package beam import ( "fmt" "net" "os" "syscall" "bufio" ) func debugCheckpoint(msg string, args ...interface{}) { return os.Stdout.Sync() tty,_ := os.OpenFile("/dev/tty", os.O_RDWR, 0700) fmt.Fprintf(tty, msg, args...) bufio.NewScanner(tty).Scan() tty.Close() } // Send sends a new message on conn with data and f as payload and // attachment, respectively. func Send(conn *net.UnixConn, data []byte, f *os.File) error { { var fd int = -1 if f != nil { fd = int(f.Fd()) } debugCheckpoint("===DEBUG=== about to send '%s'[%d]. Hit enter to confirm: ", data, fd) } var fds []int if f != nil { fds = append(fds, int(f.Fd())) } return sendUnix(conn, data, fds...) } // Receive waits for a new message on conn, and receives its payload // and attachment, or an error if any. // // If more than 1 file descriptor is sent in the message, they are all // closed except for the first, which is the attachment. // It is legal for a message to have no attachment or an empty payload. func Receive(conn *net.UnixConn) (rdata []byte, rf *os.File, rerr error) { defer func() { var fd int = -1 if rf != nil { fd = int(rf.Fd()) } debugCheckpoint("===DEBUG=== Receive() -> '%s'[%d]. Hit enter to continue.\n", rdata, fd) }() for { data, fds, err := receiveUnix(conn) if err != nil { return nil, nil, err } var f *os.File if len(fds) > 1 { for _, fd := range fds[1:] { syscall.Close(fd) } } if len(fds) >= 1 { f = os.NewFile(uintptr(fds[0]), "") } return data, f, nil } panic("impossibru") return nil, nil, nil } // SendPipe creates a new unix socket pair, sends one end as the attachment // to a beam message with the payload `data`, and returns the other end. // // This is a common pattern to open a new service endpoint. // For example, a service wishing to advertise its presence to clients might // open an endpoint with: // // endpoint, _ := SendPipe(conn, []byte("sql")) // defer endpoint.Close() // for { // conn, _ := endpoint.Receive() // go func() { // Handle(conn) // conn.Close() // }() // } // // Note that beam does not distinguish between clients and servers in the logical // sense: any program wishing to establishing a communication with another program // may use SendPipe() to create an endpoint. // For example, here is how an application might use it to connect to a database client. // // endpoint, _ := SendPipe(conn, []byte("userdb")) // defer endpoint.Close() // conn, _ := endpoint.Receive() // defer conn.Close() // db := NewDBClient(conn) // // In this example note that we only need the first connection out of the endpoint, // but we could open new ones to retry after a broken connection. // Note that, because the underlying service transport is abstracted away, this // allows for arbitrarily complex service discovery and retry logic to take place, // without complicating application code. // func SendPipe(conn *net.UnixConn, data []byte) (endpoint *net.UnixConn, err error) { local, remote, err := SocketPair() if err != nil { return nil, err } defer func() { if err != nil { local.Close() remote.Close() } }() endpoint, err = FdConn(int(local.Fd())) if err != nil { return nil, err } if err := Send(conn, data, remote); err != nil { return nil, err } return endpoint, nil } func receiveUnix(conn *net.UnixConn) ([]byte, []int, error) { buf := make([]byte, 4096) oob := make([]byte, 4096) bufn, oobn, _, _, err := conn.ReadMsgUnix(buf, oob) if err != nil { return nil, nil, err } return buf[:bufn], extractFds(oob[:oobn]), nil } func sendUnix(conn *net.UnixConn, data []byte, fds ...int) error { _, _, err := conn.WriteMsgUnix(data, syscall.UnixRights(fds...), nil) if err == nil { for _, fd := range fds { fmt.Printf("Closing sent fd %v\n", fd) syscall.Close(fd) } } return err } func extractFds(oob []byte) (fds []int) { scms, err := syscall.ParseSocketControlMessage(oob) if err != nil { return } for _, scm := range scms { gotFds, err := syscall.ParseUnixRights(&scm) if err != nil { continue } fds = append(fds, gotFds...) } return } func socketpair() ([2]int, error) { return syscall.Socketpair(syscall.AF_LOCAL, syscall.SOCK_STREAM|syscall.FD_CLOEXEC, 0) } // SocketPair is a convenience wrapper around the socketpair(2) syscall. // It returns a unix socket of type SOCK_STREAM in the form of 2 file descriptors // not bound to the underlying filesystem. // Messages sent on one end are received on the other, and vice-versa. // It is the caller's responsibility to close both ends. func SocketPair() (*os.File, *os.File, error) { pair, err := socketpair() if err != nil { return nil, nil, err } return os.NewFile(uintptr(pair[0]), ""), os.NewFile(uintptr(pair[1]), ""), nil } func USocketPair() (*net.UnixConn, *net.UnixConn, error) { a, b, err := SocketPair() if err != nil { return nil, nil, err } fmt.Printf("SocketPair() = %v, %v\n", a.Fd(), b.Fd()) uA, err := FdConn(int(a.Fd())) if err != nil { a.Close() b.Close() return nil, nil, err } uB, err := FdConn(int(b.Fd())) if err != nil { a.Close() b.Close() return nil, nil, err } return uA, uB, nil } // FdConn wraps a file descriptor in a standard *net.UnixConn object, or // returns an error if the file descriptor does not point to a unix socket. // This creates a duplicate file descriptor. It's the caller's responsibility // to close both. func FdConn(fd int) (*net.UnixConn, error) { f := os.NewFile(uintptr(fd), fmt.Sprintf("%d", fd)) conn, err := net.FileConn(f) if err != nil { return nil, err } uconn, ok := conn.(*net.UnixConn) if !ok { conn.Close() return nil, fmt.Errorf("%d: not a unix connection", fd) } return uconn, nil }