via ioctl. ASSERT_THAT(ioctl(bind_.get(), SIOCGSTAMP, &tv), SyscallFailsWithErrno(ENOENT)); } TEST_P(UdpSocketTest, WriteShutdownNotConnected) { EXPECT_THAT(shutdown(bind_.get(), SHUT_WR), SyscallFailsWithErrno(ENOTCONN)); } TEST_P(UdpSocketTest, TimestampIoctl) { // TODO(gvisor.dev/issue/1202): ioctl() is not supported by hostinet. SKIP_IF(IsRunningWithHostinet()); ASSERT_NO_ERRNO(BindLoopback()); ASSERT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); char buf[3]; // Send packet from sock to bind_. ASSERT_THAT(RetryEINTR(write)(sock_.get(), buf, sizeof(buf)), SyscallSucceedsWithValue(sizeof(buf))); struct pollfd pfd = {bind_.get(), POLLIN, 0}; ASSERT_THAT(RetryEINTR(poll)(&pfd, 1, /*timeout=*/1000), SyscallSucceedsWithValue(1)); // There should be no control messages. char recv_buf[sizeof(buf)]; ASSERT_NO_FATAL_FAILURE(RecvNoCmsg(bind_.get(), recv_buf, sizeof(recv_buf))); // A nonzero timeval should be available via ioctl. struct timeval tv = {}; ASSERT_THAT(ioctl(bind_.get(), SIOCGSTAMP, &tv), SyscallSucceeds()); ASSERT_TRUE(tv.tv_sec != 0 || tv.tv_usec != 0); } TEST_P(UdpSocketTest, TimestampIoctlNothingRead) { // TODO(gvisor.dev/issue/1202): ioctl() is not supported by hostinet. SKIP_IF(IsRunningWithHostinet()); ASSERT_NO_ERRNO(BindLoopback()); ASSERT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); struct timeval tv = {}; ASSERT_THAT(ioctl(sock_.get(), SIOCGSTAMP, &tv), SyscallFailsWithErrno(ENOENT)); } // Test that the timestamp accessed via SIOCGSTAMP is still accessible after // SO_TIMESTAMP is enabled and used to retrieve a timestamp. TEST_P(UdpSocketTest, TimestampIoctlPersistence) { // TODO(gvisor.dev/issue/1202): ioctl() and SO_TIMESTAMP socket option are not // supported by hostinet. SKIP_IF(IsRunningWithHostinet()); ASSERT_NO_ERRNO(BindLoopback()); ASSERT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); char buf[3]; // Send packet from sock to bind_. ASSERT_THAT(RetryEINTR(write)(sock_.get(), buf, sizeof(buf)), SyscallSucceedsWithValue(sizeof(buf))); ASSERT_THAT(RetryEINTR(write)(sock_.get(), buf, 0), SyscallSucceedsWithValue(0)); struct pollfd pfd = {bind_.get(), POLLIN, 0}; ASSERT_THAT(RetryEINTR(poll)(&pfd, 1, /*timeout=*/1000), SyscallSucceedsWithValue(1)); // There should be no control messages. char recv_buf[sizeof(buf)]; ASSERT_NO_FATAL_FAILURE(RecvNoCmsg(bind_.get(), recv_buf, sizeof(recv_buf))); // A nonzero timeval should be available via ioctl. struct timeval tv = {}; ASSERT_THAT(ioctl(bind_.get(), SIOCGSTAMP, &tv), SyscallSucceeds()); ASSERT_TRUE(tv.tv_sec != 0 || tv.tv_usec != 0); // Enable SO_TIMESTAMP and send a message. int v = 1; EXPECT_THAT(setsockopt(bind_.get(), SOL_SOCKET, SO_TIMESTAMP, &v, sizeof(v)), SyscallSucceeds()); ASSERT_THAT(RetryEINTR(write)(sock_.get(), buf, 0), SyscallSucceedsWithValue(0)); ASSERT_THAT(RetryEINTR(poll)(&pfd, 1, /*timeout=*/1000), SyscallSucceedsWithValue(1)); // There should be a message for SO_TIMESTAMP. char cmsgbuf[CMSG_SPACE(sizeof(struct timeval))]; msghdr msg = {}; iovec iov = {}; msg.msg_iov = &iov; msg.msg_iovlen = 1; msg.msg_control = cmsgbuf; msg.msg_controllen = sizeof(cmsgbuf); ASSERT_THAT(RetryEINTR(recvmsg)(bind_.get(), &msg, 0), SyscallSucceedsWithValue(0)); struct cmsghdr* cmsg = CMSG_FIRSTHDR(&msg); ASSERT_NE(cmsg, nullptr); // The ioctl should return the exact same values as before. struct timeval tv2 = {}; ASSERT_THAT(ioctl(bind_.get(), SIOCGSTAMP, &tv2), SyscallSucceeds()); ASSERT_EQ(tv.tv_sec, tv2.tv_sec); ASSERT_EQ(tv.tv_usec, tv2.tv_usec); } // Test that a socket with IP_TOS or IPV6_TCLASS set will set the TOS byte on // outgoing packets, and that a receiving socket with IP_RECVTOS or // IPV6_RECVTCLASS will create the corresponding control message. TEST_P(UdpSocketTest, SetAndReceiveTOS) { ASSERT_NO_ERRNO(BindLoopback()); ASSERT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); // Allow socket to receive control message. int recv_level = SOL_IP; int recv_type = IP_RECVTOS; if (GetParam() != AddressFamily::kIpv4) { recv_level = SOL_IPV6; recv_type = IPV6_RECVTCLASS; } ASSERT_THAT(setsockopt(bind_.get(), recv_level, recv_type, &kSockOptOn, sizeof(kSockOptOn)), SyscallSucceeds()); // Set socket TOS. int sent_level = recv_level; int sent_type = IP_TOS; if (sent_level == SOL_IPV6) { sent_type = IPV6_TCLASS; } int sent_tos = IPTOS_LOWDELAY; // Choose some TOS value. ASSERT_THAT(setsockopt(sock_.get(), sent_level, sent_type, &sent_tos, sizeof(sent_tos)), SyscallSucceeds()); // Prepare message to send. constexpr size_t kDataLength = 1024; struct msghdr sent_msg = {}; struct iovec sent_iov = {}; char sent_data[kDataLength]; sent_iov.iov_base = &sent_data[0]; sent_iov.iov_len = kDataLength; sent_msg.msg_iov = &sent_iov; sent_msg.msg_iovlen = 1; ASSERT_THAT(RetryEINTR(sendmsg)(sock_.get(), &sent_msg, 0), SyscallSucceedsWithValue(kDataLength)); // Receive message. struct msghdr received_msg = {}; struct iovec received_iov = {}; char received_data[kDataLength]; received_iov.iov_base = &received_data[0]; received_iov.iov_len = kDataLength; received_msg.msg_iov = &received_iov; received_msg.msg_iovlen = 1; size_t cmsg_data_len = sizeof(int8_t); if (sent_type == IPV6_TCLASS) { cmsg_data_len = sizeof(int); } std::vector received_cmsgbuf(CMSG_SPACE(cmsg_data_len)); received_msg.msg_control = &received_cmsgbuf[0]; received_msg.msg_controllen = received_cmsgbuf.size(); ASSERT_THAT(RetryEINTR(recvmsg)(bind_.get(), &received_msg, 0), SyscallSucceedsWithValue(kDataLength)); struct cmsghdr* cmsg = CMSG_FIRSTHDR(&received_msg); ASSERT_NE(cmsg, nullptr); EXPECT_EQ(cmsg->cmsg_len, CMSG_LEN(cmsg_data_len)); EXPECT_EQ(cmsg->cmsg_level, sent_level); EXPECT_EQ(cmsg->cmsg_type, sent_type); int8_t received_tos = 0; memcpy(&received_tos, CMSG_DATA(cmsg), sizeof(received_tos)); EXPECT_EQ(received_tos, sent_tos); } // Test that sendmsg with IP_TOS and IPV6_TCLASS control messages will set the // TOS byte on outgoing packets, and that a receiving socket with IP_RECVTOS or // IPV6_RECVTCLASS will create the corresponding control message. TEST_P(UdpSocketTest, SendAndReceiveTOS) { // TODO(b/146661005): Setting TOS via cmsg not supported for netstack. SKIP_IF(IsRunningOnGvisor() && !IsRunningWithHostinet()); ASSERT_NO_ERRNO(BindLoopback()); ASSERT_THAT(connect(sock_.get(), bind_addr_, addrlen_), SyscallSucceeds()); // Allow socket to receive control message. int recv_level = SOL_IP; int recv_type = IP_RECVTOS; if (GetParam() != AddressFamily::kIpv4) { recv_level = SOL_IPV6; recv_type = IPV6_RECVTCLASS; } int recv_opt = kSockOptOn; ASSERT_THAT(setsockopt(bind_.get(), recv_level, recv_type, &recv_opt, sizeof(recv_opt)), SyscallSucceeds()); // Prepare message to send. constexpr size_t kDataLength = 1024; int sent_level = recv_level; int sent_type = IP_TOS; int sent_tos = IPTOS_LOWDELAY; // Choose some TOS value. struct msghdr sent_msg = {}; struct iovec sent_iov = {}; char sent_data[kDataLength]; sent_iov.iov_base = &sent_data[0]; sent_iov.iov_len = kDataLength; sent_msg.msg_iov = &sent_iov; sent_msg.msg_iovlen = 1; size_t cmsg_data_len = sizeof(int8_t); if (sent_level == SOL_IPV6) { sent_type = IPV6_TCLASS; cmsg_data_len = sizeof(int); } std::vector sent_cmsgbuf(CMSG_SPACE(cmsg_data_len)); sent_msg.msg_control = &sent_cmsgbuf[0]; sent_msg.msg_controllen = CMSG_LEN(cmsg_data_len); // Manually add control message. struct cmsghdr* sent_cmsg = CMSG_FIRSTHDR(&sent_msg); sent_cmsg->cmsg_len = CMSG_LEN(cmsg_data_len); sent_cmsg->cmsg_level = sent_level; sent_cmsg->cmsg_type = sent_type; *(int8_t*)CMSG_DATA(sent_cmsg) = sent_tos; ASSERT_THAT(RetryEINTR(sendmsg)(sock_.get(), &sent_msg, 0), SyscallSucceedsWithValue(kDataLength)); // Receive message. struct msghdr received_msg = {}; struct iovec received_iov = {}; char received_data[kDataLength]; received_iov.iov_base = &received_data[0]; received_iov.iov_len = kDataLength; received_msg.msg_iov = &received_iov; received_msg.msg_iovlen = 1; std::vector received_cmsgbuf(CMSG_SPACE(cmsg_data_len)); received_msg.msg_control = &received_cmsgbuf[0]; received_msg.msg_controllen = CMSG_LEN(cmsg_data_len); ASSERT_THAT(RetryEINTR(recvmsg)(bind_.get(), &received_msg, 0), SyscallSucceedsWithValue(kDataLength)); struct cmsghdr* cmsg = CMSG_FIRSTHDR(&received_msg); ASSERT_NE(cmsg, nullptr); EXPECT_EQ(cmsg->cmsg_len, CMSG_LEN(cmsg_data_len)); EXPECT_EQ(cmsg->cmsg_level, sent_level); EXPECT_EQ(cmsg->cmsg_type, sent_type); int8_t received_tos = 0; memcpy(&received_tos, CMSG_DATA(cmsg), sizeof(received_tos)); EXPECT_EQ(received_tos, sent_tos); } TEST_P(UdpSocketTest, RecvBufLimitsEmptyRcvBuf) { // Discover minimum buffer size by setting it to zero. constexpr int kRcvBufSz = 0; ASSERT_THAT(setsockopt(bind_.get(), SOL_SOCKET, SO_RCVBUF, &kRcvBufSz, sizeof(kRcvBufSz)), SyscallSucceeds()); int min = 0; socklen_t min_len = sizeof(min); ASSERT_THAT(getsockopt(bind_.get(), SOL_SOCKET, SO_RCVBUF, &min, &min_len), SyscallSucceeds()); // Bind bind_ to loopback. ASSERT_NO_ERRNO(BindLoopback()); { // Send data of size min and verify that it's received. std::vector buf(min); RandomizeBuffer(buf.data(), buf.size()); ASSERT_THAT( sendto(sock_.get(), buf.data(), buf.size(), 0, bind_addr_, addrlen_), SyscallSucceedsWithValue(buf.size())); std::vector received(buf.size()); EXPECT_THAT(RecvTimeout(bind_.get(), received.data(), received.size(), 1 /*timeout*/), IsPosixErrorOkAndHolds(received.size())); } { // Send data of size min + 1 and verify that its received. Both linux and // Netstack accept a dgram that exceeds rcvBuf limits if the receive buffer // is currently empty. std::vector buf(min + 1); RandomizeBuffer(buf.data(), buf.size()); ASSERT_THAT( sendto(sock_.get(), buf.data(), buf.size(), 0, bind_addr_, addrlen_), SyscallSucceedsWithValue(buf.size())); std::vector received(buf.size()); ASSERT_THAT(RecvTimeout(bind_.get(), received.data(), received.size(), 1 /*timeout*/), IsPosixErrorOkAndHolds(received.size())); } } // Test that receive buffer limits are enforced. TEST_P(UdpSocketTest, RecvBufLimits) { // Bind s_ to loopback. ASSERT_NO_ERRNO(BindLoopback()); int min = 0; { // Discover minimum buffer size by trying to set it to zero. constexpr int kRcvBufSz = 0; ASSERT_THAT(setsockopt(bind_.get(), SOL_SOCKET, SO_RCVBUF, &kRcvBufSz, sizeof(kRcvBufSz)), SyscallSucceeds()); socklen_t min_len = sizeof(min); ASSERT_THAT(getsockopt(bind_.get(), SOL_SOCKET, SO_RCVBUF, &min, &min_len), SyscallSucceeds()); } // Now set the limit to min * 4. int new_rcv_buf_sz = min * 4; if (!IsRunningOnGvisor() || IsRunningWithHostinet()) { // Linux doubles the value specified so just set to min * 2. new_rcv_buf_sz = min * 2; } ASSERT_THAT(setsockopt(bind_.get(), SOL_SOCKET, SO_RCVBUF, &new_rcv_buf_sz, sizeof(new_rcv_buf_sz)), SyscallSucceeds()); int rcv_buf_sz = 0; { socklen_t rcv_buf_len = sizeof(rcv_buf_sz); ASSERT_THAT(getsockopt(bind_.get(), SOL_SOCKET, SO_RCVBUF, &rcv_buf_sz, &rcv_buf_len), SyscallSucceeds()); } { std::vector buf(min); RandomizeBuffer(buf.data(), buf.size()); ASSERT_THAT( sendto(sock_.get(), buf.data(), buf.size(), 0, bind_addr_, addrlen_), SyscallSucceedsWithValue(buf.size())); ASSERT_THAT( sendto(sock_.get(), buf.data(), buf.size(), 0, bind_addr_, addrlen_), SyscallSucceedsWithValue(buf.size())); ASSERT_THAT( sendto(sock_.get(), buf.data(), buf.size(), 0, bind_addr_, addrlen_), SyscallSucceedsWithValue(buf.size())); ASSERT_THAT( sendto(sock_.get(), buf.data(), buf.size(), 0, bind_addr_, addrlen_), SyscallSucceedsWithValue(buf.size())); int sent = 4; if (IsRunningOnGvisor() && !IsRunningWithHostinet()) { // Linux seems to drop the 4th packet even though technically it should // fit in the receive buffer. ASSERT_THAT( sendto(sock_.get(), buf.data(), buf.size(), 0, bind_addr_, addrlen_), SyscallSucceedsWithValue(buf.size())); sent++; } for (int i = 0; i < sent - 1; i++) { // Receive the data. std::vector received(buf.size()); EXPECT_THAT(RecvTimeout(bind_.get(), received.data(), received.size(), 1 /*timeout*/), IsPosixErrorOkAndHolds(received.size())); EXPECT_EQ(memcmp(buf.data(), received.data(), buf.size()), 0); } // The last receive should fail with EAGAIN as the last packet should have // been dropped due to lack of space in the receive buffer. std::vector received(buf.size()); EXPECT_THAT( recv(bind_.get(), received.data(), received.size(), MSG_DONTWAIT), SyscallFailsWithErrno(EAGAIN)); } } #ifdef __linux__ // TODO(gvisor.dev/2746): Support SO_ATTACH_FILTER/SO_DETACH_FILTER. // gVisor currently silently ignores attaching a filter. TEST_P(UdpSocketTest, SetSocketDetachFilter) { // Program generated using sudo tcpdump -i lo udp and port 1234 -dd struct sock_filter code[] = { {0x28, 0, 0, 0x0000000c}, {0x15, 0, 6, 0x000086dd}, {0x30, 0, 0, 0x00000014}, {0x15, 0, 15, 0x00000011}, {0x28, 0, 0, 0x00000036}, {0x15, 12, 0, 0x000004d2}, {0x28, 0, 0, 0x00000038}, {0x15, 10, 11, 0x000004d2}, {0x15, 0, 10, 0x00000800}, {0x30, 0, 0, 0x00000017}, {0x15, 0, 8, 0x00000011}, {0x28, 0, 0, 0x00000014}, {0x45, 6, 0, 0x00001fff}, {0xb1, 0, 0, 0x0000000e}, {0x48, 0, 0, 0x0000000e}, {0x15, 2, 0, 0x000004d2}, {0x48, 0, 0, 0x00000010}, {0x15, 0, 1, 0x000004d2}, {0x6, 0, 0, 0x00040000}, {0x6, 0, 0, 0x00000000}, }; struct sock_fprog bpf = { .len = ABSL_ARRAYSIZE(code), .filter = code, }; ASSERT_THAT( setsockopt(sock_.get(), SOL_SOCKET, SO_ATTACH_FILTER, &bpf, sizeof(bpf)), SyscallSucceeds()); constexpr int val = 0; ASSERT_THAT( setsockopt(sock_.get(), SOL_SOCKET, SO_DETACH_FILTER, &val, sizeof(val)), SyscallSucceeds()); } #endif // __linux__ TEST_P(UdpSocketTest, SetSocketDetachFilterNoInstalledFilter) { // TODO(gvisor.dev/2746): Support SO_ATTACH_FILTER/SO_DETACH_FILTER. SKIP_IF(IsRunningOnGvisor()); constexpr int val = 0; ASSERT_THAT( setsockopt(sock_.get(), SOL_SOCKET, SO_DETACH_FILTER, &val, sizeof(val)), SyscallFailsWithErrno(ENOENT)); } TEST_P(UdpSocketTest, GetSocketDetachFilter) { int val = 0; socklen_t val_len = sizeof(val); ASSERT_THAT( getsockopt(sock_.get(), SOL_SOCKET, SO_DETACH_FILTER, &val, &val_len), SyscallFailsWithErrno(ENOPROTOOPT)); } TEST_P(UdpSocketTest, SendToZeroPort) { char buf[8]; struct sockaddr_storage addr = InetLoopbackAddr(); // Sending to an invalid port should fail. SetPort(&addr, 0); EXPECT_THAT(sendto(sock_.get(), buf, sizeof(buf), 0, reinterpret_cast(&addr), sizeof(addr)), SyscallFailsWithErrno(EINVAL)); SetPort(&addr, 1234); EXPECT_THAT(sendto(sock_.get(), buf, sizeof(buf), 0, reinterpret_cast(&addr), sizeof(addr)), SyscallSucceedsWithValue(sizeof(buf))); } INSTANTIATE_TEST_SUITE_P(AllInetTests, UdpSocketTest, ::testing::Values(AddressFamily::kIpv4, AddressFamily::kIpv6, AddressFamily::kDualStack)); } // namespace } // namespace testing } // namespace gvisor