// 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. package container import ( "bytes" "fmt" "io" "os" "path/filepath" "sync" "syscall" "testing" "time" "github.com/kr/pty" "golang.org/x/sys/unix" "gvisor.dev/gvisor/pkg/sentry/control" "gvisor.dev/gvisor/pkg/unet" "gvisor.dev/gvisor/pkg/urpc" "gvisor.dev/gvisor/runsc/test/testutil" ) // socketPath creates a path inside bundleDir and ensures that the returned // path is under 108 charactors (the unix socket path length limit), // relativizing the path if necessary. func socketPath(bundleDir string) (string, error) { path := filepath.Join(bundleDir, "socket") cwd, err := os.Getwd() if err != nil { return "", fmt.Errorf("error getting cwd: %v", err) } relPath, err := filepath.Rel(cwd, path) if err != nil { return "", fmt.Errorf("error getting relative path for %q from cwd %q: %v", path, cwd, err) } if len(path) > len(relPath) { path = relPath } const maxPathLen = 108 if len(path) > maxPathLen { return "", fmt.Errorf("could not get socket path under length limit %d: %s", maxPathLen, path) } return path, nil } // createConsoleSocket creates a socket at the given path that will receive a // console fd from the sandbox. If no error occurs, it returns the server // socket and a cleanup function. func createConsoleSocket(path string) (*unet.ServerSocket, func() error, error) { srv, err := unet.BindAndListen(path, false) if err != nil { return nil, nil, fmt.Errorf("error binding and listening to socket %q: %v", path, err) } cleanup := func() error { if err := srv.Close(); err != nil { return fmt.Errorf("error closing socket %q: %v", path, err) } if err := os.Remove(path); err != nil { return fmt.Errorf("error removing socket %q: %v", path, err) } return nil } return srv, cleanup, nil } // receiveConsolePTY accepts a connection on the server socket and reads fds. // It fails if more than one FD is received, or if the FD is not a PTY. It // returns the PTY master file. func receiveConsolePTY(srv *unet.ServerSocket) (*os.File, error) { sock, err := srv.Accept() if err != nil { return nil, fmt.Errorf("error accepting socket connection: %v", err) } // Allow 3 fds to be received. We only expect 1. r := sock.Reader(true /* blocking */) r.EnableFDs(1) // The socket is closed right after sending the FD, so EOF is // an allowed error. b := [][]byte{{}} if _, err := r.ReadVec(b); err != nil && err != io.EOF { return nil, fmt.Errorf("error reading from socket connection: %v", err) } // We should have gotten a control message. fds, err := r.ExtractFDs() if err != nil { return nil, fmt.Errorf("error extracting fds from socket connection: %v", err) } if len(fds) != 1 { return nil, fmt.Errorf("got %d fds from socket, wanted 1", len(fds)) } // Verify that the fd is a terminal. if _, err := unix.IoctlGetTermios(fds[0], unix.TCGETS); err != nil { return nil, fmt.Errorf("fd is not a terminal (ioctl TGGETS got %v)", err) } return os.NewFile(uintptr(fds[0]), "pty_master"), nil } // Test that an pty FD is sent over the console socket if one is provided. func TestConsoleSocket(t *testing.T) { for _, conf := range configs(all...) { t.Logf("Running test with conf: %+v", conf) spec := testutil.NewSpecWithArgs("true") rootDir, bundleDir, err := testutil.SetupContainer(spec, conf) if err != nil { t.Fatalf("error setting up container: %v", err) } defer os.RemoveAll(rootDir) defer os.RemoveAll(bundleDir) sock, err := socketPath(bundleDir) if err != nil { t.Fatalf("error getting socket path: %v", err) } srv, cleanup, err := createConsoleSocket(sock) if err != nil { t.Fatalf("error creating socket at %q: %v", sock, err) } defer cleanup() // Create the container and pass the socket name. args := Args{ ID: testutil.UniqueContainerID(), Spec: spec, BundleDir: bundleDir, ConsoleSocket: sock, } c, err := New(conf, args) if err != nil { t.Fatalf("error creating container: %v", err) } defer c.Destroy() // Make sure we get a console PTY. ptyMaster, err := receiveConsolePTY(srv) if err != nil { t.Fatalf("error receiving console FD: %v", err) } ptyMaster.Close() } } // Test that job control signals work on a console created with "exec -ti". func TestJobControlSignalExec(t *testing.T) { spec := testutil.NewSpecWithArgs("/bin/sleep", "10000") conf := testutil.TestConfig() rootDir, bundleDir, err := testutil.SetupContainer(spec, conf) if err != nil { t.Fatalf("error setting up container: %v", err) } defer os.RemoveAll(rootDir) defer os.RemoveAll(bundleDir) // Create and start the container. args := Args{ ID: testutil.UniqueContainerID(), Spec: spec, BundleDir: bundleDir, } c, err := New(conf, args) if err != nil { t.Fatalf("error creating container: %v", err) } defer c.Destroy() if err := c.Start(conf); err != nil { t.Fatalf("error starting container: %v", err) } // Create a pty master/slave. The slave will be passed to the exec // process. ptyMaster, ptySlave, err := pty.Open() if err != nil { t.Fatalf("error opening pty: %v", err) } defer ptyMaster.Close() defer ptySlave.Close() // Exec bash and attach a terminal. execArgs := &control.ExecArgs{ Filename: "/bin/bash", // Don't let bash execute from profile or rc files, otherwise // our PID counts get messed up. Argv: []string{"/bin/bash", "--noprofile", "--norc"}, // Pass the pty slave as FD 0, 1, and 2. FilePayload: urpc.FilePayload{ Files: []*os.File{ptySlave, ptySlave, ptySlave}, }, StdioIsPty: true, } pid, err := c.Execute(execArgs) if err != nil { t.Fatalf("error executing: %v", err) } if pid != 2 { t.Fatalf("exec got pid %d, wanted %d", pid, 2) } // Make sure all the processes are running. expectedPL := []*control.Process{ // Root container process. {PID: 1, Cmd: "sleep"}, // Bash from exec process. {PID: 2, Cmd: "bash"}, } if err := waitForProcessList(c, expectedPL); err != nil { t.Error(err) } // Execute sleep. ptyMaster.Write([]byte("sleep 100\n")) // Wait for it to start. Sleep's PPID is bash's PID. expectedPL = append(expectedPL, &control.Process{PID: 3, PPID: 2, Cmd: "sleep"}) if err := waitForProcessList(c, expectedPL); err != nil { t.Error(err) } // Send a SIGTERM to the foreground process for the exec PID. Note that // although we pass in the PID of "bash", it should actually terminate // "sleep", since that is the foreground process. if err := c.Sandbox.SignalProcess(c.ID, pid, syscall.SIGTERM, true /* fgProcess */); err != nil { t.Fatalf("error signaling container: %v", err) } // Sleep process should be gone. expectedPL = expectedPL[:len(expectedPL)-1] if err := waitForProcessList(c, expectedPL); err != nil { t.Error(err) } // Sleep is dead, but it may take more time for bash to notice and // change the foreground process back to itself. We know it is done // when bash writes "Terminated" to the pty. if err := testutil.WaitUntilRead(ptyMaster, "Terminated", nil, 5*time.Second); err != nil { t.Fatalf("bash did not take over pty: %v", err) } // Send a SIGKILL to the foreground process again. This time "bash" // should be killed. We use SIGKILL instead of SIGTERM or SIGINT // because bash ignores those. if err := c.Sandbox.SignalProcess(c.ID, pid, syscall.SIGKILL, true /* fgProcess */); err != nil { t.Fatalf("error signaling container: %v", err) } expectedPL = expectedPL[:1] if err := waitForProcessList(c, expectedPL); err != nil { t.Error(err) } // Make sure the process indicates it was killed by a SIGKILL. ws, err := c.WaitPID(pid) if err != nil { t.Errorf("waiting on container failed: %v", err) } if !ws.Signaled() { t.Error("ws.Signaled() got false, want true") } if got, want := ws.Signal(), syscall.SIGKILL; got != want { t.Errorf("ws.Signal() got %v, want %v", got, want) } } // Test that job control signals work on a console created with "run -ti". func TestJobControlSignalRootContainer(t *testing.T) { conf := testutil.TestConfig() // Don't let bash execute from profile or rc files, otherwise our PID // counts get messed up. spec := testutil.NewSpecWithArgs("/bin/bash", "--noprofile", "--norc") spec.Process.Terminal = true rootDir, bundleDir, err := testutil.SetupContainer(spec, conf) if err != nil { t.Fatalf("error setting up container: %v", err) } defer os.RemoveAll(rootDir) defer os.RemoveAll(bundleDir) sock, err := socketPath(bundleDir) if err != nil { t.Fatalf("error getting socket path: %v", err) } srv, cleanup, err := createConsoleSocket(sock) if err != nil { t.Fatalf("error creating socket at %q: %v", sock, err) } defer cleanup() // Create the container and pass the socket name. args := Args{ ID: testutil.UniqueContainerID(), Spec: spec, BundleDir: bundleDir, ConsoleSocket: sock, } c, err := New(conf, args) if err != nil { t.Fatalf("error creating container: %v", err) } defer c.Destroy() // Get the PTY master. ptyMaster, err := receiveConsolePTY(srv) if err != nil { t.Fatalf("error receiving console FD: %v", err) } defer ptyMaster.Close() // Bash output as well as sandbox output will be written to the PTY // file. Writes after a certain point will block unless we drain the // PTY, so we must continually copy from it. // // We log the output to stdout for debugabilitly, and also to a buffer, // since we wait on particular output from bash below. We use a custom // blockingBuffer which is thread-safe and also blocks on Read calls, // which makes this a suitable Reader for WaitUntilRead. ptyBuf := newBlockingBuffer() tee := io.TeeReader(ptyMaster, ptyBuf) go io.Copy(os.Stdout, tee) // Start the container. if err := c.Start(conf); err != nil { t.Fatalf("error starting container: %v", err) } // Start waiting for the container to exit in a goroutine. We do this // very early, otherwise it might exit before we have a chance to call // Wait. var ( ws syscall.WaitStatus wg sync.WaitGroup ) wg.Add(1) go func() { var err error ws, err = c.Wait() if err != nil { t.Errorf("error waiting on container: %v", err) } wg.Done() }() // Wait for bash to start. expectedPL := []*control.Process{ {PID: 1, Cmd: "bash"}, } if err := waitForProcessList(c, expectedPL); err != nil { t.Fatal(err) } // Execute sleep via the terminal. ptyMaster.Write([]byte("sleep 100\n")) // Wait for sleep to start. expectedPL = append(expectedPL, &control.Process{PID: 2, PPID: 1, Cmd: "sleep"}) if err := waitForProcessList(c, expectedPL); err != nil { t.Fatal(err) } // Reset the pty buffer, so there is less output for us to scan later. ptyBuf.Reset() // Send a SIGTERM to the foreground process. We pass PID=0, indicating // that the root process should be killed. However, by setting // fgProcess=true, the signal should actually be sent to sleep. if err := c.Sandbox.SignalProcess(c.ID, 0 /* PID */, syscall.SIGTERM, true /* fgProcess */); err != nil { t.Fatalf("error signaling container: %v", err) } // Sleep process should be gone. expectedPL = expectedPL[:len(expectedPL)-1] if err := waitForProcessList(c, expectedPL); err != nil { t.Error(err) } // Sleep is dead, but it may take more time for bash to notice and // change the foreground process back to itself. We know it is done // when bash writes "Terminated" to the pty. if err := testutil.WaitUntilRead(ptyBuf, "Terminated", nil, 5*time.Second); err != nil { t.Fatalf("bash did not take over pty: %v", err) } // Send a SIGKILL to the foreground process again. This time "bash" // should be killed. We use SIGKILL instead of SIGTERM or SIGINT // because bash ignores those. if err := c.Sandbox.SignalProcess(c.ID, 0 /* PID */, syscall.SIGKILL, true /* fgProcess */); err != nil { t.Fatalf("error signaling container: %v", err) } // Wait for the sandbox to exit. It should exit with a SIGKILL status. wg.Wait() if !ws.Signaled() { t.Error("ws.Signaled() got false, want true") } if got, want := ws.Signal(), syscall.SIGKILL; got != want { t.Errorf("ws.Signal() got %v, want %v", got, want) } } // blockingBuffer is a thread-safe buffer that blocks when reading if the // buffer is empty. It implements io.ReadWriter. type blockingBuffer struct { // A send to readCh indicates that a previously empty buffer now has // data for reading. readCh chan struct{} // mu protects buf. mu sync.Mutex buf bytes.Buffer } func newBlockingBuffer() *blockingBuffer { return &blockingBuffer{ readCh: make(chan struct{}, 1), } } // Write implements Writer.Write. func (bb *blockingBuffer) Write(p []byte) (int, error) { bb.mu.Lock() defer bb.mu.Unlock() l := bb.buf.Len() n, err := bb.buf.Write(p) if l == 0 && n > 0 { // New data! bb.readCh <- struct{}{} } return n, err } // Read implements Reader.Read. It will block until data is available. func (bb *blockingBuffer) Read(p []byte) (int, error) { for { bb.mu.Lock() n, err := bb.buf.Read(p) if n > 0 || err != io.EOF { if bb.buf.Len() == 0 { // Reset the readCh. select { case <-bb.readCh: default: } } bb.mu.Unlock() return n, err } bb.mu.Unlock() // Wait for new data. <-bb.readCh } } // Reset resets the buffer. func (bb *blockingBuffer) Reset() { bb.mu.Lock() defer bb.mu.Unlock() bb.buf.Reset() // Reset the readCh. select { case <-bb.readCh: default: } }