// 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 boot loads the kernel and runs a container. package boot import ( "fmt" mrand "math/rand" "os" "runtime" "sync/atomic" "syscall" gtime "time" specs "github.com/opencontainers/runtime-spec/specs-go" "golang.org/x/sys/unix" "gvisor.dev/gvisor/pkg/abi/linux" "gvisor.dev/gvisor/pkg/context" "gvisor.dev/gvisor/pkg/cpuid" "gvisor.dev/gvisor/pkg/log" "gvisor.dev/gvisor/pkg/memutil" "gvisor.dev/gvisor/pkg/rand" "gvisor.dev/gvisor/pkg/sentry/arch" "gvisor.dev/gvisor/pkg/sentry/control" "gvisor.dev/gvisor/pkg/sentry/fdimport" "gvisor.dev/gvisor/pkg/sentry/fs" "gvisor.dev/gvisor/pkg/sentry/fs/host" "gvisor.dev/gvisor/pkg/sentry/fs/user" hostvfs2 "gvisor.dev/gvisor/pkg/sentry/fsimpl/host" "gvisor.dev/gvisor/pkg/sentry/inet" "gvisor.dev/gvisor/pkg/sentry/kernel" "gvisor.dev/gvisor/pkg/sentry/kernel/auth" "gvisor.dev/gvisor/pkg/sentry/loader" "gvisor.dev/gvisor/pkg/sentry/pgalloc" "gvisor.dev/gvisor/pkg/sentry/platform" "gvisor.dev/gvisor/pkg/sentry/sighandling" "gvisor.dev/gvisor/pkg/sentry/syscalls/linux/vfs2" "gvisor.dev/gvisor/pkg/sentry/time" "gvisor.dev/gvisor/pkg/sentry/usage" "gvisor.dev/gvisor/pkg/sentry/vfs" "gvisor.dev/gvisor/pkg/sentry/watchdog" "gvisor.dev/gvisor/pkg/sync" "gvisor.dev/gvisor/pkg/tcpip" "gvisor.dev/gvisor/pkg/tcpip/link/loopback" "gvisor.dev/gvisor/pkg/tcpip/link/sniffer" "gvisor.dev/gvisor/pkg/tcpip/network/arp" "gvisor.dev/gvisor/pkg/tcpip/network/ipv4" "gvisor.dev/gvisor/pkg/tcpip/network/ipv6" "gvisor.dev/gvisor/pkg/tcpip/stack" "gvisor.dev/gvisor/pkg/tcpip/transport/icmp" "gvisor.dev/gvisor/pkg/tcpip/transport/raw" "gvisor.dev/gvisor/pkg/tcpip/transport/tcp" "gvisor.dev/gvisor/pkg/tcpip/transport/udp" "gvisor.dev/gvisor/runsc/boot/filter" _ "gvisor.dev/gvisor/runsc/boot/platforms" // register all platforms. "gvisor.dev/gvisor/runsc/boot/pprof" "gvisor.dev/gvisor/runsc/specutils" // Include supported socket providers. "gvisor.dev/gvisor/pkg/sentry/socket/hostinet" _ "gvisor.dev/gvisor/pkg/sentry/socket/netlink" _ "gvisor.dev/gvisor/pkg/sentry/socket/netlink/route" _ "gvisor.dev/gvisor/pkg/sentry/socket/netlink/uevent" "gvisor.dev/gvisor/pkg/sentry/socket/netstack" _ "gvisor.dev/gvisor/pkg/sentry/socket/unix" ) // Loader keeps state needed to start the kernel and run the container.. type Loader struct { // k is the kernel. k *kernel.Kernel // ctrl is the control server. ctrl *controller conf *Config // console is set to true if terminal is enabled. console bool watchdog *watchdog.Watchdog // stdioFDs contains stdin, stdout, and stderr. stdioFDs []int // goferFDs are the FDs that attach the sandbox to the gofers. goferFDs []int // spec is the base configuration for the root container. spec *specs.Spec // stopSignalForwarding disables forwarding of signals to the sandboxed // container. It should be called when a sandbox is destroyed. stopSignalForwarding func() // restore is set to true if we are restoring a container. restore bool // rootProcArgs refers to the root sandbox init task. rootProcArgs kernel.CreateProcessArgs // sandboxID is the ID for the whole sandbox. sandboxID string // mu guards processes. mu sync.Mutex // processes maps containers init process and invocation of exec. Root // processes are keyed with container ID and pid=0, while exec invocations // have the corresponding pid set. // // processes is guardded by mu. processes map[execID]*execProcess // mountHints provides extra information about mounts for containers that // apply to the entire pod. mountHints *podMountHints } // execID uniquely identifies a sentry process that is executed in a container. type execID struct { cid string pid kernel.ThreadID } // execProcess contains the thread group and host TTY of a sentry process. type execProcess struct { // tg will be nil for containers that haven't started yet. tg *kernel.ThreadGroup // tty will be nil if the process is not attached to a terminal. tty *host.TTYFileOperations // tty will be nil if the process is not attached to a terminal. ttyVFS2 *hostvfs2.TTYFileDescription // pidnsPath is the pid namespace path in spec pidnsPath string } func init() { // Initialize the random number generator. mrand.Seed(gtime.Now().UnixNano()) } // Args are the arguments for New(). type Args struct { // Id is the sandbox ID. ID string // Spec is the sandbox specification. Spec *specs.Spec // Conf is the system configuration. Conf *Config // ControllerFD is the FD to the URPC controller. The Loader takes ownership // of this FD and may close it at any time. ControllerFD int // Device is an optional argument that is passed to the platform. The Loader // takes ownership of this file and may close it at any time. Device *os.File // GoferFDs is an array of FDs used to connect with the Gofer. The Loader // takes ownership of these FDs and may close them at any time. GoferFDs []int // StdioFDs is the stdio for the application. The Loader takes ownership of // these FDs and may close them at any time. StdioFDs []int // Console is set to true if using TTY. Console bool // NumCPU is the number of CPUs to create inside the sandbox. NumCPU int // TotalMem is the initial amount of total memory to report back to the // container. TotalMem uint64 // UserLogFD is the file descriptor to write user logs to. UserLogFD int } // make sure stdioFDs are always the same on initial start and on restore const startingStdioFD = 64 // New initializes a new kernel loader configured by spec. // New also handles setting up a kernel for restoring a container. func New(args Args) (*Loader, error) { // We initialize the rand package now to make sure /dev/urandom is pre-opened // on kernels that do not support getrandom(2). if err := rand.Init(); err != nil { return nil, fmt.Errorf("setting up rand: %v", err) } if err := usage.Init(); err != nil { return nil, fmt.Errorf("setting up memory usage: %v", err) } // Is this a VFSv2 kernel? if args.Conf.VFS2 { kernel.VFS2Enabled = true vfs2.Override() } // Create kernel and platform. p, err := createPlatform(args.Conf, args.Device) if err != nil { return nil, fmt.Errorf("creating platform: %v", err) } k := &kernel.Kernel{ Platform: p, } // Create memory file. mf, err := createMemoryFile() if err != nil { return nil, fmt.Errorf("creating memory file: %v", err) } k.SetMemoryFile(mf) // Create VDSO. // // Pass k as the platform since it is savable, unlike the actual platform. // // FIXME(b/109889800): Use non-nil context. vdso, err := loader.PrepareVDSO(nil, k) if err != nil { return nil, fmt.Errorf("creating vdso: %v", err) } // Create timekeeper. tk, err := kernel.NewTimekeeper(k, vdso.ParamPage.FileRange()) if err != nil { return nil, fmt.Errorf("creating timekeeper: %v", err) } tk.SetClocks(time.NewCalibratedClocks()) if err := enableStrace(args.Conf); err != nil { return nil, fmt.Errorf("enabling strace: %v", err) } // Create root network namespace/stack. netns, err := newRootNetworkNamespace(args.Conf, k, k) if err != nil { return nil, fmt.Errorf("creating network: %v", err) } // Create capabilities. caps, err := specutils.Capabilities(args.Conf.EnableRaw, args.Spec.Process.Capabilities) if err != nil { return nil, fmt.Errorf("converting capabilities: %v", err) } // Convert the spec's additional GIDs to KGIDs. extraKGIDs := make([]auth.KGID, 0, len(args.Spec.Process.User.AdditionalGids)) for _, GID := range args.Spec.Process.User.AdditionalGids { extraKGIDs = append(extraKGIDs, auth.KGID(GID)) } // Create credentials. creds := auth.NewUserCredentials( auth.KUID(args.Spec.Process.User.UID), auth.KGID(args.Spec.Process.User.GID), extraKGIDs, caps, auth.NewRootUserNamespace()) if args.NumCPU == 0 { args.NumCPU = runtime.NumCPU() } log.Infof("CPUs: %d", args.NumCPU) if args.TotalMem > 0 { // Adjust the total memory returned by the Sentry so that applications that // use /proc/meminfo can make allocations based on this limit. usage.MinimumTotalMemoryBytes = args.TotalMem log.Infof("Setting total memory to %.2f GB", float64(args.TotalMem)/(1<<30)) } // Initiate the Kernel object, which is required by the Context passed // to createVFS in order to mount (among other things) procfs. if err = k.Init(kernel.InitKernelArgs{ FeatureSet: cpuid.HostFeatureSet(), Timekeeper: tk, RootUserNamespace: creds.UserNamespace, RootNetworkNamespace: netns, ApplicationCores: uint(args.NumCPU), Vdso: vdso, RootUTSNamespace: kernel.NewUTSNamespace(args.Spec.Hostname, args.Spec.Hostname, creds.UserNamespace), RootIPCNamespace: kernel.NewIPCNamespace(creds.UserNamespace), RootAbstractSocketNamespace: kernel.NewAbstractSocketNamespace(), PIDNamespace: kernel.NewRootPIDNamespace(creds.UserNamespace), }); err != nil { return nil, fmt.Errorf("initializing kernel: %v", err) } if err := adjustDirentCache(k); err != nil { return nil, err } // Turn on packet logging if enabled. if args.Conf.LogPackets { log.Infof("Packet logging enabled") atomic.StoreUint32(&sniffer.LogPackets, 1) } else { log.Infof("Packet logging disabled") atomic.StoreUint32(&sniffer.LogPackets, 0) } // Create a watchdog. dogOpts := watchdog.DefaultOpts dogOpts.TaskTimeoutAction = args.Conf.WatchdogAction dog := watchdog.New(k, dogOpts) procArgs, err := newProcess(args.ID, args.Spec, creds, k, k.RootPIDNamespace()) if err != nil { return nil, fmt.Errorf("creating init process for root container: %v", err) } if err := initCompatLogs(args.UserLogFD); err != nil { return nil, fmt.Errorf("initializing compat logs: %v", err) } mountHints, err := newPodMountHints(args.Spec) if err != nil { return nil, fmt.Errorf("creating pod mount hints: %v", err) } if kernel.VFS2Enabled { // Set up host mount that will be used for imported fds. hostFilesystem := hostvfs2.NewFilesystem(k.VFS()) defer hostFilesystem.DecRef() hostMount, err := k.VFS().NewDisconnectedMount(hostFilesystem, nil, &vfs.MountOptions{}) if err != nil { return nil, fmt.Errorf("failed to create hostfs mount: %v", err) } k.SetHostMount(hostMount) } // Make host FDs stable between invocations. Host FDs must map to the exact // same number when the sandbox is restored. Otherwise the wrong FD will be // used. var stdioFDs []int newfd := startingStdioFD for _, fd := range args.StdioFDs { err := syscall.Dup3(fd, newfd, syscall.O_CLOEXEC) if err != nil { return nil, fmt.Errorf("dup3 of stdioFDs failed: %v", err) } stdioFDs = append(stdioFDs, newfd) err = syscall.Close(fd) if err != nil { return nil, fmt.Errorf("close original stdioFDs failed: %v", err) } newfd++ } eid := execID{cid: args.ID} l := &Loader{ k: k, conf: args.Conf, console: args.Console, watchdog: dog, spec: args.Spec, goferFDs: args.GoferFDs, stdioFDs: stdioFDs, rootProcArgs: procArgs, sandboxID: args.ID, processes: map[execID]*execProcess{eid: {}}, mountHints: mountHints, } // We don't care about child signals; some platforms can generate a // tremendous number of useless ones (I'm looking at you, ptrace). if err := sighandling.IgnoreChildStop(); err != nil { return nil, fmt.Errorf("ignore child stop signals failed: %v", err) } // Create the control server using the provided FD. // // This must be done *after* we have initialized the kernel since the // controller is used to configure the kernel's network stack. ctrl, err := newController(args.ControllerFD, l) if err != nil { return nil, fmt.Errorf("creating control server: %v", err) } l.ctrl = ctrl // Only start serving after Loader is set to controller and controller is set // to Loader, because they are both used in the urpc methods. if err := ctrl.srv.StartServing(); err != nil { return nil, fmt.Errorf("starting control server: %v", err) } return l, nil } // newProcess creates a process that can be run with kernel.CreateProcess. func newProcess(id string, spec *specs.Spec, creds *auth.Credentials, k *kernel.Kernel, pidns *kernel.PIDNamespace) (kernel.CreateProcessArgs, error) { // Create initial limits. ls, err := createLimitSet(spec) if err != nil { return kernel.CreateProcessArgs{}, fmt.Errorf("creating limits: %v", err) } wd := spec.Process.Cwd if wd == "" { wd = "/" } // Create the process arguments. procArgs := kernel.CreateProcessArgs{ Argv: spec.Process.Args, Envv: spec.Process.Env, WorkingDirectory: wd, Credentials: creds, Umask: 0022, Limits: ls, MaxSymlinkTraversals: linux.MaxSymlinkTraversals, UTSNamespace: k.RootUTSNamespace(), IPCNamespace: k.RootIPCNamespace(), AbstractSocketNamespace: k.RootAbstractSocketNamespace(), ContainerID: id, PIDNamespace: pidns, } return procArgs, nil } // Destroy cleans up all resources used by the loader. // // Note that this will block until all open control server connections have // been closed. For that reason, this should NOT be called in a defer, because // a panic in a control server rpc would then hang forever. func (l *Loader) Destroy() { if l.ctrl != nil { l.ctrl.srv.Stop() } if l.stopSignalForwarding != nil { l.stopSignalForwarding() } l.watchdog.Stop() } func createPlatform(conf *Config, deviceFile *os.File) (platform.Platform, error) { p, err := platform.Lookup(conf.Platform) if err != nil { panic(fmt.Sprintf("invalid platform %v: %v", conf.Platform, err)) } log.Infof("Platform: %s", conf.Platform) return p.New(deviceFile) } func createMemoryFile() (*pgalloc.MemoryFile, error) { const memfileName = "runsc-memory" memfd, err := memutil.CreateMemFD(memfileName, 0) if err != nil { return nil, fmt.Errorf("error creating memfd: %v", err) } memfile := os.NewFile(uintptr(memfd), memfileName) // We can't enable pgalloc.MemoryFileOpts.UseHostMemcgPressure even if // there are memory cgroups specified, because at this point we're already // in a mount namespace in which the relevant cgroupfs is not visible. mf, err := pgalloc.NewMemoryFile(memfile, pgalloc.MemoryFileOpts{}) if err != nil { memfile.Close() return nil, fmt.Errorf("error creating pgalloc.MemoryFile: %v", err) } return mf, nil } func (l *Loader) installSeccompFilters() error { if l.conf.DisableSeccomp { filter.Report("syscall filter is DISABLED. Running in less secure mode.") } else { opts := filter.Options{ Platform: l.k.Platform, HostNetwork: l.conf.Network == NetworkHost, ProfileEnable: l.conf.ProfileEnable, ControllerFD: l.ctrl.srv.FD(), } if err := filter.Install(opts); err != nil { return fmt.Errorf("installing seccomp filters: %v", err) } } return nil } // Run runs the root container. func (l *Loader) Run() error { err := l.run() l.ctrl.manager.startResultChan <- err if err != nil { // Give the controller some time to send the error to the // runtime. If we return too quickly here the process will exit // and the control connection will be closed before the error // is returned. gtime.Sleep(2 * gtime.Second) return err } return nil } func (l *Loader) run() error { if l.conf.Network == NetworkHost { // Delay host network configuration to this point because network namespace // is configured after the loader is created and before Run() is called. log.Debugf("Configuring host network") stack := l.k.RootNetworkNamespace().Stack().(*hostinet.Stack) if err := stack.Configure(); err != nil { return err } } l.mu.Lock() defer l.mu.Unlock() eid := execID{cid: l.sandboxID} ep, ok := l.processes[eid] if !ok { return fmt.Errorf("trying to start deleted container %q", l.sandboxID) } // If we are restoring, we do not want to create a process. // l.restore is set by the container manager when a restore call is made. var ttyFile *host.TTYFileOperations var ttyFileVFS2 *hostvfs2.TTYFileDescription if !l.restore { if l.conf.ProfileEnable { pprof.Initialize() } // Finally done with all configuration. Setup filters before user code // is loaded. if err := l.installSeccompFilters(); err != nil { return err } // Create the FD map, which will set stdin, stdout, and stderr. If console // is true, then ioctl calls will be passed through to the host fd. ctx := l.rootProcArgs.NewContext(l.k) var err error // CreateProcess takes a reference on FDMap if successful. We won't need // ours either way. l.rootProcArgs.FDTable, ttyFile, ttyFileVFS2, err = createFDTable(ctx, l.console, l.stdioFDs) if err != nil { return fmt.Errorf("importing fds: %v", err) } // Setup the root container file system. l.startGoferMonitor(l.sandboxID, l.goferFDs) mntr := newContainerMounter(l.spec, l.goferFDs, l.k, l.mountHints) if err := mntr.processHints(l.conf); err != nil { return err } if err := setupContainerFS(ctx, l.conf, mntr, &l.rootProcArgs); err != nil { return err } // Add the HOME enviroment variable if it is not already set. var envv []string if kernel.VFS2Enabled { envv, err = user.MaybeAddExecUserHomeVFS2(ctx, l.rootProcArgs.MountNamespaceVFS2, l.rootProcArgs.Credentials.RealKUID, l.rootProcArgs.Envv) } else { envv, err = user.MaybeAddExecUserHome(ctx, l.rootProcArgs.MountNamespace, l.rootProcArgs.Credentials.RealKUID, l.rootProcArgs.Envv) } if err != nil { return err } l.rootProcArgs.Envv = envv // Create the root container init task. It will begin running // when the kernel is started. if _, _, err := l.k.CreateProcess(l.rootProcArgs); err != nil { return fmt.Errorf("creating init process: %v", err) } // CreateProcess takes a reference on FDTable if successful. l.rootProcArgs.FDTable.DecRef() } ep.tg = l.k.GlobalInit() if ns, ok := specutils.GetNS(specs.PIDNamespace, l.spec); ok { ep.pidnsPath = ns.Path } if l.console { // Set the foreground process group on the TTY to the global init process // group, since that is what we are about to start running. switch { case ttyFileVFS2 != nil: ep.ttyVFS2 = ttyFileVFS2 ttyFileVFS2.InitForegroundProcessGroup(ep.tg.ProcessGroup()) case ttyFile != nil: ep.tty = ttyFile ttyFile.InitForegroundProcessGroup(ep.tg.ProcessGroup()) } } // Handle signals by forwarding them to the root container process // (except for panic signal, which should cause a panic). l.stopSignalForwarding = sighandling.StartSignalForwarding(func(sig linux.Signal) { // Panic signal should cause a panic. if l.conf.PanicSignal != -1 && sig == linux.Signal(l.conf.PanicSignal) { panic("Signal-induced panic") } // Otherwise forward to root container. deliveryMode := DeliverToProcess if l.console { // Since we are running with a console, we should forward the signal to // the foreground process group so that job control signals like ^C can // be handled properly. deliveryMode = DeliverToForegroundProcessGroup } log.Infof("Received external signal %d, mode: %v", sig, deliveryMode) if err := l.signal(l.sandboxID, 0, int32(sig), deliveryMode); err != nil { log.Warningf("error sending signal %v to container %q: %v", sig, l.sandboxID, err) } }) // l.stdioFDs are derived from dup() in boot.New() and they are now dup()ed again // either in createFDTable() during initial start or in descriptor.initAfterLoad() // during restore, we can release l.stdioFDs now. VFS2 takes ownership of the // passed FDs, so only close for VFS1. if !kernel.VFS2Enabled { for _, fd := range l.stdioFDs { err := syscall.Close(fd) if err != nil { return fmt.Errorf("close dup()ed stdioFDs: %v", err) } } } log.Infof("Process should have started...") l.watchdog.Start() return l.k.Start() } // createContainer creates a new container inside the sandbox. func (l *Loader) createContainer(cid string) error { l.mu.Lock() defer l.mu.Unlock() eid := execID{cid: cid} if _, ok := l.processes[eid]; ok { return fmt.Errorf("container %q already exists", cid) } l.processes[eid] = &execProcess{} return nil } // startContainer starts a child container. It returns the thread group ID of // the newly created process. Caller owns 'files' and may close them after // this method returns. func (l *Loader) startContainer(spec *specs.Spec, conf *Config, cid string, files []*os.File) error { // Create capabilities. caps, err := specutils.Capabilities(conf.EnableRaw, spec.Process.Capabilities) if err != nil { return fmt.Errorf("creating capabilities: %v", err) } l.mu.Lock() defer l.mu.Unlock() eid := execID{cid: cid} if _, ok := l.processes[eid]; !ok { return fmt.Errorf("trying to start a deleted container %q", cid) } // Convert the spec's additional GIDs to KGIDs. extraKGIDs := make([]auth.KGID, 0, len(spec.Process.User.AdditionalGids)) for _, GID := range spec.Process.User.AdditionalGids { extraKGIDs = append(extraKGIDs, auth.KGID(GID)) } // Create credentials. We reuse the root user namespace because the // sentry currently supports only 1 mount namespace, which is tied to a // single user namespace. Thus we must run in the same user namespace // to access mounts. creds := auth.NewUserCredentials( auth.KUID(spec.Process.User.UID), auth.KGID(spec.Process.User.GID), extraKGIDs, caps, l.k.RootUserNamespace()) var pidns *kernel.PIDNamespace if ns, ok := specutils.GetNS(specs.PIDNamespace, spec); ok { if ns.Path != "" { for _, p := range l.processes { if ns.Path == p.pidnsPath { pidns = p.tg.PIDNamespace() break } } } if pidns == nil { pidns = l.k.RootPIDNamespace().NewChild(l.k.RootUserNamespace()) } l.processes[eid].pidnsPath = ns.Path } else { pidns = l.k.RootPIDNamespace() } procArgs, err := newProcess(cid, spec, creds, l.k, pidns) if err != nil { return fmt.Errorf("creating new process: %v", err) } // setupContainerFS() dups stdioFDs, so we don't need to dup them here. var stdioFDs []int for _, f := range files[:3] { stdioFDs = append(stdioFDs, int(f.Fd())) } // Create the FD map, which will set stdin, stdout, and stderr. ctx := procArgs.NewContext(l.k) fdTable, _, _, err := createFDTable(ctx, false, stdioFDs) if err != nil { return fmt.Errorf("importing fds: %v", err) } // CreateProcess takes a reference on fdTable if successful. We won't // need ours either way. procArgs.FDTable = fdTable // Can't take ownership away from os.File. dup them to get a new FDs. var goferFDs []int for _, f := range files[3:] { fd, err := syscall.Dup(int(f.Fd())) if err != nil { return fmt.Errorf("failed to dup file: %v", err) } goferFDs = append(goferFDs, fd) } // Setup the child container file system. l.startGoferMonitor(cid, goferFDs) mntr := newContainerMounter(spec, goferFDs, l.k, l.mountHints) if err := setupContainerFS(ctx, conf, mntr, &procArgs); err != nil { return err } // Create and start the new process. tg, _, err := l.k.CreateProcess(procArgs) if err != nil { return fmt.Errorf("creating process: %v", err) } l.k.StartProcess(tg) // CreateProcess takes a reference on FDTable if successful. procArgs.FDTable.DecRef() l.processes[eid].tg = tg return nil } // startGoferMonitor runs a goroutine to monitor gofer's health. It polls on // the gofer FDs looking for disconnects, and destroys the container if a // disconnect occurs in any of the gofer FDs. func (l *Loader) startGoferMonitor(cid string, goferFDs []int) { go func() { log.Debugf("Monitoring gofer health for container %q", cid) var events []unix.PollFd for _, fd := range goferFDs { events = append(events, unix.PollFd{ Fd: int32(fd), Events: unix.POLLHUP | unix.POLLRDHUP, }) } _, _, err := specutils.RetryEintr(func() (uintptr, uintptr, error) { // Use ppoll instead of poll because it's already whilelisted in seccomp. n, err := unix.Ppoll(events, nil, nil) return uintptr(n), 0, err }) if err != nil { panic(fmt.Sprintf("Error monitoring gofer FDs: %v", err)) } // Check if the gofer has stopped as part of normal container destruction. // This is done just to avoid sending an annoying error message to the log. // Note that there is a small race window in between mu.Unlock() and the // lock being reacquired in destroyContainer(), but it's harmless to call // destroyContainer() multiple times. l.mu.Lock() _, ok := l.processes[execID{cid: cid}] l.mu.Unlock() if ok { log.Infof("Gofer socket disconnected, destroying container %q", cid) if err := l.destroyContainer(cid); err != nil { log.Warningf("Error destroying container %q after gofer stopped: %v", cid, err) } } }() } // destroyContainer stops a container if it is still running and cleans up its // filesystem. func (l *Loader) destroyContainer(cid string) error { l.mu.Lock() defer l.mu.Unlock() tg, err := l.tryThreadGroupFromIDLocked(execID{cid: cid}) if err != nil { // Container doesn't exist. return err } // The container exists, but has it been started? if tg != nil { if err := l.signalAllProcesses(cid, int32(linux.SIGKILL)); err != nil { return fmt.Errorf("sending SIGKILL to all container processes: %v", err) } // Wait for all processes that belong to the container to exit (including // exec'd processes). for _, t := range l.k.TaskSet().Root.Tasks() { if t.ContainerID() == cid { t.ThreadGroup().WaitExited() } } // At this point, all processes inside of the container have exited, // releasing all references to the container's MountNamespace and // causing all submounts and overlays to be unmounted. // // Since the container's MountNamespace has been released, // MountNamespace.destroy() will have executed, but that function may // trigger async close operations. We must wait for those to complete // before returning, otherwise the caller may kill the gofer before // they complete, causing a cascade of failing RPCs. fs.AsyncBarrier() } // No more failure from this point on. Remove all container thread groups // from the map. for key := range l.processes { if key.cid == cid { delete(l.processes, key) } } log.Debugf("Container destroyed %q", cid) return nil } func (l *Loader) executeAsync(args *control.ExecArgs) (kernel.ThreadID, error) { // Hold the lock for the entire operation to ensure that exec'd process is // added to 'processes' in case it races with destroyContainer(). l.mu.Lock() defer l.mu.Unlock() tg, err := l.tryThreadGroupFromIDLocked(execID{cid: args.ContainerID}) if err != nil { return 0, err } if tg == nil { return 0, fmt.Errorf("container %q not started", args.ContainerID) } // Get the container MountNamespace from the Task. if kernel.VFS2Enabled { // task.MountNamespace() does not take a ref, so we must do so ourselves. args.MountNamespaceVFS2 = tg.Leader().MountNamespaceVFS2() args.MountNamespaceVFS2.IncRef() } else { tg.Leader().WithMuLocked(func(t *kernel.Task) { // task.MountNamespace() does not take a ref, so we must do so ourselves. args.MountNamespace = t.MountNamespace() args.MountNamespace.IncRef() }) } // Add the HOME environment variable if it is not already set. if kernel.VFS2Enabled { defer args.MountNamespaceVFS2.DecRef() root := args.MountNamespaceVFS2.Root() defer root.DecRef() ctx := vfs.WithRoot(l.k.SupervisorContext(), root) envv, err := user.MaybeAddExecUserHomeVFS2(ctx, args.MountNamespaceVFS2, args.KUID, args.Envv) if err != nil { return 0, err } args.Envv = envv } else { defer args.MountNamespace.DecRef() root := args.MountNamespace.Root() defer root.DecRef() ctx := fs.WithRoot(l.k.SupervisorContext(), root) envv, err := user.MaybeAddExecUserHome(ctx, args.MountNamespace, args.KUID, args.Envv) if err != nil { return 0, err } args.Envv = envv } // Start the process. proc := control.Proc{Kernel: l.k} args.PIDNamespace = tg.PIDNamespace() newTG, tgid, ttyFile, ttyFileVFS2, err := control.ExecAsync(&proc, args) if err != nil { return 0, err } eid := execID{cid: args.ContainerID, pid: tgid} l.processes[eid] = &execProcess{ tg: newTG, tty: ttyFile, ttyVFS2: ttyFileVFS2, } log.Debugf("updated processes: %v", l.processes) return tgid, nil } // waitContainer waits for the init process of a container to exit. func (l *Loader) waitContainer(cid string, waitStatus *uint32) error { // Don't defer unlock, as doing so would make it impossible for // multiple clients to wait on the same container. tg, err := l.threadGroupFromID(execID{cid: cid}) if err != nil { return fmt.Errorf("can't wait for container %q: %v", cid, err) } // If the thread either has already exited or exits during waiting, // consider the container exited. ws := l.wait(tg) *waitStatus = ws return nil } func (l *Loader) waitPID(tgid kernel.ThreadID, cid string, waitStatus *uint32) error { if tgid <= 0 { return fmt.Errorf("PID (%d) must be positive", tgid) } // Try to find a process that was exec'd eid := execID{cid: cid, pid: tgid} execTG, err := l.threadGroupFromID(eid) if err == nil { ws := l.wait(execTG) *waitStatus = ws l.mu.Lock() delete(l.processes, eid) log.Debugf("updated processes (removal): %v", l.processes) l.mu.Unlock() return nil } // The caller may be waiting on a process not started directly via exec. // In this case, find the process in the container's PID namespace. initTG, err := l.threadGroupFromID(execID{cid: cid}) if err != nil { return fmt.Errorf("waiting for PID %d: %v", tgid, err) } tg := initTG.PIDNamespace().ThreadGroupWithID(tgid) if tg == nil { return fmt.Errorf("waiting for PID %d: no such process", tgid) } if tg.Leader().ContainerID() != cid { return fmt.Errorf("process %d is part of a different container: %q", tgid, tg.Leader().ContainerID()) } ws := l.wait(tg) *waitStatus = ws return nil } // wait waits for the process with TGID 'tgid' in a container's PID namespace // to exit. func (l *Loader) wait(tg *kernel.ThreadGroup) uint32 { tg.WaitExited() return tg.ExitStatus().Status() } // WaitForStartSignal waits for a start signal from the control server. func (l *Loader) WaitForStartSignal() { <-l.ctrl.manager.startChan } // WaitExit waits for the root container to exit, and returns its exit status. func (l *Loader) WaitExit() kernel.ExitStatus { // Wait for container. l.k.WaitExited() return l.k.GlobalInit().ExitStatus() } func newRootNetworkNamespace(conf *Config, clock tcpip.Clock, uniqueID stack.UniqueID) (*inet.Namespace, error) { // Create an empty network stack because the network namespace may be empty at // this point. Netns is configured before Run() is called. Netstack is // configured using a control uRPC message. Host network is configured inside // Run(). switch conf.Network { case NetworkHost: // No network namespacing support for hostinet yet, hence creator is nil. return inet.NewRootNamespace(hostinet.NewStack(), nil), nil case NetworkNone, NetworkSandbox: s, err := newEmptySandboxNetworkStack(clock, uniqueID) if err != nil { return nil, err } creator := &sandboxNetstackCreator{ clock: clock, uniqueID: uniqueID, } return inet.NewRootNamespace(s, creator), nil default: panic(fmt.Sprintf("invalid network configuration: %v", conf.Network)) } } func newEmptySandboxNetworkStack(clock tcpip.Clock, uniqueID stack.UniqueID) (inet.Stack, error) { netProtos := []stack.NetworkProtocol{ipv4.NewProtocol(), ipv6.NewProtocol(), arp.NewProtocol()} transProtos := []stack.TransportProtocol{tcp.NewProtocol(), udp.NewProtocol(), icmp.NewProtocol4()} s := netstack.Stack{stack.New(stack.Options{ NetworkProtocols: netProtos, TransportProtocols: transProtos, Clock: clock, Stats: netstack.Metrics, HandleLocal: true, // Enable raw sockets for users with sufficient // privileges. RawFactory: raw.EndpointFactory{}, UniqueID: uniqueID, })} // Enable SACK Recovery. if err := s.Stack.SetTransportProtocolOption(tcp.ProtocolNumber, tcp.SACKEnabled(true)); err != nil { return nil, fmt.Errorf("failed to enable SACK: %v", err) } // Set default TTLs as required by socket/netstack. s.Stack.SetNetworkProtocolOption(ipv4.ProtocolNumber, tcpip.DefaultTTLOption(netstack.DefaultTTL)) s.Stack.SetNetworkProtocolOption(ipv6.ProtocolNumber, tcpip.DefaultTTLOption(netstack.DefaultTTL)) // Enable Receive Buffer Auto-Tuning. if err := s.Stack.SetTransportProtocolOption(tcp.ProtocolNumber, tcpip.ModerateReceiveBufferOption(true)); err != nil { return nil, fmt.Errorf("SetTransportProtocolOption failed: %v", err) } s.FillDefaultIPTables() return &s, nil } // sandboxNetstackCreator implements kernel.NetworkStackCreator. // // +stateify savable type sandboxNetstackCreator struct { clock tcpip.Clock uniqueID stack.UniqueID } // CreateStack implements kernel.NetworkStackCreator.CreateStack. func (f *sandboxNetstackCreator) CreateStack() (inet.Stack, error) { s, err := newEmptySandboxNetworkStack(f.clock, f.uniqueID) if err != nil { return nil, err } // Setup loopback. n := &Network{Stack: s.(*netstack.Stack).Stack} nicID := tcpip.NICID(f.uniqueID.UniqueID()) link := DefaultLoopbackLink linkEP := loopback.New() if err := n.createNICWithAddrs(nicID, link.Name, linkEP, link.Addresses); err != nil { return nil, err } return s, nil } // signal sends a signal to one or more processes in a container. If PID is 0, // then the container init process is used. Depending on the SignalDeliveryMode // option, the signal may be sent directly to the indicated process, to all // processes in the container, or to the foreground process group. func (l *Loader) signal(cid string, pid, signo int32, mode SignalDeliveryMode) error { if pid < 0 { return fmt.Errorf("PID (%d) must be positive", pid) } switch mode { case DeliverToProcess: if err := l.signalProcess(cid, kernel.ThreadID(pid), signo); err != nil { return fmt.Errorf("signaling process in container %q PID %d: %v", cid, pid, err) } return nil case DeliverToForegroundProcessGroup: if err := l.signalForegrondProcessGroup(cid, kernel.ThreadID(pid), signo); err != nil { return fmt.Errorf("signaling foreground process group in container %q PID %d: %v", cid, pid, err) } return nil case DeliverToAllProcesses: if pid != 0 { return fmt.Errorf("PID (%d) cannot be set when signaling all processes", pid) } // Check that the container has actually started before signaling it. if _, err := l.threadGroupFromID(execID{cid: cid}); err != nil { return err } if err := l.signalAllProcesses(cid, signo); err != nil { return fmt.Errorf("signaling all processes in container %q: %v", cid, err) } return nil default: panic(fmt.Sprintf("unknown signal delivery mode %v", mode)) } } func (l *Loader) signalProcess(cid string, tgid kernel.ThreadID, signo int32) error { execTG, err := l.threadGroupFromID(execID{cid: cid, pid: tgid}) if err == nil { // Send signal directly to the identified process. return l.k.SendExternalSignalThreadGroup(execTG, &arch.SignalInfo{Signo: signo}) } // The caller may be signaling a process not started directly via exec. // In this case, find the process in the container's PID namespace and // signal it. initTG, err := l.threadGroupFromID(execID{cid: cid}) if err != nil { return fmt.Errorf("no thread group found: %v", err) } tg := initTG.PIDNamespace().ThreadGroupWithID(tgid) if tg == nil { return fmt.Errorf("no such process with PID %d", tgid) } if tg.Leader().ContainerID() != cid { return fmt.Errorf("process %d is part of a different container: %q", tgid, tg.Leader().ContainerID()) } return l.k.SendExternalSignalThreadGroup(tg, &arch.SignalInfo{Signo: signo}) } // signalForegrondProcessGroup looks up foreground process group from the TTY // for the given "tgid" inside container "cid", and send the signal to it. func (l *Loader) signalForegrondProcessGroup(cid string, tgid kernel.ThreadID, signo int32) error { l.mu.Lock() tg, err := l.tryThreadGroupFromIDLocked(execID{cid: cid, pid: tgid}) if err != nil { l.mu.Unlock() return fmt.Errorf("no thread group found: %v", err) } if tg == nil { l.mu.Unlock() return fmt.Errorf("container %q not started", cid) } tty, ttyVFS2, err := l.ttyFromIDLocked(execID{cid: cid, pid: tgid}) l.mu.Unlock() if err != nil { return fmt.Errorf("no thread group found: %v", err) } var pg *kernel.ProcessGroup switch { case ttyVFS2 != nil: pg = ttyVFS2.ForegroundProcessGroup() case tty != nil: pg = tty.ForegroundProcessGroup() default: return fmt.Errorf("no TTY attached") } if pg == nil { // No foreground process group has been set. Signal the // original thread group. log.Warningf("No foreground process group for container %q and PID %d. Sending signal directly to PID %d.", cid, tgid, tgid) return l.k.SendExternalSignalThreadGroup(tg, &arch.SignalInfo{Signo: signo}) } // Send the signal to all processes in the process group. var lastErr error for _, tg := range l.k.TaskSet().Root.ThreadGroups() { if tg.ProcessGroup() != pg { continue } if err := l.k.SendExternalSignalThreadGroup(tg, &arch.SignalInfo{Signo: signo}); err != nil { lastErr = err } } return lastErr } // signalAllProcesses that belong to specified container. It's a noop if the // container hasn't started or has exited. func (l *Loader) signalAllProcesses(cid string, signo int32) error { // Pause the kernel to prevent new processes from being created while // the signal is delivered. This prevents process leaks when SIGKILL is // sent to the entire container. l.k.Pause() defer l.k.Unpause() return l.k.SendContainerSignal(cid, &arch.SignalInfo{Signo: signo}) } // threadGroupFromID is similar to tryThreadGroupFromIDLocked except that it // acquires mutex before calling it and fails in case container hasn't started // yet. func (l *Loader) threadGroupFromID(key execID) (*kernel.ThreadGroup, error) { l.mu.Lock() defer l.mu.Unlock() tg, err := l.tryThreadGroupFromIDLocked(key) if err != nil { return nil, err } if tg == nil { return nil, fmt.Errorf("container %q not started", key.cid) } return tg, nil } // tryThreadGroupFromIDLocked returns the thread group for the given execution // ID. It may return nil in case the container has not started yet. Returns // error if execution ID is invalid or if the container cannot be found (maybe // it has been deleted). Caller must hold 'mu'. func (l *Loader) tryThreadGroupFromIDLocked(key execID) (*kernel.ThreadGroup, error) { ep := l.processes[key] if ep == nil { return nil, fmt.Errorf("container %q not found", key.cid) } return ep.tg, nil } // ttyFromIDLocked returns the TTY files for the given execution ID. It may // return nil in case the container has not started yet. Returns error if // execution ID is invalid or if the container cannot be found (maybe it has // been deleted). Caller must hold 'mu'. func (l *Loader) ttyFromIDLocked(key execID) (*host.TTYFileOperations, *hostvfs2.TTYFileDescription, error) { ep := l.processes[key] if ep == nil { return nil, nil, fmt.Errorf("container %q not found", key.cid) } return ep.tty, ep.ttyVFS2, nil } func createFDTable(ctx context.Context, console bool, stdioFDs []int) (*kernel.FDTable, *host.TTYFileOperations, *hostvfs2.TTYFileDescription, error) { if len(stdioFDs) != 3 { return nil, nil, nil, fmt.Errorf("stdioFDs should contain exactly 3 FDs (stdin, stdout, and stderr), but %d FDs received", len(stdioFDs)) } k := kernel.KernelFromContext(ctx) fdTable := k.NewFDTable() ttyFile, ttyFileVFS2, err := fdimport.Import(ctx, fdTable, console, stdioFDs) if err != nil { fdTable.DecRef() return nil, nil, nil, err } return fdTable, ttyFile, ttyFileVFS2, nil }