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// 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 kernel
import (
"gvisor.googlesource.com/gvisor/pkg/abi/linux"
"gvisor.googlesource.com/gvisor/pkg/refs"
"gvisor.googlesource.com/gvisor/pkg/syserror"
)
// SessionID is the public identifier.
type SessionID ThreadID
// ProcessGroupID is the public identifier.
type ProcessGroupID ThreadID
// Session contains a leader threadgroup and a list of ProcessGroups.
//
// +stateify savable
type Session struct {
refs refs.AtomicRefCount
// leader is the originator of the Session.
//
// Note that this may no longer be running (and may be reaped), so the
// ID is cached upon initial creation. The leader is still required
// however, since its PIDNamespace defines the scope of the Session.
//
// The leader is immutable.
leader *ThreadGroup
// id is the cached identifier in the leader's namespace.
//
// The id is immutable.
id SessionID
// ProcessGroups is a list of process groups in this Session. This is
// protected by TaskSet.mu.
processGroups processGroupList
// sessionEntry is the embed for TaskSet.sessions. This is protected by
// TaskSet.mu.
sessionEntry
}
// incRef grabs a reference.
func (s *Session) incRef() {
s.refs.IncRef()
}
// decRef drops a reference.
//
// Precondition: callers must hold TaskSet.mu for writing.
func (s *Session) decRef() {
s.refs.DecRefWithDestructor(func() {
// Remove translations from the leader.
for ns := s.leader.pidns; ns != nil; ns = ns.parent {
id := ns.sids[s]
delete(ns.sids, s)
delete(ns.sessions, id)
}
// Remove from the list of global Sessions.
s.leader.pidns.owner.sessions.Remove(s)
})
}
// ProcessGroup contains an originator threadgroup and a parent Session.
//
// +stateify savable
type ProcessGroup struct {
refs refs.AtomicRefCount // not exported.
// originator is the originator of the group.
//
// See note re: leader in Session. The same applies here.
//
// The originator is immutable.
originator *ThreadGroup
// id is the cached identifier in the originator's namespace.
//
// The id is immutable.
id ProcessGroupID
// Session is the parent Session.
//
// The session is immutable.
session *Session
// ancestors is the number of thread groups in this process group whose
// parent is in a different process group in the same session.
//
// The name is derived from the fact that process groups where
// ancestors is zero are considered "orphans".
//
// ancestors is protected by TaskSet.mu.
ancestors uint32
// processGroupEntry is the embedded entry for Sessions.groups. This is
// protected by TaskSet.mu.
processGroupEntry
}
// Originator retuns the originator of the process group.
func (pg *ProcessGroup) Originator() *ThreadGroup {
return pg.originator
}
// incRefWithParent grabs a reference.
//
// This function is called when this ProcessGroup is being associated with some
// new ThreadGroup, tg. parentPG is the ProcessGroup of tg's parent
// ThreadGroup. If tg is init, then parentPG may be nil.
//
// Precondition: callers must hold TaskSet.mu for writing.
func (pg *ProcessGroup) incRefWithParent(parentPG *ProcessGroup) {
// We acquire an "ancestor" reference in the case of a nil parent.
// This is because the process being associated is init, and init can
// never be orphaned (we count it as always having an ancestor).
if pg != parentPG && (parentPG == nil || pg.session == parentPG.session) {
pg.ancestors++
}
pg.refs.IncRef()
}
// decRefWithParent drops a reference.
//
// parentPG is per incRefWithParent.
//
// Precondition: callers must hold TaskSet.mu for writing.
func (pg *ProcessGroup) decRefWithParent(parentPG *ProcessGroup) {
// See incRefWithParent regarding parent == nil.
if pg != parentPG && (parentPG == nil || pg.session == parentPG.session) {
pg.ancestors--
}
alive := true
pg.refs.DecRefWithDestructor(func() {
alive = false // don't bother with handleOrphan.
// Remove translations from the originator.
for ns := pg.originator.pidns; ns != nil; ns = ns.parent {
id := ns.pgids[pg]
delete(ns.pgids, pg)
delete(ns.processGroups, id)
}
// Remove the list of process groups.
pg.session.processGroups.Remove(pg)
pg.session.decRef()
})
if alive {
pg.handleOrphan()
}
}
// parentPG returns the parent process group.
//
// Precondition: callers must hold TaskSet.mu.
func (tg *ThreadGroup) parentPG() *ProcessGroup {
if tg.leader.parent != nil {
return tg.leader.parent.tg.processGroup
}
return nil
}
// handleOrphan checks whether the process group is an orphan and has any
// stopped jobs. If yes, then appropriate signals are delivered to each thread
// group within the process group.
//
// Precondition: callers must hold TaskSet.mu for writing.
func (pg *ProcessGroup) handleOrphan() {
// Check if this process is an orphan.
if pg.ancestors != 0 {
return
}
// See if there are any stopped jobs.
hasStopped := false
pg.originator.pidns.owner.forEachThreadGroupLocked(func(tg *ThreadGroup) {
if tg.processGroup != pg {
return
}
tg.signalHandlers.mu.Lock()
if tg.groupStopPhase == groupStopComplete {
hasStopped = true
}
tg.signalHandlers.mu.Unlock()
})
if !hasStopped {
return
}
// Deliver appropriate signals to all thread groups.
pg.originator.pidns.owner.forEachThreadGroupLocked(func(tg *ThreadGroup) {
if tg.processGroup != pg {
return
}
tg.signalHandlers.mu.Lock()
tg.leader.sendSignalLocked(sigPriv(linux.SIGHUP), true /* group */)
tg.leader.sendSignalLocked(sigPriv(linux.SIGCONT), true /* group */)
tg.signalHandlers.mu.Unlock()
})
return
}
// CreateSession creates a new Session, with the ThreadGroup as the leader.
//
// EPERM may be returned if either the given ThreadGroup is already a Session
// leader, or a ProcessGroup already exists for the ThreadGroup's ID.
func (tg *ThreadGroup) CreateSession() error {
tg.pidns.owner.mu.Lock()
defer tg.pidns.owner.mu.Unlock()
return tg.createSession()
}
// createSession creates a new session for a threadgroup.
//
// Precondition: callers must hold TaskSet.mu for writing.
func (tg *ThreadGroup) createSession() error {
// Get the ID for this thread in the current namespace.
id := tg.pidns.tids[tg.leader]
// Check if this ThreadGroup already leads a Session, or
// if the proposed group is already taken.
for s := tg.pidns.owner.sessions.Front(); s != nil; s = s.Next() {
if s.leader.pidns != tg.pidns {
continue
}
if s.leader == tg {
return syserror.EPERM
}
if s.id == SessionID(id) {
return syserror.EPERM
}
for pg := s.processGroups.Front(); pg != nil; pg = pg.Next() {
if pg.id == ProcessGroupID(id) {
return syserror.EPERM
}
}
}
// Create a new Session, with a single reference.
s := &Session{
id: SessionID(id),
leader: tg,
}
// Create a new ProcessGroup, belonging to that Session.
// This also has a single reference (assigned below).
//
// Note that since this is a new session and a new process group, there
// will be zero ancestors for this process group. (It is an orphan at
// this point.)
pg := &ProcessGroup{
id: ProcessGroupID(id),
originator: tg,
session: s,
ancestors: 0,
}
// Tie them and return the result.
s.processGroups.PushBack(pg)
tg.pidns.owner.sessions.PushBack(s)
// Leave the current group, and assign the new one.
if tg.processGroup != nil {
oldParentPG := tg.parentPG()
tg.forEachChildThreadGroupLocked(func(childTG *ThreadGroup) {
childTG.processGroup.incRefWithParent(pg)
childTG.processGroup.decRefWithParent(oldParentPG)
})
tg.processGroup.decRefWithParent(oldParentPG)
tg.processGroup = pg
} else {
// The current process group may be nil only in the case of an
// unparented thread group (i.e. the init process). This would
// not normally occur, but we allow it for the convenience of
// CreateSession working from that point. There will be no
// child processes. We always say that the very first group
// created has ancestors (avoids checks elsewhere).
//
// Note that this mirrors the parent == nil logic in
// incRef/decRef/reparent, which counts nil as an ancestor.
tg.processGroup = pg
tg.processGroup.ancestors++
}
// Ensure a translation is added to all namespaces.
for ns := tg.pidns; ns != nil; ns = ns.parent {
local := ns.tids[tg.leader]
ns.sids[s] = SessionID(local)
ns.sessions[SessionID(local)] = s
ns.pgids[pg] = ProcessGroupID(local)
ns.processGroups[ProcessGroupID(local)] = pg
}
return nil
}
// CreateProcessGroup creates a new process group.
//
// An EPERM error will be returned if the ThreadGroup belongs to a different
// Session, is a Session leader or the group already exists.
func (tg *ThreadGroup) CreateProcessGroup() error {
tg.pidns.owner.mu.Lock()
defer tg.pidns.owner.mu.Unlock()
// Get the ID for this thread in the current namespace.
id := tg.pidns.tids[tg.leader]
// Per above, check for a Session leader or existing group.
for s := tg.pidns.owner.sessions.Front(); s != nil; s = s.Next() {
if s.leader.pidns != tg.pidns {
continue
}
if s.leader == tg {
return syserror.EPERM
}
for pg := s.processGroups.Front(); pg != nil; pg = pg.Next() {
if pg.id == ProcessGroupID(id) {
return syserror.EPERM
}
}
}
// Create a new ProcessGroup, belonging to the current Session.
//
// We manually adjust the ancestors if the parent is in the same
// session.
tg.processGroup.session.incRef()
pg := &ProcessGroup{
id: ProcessGroupID(id),
originator: tg,
session: tg.processGroup.session,
}
if tg.leader.parent != nil && tg.leader.parent.tg.processGroup.session == pg.session {
pg.ancestors++
}
// Assign the new process group; adjust children.
oldParentPG := tg.parentPG()
tg.forEachChildThreadGroupLocked(func(childTG *ThreadGroup) {
childTG.processGroup.incRefWithParent(pg)
childTG.processGroup.decRefWithParent(oldParentPG)
})
tg.processGroup.decRefWithParent(oldParentPG)
tg.processGroup = pg
// Ensure this translation is added to all namespaces.
for ns := tg.pidns; ns != nil; ns = ns.parent {
local := ns.tids[tg.leader]
ns.pgids[pg] = ProcessGroupID(local)
ns.processGroups[ProcessGroupID(local)] = pg
}
return nil
}
// JoinProcessGroup joins an existing process group.
//
// This function will return EACCES if an exec has been performed since fork
// by the given ThreadGroup, and EPERM if the Sessions are not the same or the
// group does not exist.
//
// If checkExec is set, then the join is not permitted after the process has
// executed exec at least once.
func (tg *ThreadGroup) JoinProcessGroup(pidns *PIDNamespace, pgid ProcessGroupID, checkExec bool) error {
pidns.owner.mu.Lock()
defer pidns.owner.mu.Unlock()
// Lookup the ProcessGroup.
pg := pidns.processGroups[pgid]
if pg == nil {
return syserror.EPERM
}
// Disallow the join if an execve has performed, per POSIX.
if checkExec && tg.execed {
return syserror.EACCES
}
// See if it's in the same session as ours.
if pg.session != tg.processGroup.session {
return syserror.EPERM
}
// Join the group; adjust children.
parentPG := tg.parentPG()
pg.incRefWithParent(parentPG)
tg.forEachChildThreadGroupLocked(func(childTG *ThreadGroup) {
childTG.processGroup.incRefWithParent(pg)
childTG.processGroup.decRefWithParent(tg.processGroup)
})
tg.processGroup.decRefWithParent(parentPG)
tg.processGroup = pg
return nil
}
// Session returns the ThreadGroup's Session.
//
// A reference is not taken on the session.
func (tg *ThreadGroup) Session() *Session {
tg.pidns.owner.mu.RLock()
defer tg.pidns.owner.mu.RUnlock()
return tg.processGroup.session
}
// IDOfSession returns the Session assigned to s in PID namespace ns.
//
// If this group isn't visible in this namespace, zero will be returned. It is
// the callers responsibility to check that before using this function.
func (pidns *PIDNamespace) IDOfSession(s *Session) SessionID {
pidns.owner.mu.RLock()
defer pidns.owner.mu.RUnlock()
return pidns.sids[s]
}
// SessionWithID returns the Session with the given ID in the PID namespace ns,
// or nil if that given ID is not defined in this namespace.
//
// A reference is not taken on the session.
func (pidns *PIDNamespace) SessionWithID(id SessionID) *Session {
pidns.owner.mu.RLock()
defer pidns.owner.mu.RUnlock()
return pidns.sessions[id]
}
// ProcessGroup returns the ThreadGroup's ProcessGroup.
//
// A reference is not taken on the process group.
func (tg *ThreadGroup) ProcessGroup() *ProcessGroup {
tg.pidns.owner.mu.RLock()
defer tg.pidns.owner.mu.RUnlock()
return tg.processGroup
}
// IDOfProcessGroup returns the process group assigned to pg in PID namespace ns.
//
// The same constraints apply as IDOfSession.
func (pidns *PIDNamespace) IDOfProcessGroup(pg *ProcessGroup) ProcessGroupID {
pidns.owner.mu.RLock()
defer pidns.owner.mu.RUnlock()
return pidns.pgids[pg]
}
// ProcessGroupWithID returns the ProcessGroup with the given ID in the PID
// namespace ns, or nil if that given ID is not defined in this namespace.
//
// A reference is not taken on the process group.
func (pidns *PIDNamespace) ProcessGroupWithID(id ProcessGroupID) *ProcessGroup {
pidns.owner.mu.RLock()
defer pidns.owner.mu.RUnlock()
return pidns.processGroups[id]
}
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