// 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 kernel import ( gocontext "context" "runtime/trace" "sync/atomic" "gvisor.dev/gvisor/pkg/abi/linux" "gvisor.dev/gvisor/pkg/bpf" "gvisor.dev/gvisor/pkg/hostarch" "gvisor.dev/gvisor/pkg/sentry/fs" "gvisor.dev/gvisor/pkg/sentry/inet" "gvisor.dev/gvisor/pkg/sentry/kernel/auth" "gvisor.dev/gvisor/pkg/sentry/kernel/futex" "gvisor.dev/gvisor/pkg/sentry/kernel/sched" ktime "gvisor.dev/gvisor/pkg/sentry/kernel/time" "gvisor.dev/gvisor/pkg/sentry/platform" "gvisor.dev/gvisor/pkg/sentry/usage" "gvisor.dev/gvisor/pkg/sentry/vfs" "gvisor.dev/gvisor/pkg/sync" "gvisor.dev/gvisor/pkg/syserror" "gvisor.dev/gvisor/pkg/waiter" ) // Task represents a thread of execution in the untrusted app. It // includes registers and any thread-specific state that you would // normally expect. // // Each task is associated with a goroutine, called the task goroutine, that // executes code (application code, system calls, etc.) on behalf of that task. // See Task.run (task_run.go). // // All fields that are "owned by the task goroutine" can only be mutated by the // task goroutine while it is running. The task goroutine does not require // synchronization to read these fields, although it still requires // synchronization as described for those fields to mutate them. // // All fields that are "exclusive to the task goroutine" can only be accessed // by the task goroutine while it is running. The task goroutine does not // require synchronization to read or write these fields. // // +stateify savable type Task struct { taskNode // goid is the task goroutine's ID. goid is owned by the task goroutine, // but since it's used to detect cases where non-task goroutines // incorrectly access state owned by, or exclusive to, the task goroutine, // goid is always accessed using atomic memory operations. goid int64 `state:"nosave"` // runState is what the task goroutine is executing if it is not stopped. // If runState is nil, the task goroutine should exit or has exited. // runState is exclusive to the task goroutine. runState taskRunState // taskWorkCount represents the current size of the task work queue. It is // used to avoid acquiring taskWorkMu when the queue is empty. // // Must accessed with atomic memory operations. taskWorkCount int32 // taskWorkMu protects taskWork. taskWorkMu sync.Mutex `state:"nosave"` // taskWork is a queue of work to be executed before resuming user execution. // It is similar to the task_work mechanism in Linux. // // taskWork is exclusive to the task goroutine. taskWork []TaskWorker // haveSyscallReturn is true if image.Arch().Return() represents a value // returned by a syscall (or set by ptrace after a syscall). // // haveSyscallReturn is exclusive to the task goroutine. haveSyscallReturn bool // interruptChan is notified whenever the task goroutine is interrupted // (usually by a pending signal). interruptChan is effectively a condition // variable that can be used in select statements. // // interruptChan is not saved; because saving interrupts all tasks, // interruptChan is always notified after restore (see Task.run). interruptChan chan struct{} `state:"nosave"` // gosched contains the current scheduling state of the task goroutine. // // gosched is protected by goschedSeq. gosched is owned by the task // goroutine. goschedSeq sync.SeqCount `state:"nosave"` gosched TaskGoroutineSchedInfo // yieldCount is the number of times the task goroutine has called // Task.InterruptibleSleepStart, Task.UninterruptibleSleepStart, or // Task.Yield(), voluntarily ceasing execution. // // yieldCount is accessed using atomic memory operations. yieldCount is // owned by the task goroutine. yieldCount uint64 // pendingSignals is the set of pending signals that may be handled only by // this task. // // pendingSignals is protected by (taskNode.)tg.signalHandlers.mu // (hereafter "the signal mutex"); see comment on // ThreadGroup.signalHandlers. pendingSignals pendingSignals // signalMask is the set of signals whose delivery is currently blocked. // // signalMask is accessed using atomic memory operations, and is protected // by the signal mutex (such that reading signalMask is safe if either the // signal mutex is locked or if atomic memory operations are used, while // writing signalMask requires both). signalMask is owned by the task // goroutine. signalMask linux.SignalSet // If the task goroutine is currently executing Task.sigtimedwait, // realSignalMask is the previous value of signalMask, which has temporarily // been replaced by Task.sigtimedwait. Otherwise, realSignalMask is 0. // // realSignalMask is exclusive to the task goroutine. realSignalMask linux.SignalSet // If haveSavedSignalMask is true, savedSignalMask is the signal mask that // should be applied after the task has either delivered one signal to a // user handler or is about to resume execution in the untrusted // application. // // Both haveSavedSignalMask and savedSignalMask are exclusive to the task // goroutine. haveSavedSignalMask bool savedSignalMask linux.SignalSet // signalStack is the alternate signal stack used by signal handlers for // which the SA_ONSTACK flag is set. // // signalStack is exclusive to the task goroutine. signalStack linux.SignalStack // signalQueue is a set of registered waiters for signal-related events. // // signalQueue is protected by the signalMutex. Note that the task does // not implement all queue methods, specifically the readiness checks. // The task only broadcast a notification on signal delivery. signalQueue waiter.Queue `state:"zerovalue"` // If groupStopPending is true, the task should participate in a group // stop in the interrupt path. // // groupStopPending is analogous to JOBCTL_STOP_PENDING in Linux. // // groupStopPending is protected by the signal mutex. groupStopPending bool // If groupStopAcknowledged is true, the task has already acknowledged that // it is entering the most recent group stop that has been initiated on its // thread group. // // groupStopAcknowledged is analogous to !JOBCTL_STOP_CONSUME in Linux. // // groupStopAcknowledged is protected by the signal mutex. groupStopAcknowledged bool // If trapStopPending is true, the task goroutine should enter a // PTRACE_INTERRUPT-induced stop from the interrupt path. // // trapStopPending is analogous to JOBCTL_TRAP_STOP in Linux, except that // Linux also sets JOBCTL_TRAP_STOP when a ptraced task detects // JOBCTL_STOP_PENDING. // // trapStopPending is protected by the signal mutex. trapStopPending bool // If trapNotifyPending is true, this task is PTRACE_SEIZEd, and a group // stop has begun or ended since the last time the task entered a // ptrace-stop from the group-stop path. // // trapNotifyPending is analogous to JOBCTL_TRAP_NOTIFY in Linux. // // trapNotifyPending is protected by the signal mutex. trapNotifyPending bool // If stop is not nil, it is the internally-initiated condition that // currently prevents the task goroutine from running. // // stop is protected by the signal mutex. stop TaskStop // stopCount is the number of active external stops (calls to // Task.BeginExternalStop that have not been paired with a call to // Task.EndExternalStop), plus 1 if stop is not nil. Hence stopCount is // non-zero if the task goroutine should stop. // // Mutating stopCount requires both locking the signal mutex and using // atomic memory operations. Reading stopCount requires either locking the // signal mutex or using atomic memory operations. This allows Task.doStop // to require only a single atomic read in the common case where stopCount // is 0. // // stopCount is not saved, because external stops cannot be retained across // a save/restore cycle. (Suppose a sentryctl command issues an external // stop; after a save/restore cycle, the restored sentry has no knowledge // of the pre-save sentryctl command, and the stopped task would remain // stopped forever.) stopCount int32 `state:"nosave"` // endStopCond is signaled when stopCount transitions to 0. The combination // of stopCount and endStopCond effectively form a sync.WaitGroup, but // WaitGroup provides no way to read its counter value. // // Invariant: endStopCond.L is the signal mutex. (This is not racy because // sync.Cond.Wait is the only user of sync.Cond.L; only the task goroutine // calls sync.Cond.Wait; and only the task goroutine can change the // identity of the signal mutex, in Task.finishExec.) endStopCond sync.Cond `state:"nosave"` // exitStatus is the task's exit status. // // exitStatus is protected by the signal mutex. exitStatus ExitStatus // syscallRestartBlock represents a custom restart function to run in // restart_syscall(2) to resume an interrupted syscall. // // syscallRestartBlock is exclusive to the task goroutine. syscallRestartBlock SyscallRestartBlock // p provides the mechanism by which the task runs code in userspace. The p // interface object is immutable. p platform.Context `state:"nosave"` // k is the Kernel that this task belongs to. The k pointer is immutable. k *Kernel // containerID has no equivalent in Linux; it's used by runsc to track all // tasks that belong to a given containers since cgroups aren't implemented. // It's inherited by the children, is immutable, and may be empty. // // NOTE: cgroups can be used to track this when implemented. containerID string // mu protects some of the following fields. mu sync.Mutex `state:"nosave"` // image holds task data provided by the ELF loader. // // image is protected by mu, and is owned by the task goroutine. image TaskImage // fsContext is the task's filesystem context. // // fsContext is protected by mu, and is owned by the task goroutine. fsContext *FSContext // fdTable is the task's file descriptor table. // // fdTable is protected by mu, and is owned by the task goroutine. fdTable *FDTable // If vforkParent is not nil, it is the task that created this task with // vfork() or clone(CLONE_VFORK), and should have its vforkStop ended when // this TaskImage is released. // // vforkParent is protected by the TaskSet mutex. vforkParent *Task // exitState is the task's progress through the exit path. // // exitState is protected by the TaskSet mutex. exitState is owned by the // task goroutine. exitState TaskExitState // exitTracerNotified is true if the exit path has either signaled the // task's tracer to indicate the exit, or determined that no such signal is // needed. exitTracerNotified can only be true if exitState is // TaskExitZombie or TaskExitDead. // // exitTracerNotified is protected by the TaskSet mutex. exitTracerNotified bool // exitTracerAcked is true if exitTracerNotified is true and either the // task's tracer has acknowledged the exit notification, or the exit path // has determined that no such notification is needed. // // exitTracerAcked is protected by the TaskSet mutex. exitTracerAcked bool // exitParentNotified is true if the exit path has either signaled the // task's parent to indicate the exit, or determined that no such signal is // needed. exitParentNotified can only be true if exitState is // TaskExitZombie or TaskExitDead. // // exitParentNotified is protected by the TaskSet mutex. exitParentNotified bool // exitParentAcked is true if exitParentNotified is true and either the // task's parent has acknowledged the exit notification, or the exit path // has determined that no such acknowledgment is needed. // // exitParentAcked is protected by the TaskSet mutex. exitParentAcked bool // goroutineStopped is a WaitGroup whose counter value is 1 when the task // goroutine is running and 0 when the task goroutine is stopped or has // exited. goroutineStopped sync.WaitGroup `state:"nosave"` // ptraceTracer is the task that is ptrace-attached to this one. If // ptraceTracer is nil, this task is not being traced. Note that due to // atomic.Value limitations (atomic.Value.Store(nil) panics), a nil // ptraceTracer is always represented as a typed nil (i.e. (*Task)(nil)). // // ptraceTracer is protected by the TaskSet mutex, and accessed with atomic // operations. This allows paths that wouldn't otherwise lock the TaskSet // mutex, notably the syscall path, to check if ptraceTracer is nil without // additional synchronization. ptraceTracer atomic.Value `state:".(*Task)"` // ptraceTracees is the set of tasks that this task is ptrace-attached to. // // ptraceTracees is protected by the TaskSet mutex. ptraceTracees map[*Task]struct{} // ptraceSeized is true if ptraceTracer attached to this task with // PTRACE_SEIZE. // // ptraceSeized is protected by the TaskSet mutex. ptraceSeized bool // ptraceOpts contains ptrace options explicitly set by the tracer. If // ptraceTracer is nil, ptraceOpts is expected to be the zero value. // // ptraceOpts is protected by the TaskSet mutex. ptraceOpts ptraceOptions // ptraceSyscallMode controls ptrace behavior around syscall entry and // exit. // // ptraceSyscallMode is protected by the TaskSet mutex. ptraceSyscallMode ptraceSyscallMode // If ptraceSinglestep is true, the next time the task executes application // code, single-stepping should be enabled. ptraceSinglestep is stored // independently of the architecture-specific trap flag because tracer // detaching (which can happen concurrently with the tracee's execution if // the tracer exits) must disable single-stepping, and the task's // architectural state is implicitly exclusive to the task goroutine (no // synchronization occurs before passing registers to SwitchToApp). // // ptraceSinglestep is analogous to Linux's TIF_SINGLESTEP. // // ptraceSinglestep is protected by the TaskSet mutex. ptraceSinglestep bool // If t is ptrace-stopped, ptraceCode is a ptrace-defined value set at the // time that t entered the ptrace stop, reset to 0 when the tracer // acknowledges the stop with a wait*() syscall. Otherwise, it is the // signal number passed to the ptrace operation that ended the last ptrace // stop on this task. In the latter case, the effect of ptraceCode depends // on the nature of the ptrace stop; signal-delivery-stop uses it to // conditionally override ptraceSiginfo, syscall-entry/exit-stops send the // signal to the task after leaving the stop, and PTRACE_EVENT stops and // traced group stops ignore it entirely. // // Linux contextually stores the equivalent of ptraceCode in // task_struct::exit_code. // // ptraceCode is protected by the TaskSet mutex. ptraceCode int32 // ptraceSiginfo is the value returned to the tracer by // ptrace(PTRACE_GETSIGINFO) and modified by ptrace(PTRACE_SETSIGINFO). // (Despite the name, PTRACE_PEEKSIGINFO is completely unrelated.) // ptraceSiginfo is nil if the task is in a ptraced group-stop (this is // required for PTRACE_GETSIGINFO to return EINVAL during such stops, which // is in turn required to distinguish group stops from other ptrace stops, // per subsection "Group-stop" in ptrace(2)). // // ptraceSiginfo is analogous to Linux's task_struct::last_siginfo. // // ptraceSiginfo is protected by the TaskSet mutex. ptraceSiginfo *linux.SignalInfo // ptraceEventMsg is the value set by PTRACE_EVENT stops and returned to // the tracer by ptrace(PTRACE_GETEVENTMSG). // // ptraceEventMsg is protected by the TaskSet mutex. ptraceEventMsg uint64 // ptraceYAMAExceptionAdded is true if a YAMA exception involving the task has // been added before. This is used during task exit to decide whether we need // to clean up YAMA exceptions. // // ptraceYAMAExceptionAdded is protected by the TaskSet mutex. ptraceYAMAExceptionAdded bool // The struct that holds the IO-related usage. The ioUsage pointer is // immutable. ioUsage *usage.IO // logPrefix is a string containing the task's thread ID in the root PID // namespace, and is prepended to log messages emitted by Task.Infof etc. logPrefix atomic.Value `state:"nosave"` // traceContext and traceTask are both used for tracing, and are // updated along with the logPrefix in updateInfoLocked. // // These are exclusive to the task goroutine. traceContext gocontext.Context `state:"nosave"` traceTask *trace.Task `state:"nosave"` // creds is the task's credentials. // // creds.Load() may be called without synchronization. creds.Store() is // serialized by mu. creds is owned by the task goroutine. All // auth.Credentials objects that creds may point to, or have pointed to // in the past, must be treated as immutable. creds auth.AtomicPtrCredentials // utsns is the task's UTS namespace. // // utsns is protected by mu. utsns is owned by the task goroutine. utsns *UTSNamespace // ipcns is the task's IPC namespace. // // ipcns is protected by mu. ipcns is owned by the task goroutine. ipcns *IPCNamespace // abstractSockets tracks abstract sockets that are in use. // // abstractSockets is protected by mu. abstractSockets *AbstractSocketNamespace // mountNamespaceVFS2 is the task's mount namespace. // // It is protected by mu. It is owned by the task goroutine. mountNamespaceVFS2 *vfs.MountNamespace // parentDeathSignal is sent to this task's thread group when its parent exits. // // parentDeathSignal is protected by mu. parentDeathSignal linux.Signal // syscallFilters is all seccomp-bpf syscall filters applicable to the // task, in the order in which they were installed. The type of the atomic // is []bpf.Program. Writing needs to be protected by the signal mutex. // // syscallFilters is owned by the task goroutine. syscallFilters atomic.Value `state:".([]bpf.Program)"` // If cleartid is non-zero, treat it as a pointer to a ThreadID in the // task's virtual address space; when the task exits, set the pointed-to // ThreadID to 0, and wake any futex waiters. // // cleartid is exclusive to the task goroutine. cleartid hostarch.Addr // This is mostly a fake cpumask just for sched_set/getaffinity as we // don't really control the affinity. // // Invariant: allowedCPUMask.Size() == // sched.CPUMaskSize(Kernel.applicationCores). // // allowedCPUMask is protected by mu. allowedCPUMask sched.CPUSet // cpu is the fake cpu number returned by getcpu(2). cpu is ignored // entirely if Kernel.useHostCores is true. // // cpu is accessed using atomic memory operations. cpu int32 // This is used to keep track of changes made to a process' priority/niceness. // It is mostly used to provide some reasonable return value from // getpriority(2) after a call to setpriority(2) has been made. // We currently do not actually modify a process' scheduling priority. // NOTE: This represents the userspace view of priority (nice). // This means that the value should be in the range [-20, 19]. // // niceness is protected by mu. niceness int // This is used to track the numa policy for the current thread. This can be // modified through a set_mempolicy(2) syscall. Since we always report a // single numa node, all policies are no-ops. We only track this information // so that we can return reasonable values if the application calls // get_mempolicy(2) after setting a non-default policy. Note that in the // real syscall, nodemask can be longer than a single unsigned long, but we // always report a single node so never need to save more than a single // bit. // // numaPolicy and numaNodeMask are protected by mu. numaPolicy linux.NumaPolicy numaNodeMask uint64 // netns is the task's network namespace. netns is never nil. // // netns is protected by mu. netns *inet.Namespace // If rseqPreempted is true, before the next call to p.Switch(), // interrupt rseq critical regions as defined by rseqAddr and // tg.oldRSeqCritical and write the task goroutine's CPU number to // rseqAddr/oldRSeqCPUAddr. // // We support two ABIs for restartable sequences: // // 1. The upstream interface added in v4.18, // 2. An "old" interface never merged upstream. In the implementation, // this is referred to as "old rseq". // // rseqPreempted is exclusive to the task goroutine. rseqPreempted bool `state:"nosave"` // rseqCPU is the last CPU number written to rseqAddr/oldRSeqCPUAddr. // // If rseq is unused, rseqCPU is -1 for convenient use in // platform.Context.Switch. // // rseqCPU is exclusive to the task goroutine. rseqCPU int32 // oldRSeqCPUAddr is a pointer to the userspace old rseq CPU variable. // // oldRSeqCPUAddr is exclusive to the task goroutine. oldRSeqCPUAddr hostarch.Addr // rseqAddr is a pointer to the userspace linux.RSeq structure. // // rseqAddr is exclusive to the task goroutine. rseqAddr hostarch.Addr // rseqSignature is the signature that the rseq abort IP must be signed // with. // // rseqSignature is exclusive to the task goroutine. rseqSignature uint32 // copyScratchBuffer is a buffer available to CopyIn/CopyOut // implementations that require an intermediate buffer to copy data // into/out of. It prevents these buffers from being allocated/zeroed in // each syscall and eventually garbage collected. // // copyScratchBuffer is exclusive to the task goroutine. copyScratchBuffer [copyScratchBufferLen]byte `state:"nosave"` // blockingTimer is used for blocking timeouts. blockingTimerChan is the // channel that is sent to when blockingTimer fires. // // blockingTimer is exclusive to the task goroutine. blockingTimer *ktime.Timer `state:"nosave"` blockingTimerChan <-chan struct{} `state:"nosave"` // futexWaiter is used for futex(FUTEX_WAIT) syscalls. // // futexWaiter is exclusive to the task goroutine. futexWaiter *futex.Waiter `state:"nosave"` // robustList is a pointer to the head of the tasks's robust futex // list. robustList hostarch.Addr // startTime is the real time at which the task started. It is set when // a Task is created or invokes execve(2). // // startTime is protected by mu. startTime ktime.Time // kcov is the kcov instance providing code coverage owned by this task. // // kcov is exclusive to the task goroutine. kcov *Kcov // cgroups is the set of cgroups this task belongs to. This may be empty if // no cgroup controllers are enabled. Protected by mu. // // +checklocks:mu cgroups map[Cgroup]struct{} } func (t *Task) savePtraceTracer() *Task { return t.ptraceTracer.Load().(*Task) } func (t *Task) loadPtraceTracer(tracer *Task) { t.ptraceTracer.Store(tracer) } func (t *Task) saveSyscallFilters() []bpf.Program { if f := t.syscallFilters.Load(); f != nil { return f.([]bpf.Program) } return nil } func (t *Task) loadSyscallFilters(filters []bpf.Program) { t.syscallFilters.Store(filters) } // afterLoad is invoked by stateify. func (t *Task) afterLoad() { t.updateInfoLocked() t.interruptChan = make(chan struct{}, 1) t.gosched.State = TaskGoroutineNonexistent if t.stop != nil { t.stopCount = 1 } t.endStopCond.L = &t.tg.signalHandlers.mu t.p = t.k.Platform.NewContext() t.rseqPreempted = true t.futexWaiter = futex.NewWaiter() } // copyScratchBufferLen is the length of Task.copyScratchBuffer. const copyScratchBufferLen = 144 // sizeof(struct stat) // CopyScratchBuffer returns a scratch buffer to be used in CopyIn/CopyOut // functions. It must only be used within those functions and can only be used // by the task goroutine; it exists to improve performance and thus // intentionally lacks any synchronization. // // Callers should pass a constant value as an argument if possible, which will // allow the compiler to inline and optimize out the if statement below. func (t *Task) CopyScratchBuffer(size int) []byte { if size > copyScratchBufferLen { return make([]byte, size) } return t.copyScratchBuffer[:size] } // FutexWaiter returns the Task's futex.Waiter. func (t *Task) FutexWaiter() *futex.Waiter { return t.futexWaiter } // Kernel returns the Kernel containing t. func (t *Task) Kernel() *Kernel { return t.k } // SetClearTID sets t's cleartid. // // Preconditions: The caller must be running on the task goroutine. func (t *Task) SetClearTID(addr hostarch.Addr) { t.cleartid = addr } // SetSyscallRestartBlock sets the restart block for use in // restart_syscall(2). After registering a restart block, a syscall should // return ERESTART_RESTARTBLOCK to request a restart using the block. // // Precondition: The caller must be running on the task goroutine. func (t *Task) SetSyscallRestartBlock(r SyscallRestartBlock) { t.syscallRestartBlock = r } // SyscallRestartBlock returns the currently registered restart block for use in // restart_syscall(2). This function is *not* idempotent and may be called once // per syscall. This function must not be called if a restart block has not been // registered for the current syscall. // // Precondition: The caller must be running on the task goroutine. func (t *Task) SyscallRestartBlock() SyscallRestartBlock { r := t.syscallRestartBlock // Explicitly set the restart block to nil so that a future syscall can't // accidentally reuse it. t.syscallRestartBlock = nil return r } // IsChrooted returns true if the root directory of t's FSContext is not the // root directory of t's MountNamespace. // // Preconditions: The caller must be running on the task goroutine, or t.mu // must be locked. func (t *Task) IsChrooted() bool { if VFS2Enabled { realRoot := t.mountNamespaceVFS2.Root() root := t.fsContext.RootDirectoryVFS2() defer root.DecRef(t) return root != realRoot } realRoot := t.tg.mounts.Root() defer realRoot.DecRef(t) root := t.fsContext.RootDirectory() if root != nil { defer root.DecRef(t) } return root != realRoot } // TaskImage returns t's TaskImage. // // Precondition: The caller must be running on the task goroutine, or t.mu must // be locked. func (t *Task) TaskImage() *TaskImage { return &t.image } // FSContext returns t's FSContext. FSContext does not take an additional // reference on the returned FSContext. // // Precondition: The caller must be running on the task goroutine, or t.mu must // be locked. func (t *Task) FSContext() *FSContext { return t.fsContext } // FDTable returns t's FDTable. FDMTable does not take an additional reference // on the returned FDMap. // // Precondition: The caller must be running on the task goroutine, or t.mu must // be locked. func (t *Task) FDTable() *FDTable { return t.fdTable } // GetFile is a convenience wrapper for t.FDTable().Get. // // Precondition: same as FDTable.Get. func (t *Task) GetFile(fd int32) *fs.File { f, _ := t.fdTable.Get(fd) return f } // GetFileVFS2 is a convenience wrapper for t.FDTable().GetVFS2. // // Precondition: same as FDTable.Get. func (t *Task) GetFileVFS2(fd int32) *vfs.FileDescription { f, _ := t.fdTable.GetVFS2(fd) return f } // NewFDs is a convenience wrapper for t.FDTable().NewFDs. // // This automatically passes the task as the context. // // Precondition: same as FDTable. func (t *Task) NewFDs(fd int32, files []*fs.File, flags FDFlags) ([]int32, error) { return t.fdTable.NewFDs(t, fd, files, flags) } // NewFDsVFS2 is a convenience wrapper for t.FDTable().NewFDsVFS2. // // This automatically passes the task as the context. // // Precondition: same as FDTable. func (t *Task) NewFDsVFS2(fd int32, files []*vfs.FileDescription, flags FDFlags) ([]int32, error) { return t.fdTable.NewFDsVFS2(t, fd, files, flags) } // NewFDFrom is a convenience wrapper for t.FDTable().NewFDs with a single file. // // This automatically passes the task as the context. // // Precondition: same as FDTable. func (t *Task) NewFDFrom(fd int32, file *fs.File, flags FDFlags) (int32, error) { fds, err := t.fdTable.NewFDs(t, fd, []*fs.File{file}, flags) if err != nil { return 0, err } return fds[0], nil } // NewFDFromVFS2 is a convenience wrapper for t.FDTable().NewFDVFS2. // // This automatically passes the task as the context. // // Precondition: same as FDTable.Get. func (t *Task) NewFDFromVFS2(fd int32, file *vfs.FileDescription, flags FDFlags) (int32, error) { return t.fdTable.NewFDVFS2(t, fd, file, flags) } // NewFDAt is a convenience wrapper for t.FDTable().NewFDAt. // // This automatically passes the task as the context. // // Precondition: same as FDTable. func (t *Task) NewFDAt(fd int32, file *fs.File, flags FDFlags) error { return t.fdTable.NewFDAt(t, fd, file, flags) } // NewFDAtVFS2 is a convenience wrapper for t.FDTable().NewFDAtVFS2. // // This automatically passes the task as the context. // // Precondition: same as FDTable. func (t *Task) NewFDAtVFS2(fd int32, file *vfs.FileDescription, flags FDFlags) error { return t.fdTable.NewFDAtVFS2(t, fd, file, flags) } // WithMuLocked executes f with t.mu locked. func (t *Task) WithMuLocked(f func(*Task)) { t.mu.Lock() f(t) t.mu.Unlock() } // MountNamespace returns t's MountNamespace. MountNamespace does not take an // additional reference on the returned MountNamespace. func (t *Task) MountNamespace() *fs.MountNamespace { return t.tg.mounts } // MountNamespaceVFS2 returns t's MountNamespace. A reference is taken on the // returned mount namespace. func (t *Task) MountNamespaceVFS2() *vfs.MountNamespace { t.mu.Lock() defer t.mu.Unlock() return t.mountNamespaceVFS2 } // AbstractSockets returns t's AbstractSocketNamespace. func (t *Task) AbstractSockets() *AbstractSocketNamespace { return t.abstractSockets } // ContainerID returns t's container ID. func (t *Task) ContainerID() string { return t.containerID } // OOMScoreAdj gets the task's thread group's OOM score adjustment. func (t *Task) OOMScoreAdj() int32 { return atomic.LoadInt32(&t.tg.oomScoreAdj) } // SetOOMScoreAdj sets the task's thread group's OOM score adjustment. The // value should be between -1000 and 1000 inclusive. func (t *Task) SetOOMScoreAdj(adj int32) error { if adj > 1000 || adj < -1000 { return syserror.EINVAL } atomic.StoreInt32(&t.tg.oomScoreAdj, adj) return nil } // KUID returns t's kuid. func (t *Task) KUID() uint32 { return uint32(t.Credentials().EffectiveKUID) } // KGID returns t's kgid. func (t *Task) KGID() uint32 { return uint32(t.Credentials().EffectiveKGID) } // SetKcov sets the kcov instance associated with t. func (t *Task) SetKcov(k *Kcov) { t.kcov = k } // ResetKcov clears the kcov instance associated with t. func (t *Task) ResetKcov() { if t.kcov != nil { t.kcov.OnTaskExit() t.kcov = nil } }