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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 (
"math"
"gvisor.dev/gvisor/pkg/abi/linux"
"gvisor.dev/gvisor/pkg/sentry/arch"
ktime "gvisor.dev/gvisor/pkg/sentry/kernel/time"
"gvisor.dev/gvisor/pkg/syserror"
)
// IntervalTimer represents a POSIX interval timer as described by
// timer_create(2).
//
// +stateify savable
type IntervalTimer struct {
timer *ktime.Timer
// If target is not nil, it receives signo from timer expirations. If group
// is true, these signals are thread-group-directed. These fields are
// immutable.
target *Task
signo linux.Signal
id linux.TimerID
sigval uint64
group bool
// If sigpending is true, a signal to target is already queued, and timer
// expirations should increment overrunCur instead of sending another
// signal. sigpending is protected by target's signal mutex. (If target is
// nil, the timer will never send signals, so sigpending will be unused.)
sigpending bool
// If sigorphan is true, timer's setting has been changed since sigpending
// last became true, such that overruns should no longer be counted in the
// pending signals si_overrun. sigorphan is protected by target's signal
// mutex.
sigorphan bool
// overrunCur is the number of overruns that have occurred since the last
// time a signal was sent. overrunCur is protected by target's signal
// mutex.
overrunCur uint64
// Consider the last signal sent by this timer that has been dequeued.
// overrunLast is the number of overruns that occurred between when this
// signal was sent and when it was dequeued. Equivalently, overrunLast was
// the value of overrunCur when this signal was dequeued. overrunLast is
// protected by target's signal mutex.
overrunLast uint64
}
// DestroyTimer releases it's resources.
func (it *IntervalTimer) DestroyTimer() {
it.timer.Destroy()
it.timerSettingChanged()
// A destroyed IntervalTimer is still potentially reachable via a
// pendingSignal; nil out timer so that it won't be saved.
it.timer = nil
}
func (it *IntervalTimer) timerSettingChanged() {
if it.target == nil {
return
}
it.target.tg.pidns.owner.mu.RLock()
defer it.target.tg.pidns.owner.mu.RUnlock()
it.target.tg.signalHandlers.mu.Lock()
defer it.target.tg.signalHandlers.mu.Unlock()
it.sigorphan = true
it.overrunCur = 0
it.overrunLast = 0
}
// PauseTimer pauses the associated Timer.
func (it *IntervalTimer) PauseTimer() {
it.timer.Pause()
}
// ResumeTimer resumes the associated Timer.
func (it *IntervalTimer) ResumeTimer() {
it.timer.Resume()
}
// Preconditions: it.target's signal mutex must be locked.
func (it *IntervalTimer) updateDequeuedSignalLocked(si *arch.SignalInfo) {
it.sigpending = false
if it.sigorphan {
return
}
it.overrunLast = it.overrunCur
it.overrunCur = 0
si.SetOverrun(saturateI32FromU64(it.overrunLast))
}
// Preconditions: it.target's signal mutex must be locked.
func (it *IntervalTimer) signalRejectedLocked() {
it.sigpending = false
if it.sigorphan {
return
}
it.overrunCur++
}
// Notify implements ktime.TimerListener.Notify.
func (it *IntervalTimer) Notify(exp uint64, setting ktime.Setting) (ktime.Setting, bool) {
if it.target == nil {
return ktime.Setting{}, false
}
it.target.tg.pidns.owner.mu.RLock()
defer it.target.tg.pidns.owner.mu.RUnlock()
it.target.tg.signalHandlers.mu.Lock()
defer it.target.tg.signalHandlers.mu.Unlock()
if it.sigpending {
it.overrunCur += exp
return ktime.Setting{}, false
}
// sigpending must be set before sendSignalTimerLocked() so that it can be
// unset if the signal is discarded (in which case sendSignalTimerLocked()
// will return nil).
it.sigpending = true
it.sigorphan = false
it.overrunCur += exp - 1
si := &arch.SignalInfo{
Signo: int32(it.signo),
Code: arch.SignalInfoTimer,
}
si.SetTimerID(it.id)
si.SetSigval(it.sigval)
// si_overrun is set when the signal is dequeued.
if err := it.target.sendSignalTimerLocked(si, it.group, it); err != nil {
it.signalRejectedLocked()
}
return ktime.Setting{}, false
}
// Destroy implements ktime.TimerListener.Destroy. Users of Timer should call
// DestroyTimer instead.
func (it *IntervalTimer) Destroy() {
}
// IntervalTimerCreate implements timer_create(2).
func (t *Task) IntervalTimerCreate(c ktime.Clock, sigev *linux.Sigevent) (linux.TimerID, error) {
t.tg.timerMu.Lock()
defer t.tg.timerMu.Unlock()
// Allocate a timer ID.
var id linux.TimerID
end := t.tg.nextTimerID
for {
id = t.tg.nextTimerID
_, ok := t.tg.timers[id]
t.tg.nextTimerID++
if t.tg.nextTimerID < 0 {
t.tg.nextTimerID = 0
}
if !ok {
break
}
if t.tg.nextTimerID == end {
return 0, syserror.EAGAIN
}
}
// "The implementation of the default case where evp [sic] is NULL is
// handled inside glibc, which invokes the underlying system call with a
// suitably populated sigevent structure." - timer_create(2). This is
// misleading; the timer_create syscall also handles a NULL sevp as
// described by the man page
// (kernel/time/posix-timers.c:sys_timer_create(), do_timer_create()). This
// must be handled here instead of the syscall wrapper since sigval is the
// timer ID, which isn't available until we allocate it in this function.
if sigev == nil {
sigev = &linux.Sigevent{
Signo: int32(linux.SIGALRM),
Notify: linux.SIGEV_SIGNAL,
Value: uint64(id),
}
}
// Construct the timer.
it := &IntervalTimer{
id: id,
sigval: sigev.Value,
}
switch sigev.Notify {
case linux.SIGEV_NONE:
// leave it.target = nil
case linux.SIGEV_SIGNAL, linux.SIGEV_THREAD:
// POSIX SIGEV_THREAD semantics are implemented in userspace by libc;
// to the kernel, SIGEV_THREAD and SIGEV_SIGNAL are equivalent. (See
// Linux's kernel/time/posix-timers.c:good_sigevent().)
it.target = t.tg.leader
it.group = true
case linux.SIGEV_THREAD_ID:
t.tg.pidns.owner.mu.RLock()
target, ok := t.tg.pidns.tasks[ThreadID(sigev.Tid)]
t.tg.pidns.owner.mu.RUnlock()
if !ok || target.tg != t.tg {
return 0, syserror.EINVAL
}
it.target = target
default:
return 0, syserror.EINVAL
}
if sigev.Notify != linux.SIGEV_NONE {
it.signo = linux.Signal(sigev.Signo)
if !it.signo.IsValid() {
return 0, syserror.EINVAL
}
}
it.timer = ktime.NewTimer(c, it)
t.tg.timers[id] = it
return id, nil
}
// IntervalTimerDelete implements timer_delete(2).
func (t *Task) IntervalTimerDelete(id linux.TimerID) error {
t.tg.timerMu.Lock()
defer t.tg.timerMu.Unlock()
it := t.tg.timers[id]
if it == nil {
return syserror.EINVAL
}
delete(t.tg.timers, id)
it.DestroyTimer()
return nil
}
// IntervalTimerSettime implements timer_settime(2).
func (t *Task) IntervalTimerSettime(id linux.TimerID, its linux.Itimerspec, abs bool) (linux.Itimerspec, error) {
t.tg.timerMu.Lock()
defer t.tg.timerMu.Unlock()
it := t.tg.timers[id]
if it == nil {
return linux.Itimerspec{}, syserror.EINVAL
}
newS, err := ktime.SettingFromItimerspec(its, abs, it.timer.Clock())
if err != nil {
return linux.Itimerspec{}, err
}
tm, oldS := it.timer.SwapAnd(newS, it.timerSettingChanged)
its = ktime.ItimerspecFromSetting(tm, oldS)
return its, nil
}
// IntervalTimerGettime implements timer_gettime(2).
func (t *Task) IntervalTimerGettime(id linux.TimerID) (linux.Itimerspec, error) {
t.tg.timerMu.Lock()
defer t.tg.timerMu.Unlock()
it := t.tg.timers[id]
if it == nil {
return linux.Itimerspec{}, syserror.EINVAL
}
tm, s := it.timer.Get()
its := ktime.ItimerspecFromSetting(tm, s)
return its, nil
}
// IntervalTimerGetoverrun implements timer_getoverrun(2).
//
// Preconditions: The caller must be running on the task goroutine.
func (t *Task) IntervalTimerGetoverrun(id linux.TimerID) (int32, error) {
t.tg.timerMu.Lock()
defer t.tg.timerMu.Unlock()
it := t.tg.timers[id]
if it == nil {
return 0, syserror.EINVAL
}
// By timer_create(2) invariant, either it.target == nil (in which case
// it.overrunLast is immutably 0) or t.tg == it.target.tg; and the fact
// that t is executing timer_getoverrun(2) means that t.tg can't be
// completing execve, so t.tg.signalHandlers can't be changing, allowing us
// to lock t.tg.signalHandlers.mu without holding the TaskSet mutex.
t.tg.signalHandlers.mu.Lock()
defer t.tg.signalHandlers.mu.Unlock()
// This is consistent with Linux after 78c9c4dfbf8c ("posix-timers:
// Sanitize overrun handling").
return saturateI32FromU64(it.overrunLast), nil
}
func saturateI32FromU64(x uint64) int32 {
if x > math.MaxInt32 {
return math.MaxInt32
}
return int32(x)
}
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