// 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. #ifndef GVISOR_TEST_SYSCALLS_SOCKET_TEST_UTIL_H_ #define GVISOR_TEST_SYSCALLS_SOCKET_TEST_UTIL_H_ #include #include #include #include #include #include #include #include #include #include #include #include #include "gtest/gtest.h" #include "absl/strings/str_format.h" #include "test/util/file_descriptor.h" #include "test/util/posix_error.h" #include "test/util/test_util.h" namespace gvisor { namespace testing { // Wrapper for socket(2) that returns a FileDescriptor. inline PosixErrorOr Socket(int family, int type, int protocol) { int fd = socket(family, type, protocol); MaybeSave(); if (fd < 0) { return PosixError( errno, absl::StrFormat("socket(%d, %d, %d)", family, type, protocol)); } return FileDescriptor(fd); } // Wrapper for accept(2) that returns a FileDescriptor. inline PosixErrorOr Accept(int sockfd, sockaddr* addr, socklen_t* addrlen) { int fd = RetryEINTR(accept)(sockfd, addr, addrlen); MaybeSave(); if (fd < 0) { return PosixError( errno, absl::StrFormat("accept(%d, %p, %p)", sockfd, addr, addrlen)); } return FileDescriptor(fd); } // Wrapper for accept4(2) that returns a FileDescriptor. inline PosixErrorOr Accept4(int sockfd, sockaddr* addr, socklen_t* addrlen, int flags) { int fd = RetryEINTR(accept4)(sockfd, addr, addrlen, flags); MaybeSave(); if (fd < 0) { return PosixError(errno, absl::StrFormat("accept4(%d, %p, %p, %#x)", sockfd, addr, addrlen, flags)); } return FileDescriptor(fd); } inline ssize_t SendFd(int fd, void* buf, size_t count, int flags) { return internal::ApplyFileIoSyscall( [&](size_t completed) { return sendto(fd, static_cast(buf) + completed, count - completed, flags, nullptr, 0); }, count); } PosixErrorOr UniqueUnixAddr(bool abstract, int domain); // A Creator is a function that attempts to create and return a new T. (This // is copy/pasted from cloud/gvisor/api/sandbox_util.h and is just duplicated // here for clarity.) template using Creator = std::function>()>; // A SocketPair represents a pair of socket file descriptors owned by the // SocketPair. class SocketPair { public: virtual ~SocketPair() = default; virtual int first_fd() const = 0; virtual int second_fd() const = 0; virtual int release_first_fd() = 0; virtual int release_second_fd() = 0; virtual const struct sockaddr* first_addr() const = 0; virtual const struct sockaddr* second_addr() const = 0; virtual size_t first_addr_size() const = 0; virtual size_t second_addr_size() const = 0; virtual size_t first_addr_len() const = 0; virtual size_t second_addr_len() const = 0; }; // A FDSocketPair is a SocketPair that consists of only a pair of file // descriptors. class FDSocketPair : public SocketPair { public: FDSocketPair(int first_fd, int second_fd) : first_(first_fd), second_(second_fd) {} FDSocketPair(std::unique_ptr first_fd, std::unique_ptr second_fd) : first_(first_fd->release()), second_(second_fd->release()) {} int first_fd() const override { return first_.get(); } int second_fd() const override { return second_.get(); } int release_first_fd() override { return first_.release(); } int release_second_fd() override { return second_.release(); } const struct sockaddr* first_addr() const override { return nullptr; } const struct sockaddr* second_addr() const override { return nullptr; } size_t first_addr_size() const override { return 0; } size_t second_addr_size() const override { return 0; } size_t first_addr_len() const override { return 0; } size_t second_addr_len() const override { return 0; } private: FileDescriptor first_; FileDescriptor second_; }; // CalculateUnixSockAddrLen calculates the length returned by recvfrom(2) and // recvmsg(2) for Unix sockets. size_t CalculateUnixSockAddrLen(const char* sun_path); // A AddrFDSocketPair is a SocketPair that consists of a pair of file // descriptors in addition to a pair of socket addresses. class AddrFDSocketPair : public SocketPair { public: AddrFDSocketPair(int first_fd, int second_fd, const struct sockaddr_un& first_address, const struct sockaddr_un& second_address) : first_(first_fd), second_(second_fd), first_addr_(to_storage(first_address)), second_addr_(to_storage(second_address)), first_len_(CalculateUnixSockAddrLen(first_address.sun_path)), second_len_(CalculateUnixSockAddrLen(second_address.sun_path)), first_size_(sizeof(first_address)), second_size_(sizeof(second_address)) {} AddrFDSocketPair(int first_fd, int second_fd, const struct sockaddr_in& first_address, const struct sockaddr_in& second_address) : first_(first_fd), second_(second_fd), first_addr_(to_storage(first_address)), second_addr_(to_storage(second_address)), first_len_(sizeof(first_address)), second_len_(sizeof(second_address)), first_size_(sizeof(first_address)), second_size_(sizeof(second_address)) {} AddrFDSocketPair(int first_fd, int second_fd, const struct sockaddr_in6& first_address, const struct sockaddr_in6& second_address) : first_(first_fd), second_(second_fd), first_addr_(to_storage(first_address)), second_addr_(to_storage(second_address)), first_len_(sizeof(first_address)), second_len_(sizeof(second_address)), first_size_(sizeof(first_address)), second_size_(sizeof(second_address)) {} int first_fd() const override { return first_.get(); } int second_fd() const override { return second_.get(); } int release_first_fd() override { return first_.release(); } int release_second_fd() override { return second_.release(); } const struct sockaddr* first_addr() const override { return reinterpret_cast(&first_addr_); } const struct sockaddr* second_addr() const override { return reinterpret_cast(&second_addr_); } size_t first_addr_size() const override { return first_size_; } size_t second_addr_size() const override { return second_size_; } size_t first_addr_len() const override { return first_len_; } size_t second_addr_len() const override { return second_len_; } private: // to_storage coverts a sockaddr_* to a sockaddr_storage. static struct sockaddr_storage to_storage(const sockaddr_un& addr); static struct sockaddr_storage to_storage(const sockaddr_in& addr); static struct sockaddr_storage to_storage(const sockaddr_in6& addr); FileDescriptor first_; FileDescriptor second_; const struct sockaddr_storage first_addr_; const struct sockaddr_storage second_addr_; const size_t first_len_; const size_t second_len_; const size_t first_size_; const size_t second_size_; }; // SyscallSocketPairCreator returns a Creator that obtains file // descriptors by invoking the socketpair() syscall. Creator SyscallSocketPairCreator(int domain, int type, int protocol); // SyscallSocketCreator returns a Creator that obtains a file // descriptor by invoking the socket() syscall. Creator SyscallSocketCreator(int domain, int type, int protocol); // FilesystemBidirectionalBindSocketPairCreator returns a Creator // that obtains file descriptors by invoking the bind() and connect() syscalls // on filesystem paths. Only works for DGRAM sockets. Creator FilesystemBidirectionalBindSocketPairCreator(int domain, int type, int protocol); // AbstractBidirectionalBindSocketPairCreator returns a Creator that // obtains file descriptors by invoking the bind() and connect() syscalls on // abstract namespace paths. Only works for DGRAM sockets. Creator AbstractBidirectionalBindSocketPairCreator(int domain, int type, int protocol); // SocketpairGoferSocketPairCreator returns a Creator that // obtains file descriptors by connect() syscalls on two sockets with socketpair // gofer paths. Creator SocketpairGoferSocketPairCreator(int domain, int type, int protocol); // SocketpairGoferFileSocketPairCreator returns a Creator that // obtains file descriptors by open() syscalls on socketpair gofer paths. Creator SocketpairGoferFileSocketPairCreator(int flags); // FilesystemAcceptBindSocketPairCreator returns a Creator that // obtains file descriptors by invoking the accept() and bind() syscalls on // a filesystem path. Only works for STREAM and SEQPACKET sockets. Creator FilesystemAcceptBindSocketPairCreator(int domain, int type, int protocol); // AbstractAcceptBindSocketPairCreator returns a Creator that // obtains file descriptors by invoking the accept() and bind() syscalls on a // abstract namespace path. Only works for STREAM and SEQPACKET sockets. Creator AbstractAcceptBindSocketPairCreator(int domain, int type, int protocol); // FilesystemUnboundSocketPairCreator returns a Creator that obtains // file descriptors by invoking the socket() syscall and generates a filesystem // path for binding. Creator FilesystemUnboundSocketPairCreator(int domain, int type, int protocol); // AbstractUnboundSocketPairCreator returns a Creator that obtains // file descriptors by invoking the socket() syscall and generates an abstract // path for binding. Creator AbstractUnboundSocketPairCreator(int domain, int type, int protocol); // TCPAcceptBindSocketPairCreator returns a Creator that obtains // file descriptors by invoking the accept() and bind() syscalls on TCP sockets. Creator TCPAcceptBindSocketPairCreator(int domain, int type, int protocol, bool dual_stack); // TCPAcceptBindPersistentListenerSocketPairCreator is like // TCPAcceptBindSocketPairCreator, except it uses the same listening socket to // create all SocketPairs. Creator TCPAcceptBindPersistentListenerSocketPairCreator( int domain, int type, int protocol, bool dual_stack); // UDPBidirectionalBindSocketPairCreator returns a Creator that // obtains file descriptors by invoking the bind() and connect() syscalls on UDP // sockets. Creator UDPBidirectionalBindSocketPairCreator(int domain, int type, int protocol, bool dual_stack); // UDPUnboundSocketPairCreator returns a Creator that obtains file // descriptors by creating UDP sockets. Creator UDPUnboundSocketPairCreator(int domain, int type, int protocol, bool dual_stack); // UnboundSocketCreator returns a Creator that obtains a file // descriptor by creating a socket. Creator UnboundSocketCreator(int domain, int type, int protocol); // A SocketPairKind couples a human-readable description of a socket pair with // a function that creates such a socket pair. struct SocketPairKind { std::string description; int domain; int type; int protocol; Creator creator; // Create creates a socket pair of this kind. PosixErrorOr> Create() const { return creator(); } }; // A SocketKind couples a human-readable description of a socket with // a function that creates such a socket. struct SocketKind { std::string description; int domain; int type; int protocol; Creator creator; // Create creates a socket pair of this kind. PosixErrorOr> Create() const { return creator(); } }; // A ReversedSocketPair wraps another SocketPair but flips the first and second // file descriptors. ReversedSocketPair is used to test socket pairs that // should be symmetric. class ReversedSocketPair : public SocketPair { public: explicit ReversedSocketPair(std::unique_ptr base) : base_(std::move(base)) {} int first_fd() const override { return base_->second_fd(); } int second_fd() const override { return base_->first_fd(); } int release_first_fd() override { return base_->release_second_fd(); } int release_second_fd() override { return base_->release_first_fd(); } const struct sockaddr* first_addr() const override { return base_->second_addr(); } const struct sockaddr* second_addr() const override { return base_->first_addr(); } size_t first_addr_size() const override { return base_->second_addr_size(); } size_t second_addr_size() const override { return base_->first_addr_size(); } size_t first_addr_len() const override { return base_->second_addr_len(); } size_t second_addr_len() const override { return base_->first_addr_len(); } private: std::unique_ptr base_; }; // Reversed returns a SocketPairKind that represents SocketPairs created by // flipping the file descriptors provided by another SocketPair. SocketPairKind Reversed(SocketPairKind const& base); // IncludeReversals returns a vector that returns all // SocketPairKinds in `vec` as well as all SocketPairKinds obtained by flipping // the file descriptors provided by the kinds in `vec`. std::vector IncludeReversals(std::vector vec); // A Middleware is a function wraps a SocketPairKind. using Middleware = std::function; // Reversed returns a SocketPairKind that represents SocketPairs created by // flipping the file descriptors provided by another SocketPair. template Middleware SetSockOpt(int level, int optname, T* value) { return [=](SocketPairKind const& base) { auto const& creator = base.creator; return SocketPairKind{ absl::StrCat("setsockopt(", level, ", ", optname, ", ", *value, ") ", base.description), base.domain, base.type, base.protocol, [creator, level, optname, value]() -> PosixErrorOr> { ASSIGN_OR_RETURN_ERRNO(auto creator_value, creator()); if (creator_value->first_fd() >= 0) { RETURN_ERROR_IF_SYSCALL_FAIL(setsockopt( creator_value->first_fd(), level, optname, value, sizeof(T))); } if (creator_value->second_fd() >= 0) { RETURN_ERROR_IF_SYSCALL_FAIL(setsockopt( creator_value->second_fd(), level, optname, value, sizeof(T))); } return creator_value; }}; }; } constexpr int kSockOptOn = 1; constexpr int kSockOptOff = 0; // NoOp returns the same SocketPairKind that it is passed. SocketPairKind NoOp(SocketPairKind const& base); // TransferTest tests that data can be send back and fourth between two // specified FDs. Note that calls to this function should be wrapped in // ASSERT_NO_FATAL_FAILURE(). void TransferTest(int fd1, int fd2); // Fills [buf, buf+len) with random bytes. void RandomizeBuffer(char* buf, size_t len); // Base test fixture for tests that operate on pairs of connected sockets. class SocketPairTest : public ::testing::TestWithParam { protected: SocketPairTest() { // gUnit uses printf, so so will we. printf("Testing with %s\n", GetParam().description.c_str()); fflush(stdout); } PosixErrorOr> NewSocketPair() const { return GetParam().Create(); } }; // Base test fixture for tests that operate on simple Sockets. class SimpleSocketTest : public ::testing::TestWithParam { protected: SimpleSocketTest() { // gUnit uses printf, so so will we. printf("Testing with %s\n", GetParam().description.c_str()); } PosixErrorOr> NewSocket() const { return GetParam().Create(); } }; SocketKind SimpleSocket(int fam, int type, int proto); // Send a buffer of size 'size' to sockets->first_fd(), returning the result of // sendmsg. // // If reader, read from second_fd() until size bytes have been read. ssize_t SendLargeSendMsg(const std::unique_ptr& sockets, size_t size, bool reader); // Initializes the given buffer with random data. void RandomizeBuffer(char* ptr, size_t len); enum class AddressFamily { kIpv4 = 1, kIpv6 = 2, kDualStack = 3 }; enum class SocketType { kUdp = 1, kTcp = 2 }; // Returns a PosixError or a port that is available. If 0 is specified as the // port it will bind port 0 (and allow the kernel to select any free port). // Otherwise, it will try to bind the specified port and validate that it can be // used for the requested family and socket type. The final option is // reuse_addr. This specifies whether SO_REUSEADDR should be applied before a // bind(2) attempt. SO_REUSEADDR means that sockets in TIME_WAIT states or other // bound UDP sockets would not cause an error on bind(2). This option should be // set if subsequent calls to bind on the returned port will also use // SO_REUSEADDR. // // Note: That this test will attempt to bind the ANY address for the respective // protocol. PosixErrorOr PortAvailable(int port, AddressFamily family, SocketType type, bool reuse_addr); // FreeAvailablePort is used to return a port that was obtained by using // the PortAvailable helper with port 0. PosixError FreeAvailablePort(int port); // SendMsg converts a buffer to an iovec and adds it to msg before sending it. PosixErrorOr SendMsg(int sock, msghdr* msg, char buf[], int buf_size); // RecvTimeout calls select on sock with timeout and then calls recv on sock. PosixErrorOr RecvTimeout(int sock, char buf[], int buf_size, int timeout); // RecvMsgTimeout calls select on sock with timeout and then calls recvmsg on // sock. PosixErrorOr RecvMsgTimeout(int sock, msghdr* msg, int timeout); // RecvNoData checks that no data is receivable on sock. void RecvNoData(int sock); // Base test fixture for tests that apply to all kinds of pairs of connected // sockets. using AllSocketPairTest = SocketPairTest; struct TestAddress { std::string description; sockaddr_storage addr; socklen_t addr_len; explicit TestAddress(std::string description = "") : description(std::move(description)), addr(), addr_len() {} int family() const { return addr.ss_family; } // Returns a new TestAddress with specified port. If port is not supported, // the same TestAddress is returned. TestAddress WithPort(uint16_t port) const; }; constexpr char kMulticastAddress[] = "224.0.2.1"; constexpr char kBroadcastAddress[] = "255.255.255.255"; // Returns a TestAddress with `addr` parsed as an IPv4 address described by // `description`. TestAddress V4AddrStr(std::string description, const char* addr); // Returns a TestAddress with `addr` parsed as an IPv6 address described by // `description`. TestAddress V6AddrStr(std::string description, const char* addr); // Returns a TestAddress for the IPv4 any address. TestAddress V4Any(); // Returns a TestAddress for the IPv4 limited broadcast address. TestAddress V4Broadcast(); // Returns a TestAddress for the IPv4 loopback address. TestAddress V4Loopback(); // Returns a TestAddress for the subnet broadcast of the IPv4 loopback address. TestAddress V4LoopbackSubnetBroadcast(); // Returns a TestAddress for the IPv4-mapped IPv6 any address. TestAddress V4MappedAny(); // Returns a TestAddress for the IPv4-mapped IPv6 loopback address. TestAddress V4MappedLoopback(); // Returns a TestAddress for a IPv4 multicast address. TestAddress V4Multicast(); // Returns a TestAddress for the IPv4 all-hosts multicast group address. TestAddress V4MulticastAllHosts(); // Returns a TestAddress for the IPv6 any address. TestAddress V6Any(); // Returns a TestAddress for the IPv6 loopback address. TestAddress V6Loopback(); // Returns a TestAddress for a IPv6 multicast address. TestAddress V6Multicast(); // Returns a TestAddress for the IPv6 interface-local all-nodes multicast group // address. TestAddress V6MulticastInterfaceLocalAllNodes(); // Returns a TestAddress for the IPv6 link-local all-nodes multicast group // address. TestAddress V6MulticastLinkLocalAllNodes(); // Returns a TestAddress for the IPv6 link-local all-routers multicast group // address. TestAddress V6MulticastLinkLocalAllRouters(); // Compute the internet checksum of an IP header. uint16_t IPChecksum(struct iphdr ip); // Compute the internet checksum of a UDP header. uint16_t UDPChecksum(struct iphdr iphdr, struct udphdr udphdr, const char* payload, ssize_t payload_len); // Compute the internet checksum of an ICMP header. uint16_t ICMPChecksum(struct icmphdr icmphdr, const char* payload, ssize_t payload_len); // Convenient functions for reinterpreting common types to sockaddr pointer. inline sockaddr* AsSockAddr(sockaddr_storage* s) { return reinterpret_cast(s); } inline sockaddr* AsSockAddr(sockaddr_in* s) { return reinterpret_cast(s); } inline sockaddr* AsSockAddr(sockaddr_in6* s) { return reinterpret_cast(s); } inline sockaddr* AsSockAddr(sockaddr_un* s) { return reinterpret_cast(s); } namespace internal { PosixErrorOr TryPortAvailable(int port, AddressFamily family, SocketType type, bool reuse_addr); } // namespace internal } // namespace testing } // namespace gvisor #endif // GVISOR_TEST_SYSCALLS_SOCKET_TEST_UTIL_H_