// Copyright 2018 Google Inc. // // 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 import ( "errors" "fmt" "path" specs "github.com/opencontainers/runtime-spec/specs-go" "gvisor.googlesource.com/gvisor/pkg/control/server" "gvisor.googlesource.com/gvisor/pkg/log" "gvisor.googlesource.com/gvisor/pkg/sentry/control" "gvisor.googlesource.com/gvisor/pkg/sentry/fs" "gvisor.googlesource.com/gvisor/pkg/sentry/kernel" "gvisor.googlesource.com/gvisor/pkg/sentry/socket/epsocket" "gvisor.googlesource.com/gvisor/pkg/sentry/state" "gvisor.googlesource.com/gvisor/pkg/sentry/time" "gvisor.googlesource.com/gvisor/pkg/sentry/watchdog" "gvisor.googlesource.com/gvisor/pkg/urpc" ) const ( // ContainerCheckpoint checkpoints a container. ContainerCheckpoint = "containerManager.Checkpoint" // ContainerEvent is the URPC endpoint for getting stats about the // container used by "runsc events". ContainerEvent = "containerManager.Event" // ContainerExecute is the URPC endpoint for executing a command in a // container.. ContainerExecute = "containerManager.Execute" // ContainerPause pauses the container. ContainerPause = "containerManager.Pause" // ContainerProcesses is the URPC endpoint for getting the list of // processes running in a container. ContainerProcesses = "containerManager.Processes" // ContainerRestore restores a container from a statefile. ContainerRestore = "containerManager.Restore" // ContainerResume unpauses the paused container. ContainerResume = "containerManager.Resume" // ContainerWaitForLoader blocks until the container's loader has been created. ContainerWaitForLoader = "containerManager.WaitForLoader" // ContainerSignal is used to send a signal to a container. ContainerSignal = "containerManager.Signal" // ContainerStart is the URPC endpoint for running a non-root container // within a sandbox. ContainerStart = "containerManager.Start" // ContainerWait is used to wait on the init process of the container // and return its ExitStatus. ContainerWait = "containerManager.Wait" // ContainerWaitPID is used to wait on a process with a certain PID in // the sandbox and return its ExitStatus. ContainerWaitPID = "containerManager.WaitPID" // NetworkCreateLinksAndRoutes is the URPC endpoint for creating links // and routes in a network stack. NetworkCreateLinksAndRoutes = "Network.CreateLinksAndRoutes" // RootContainerStart is the URPC endpoint for starting a new sandbox // with root container. RootContainerStart = "containerManager.StartRoot" // SandboxStacks collects sandbox stacks for debugging. SandboxStacks = "debug.Stacks" ) // ControlSocketAddr generates an abstract unix socket name for the given id. func ControlSocketAddr(id string) string { return fmt.Sprintf("\x00runsc-sandbox.%s", id) } // controller holds the control server, and is used for communication into the // sandbox. type controller struct { // srv is the control server. srv *server.Server // manager holds the containerManager methods. manager *containerManager } // newController creates a new controller and starts it listening. func newController(fd int, k *kernel.Kernel, w *watchdog.Watchdog) (*controller, error) { srv, err := server.CreateFromFD(fd) if err != nil { return nil, err } manager := &containerManager{ startChan: make(chan struct{}), startResultChan: make(chan error), loaderCreatedChan: make(chan struct{}), } srv.Register(manager) if eps, ok := k.NetworkStack().(*epsocket.Stack); ok { net := &Network{ Stack: eps.Stack, } srv.Register(net) } srv.Register(&debug{}) if err := srv.StartServing(); err != nil { return nil, err } return &controller{ srv: srv, manager: manager, }, nil } // containerManager manages sandboes containers. type containerManager struct { // startChan is used to signal when the root container process should // be started. startChan chan struct{} // startResultChan is used to signal when the root container has // started. Any errors encountered during startup will be sent to the // channel. A nil value indicates success. startResultChan chan error // l is the loader that creates containers and sandboxes. l *Loader // loaderCreatedChan is used to signal when the loader has been created. // After a loader is created, a notify method is called that writes to // this channel. loaderCreatedChan chan struct{} } // StartRoot will start the root container process. func (cm *containerManager) StartRoot(cid *string, _ *struct{}) error { log.Debugf("containerManager.StartRoot") // Tell the root container to start and wait for the result. cm.startChan <- struct{}{} cm.l.setRootContainerID(*cid) return <-cm.startResultChan } // Processes retrieves information about processes running in the sandbox. func (cm *containerManager) Processes(_, out *[]*control.Process) error { log.Debugf("containerManager.Processes") return control.Processes(cm.l.k, out) } // StartArgs contains arguments to the Start method. type StartArgs struct { // Spec is the spec of the container to start. Spec *specs.Spec // TODO: Separate sandbox and container configs. // Config is the runsc-specific configuration for the sandbox. Conf *Config // CID is the ID of the container to start. CID string // FilePayload contains the file descriptor over which the sandbox will // request files from its root filesystem. urpc.FilePayload } // Start runs a created container within a sandbox. func (cm *containerManager) Start(args *StartArgs, _ *struct{}) error { log.Debugf("containerManager.Start: %+v", args) // Validate arguments. if args == nil { return errors.New("start missing arguments") } if args.Spec == nil { return errors.New("start arguments missing spec") } if args.Conf == nil { return errors.New("start arguments missing config") } if args.CID == "" { return errors.New("start argument missing container ID") } // Prevent CIDs containing ".." from confusing the sentry when creating // /containers/ directory. // TODO: Once we have multiple independant roots, this // check won't be necessary. if path.Clean(args.CID) != args.CID { return fmt.Errorf("container ID shouldn't contain directory traversals such as \"..\": %q", args.CID) } if len(args.FilePayload.Files) == 0 { return fmt.Errorf("start arguments must contain at least one file for the container root") } tgid, err := cm.l.startContainer(cm.l.k, args.Spec, args.Conf, args.CID, args.FilePayload.Files) if err != nil { return err } log.Debugf("Container %q started with root PID of %d", args.CID, tgid) return nil } // ExecArgs contains arguments to Execute. type ExecArgs struct { control.ExecArgs // CID is the ID of the container to exec in. CID string } // Execute runs a command on a created or running sandbox. func (cm *containerManager) Execute(e *ExecArgs, waitStatus *uint32) error { log.Debugf("containerManager.Execute: %+v", *e) // Get the container Root Dirent from the Task, since we must run this // process with the same Root. cm.l.mu.Lock() tgid, ok := cm.l.containerRootTGIDs[e.CID] cm.l.mu.Unlock() if !ok { return fmt.Errorf("cannot exec in container %q: no such container", e.CID) } t := cm.l.k.TaskSet().Root.TaskWithID(kernel.ThreadID(tgid)) if t == nil { return fmt.Errorf("cannot exec in container %q: no thread group with ID %d", e.CID, tgid) } t.WithMuLocked(func(t *kernel.Task) { e.Root = t.FSContext().RootDirectory() }) if e.Root != nil { defer e.Root.DecRef() } proc := control.Proc{Kernel: cm.l.k} if err := proc.Exec(&e.ExecArgs, waitStatus); err != nil { return fmt.Errorf("error executing: %+v: %v", e, err) } return nil } // Checkpoint pauses a sandbox and saves its state. func (cm *containerManager) Checkpoint(o *control.SaveOpts, _ *struct{}) error { log.Debugf("containerManager.Checkpoint") state := control.State{ Kernel: cm.l.k, Watchdog: cm.l.watchdog, } return state.Save(o, nil) } // Pause suspends a container. func (cm *containerManager) Pause(_, _ *struct{}) error { cm.l.k.Pause() return nil } // WaitForLoader blocks until the container's loader has been created. func (cm *containerManager) WaitForLoader(_, _ *struct{}) error { log.Debugf("containerManager.WaitForLoader") <-cm.loaderCreatedChan return nil } // RestoreOpts contains options related to restoring a container's file system. type RestoreOpts struct { // FilePayload contains the state file to be restored. urpc.FilePayload // SandboxID contains the ID of the sandbox. SandboxID string } // Restore loads a container from a statefile. // The container's current kernel is destroyed, a restore environment is created, // and the kernel is recreated with the restore state file. The container then sends the // signal to start. func (cm *containerManager) Restore(o *RestoreOpts, _ *struct{}) error { log.Debugf("containerManager.Restore") if len(o.FilePayload.Files) != 1 { return fmt.Errorf("exactly one file must be provided") } defer o.FilePayload.Files[0].Close() // Destroy the old kernel and create a new kernel. cm.l.k.Pause() cm.l.k.Destroy() p, err := createPlatform(cm.l.conf) if err != nil { return fmt.Errorf("error creating platform: %v", err) } k := &kernel.Kernel{ Platform: p, } cm.l.k = k // Set up the restore environment. fds := &fdDispenser{fds: cm.l.ioFDs} renv, err := createRestoreEnvironment(cm.l.spec, cm.l.conf, fds) if err != nil { return fmt.Errorf("error creating RestoreEnvironment: %v", err) } fs.SetRestoreEnvironment(*renv) // Prepare to load from the state file. networkStack, err := newEmptyNetworkStack(cm.l.conf, k) if err != nil { return fmt.Errorf("failed to create network: %v", err) } info, err := o.FilePayload.Files[0].Stat() if err != nil { return err } if info.Size() == 0 { return fmt.Errorf("error file was empty") } // Load the state. loadOpts := state.LoadOpts{ Source: o.FilePayload.Files[0], } if err := loadOpts.Load(k, p, networkStack); err != nil { return err } // Set timekeeper. k.Timekeeper().SetClocks(time.NewCalibratedClocks()) // Since we have a new kernel we also must make a new watchdog. watchdog := watchdog.New(k, watchdog.DefaultTimeout, cm.l.conf.WatchdogAction) // Change the loader fields to reflect the changes made when restoring. cm.l.k = k cm.l.watchdog = watchdog cm.l.rootProcArgs = kernel.CreateProcessArgs{} cm.l.setRootContainerID(o.SandboxID) cm.l.restore = true // Tell the root container to start and wait for the result. cm.startChan <- struct{}{} return <-cm.startResultChan } // Resume unpauses a container. func (cm *containerManager) Resume(_, _ *struct{}) error { cm.l.k.Unpause() return nil } // Wait waits for the init process in the given container. func (cm *containerManager) Wait(cid *string, waitStatus *uint32) error { log.Debugf("containerManager.Wait") return cm.l.waitContainer(*cid, waitStatus) } // WaitPIDArgs are arguments to the WaitPID method. type WaitPIDArgs struct { // PID is the PID in the container's PID namespace. PID int32 // CID is the container ID. CID string } // WaitPID waits for the process with PID 'pid' in the sandbox. func (cm *containerManager) WaitPID(args *WaitPIDArgs, waitStatus *uint32) error { log.Debugf("containerManager.Wait") return cm.l.waitPID(kernel.ThreadID(args.PID), args.CID, waitStatus) } // SignalArgs are arguments to the Signal method. type SignalArgs struct { // CID is the container id. CID string // Signo is the signal to send to the process. Signo int32 } // Signal sends a signal to the init process of the container. func (cm *containerManager) Signal(args *SignalArgs, _ *struct{}) error { log.Debugf("containerManager.Signal") return cm.l.signal(args.CID, args.Signo) }