// 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 "test/syscalls/linux/socket_test_util.h" #include #include #include #include #include "gtest/gtest.h" #include "absl/memory/memory.h" #include "absl/strings/str_cat.h" #include "absl/time/clock.h" #include "absl/types/optional.h" #include "test/util/file_descriptor.h" #include "test/util/posix_error.h" #include "test/util/temp_path.h" #include "test/util/thread_util.h" namespace gvisor { namespace testing { Creator SyscallSocketPairCreator(int domain, int type, int protocol) { return [=]() -> PosixErrorOr> { int pair[2]; RETURN_ERROR_IF_SYSCALL_FAIL(socketpair(domain, type, protocol, pair)); MaybeSave(); // Save on successful creation. return absl::make_unique(pair[0], pair[1]); }; } Creator SyscallSocketCreator(int domain, int type, int protocol) { return [=]() -> PosixErrorOr> { int fd = 0; RETURN_ERROR_IF_SYSCALL_FAIL(fd = socket(domain, type, protocol)); MaybeSave(); // Save on successful creation. return absl::make_unique(fd); }; } PosixErrorOr UniqueUnixAddr(bool abstract, int domain) { struct sockaddr_un addr = {}; std::string path = NewTempAbsPathInDir("/tmp"); if (path.size() >= sizeof(addr.sun_path)) { return PosixError(EINVAL, "Unable to generate a temp path of appropriate length"); } if (abstract) { // Indicate that the path is in the abstract namespace. path[0] = 0; } memcpy(addr.sun_path, path.c_str(), path.length()); addr.sun_family = domain; return addr; } Creator AcceptBindSocketPairCreator(bool abstract, int domain, int type, int protocol) { return [=]() -> PosixErrorOr> { ASSIGN_OR_RETURN_ERRNO(struct sockaddr_un bind_addr, UniqueUnixAddr(abstract, domain)); ASSIGN_OR_RETURN_ERRNO(struct sockaddr_un extra_addr, UniqueUnixAddr(abstract, domain)); int bound; RETURN_ERROR_IF_SYSCALL_FAIL(bound = socket(domain, type, protocol)); MaybeSave(); // Successful socket creation. RETURN_ERROR_IF_SYSCALL_FAIL( bind(bound, reinterpret_cast(&bind_addr), sizeof(bind_addr))); MaybeSave(); // Successful bind. RETURN_ERROR_IF_SYSCALL_FAIL(listen(bound, /* backlog = */ 5)); MaybeSave(); // Successful listen. int connected; RETURN_ERROR_IF_SYSCALL_FAIL(connected = socket(domain, type, protocol)); MaybeSave(); // Successful socket creation. RETURN_ERROR_IF_SYSCALL_FAIL( connect(connected, reinterpret_cast(&bind_addr), sizeof(bind_addr))); MaybeSave(); // Successful connect. int accepted; RETURN_ERROR_IF_SYSCALL_FAIL( accepted = accept4(bound, nullptr, nullptr, type & (SOCK_NONBLOCK | SOCK_CLOEXEC))); MaybeSave(); // Successful connect. // Cleanup no longer needed resources. RETURN_ERROR_IF_SYSCALL_FAIL(close(bound)); MaybeSave(); // Dropped original socket. // Only unlink if path is not in abstract namespace. if (bind_addr.sun_path[0] != 0) { RETURN_ERROR_IF_SYSCALL_FAIL(unlink(bind_addr.sun_path)); MaybeSave(); // Unlinked path. } // accepted is before connected to destruct connected before accepted. // Destructors for nonstatic member objects are called in the reverse order // in which they appear in the class declaration. return absl::make_unique(accepted, connected, bind_addr, extra_addr); }; } Creator FilesystemAcceptBindSocketPairCreator(int domain, int type, int protocol) { return AcceptBindSocketPairCreator(/* abstract= */ false, domain, type, protocol); } Creator AbstractAcceptBindSocketPairCreator(int domain, int type, int protocol) { return AcceptBindSocketPairCreator(/* abstract= */ true, domain, type, protocol); } Creator BidirectionalBindSocketPairCreator(bool abstract, int domain, int type, int protocol) { return [=]() -> PosixErrorOr> { ASSIGN_OR_RETURN_ERRNO(struct sockaddr_un addr1, UniqueUnixAddr(abstract, domain)); ASSIGN_OR_RETURN_ERRNO(struct sockaddr_un addr2, UniqueUnixAddr(abstract, domain)); int sock1; RETURN_ERROR_IF_SYSCALL_FAIL(sock1 = socket(domain, type, protocol)); MaybeSave(); // Successful socket creation. RETURN_ERROR_IF_SYSCALL_FAIL( bind(sock1, reinterpret_cast(&addr1), sizeof(addr1))); MaybeSave(); // Successful bind. int sock2; RETURN_ERROR_IF_SYSCALL_FAIL(sock2 = socket(domain, type, protocol)); MaybeSave(); // Successful socket creation. RETURN_ERROR_IF_SYSCALL_FAIL( bind(sock2, reinterpret_cast(&addr2), sizeof(addr2))); MaybeSave(); // Successful bind. RETURN_ERROR_IF_SYSCALL_FAIL(connect( sock1, reinterpret_cast(&addr2), sizeof(addr2))); MaybeSave(); // Successful connect. RETURN_ERROR_IF_SYSCALL_FAIL(connect( sock2, reinterpret_cast(&addr1), sizeof(addr1))); MaybeSave(); // Successful connect. // Cleanup no longer needed resources. // Only unlink if path is not in abstract namespace. if (addr1.sun_path[0] != 0) { RETURN_ERROR_IF_SYSCALL_FAIL(unlink(addr1.sun_path)); MaybeSave(); // Successful unlink. } // Only unlink if path is not in abstract namespace. if (addr2.sun_path[0] != 0) { RETURN_ERROR_IF_SYSCALL_FAIL(unlink(addr2.sun_path)); MaybeSave(); // Successful unlink. } return absl::make_unique(sock1, sock2); }; } Creator FilesystemBidirectionalBindSocketPairCreator(int domain, int type, int protocol) { return BidirectionalBindSocketPairCreator(/* abstract= */ false, domain, type, protocol); } Creator AbstractBidirectionalBindSocketPairCreator(int domain, int type, int protocol) { return BidirectionalBindSocketPairCreator(/* abstract= */ true, domain, type, protocol); } Creator SocketpairGoferSocketPairCreator(int domain, int type, int protocol) { return [=]() -> PosixErrorOr> { struct sockaddr_un addr = {}; constexpr char kSocketGoferPath[] = "/socket"; memcpy(addr.sun_path, kSocketGoferPath, sizeof(kSocketGoferPath)); addr.sun_family = domain; int sock1; RETURN_ERROR_IF_SYSCALL_FAIL(sock1 = socket(domain, type, protocol)); MaybeSave(); // Successful socket creation. RETURN_ERROR_IF_SYSCALL_FAIL(connect( sock1, reinterpret_cast(&addr), sizeof(addr))); MaybeSave(); // Successful connect. int sock2; RETURN_ERROR_IF_SYSCALL_FAIL(sock2 = socket(domain, type, protocol)); MaybeSave(); // Successful socket creation. RETURN_ERROR_IF_SYSCALL_FAIL(connect( sock2, reinterpret_cast(&addr), sizeof(addr))); MaybeSave(); // Successful connect. // Make and close another socketpair to ensure that the duped ends of the // first socketpair get closed. // // The problem is that there is no way to atomically send and close an FD. // The closest that we can do is send and then immediately close the FD, // which is what we do in the gofer. The gofer won't respond to another // request until the reply is sent and the FD is closed, so forcing the // gofer to handle another request will ensure that this has happened. for (int i = 0; i < 2; i++) { int sock; RETURN_ERROR_IF_SYSCALL_FAIL(sock = socket(domain, type, protocol)); RETURN_ERROR_IF_SYSCALL_FAIL(connect( sock, reinterpret_cast(&addr), sizeof(addr))); RETURN_ERROR_IF_SYSCALL_FAIL(close(sock)); } return absl::make_unique(sock1, sock2); }; } Creator SocketpairGoferFileSocketPairCreator(int flags) { return [=]() -> PosixErrorOr> { constexpr char kSocketGoferPath[] = "/socket"; int sock1; RETURN_ERROR_IF_SYSCALL_FAIL(sock1 = open(kSocketGoferPath, O_RDWR | flags)); MaybeSave(); // Successful socket creation. int sock2; RETURN_ERROR_IF_SYSCALL_FAIL(sock2 = open(kSocketGoferPath, O_RDWR | flags)); MaybeSave(); // Successful socket creation. return absl::make_unique(sock1, sock2); }; } Creator UnboundSocketPairCreator(bool abstract, int domain, int type, int protocol) { return [=]() -> PosixErrorOr> { ASSIGN_OR_RETURN_ERRNO(struct sockaddr_un addr1, UniqueUnixAddr(abstract, domain)); ASSIGN_OR_RETURN_ERRNO(struct sockaddr_un addr2, UniqueUnixAddr(abstract, domain)); int sock1; RETURN_ERROR_IF_SYSCALL_FAIL(sock1 = socket(domain, type, protocol)); MaybeSave(); // Successful socket creation. int sock2; RETURN_ERROR_IF_SYSCALL_FAIL(sock2 = socket(domain, type, protocol)); MaybeSave(); // Successful socket creation. return absl::make_unique(sock1, sock2, addr1, addr2); }; } Creator FilesystemUnboundSocketPairCreator(int domain, int type, int protocol) { return UnboundSocketPairCreator(/* abstract= */ false, domain, type, protocol); } Creator AbstractUnboundSocketPairCreator(int domain, int type, int protocol) { return UnboundSocketPairCreator(/* abstract= */ true, domain, type, protocol); } void LocalhostAddr(struct sockaddr_in* addr, bool dual_stack) { addr->sin_family = AF_INET; addr->sin_port = htons(0); inet_pton(AF_INET, "127.0.0.1", reinterpret_cast(&addr->sin_addr.s_addr)); } void LocalhostAddr(struct sockaddr_in6* addr, bool dual_stack) { addr->sin6_family = AF_INET6; addr->sin6_port = htons(0); if (dual_stack) { inet_pton(AF_INET6, "::ffff:127.0.0.1", reinterpret_cast(&addr->sin6_addr.s6_addr)); } else { inet_pton(AF_INET6, "::1", reinterpret_cast(&addr->sin6_addr.s6_addr)); } addr->sin6_scope_id = 0; } template PosixErrorOr BindIP(int fd, bool dual_stack) { T addr = {}; LocalhostAddr(&addr, dual_stack); RETURN_ERROR_IF_SYSCALL_FAIL( bind(fd, reinterpret_cast(&addr), sizeof(addr))); socklen_t addrlen = sizeof(addr); RETURN_ERROR_IF_SYSCALL_FAIL( getsockname(fd, reinterpret_cast(&addr), &addrlen)); return addr; } template PosixErrorOr TCPBindAndListen(int fd, bool dual_stack) { ASSIGN_OR_RETURN_ERRNO(T addr, BindIP(fd, dual_stack)); RETURN_ERROR_IF_SYSCALL_FAIL(listen(fd, /* backlog = */ 5)); return addr; } template PosixErrorOr> CreateTCPConnectAcceptSocketPair(int bound, int connected, int type, bool dual_stack, T bind_addr) { int connect_result = 0; RETURN_ERROR_IF_SYSCALL_FAIL( (connect_result = RetryEINTR(connect)( connected, reinterpret_cast(&bind_addr), sizeof(bind_addr))) == -1 && errno == EINPROGRESS ? 0 : connect_result); MaybeSave(); // Successful connect. if (connect_result == -1) { struct pollfd connect_poll = {connected, POLLOUT | POLLERR | POLLHUP, 0}; RETURN_ERROR_IF_SYSCALL_FAIL(RetryEINTR(poll)(&connect_poll, 1, 0)); int error = 0; socklen_t errorlen = sizeof(error); RETURN_ERROR_IF_SYSCALL_FAIL( getsockopt(connected, SOL_SOCKET, SO_ERROR, &error, &errorlen)); errno = error; RETURN_ERROR_IF_SYSCALL_FAIL( /* connect */ error == 0 ? 0 : -1); } int accepted = -1; struct pollfd accept_poll = {bound, POLLIN, 0}; while (accepted == -1) { RETURN_ERROR_IF_SYSCALL_FAIL(RetryEINTR(poll)(&accept_poll, 1, 0)); RETURN_ERROR_IF_SYSCALL_FAIL( (accepted = RetryEINTR(accept4)( bound, nullptr, nullptr, type & (SOCK_NONBLOCK | SOCK_CLOEXEC))) == -1 && errno == EAGAIN ? 0 : accepted); } MaybeSave(); // Successful accept. T extra_addr = {}; LocalhostAddr(&extra_addr, dual_stack); return absl::make_unique(connected, accepted, bind_addr, extra_addr); } template PosixErrorOr> CreateTCPAcceptBindSocketPair( int bound, int connected, int type, bool dual_stack) { ASSIGN_OR_RETURN_ERRNO(T bind_addr, TCPBindAndListen(bound, dual_stack)); auto result = CreateTCPConnectAcceptSocketPair(bound, connected, type, dual_stack, bind_addr); // Cleanup no longer needed resources. RETURN_ERROR_IF_SYSCALL_FAIL(close(bound)); MaybeSave(); // Successful close. return result; } Creator TCPAcceptBindSocketPairCreator(int domain, int type, int protocol, bool dual_stack) { return [=]() -> PosixErrorOr> { int bound; RETURN_ERROR_IF_SYSCALL_FAIL(bound = socket(domain, type, protocol)); MaybeSave(); // Successful socket creation. int connected; RETURN_ERROR_IF_SYSCALL_FAIL(connected = socket(domain, type, protocol)); MaybeSave(); // Successful socket creation. if (domain == AF_INET) { return CreateTCPAcceptBindSocketPair(bound, connected, type, dual_stack); } return CreateTCPAcceptBindSocketPair(bound, connected, type, dual_stack); }; } Creator TCPAcceptBindPersistentListenerSocketPairCreator( int domain, int type, int protocol, bool dual_stack) { // These are lazily initialized below, on the first call to the returned // lambda. These values are private to each returned lambda, but shared across // invocations of a specific lambda. // // The sharing allows pairs created with the same parameters to share a // listener. This prevents future connects from failing if the connecting // socket selects a port which had previously been used by a listening socket // that still has some connections in TIME-WAIT. // // The lazy initialization is to avoid creating sockets during parameter // enumeration. This is important because parameters are enumerated during the // build process where networking may not be available. auto listener = std::make_shared>(absl::optional()); auto addr4 = std::make_shared>( absl::optional()); auto addr6 = std::make_shared>( absl::optional()); return [=]() -> PosixErrorOr> { int connected; RETURN_ERROR_IF_SYSCALL_FAIL(connected = socket(domain, type, protocol)); MaybeSave(); // Successful socket creation. // Share the listener across invocations. if (!listener->has_value()) { int fd = socket(domain, type, protocol); if (fd < 0) { return PosixError(errno, absl::StrCat("socket(", domain, ", ", type, ", ", protocol, ")")); } listener->emplace(fd); MaybeSave(); // Successful socket creation. } // Bind the listener once, but create a new connect/accept pair each // time. if (domain == AF_INET) { if (!addr4->has_value()) { addr4->emplace( TCPBindAndListen(listener->value(), dual_stack) .ValueOrDie()); } return CreateTCPConnectAcceptSocketPair(listener->value(), connected, type, dual_stack, addr4->value()); } if (!addr6->has_value()) { addr6->emplace( TCPBindAndListen(listener->value(), dual_stack) .ValueOrDie()); } return CreateTCPConnectAcceptSocketPair(listener->value(), connected, type, dual_stack, addr6->value()); }; } template PosixErrorOr> CreateUDPBoundSocketPair( int sock1, int sock2, int type, bool dual_stack) { ASSIGN_OR_RETURN_ERRNO(T addr1, BindIP(sock1, dual_stack)); ASSIGN_OR_RETURN_ERRNO(T addr2, BindIP(sock2, dual_stack)); return absl::make_unique(sock1, sock2, addr1, addr2); } template PosixErrorOr> CreateUDPBidirectionalBindSocketPair(int sock1, int sock2, int type, bool dual_stack) { ASSIGN_OR_RETURN_ERRNO( auto socks, CreateUDPBoundSocketPair(sock1, sock2, type, dual_stack)); // Connect sock1 to sock2. RETURN_ERROR_IF_SYSCALL_FAIL(connect(socks->first_fd(), socks->second_addr(), socks->second_addr_size())); MaybeSave(); // Successful connection. // Connect sock2 to sock1. RETURN_ERROR_IF_SYSCALL_FAIL(connect(socks->second_fd(), socks->first_addr(), socks->first_addr_size())); MaybeSave(); // Successful connection. return socks; } Creator UDPBidirectionalBindSocketPairCreator(int domain, int type, int protocol, bool dual_stack) { return [=]() -> PosixErrorOr> { int sock1; RETURN_ERROR_IF_SYSCALL_FAIL(sock1 = socket(domain, type, protocol)); MaybeSave(); // Successful socket creation. int sock2; RETURN_ERROR_IF_SYSCALL_FAIL(sock2 = socket(domain, type, protocol)); MaybeSave(); // Successful socket creation. if (domain == AF_INET) { return CreateUDPBidirectionalBindSocketPair( sock1, sock2, type, dual_stack); } return CreateUDPBidirectionalBindSocketPair(sock1, sock2, type, dual_stack); }; } Creator UDPUnboundSocketPairCreator(int domain, int type, int protocol, bool dual_stack) { return [=]() -> PosixErrorOr> { int sock1; RETURN_ERROR_IF_SYSCALL_FAIL(sock1 = socket(domain, type, protocol)); MaybeSave(); // Successful socket creation. int sock2; RETURN_ERROR_IF_SYSCALL_FAIL(sock2 = socket(domain, type, protocol)); MaybeSave(); // Successful socket creation. return absl::make_unique(sock1, sock2); }; } SocketPairKind Reversed(SocketPairKind const& base) { auto const& creator = base.creator; return SocketPairKind{ absl::StrCat("reversed ", base.description), base.domain, base.type, base.protocol, [creator]() -> PosixErrorOr> { ASSIGN_OR_RETURN_ERRNO(auto creator_value, creator()); return absl::make_unique(std::move(creator_value)); }}; } Creator UnboundSocketCreator(int domain, int type, int protocol) { return [=]() -> PosixErrorOr> { int sock; RETURN_ERROR_IF_SYSCALL_FAIL(sock = socket(domain, type, protocol)); MaybeSave(); // Successful socket creation. return absl::make_unique(sock); }; } std::vector IncludeReversals(std::vector vec) { return ApplyVecToVec(std::vector{NoOp, Reversed}, vec); } SocketPairKind NoOp(SocketPairKind const& base) { return base; } void TransferTest(int fd1, int fd2) { char buf1[20]; RandomizeBuffer(buf1, sizeof(buf1)); ASSERT_THAT(WriteFd(fd1, buf1, sizeof(buf1)), SyscallSucceedsWithValue(sizeof(buf1))); char buf2[20]; ASSERT_THAT(ReadFd(fd2, buf2, sizeof(buf2)), SyscallSucceedsWithValue(sizeof(buf2))); EXPECT_EQ(0, memcmp(buf1, buf2, sizeof(buf1))); RandomizeBuffer(buf1, sizeof(buf1)); ASSERT_THAT(WriteFd(fd2, buf1, sizeof(buf1)), SyscallSucceedsWithValue(sizeof(buf1))); ASSERT_THAT(ReadFd(fd1, buf2, sizeof(buf2)), SyscallSucceedsWithValue(sizeof(buf2))); EXPECT_EQ(0, memcmp(buf1, buf2, sizeof(buf1))); } // Initializes the given buffer with random data. void RandomizeBuffer(char* ptr, size_t len) { uint32_t seed = time(nullptr); for (size_t i = 0; i < len; ++i) { ptr[i] = static_cast(rand_r(&seed)); } } size_t CalculateUnixSockAddrLen(const char* sun_path) { // Abstract addresses always return the full length. if (sun_path[0] == 0) { return sizeof(sockaddr_un); } // Filesystem addresses use the address length plus the 2 byte sun_family // and null terminator. return strlen(sun_path) + 3; } struct sockaddr_storage AddrFDSocketPair::to_storage(const sockaddr_un& addr) { struct sockaddr_storage addr_storage = {}; memcpy(&addr_storage, &addr, sizeof(addr)); return addr_storage; } struct sockaddr_storage AddrFDSocketPair::to_storage(const sockaddr_in& addr) { struct sockaddr_storage addr_storage = {}; memcpy(&addr_storage, &addr, sizeof(addr)); return addr_storage; } struct sockaddr_storage AddrFDSocketPair::to_storage(const sockaddr_in6& addr) { struct sockaddr_storage addr_storage = {}; memcpy(&addr_storage, &addr, sizeof(addr)); return addr_storage; } SocketKind SimpleSocket(int fam, int type, int proto) { return SocketKind{ absl::StrCat("Family ", fam, ", type ", type, ", proto ", proto), fam, type, proto, SyscallSocketCreator(fam, type, proto)}; } ssize_t SendLargeSendMsg(const std::unique_ptr& sockets, size_t size, bool reader) { const int rfd = sockets->second_fd(); ScopedThread t([rfd, size, reader] { if (!reader) { return; } // Potentially too many syscalls in the loop. const DisableSave ds; std::vector buf(size); size_t total = 0; while (total < size) { int ret = read(rfd, buf.data(), buf.size()); if (ret == -1 && errno == EAGAIN) { continue; } if (ret > 0) { total += ret; } // Assert to return on first failure. ASSERT_THAT(ret, SyscallSucceeds()); } }); std::vector buf(size); struct iovec iov = {}; iov.iov_base = buf.data(); iov.iov_len = buf.size(); struct msghdr msg = {}; msg.msg_iov = &iov; msg.msg_iovlen = 1; return RetryEINTR(sendmsg)(sockets->first_fd(), &msg, 0); } namespace internal { PosixErrorOr TryPortAvailable(int port, AddressFamily family, SocketType type, bool reuse_addr) { if (port < 0) { return PosixError(EINVAL, "Invalid port"); } // Both Ipv6 and Dualstack are AF_INET6. int sock_fam = (family == AddressFamily::kIpv4 ? AF_INET : AF_INET6); int sock_type = (type == SocketType::kTcp ? SOCK_STREAM : SOCK_DGRAM); ASSIGN_OR_RETURN_ERRNO(auto fd, Socket(sock_fam, sock_type, 0)); if (reuse_addr) { int one = 1; RETURN_ERROR_IF_SYSCALL_FAIL( setsockopt(fd.get(), SOL_SOCKET, SO_REUSEADDR, &one, sizeof(one))); } // Try to bind. sockaddr_storage storage = {}; int storage_size = 0; if (family == AddressFamily::kIpv4) { sockaddr_in* addr = reinterpret_cast(&storage); storage_size = sizeof(*addr); addr->sin_family = AF_INET; addr->sin_port = htons(port); addr->sin_addr.s_addr = htonl(INADDR_ANY); } else { sockaddr_in6* addr = reinterpret_cast(&storage); storage_size = sizeof(*addr); addr->sin6_family = AF_INET6; addr->sin6_port = htons(port); if (family == AddressFamily::kDualStack) { inet_pton(AF_INET6, "::ffff:0.0.0.0", reinterpret_cast(&addr->sin6_addr.s6_addr)); } else { addr->sin6_addr = in6addr_any; } } RETURN_ERROR_IF_SYSCALL_FAIL( bind(fd.get(), reinterpret_cast(&storage), storage_size)); // If the user specified 0 as the port, we will return the port that the // kernel gave us, otherwise we will validate that this socket bound to the // requested port. sockaddr_storage bound_storage = {}; socklen_t bound_storage_size = sizeof(bound_storage); RETURN_ERROR_IF_SYSCALL_FAIL( getsockname(fd.get(), reinterpret_cast(&bound_storage), &bound_storage_size)); int available_port = -1; if (bound_storage.ss_family == AF_INET) { sockaddr_in* addr = reinterpret_cast(&bound_storage); available_port = ntohs(addr->sin_port); } else if (bound_storage.ss_family == AF_INET6) { sockaddr_in6* addr = reinterpret_cast(&bound_storage); available_port = ntohs(addr->sin6_port); } else { return PosixError(EPROTOTYPE, "Getsockname returned invalid family"); } // If we requested a specific port make sure our bound port is that port. if (port != 0 && available_port != port) { return PosixError(EINVAL, absl::StrCat("Bound port ", available_port, " was not equal to requested port ", port)); } // If we're trying to do a TCP socket, let's also try to listen. if (type == SocketType::kTcp) { RETURN_ERROR_IF_SYSCALL_FAIL(listen(fd.get(), 1)); } return available_port; } } // namespace internal PosixErrorOr SendMsg(int sock, msghdr* msg, char buf[], int buf_size) { struct iovec iov; iov.iov_base = buf; iov.iov_len = buf_size; msg->msg_iov = &iov; msg->msg_iovlen = 1; int ret; RETURN_ERROR_IF_SYSCALL_FAIL(ret = RetryEINTR(sendmsg)(sock, msg, 0)); return ret; } PosixErrorOr RecvTimeout(int sock, char buf[], int buf_size, int timeout) { fd_set rfd; struct timeval to = {.tv_sec = timeout, .tv_usec = 0}; FD_ZERO(&rfd); FD_SET(sock, &rfd); int ret; RETURN_ERROR_IF_SYSCALL_FAIL(ret = select(1, &rfd, NULL, NULL, &to)); RETURN_ERROR_IF_SYSCALL_FAIL( ret = RetryEINTR(recv)(sock, buf, buf_size, MSG_DONTWAIT)); return ret; } PosixErrorOr RecvMsgTimeout(int sock, struct msghdr* msg, int timeout) { fd_set rfd; struct timeval to = {.tv_sec = timeout, .tv_usec = 0}; FD_ZERO(&rfd); FD_SET(sock, &rfd); int ret; RETURN_ERROR_IF_SYSCALL_FAIL(ret = select(1, &rfd, NULL, NULL, &to)); RETURN_ERROR_IF_SYSCALL_FAIL( ret = RetryEINTR(recvmsg)(sock, msg, MSG_DONTWAIT)); return ret; } void RecvNoData(int sock) { char data = 0; struct iovec iov; iov.iov_base = &data; iov.iov_len = 1; struct msghdr msg = {}; msg.msg_iov = &iov; msg.msg_iovlen = 1; ASSERT_THAT(RetryEINTR(recvmsg)(sock, &msg, MSG_DONTWAIT), SyscallFailsWithErrno(EAGAIN)); } TestAddress V4Any() { TestAddress t("V4Any"); t.addr.ss_family = AF_INET; t.addr_len = sizeof(sockaddr_in); reinterpret_cast(&t.addr)->sin_addr.s_addr = htonl(INADDR_ANY); return t; } TestAddress V4Loopback() { TestAddress t("V4Loopback"); t.addr.ss_family = AF_INET; t.addr_len = sizeof(sockaddr_in); reinterpret_cast(&t.addr)->sin_addr.s_addr = htonl(INADDR_LOOPBACK); return t; } TestAddress V4MappedAny() { TestAddress t("V4MappedAny"); t.addr.ss_family = AF_INET6; t.addr_len = sizeof(sockaddr_in6); inet_pton(AF_INET6, "::ffff:0.0.0.0", reinterpret_cast(&t.addr)->sin6_addr.s6_addr); return t; } TestAddress V4MappedLoopback() { TestAddress t("V4MappedLoopback"); t.addr.ss_family = AF_INET6; t.addr_len = sizeof(sockaddr_in6); inet_pton(AF_INET6, "::ffff:127.0.0.1", reinterpret_cast(&t.addr)->sin6_addr.s6_addr); return t; } TestAddress V4Multicast() { TestAddress t("V4Multicast"); t.addr.ss_family = AF_INET; t.addr_len = sizeof(sockaddr_in); reinterpret_cast(&t.addr)->sin_addr.s_addr = inet_addr(kMulticastAddress); return t; } TestAddress V4Broadcast() { TestAddress t("V4Broadcast"); t.addr.ss_family = AF_INET; t.addr_len = sizeof(sockaddr_in); reinterpret_cast(&t.addr)->sin_addr.s_addr = htonl(INADDR_BROADCAST); return t; } TestAddress V6Any() { TestAddress t("V6Any"); t.addr.ss_family = AF_INET6; t.addr_len = sizeof(sockaddr_in6); reinterpret_cast(&t.addr)->sin6_addr = in6addr_any; return t; } TestAddress V6Loopback() { TestAddress t("V6Loopback"); t.addr.ss_family = AF_INET6; t.addr_len = sizeof(sockaddr_in6); reinterpret_cast(&t.addr)->sin6_addr = in6addr_loopback; return t; } TestAddress V6Multicast() { TestAddress t("V6Multicast"); t.addr.ss_family = AF_INET6; t.addr_len = sizeof(sockaddr_in6); EXPECT_EQ( 1, inet_pton(AF_INET6, "ff05::1234", reinterpret_cast(&t.addr)->sin6_addr.s6_addr)); return t; } // Checksum computes the internet checksum of a buffer. uint16_t Checksum(uint16_t* buf, ssize_t buf_size) { // Add up the 16-bit values in the buffer. uint32_t total = 0; for (unsigned int i = 0; i < buf_size; i += sizeof(*buf)) { total += *buf; buf++; } // If buf has an odd size, add the remaining byte. if (buf_size % 2) { total += *(reinterpret_cast(buf) - 1); } // This carries any bits past the lower 16 until everything fits in 16 bits. while (total >> 16) { uint16_t lower = total & 0xffff; uint16_t upper = total >> 16; total = lower + upper; } return ~total; } uint16_t IPChecksum(struct iphdr ip) { return Checksum(reinterpret_cast(&ip), sizeof(ip)); } // The pseudo-header defined in RFC 768 for calculating the UDP checksum. struct udp_pseudo_hdr { uint32_t srcip; uint32_t destip; char zero; char protocol; uint16_t udplen; }; uint16_t UDPChecksum(struct iphdr iphdr, struct udphdr udphdr, const char* payload, ssize_t payload_len) { struct udp_pseudo_hdr phdr = {}; phdr.srcip = iphdr.saddr; phdr.destip = iphdr.daddr; phdr.zero = 0; phdr.protocol = IPPROTO_UDP; phdr.udplen = udphdr.len; ssize_t buf_size = sizeof(phdr) + sizeof(udphdr) + payload_len; char* buf = static_cast(malloc(buf_size)); memcpy(buf, &phdr, sizeof(phdr)); memcpy(buf + sizeof(phdr), &udphdr, sizeof(udphdr)); memcpy(buf + sizeof(phdr) + sizeof(udphdr), payload, payload_len); uint16_t csum = Checksum(reinterpret_cast(buf), buf_size); free(buf); return csum; } uint16_t ICMPChecksum(struct icmphdr icmphdr, const char* payload, ssize_t payload_len) { ssize_t buf_size = sizeof(icmphdr) + payload_len; char* buf = static_cast(malloc(buf_size)); memcpy(buf, &icmphdr, sizeof(icmphdr)); memcpy(buf + sizeof(icmphdr), payload, payload_len); uint16_t csum = Checksum(reinterpret_cast(buf), buf_size); free(buf); return csum; } } // namespace testing } // namespace gvisor