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// 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 (
"sync/atomic"
"gvisor.dev/gvisor/pkg/abi/linux"
"gvisor.dev/gvisor/pkg/context"
"gvisor.dev/gvisor/pkg/errors/linuxerr"
"gvisor.dev/gvisor/pkg/sentry/fs"
"gvisor.dev/gvisor/pkg/sentry/kernel/auth"
ktime "gvisor.dev/gvisor/pkg/sentry/kernel/time"
"gvisor.dev/gvisor/pkg/sentry/limits"
"gvisor.dev/gvisor/pkg/sentry/usage"
"gvisor.dev/gvisor/pkg/sync"
"gvisor.dev/gvisor/pkg/syserror"
)
// A ThreadGroup is a logical grouping of tasks that has widespread
// significance to other kernel features (e.g. signal handling). ("Thread
// groups" are usually called "processes" in userspace documentation.)
//
// ThreadGroup is a superset of Linux's struct signal_struct.
//
// +stateify savable
type ThreadGroup struct {
threadGroupNode
// signalHandlers is the set of signal handlers used by every task in this
// thread group. (signalHandlers may also be shared with other thread
// groups.)
//
// signalHandlers.mu (hereafter "the signal mutex") protects state related
// to signal handling, as well as state that usually needs to be atomic
// with signal handling, for all ThreadGroups and Tasks using
// signalHandlers. (This is analogous to Linux's use of struct
// sighand_struct::siglock.)
//
// The signalHandlers pointer can only be mutated during an execve
// (Task.finishExec). Consequently, when it's possible for a task in the
// thread group to be completing an execve, signalHandlers is protected by
// the owning TaskSet.mu. Otherwise, it is possible to read the
// signalHandlers pointer without synchronization. In particular,
// completing an execve requires that all other tasks in the thread group
// have exited, so task goroutines do not need the owning TaskSet.mu to
// read the signalHandlers pointer of their thread groups.
signalHandlers *SignalHandlers
// pendingSignals is the set of pending signals that may be handled by any
// task in this thread group.
//
// pendingSignals is protected by the signal mutex.
pendingSignals pendingSignals
// If groupStopDequeued is true, a task in the thread group has dequeued a
// stop signal, but has not yet initiated the group stop.
//
// groupStopDequeued is analogous to Linux's JOBCTL_STOP_DEQUEUED.
//
// groupStopDequeued is protected by the signal mutex.
groupStopDequeued bool
// groupStopSignal is the signal that caused a group stop to be initiated.
//
// groupStopSignal is protected by the signal mutex.
groupStopSignal linux.Signal
// groupStopPendingCount is the number of active tasks in the thread group
// for which Task.groupStopPending is set.
//
// groupStopPendingCount is analogous to Linux's
// signal_struct::group_stop_count.
//
// groupStopPendingCount is protected by the signal mutex.
groupStopPendingCount int
// If groupStopComplete is true, groupStopPendingCount transitioned from
// non-zero to zero without an intervening SIGCONT.
//
// groupStopComplete is analogous to Linux's SIGNAL_STOP_STOPPED.
//
// groupStopComplete is protected by the signal mutex.
groupStopComplete bool
// If groupStopWaitable is true, the thread group is indicating a waitable
// group stop event (as defined by EventChildGroupStop).
//
// Linux represents the analogous state as SIGNAL_STOP_STOPPED being set
// and group_exit_code being non-zero.
//
// groupStopWaitable is protected by the signal mutex.
groupStopWaitable bool
// If groupContNotify is true, then a SIGCONT has recently ended a group
// stop on this thread group, and the first task to observe it should
// notify its parent. groupContInterrupted is true iff SIGCONT ended an
// incomplete group stop. If groupContNotify is false, groupContInterrupted is
// meaningless.
//
// Analogues in Linux:
//
// - groupContNotify && groupContInterrupted is represented by
// SIGNAL_CLD_STOPPED.
//
// - groupContNotify && !groupContInterrupted is represented by
// SIGNAL_CLD_CONTINUED.
//
// - !groupContNotify is represented by neither flag being set.
//
// groupContNotify and groupContInterrupted are protected by the signal
// mutex.
groupContNotify bool
groupContInterrupted bool
// If groupContWaitable is true, the thread group is indicating a waitable
// continue event (as defined by EventGroupContinue).
//
// groupContWaitable is analogous to Linux's SIGNAL_STOP_CONTINUED.
//
// groupContWaitable is protected by the signal mutex.
groupContWaitable bool
// exiting is true if all tasks in the ThreadGroup should exit. exiting is
// analogous to Linux's SIGNAL_GROUP_EXIT.
//
// exiting is protected by the signal mutex. exiting can only transition
// from false to true.
exiting bool
// exitStatus is the thread group's exit status.
//
// While exiting is false, exitStatus is protected by the signal mutex.
// When exiting becomes true, exitStatus becomes immutable.
exitStatus ExitStatus
// terminationSignal is the signal that this thread group's leader will
// send to its parent when it exits.
//
// terminationSignal is protected by the TaskSet mutex.
terminationSignal linux.Signal
// liveGoroutines is the number of non-exited task goroutines in the thread
// group.
//
// liveGoroutines is not saved; it is reset as task goroutines are
// restarted by Task.Start.
liveGoroutines sync.WaitGroup `state:"nosave"`
timerMu sync.Mutex `state:"nosave"`
// itimerRealTimer implements ITIMER_REAL for the thread group.
itimerRealTimer *ktime.Timer
// itimerVirtSetting is the ITIMER_VIRTUAL setting for the thread group.
//
// itimerVirtSetting is protected by the signal mutex.
itimerVirtSetting ktime.Setting
// itimerProfSetting is the ITIMER_PROF setting for the thread group.
//
// itimerProfSetting is protected by the signal mutex.
itimerProfSetting ktime.Setting
// rlimitCPUSoftSetting is the setting for RLIMIT_CPU soft limit
// notifications for the thread group.
//
// rlimitCPUSoftSetting is protected by the signal mutex.
rlimitCPUSoftSetting ktime.Setting
// cpuTimersEnabled is non-zero if itimerVirtSetting.Enabled is true,
// itimerProfSetting.Enabled is true, rlimitCPUSoftSetting.Enabled is true,
// or limits.Get(CPU) is finite.
//
// cpuTimersEnabled is protected by the signal mutex. cpuTimersEnabled is
// accessed using atomic memory operations.
cpuTimersEnabled uint32
// timers is the thread group's POSIX interval timers. nextTimerID is the
// TimerID at which allocation should begin searching for an unused ID.
//
// timers and nextTimerID are protected by timerMu.
timers map[linux.TimerID]*IntervalTimer
nextTimerID linux.TimerID
// exitedCPUStats is the CPU usage for all exited tasks in the thread
// group. exitedCPUStats is protected by the TaskSet mutex.
exitedCPUStats usage.CPUStats
// childCPUStats is the CPU usage of all joined descendants of this thread
// group. childCPUStats is protected by the TaskSet mutex.
childCPUStats usage.CPUStats
// ioUsage is the I/O usage for all exited tasks in the thread group.
// The ioUsage pointer is immutable.
ioUsage *usage.IO
// maxRSS is the historical maximum resident set size of the thread group, updated when:
//
// - A task in the thread group exits, since after all tasks have
// exited the MemoryManager is no longer reachable.
//
// - The thread group completes an execve, since this changes
// MemoryManagers.
//
// maxRSS is protected by the TaskSet mutex.
maxRSS uint64
// childMaxRSS is the maximum resident set size in bytes of all joined
// descendants of this thread group.
//
// childMaxRSS is protected by the TaskSet mutex.
childMaxRSS uint64
// Resource limits for this ThreadGroup. The limits pointer is immutable.
limits *limits.LimitSet
// processGroup is the processGroup for this thread group.
//
// processGroup is protected by the TaskSet mutex.
processGroup *ProcessGroup
// execed indicates an exec has occurred since creation. This will be
// set by finishExec, and new TheadGroups will have this field cleared.
// When execed is set, the processGroup may no longer be changed.
//
// execed is protected by the TaskSet mutex.
execed bool
// oldRSeqCritical is the thread group's old rseq critical region.
oldRSeqCritical atomic.Value `state:".(*OldRSeqCriticalRegion)"`
// mounts is the thread group's mount namespace. This does not really
// correspond to a "mount namespace" in Linux, but is more like a
// complete VFS that need not be shared between processes. See the
// comment in mounts.go for more information.
//
// mounts is immutable.
mounts *fs.MountNamespace
// tty is the thread group's controlling terminal. If nil, there is no
// controlling terminal.
//
// tty is protected by the signal mutex.
tty *TTY
// oomScoreAdj is the thread group's OOM score adjustment. This is
// currently not used but is maintained for consistency.
// TODO(gvisor.dev/issue/1967)
//
// oomScoreAdj is accessed using atomic memory operations.
oomScoreAdj int32
}
// NewThreadGroup returns a new, empty thread group in PID namespace pidns. The
// thread group leader will send its parent terminationSignal when it exits.
// The new thread group isn't visible to the system until a task has been
// created inside of it by a successful call to TaskSet.NewTask.
func (k *Kernel) NewThreadGroup(mntns *fs.MountNamespace, pidns *PIDNamespace, sh *SignalHandlers, terminationSignal linux.Signal, limits *limits.LimitSet) *ThreadGroup {
tg := &ThreadGroup{
threadGroupNode: threadGroupNode{
pidns: pidns,
},
signalHandlers: sh,
terminationSignal: terminationSignal,
ioUsage: &usage.IO{},
limits: limits,
mounts: mntns,
}
tg.itimerRealTimer = ktime.NewTimer(k.timekeeper.monotonicClock, &itimerRealListener{tg: tg})
tg.timers = make(map[linux.TimerID]*IntervalTimer)
tg.oldRSeqCritical.Store(&OldRSeqCriticalRegion{})
return tg
}
// saveOldRSeqCritical is invoked by stateify.
func (tg *ThreadGroup) saveOldRSeqCritical() *OldRSeqCriticalRegion {
return tg.oldRSeqCritical.Load().(*OldRSeqCriticalRegion)
}
// loadOldRSeqCritical is invoked by stateify.
func (tg *ThreadGroup) loadOldRSeqCritical(r *OldRSeqCriticalRegion) {
tg.oldRSeqCritical.Store(r)
}
// SignalHandlers returns the signal handlers used by tg.
//
// Preconditions: The caller must provide the synchronization required to read
// tg.signalHandlers, as described in the field's comment.
func (tg *ThreadGroup) SignalHandlers() *SignalHandlers {
return tg.signalHandlers
}
// Limits returns tg's limits.
func (tg *ThreadGroup) Limits() *limits.LimitSet {
return tg.limits
}
// Release releases the thread group's resources.
func (tg *ThreadGroup) Release(ctx context.Context) {
// Timers must be destroyed without holding the TaskSet or signal mutexes
// since timers send signals with Timer.mu locked.
tg.itimerRealTimer.Destroy()
var its []*IntervalTimer
tg.pidns.owner.mu.Lock()
tg.signalHandlers.mu.Lock()
for _, it := range tg.timers {
its = append(its, it)
}
tg.timers = make(map[linux.TimerID]*IntervalTimer) // nil maps can't be saved
tg.signalHandlers.mu.Unlock()
tg.pidns.owner.mu.Unlock()
for _, it := range its {
it.DestroyTimer()
}
if tg.mounts != nil {
tg.mounts.DecRef(ctx)
}
}
// forEachChildThreadGroupLocked indicates over all child ThreadGroups.
//
// Precondition: TaskSet.mu must be held.
func (tg *ThreadGroup) forEachChildThreadGroupLocked(fn func(*ThreadGroup)) {
for t := tg.tasks.Front(); t != nil; t = t.Next() {
for child := range t.children {
if child == child.tg.leader {
fn(child.tg)
}
}
}
}
// SetControllingTTY sets tty as the controlling terminal of tg.
func (tg *ThreadGroup) SetControllingTTY(tty *TTY, steal bool, isReadable bool) error {
tty.mu.Lock()
defer tty.mu.Unlock()
// We might be asked to set the controlling terminal of multiple
// processes, so we lock both the TaskSet and SignalHandlers.
tg.pidns.owner.mu.Lock()
defer tg.pidns.owner.mu.Unlock()
tg.signalHandlers.mu.Lock()
defer tg.signalHandlers.mu.Unlock()
// "The calling process must be a session leader and not have a
// controlling terminal already." - tty_ioctl(4)
if tg.processGroup.session.leader != tg || tg.tty != nil {
return linuxerr.EINVAL
}
creds := auth.CredentialsFromContext(tg.leader)
hasAdmin := creds.HasCapabilityIn(linux.CAP_SYS_ADMIN, creds.UserNamespace.Root())
// "If this terminal is already the controlling terminal of a different
// session group, then the ioctl fails with EPERM, unless the caller
// has the CAP_SYS_ADMIN capability and arg equals 1, in which case the
// terminal is stolen, and all processes that had it as controlling
// terminal lose it." - tty_ioctl(4)
if tty.tg != nil && tg.processGroup.session != tty.tg.processGroup.session {
// Stealing requires CAP_SYS_ADMIN in the root user namespace.
if !hasAdmin || !steal {
return syserror.EPERM
}
// Steal the TTY away. Unlike TIOCNOTTY, don't send signals.
for othertg := range tg.pidns.owner.Root.tgids {
// This won't deadlock by locking tg.signalHandlers
// because at this point:
// - We only lock signalHandlers if it's in the same
// session as the tty's controlling thread group.
// - We know that the calling thread group is not in
// the same session as the tty's controlling thread
// group.
if othertg.processGroup.session == tty.tg.processGroup.session {
othertg.signalHandlers.mu.Lock()
othertg.tty = nil
othertg.signalHandlers.mu.Unlock()
}
}
}
if !isReadable && !hasAdmin {
return syserror.EPERM
}
// Set the controlling terminal and foreground process group.
tg.tty = tty
tg.processGroup.session.foreground = tg.processGroup
// Set this as the controlling process of the terminal.
tty.tg = tg
return nil
}
// ReleaseControllingTTY gives up tty as the controlling tty of tg.
func (tg *ThreadGroup) ReleaseControllingTTY(tty *TTY) error {
tty.mu.Lock()
defer tty.mu.Unlock()
// We might be asked to set the controlling terminal of multiple
// processes, so we lock both the TaskSet and SignalHandlers.
tg.pidns.owner.mu.RLock()
defer tg.pidns.owner.mu.RUnlock()
// Just below, we may re-lock signalHandlers in order to send signals.
// Thus we can't defer Unlock here.
tg.signalHandlers.mu.Lock()
if tg.tty == nil || tg.tty != tty {
tg.signalHandlers.mu.Unlock()
return syserror.ENOTTY
}
// "If the process was session leader, then send SIGHUP and SIGCONT to
// the foreground process group and all processes in the current
// session lose their controlling terminal." - tty_ioctl(4)
// Remove tty as the controlling tty for each process in the session,
// then send them SIGHUP and SIGCONT.
// If we're not the session leader, we don't have to do much.
if tty.tg != tg {
tg.tty = nil
tg.signalHandlers.mu.Unlock()
return nil
}
tg.signalHandlers.mu.Unlock()
// We're the session leader. SIGHUP and SIGCONT the foreground process
// group and remove all controlling terminals in the session.
var lastErr error
for othertg := range tg.pidns.owner.Root.tgids {
if othertg.processGroup.session == tg.processGroup.session {
othertg.signalHandlers.mu.Lock()
othertg.tty = nil
if othertg.processGroup == tg.processGroup.session.foreground {
if err := othertg.leader.sendSignalLocked(&linux.SignalInfo{Signo: int32(linux.SIGHUP)}, true /* group */); err != nil {
lastErr = err
}
if err := othertg.leader.sendSignalLocked(&linux.SignalInfo{Signo: int32(linux.SIGCONT)}, true /* group */); err != nil {
lastErr = err
}
}
othertg.signalHandlers.mu.Unlock()
}
}
return lastErr
}
// ForegroundProcessGroup returns the process group ID of the foreground
// process group.
func (tg *ThreadGroup) ForegroundProcessGroup(tty *TTY) (int32, error) {
tty.mu.Lock()
defer tty.mu.Unlock()
tg.pidns.owner.mu.Lock()
defer tg.pidns.owner.mu.Unlock()
tg.signalHandlers.mu.Lock()
defer tg.signalHandlers.mu.Unlock()
// "When fd does not refer to the controlling terminal of the calling
// process, -1 is returned" - tcgetpgrp(3)
if tg.tty != tty {
return -1, syserror.ENOTTY
}
return int32(tg.processGroup.session.foreground.id), nil
}
// SetForegroundProcessGroup sets the foreground process group of tty to pgid.
func (tg *ThreadGroup) SetForegroundProcessGroup(tty *TTY, pgid ProcessGroupID) (int32, error) {
tty.mu.Lock()
defer tty.mu.Unlock()
tg.pidns.owner.mu.Lock()
defer tg.pidns.owner.mu.Unlock()
tg.signalHandlers.mu.Lock()
defer tg.signalHandlers.mu.Unlock()
// TODO(gvisor.dev/issue/6148): "If tcsetpgrp() is called by a member of a
// background process group in its session, and the calling process is not
// blocking or ignoring SIGTTOU, a SIGTTOU signal is sent to all members of
// this background process group."
// tty must be the controlling terminal.
if tg.tty != tty {
return -1, syserror.ENOTTY
}
// pgid must be positive.
if pgid < 0 {
return -1, linuxerr.EINVAL
}
// pg must not be empty. Empty process groups are removed from their
// pid namespaces.
pg, ok := tg.pidns.processGroups[pgid]
if !ok {
return -1, syserror.ESRCH
}
// pg must be part of this process's session.
if tg.processGroup.session != pg.session {
return -1, syserror.EPERM
}
tg.processGroup.session.foreground.id = pgid
return 0, nil
}
// itimerRealListener implements ktime.Listener for ITIMER_REAL expirations.
//
// +stateify savable
type itimerRealListener struct {
tg *ThreadGroup
}
// Notify implements ktime.TimerListener.Notify.
func (l *itimerRealListener) Notify(exp uint64, setting ktime.Setting) (ktime.Setting, bool) {
l.tg.SendSignal(SignalInfoPriv(linux.SIGALRM))
return ktime.Setting{}, false
}
// Destroy implements ktime.TimerListener.Destroy.
func (l *itimerRealListener) Destroy() {
}
|