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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/bpf"
"gvisor.googlesource.com/gvisor/pkg/sentry/kernel/auth"
"gvisor.googlesource.com/gvisor/pkg/sentry/usermem"
"gvisor.googlesource.com/gvisor/pkg/syserror"
)
// SharingOptions controls what resources are shared by a new task created by
// Task.Clone, or an existing task affected by Task.Unshare.
type SharingOptions struct {
// If NewAddressSpace is true, the task should have an independent virtual
// address space.
NewAddressSpace bool
// If NewSignalHandlers is true, the task should use an independent set of
// signal handlers.
NewSignalHandlers bool
// If NewThreadGroup is true, the task should be the leader of its own
// thread group. TerminationSignal is the signal that the thread group
// will send to its parent when it exits. If NewThreadGroup is false,
// TerminationSignal is ignored.
NewThreadGroup bool
TerminationSignal linux.Signal
// If NewPIDNamespace is true:
//
// - In the context of Task.Clone, the new task should be the init task
// (TID 1) in a new PID namespace.
//
// - In the context of Task.Unshare, the task should create a new PID
// namespace, and all subsequent clones of the task should be members of
// the new PID namespace.
NewPIDNamespace bool
// If NewUserNamespace is true, the task should have an independent user
// namespace.
NewUserNamespace bool
// If NewNetworkNamespace is true, the task should have an independent
// network namespace. (Note that network namespaces are not really
// implemented; see comment on Task.netns for details.)
NewNetworkNamespace bool
// If NewFiles is true, the task should use an independent file descriptor
// table.
NewFiles bool
// If NewFSContext is true, the task should have an independent FSContext.
NewFSContext bool
// If NewUTSNamespace is true, the task should have an independent UTS
// namespace.
NewUTSNamespace bool
// If NewIPCNamespace is true, the task should have an independent IPC
// namespace.
NewIPCNamespace bool
}
// CloneOptions controls the behavior of Task.Clone.
type CloneOptions struct {
// SharingOptions defines the set of resources that the new task will share
// with its parent.
SharingOptions
// Stack is the initial stack pointer of the new task. If Stack is 0, the
// new task will start with the same stack pointer as its parent.
Stack usermem.Addr
// If SetTLS is true, set the new task's TLS (thread-local storage)
// descriptor to TLS. If SetTLS is false, TLS is ignored.
SetTLS bool
TLS usermem.Addr
// If ChildClearTID is true, when the child exits, 0 is written to the
// address ChildTID in the child's memory, and if the write is successful a
// futex wake on the same address is performed.
//
// If ChildSetTID is true, the child's thread ID (in the child's PID
// namespace) is written to address ChildTID in the child's memory. (As in
// Linux, failed writes are silently ignored.)
ChildClearTID bool
ChildSetTID bool
ChildTID usermem.Addr
// If ParentSetTID is true, the child's thread ID (in the parent's PID
// namespace) is written to address ParentTID in the parent's memory. (As
// in Linux, failed writes are silently ignored.)
//
// Older versions of the clone(2) man page state that CLONE_PARENT_SETTID
// causes the child's thread ID to be written to ptid in both the parent
// and child's memory, but this is a documentation error fixed by
// 87ab04792ced ("clone.2: Fix description of CLONE_PARENT_SETTID").
ParentSetTID bool
ParentTID usermem.Addr
// If Vfork is true, place the parent in vforkStop until the cloned task
// releases its TaskContext.
Vfork bool
// If Untraced is true, do not report PTRACE_EVENT_CLONE/FORK/VFORK for
// this clone(), and do not ptrace-attach the caller's tracer to the new
// task. (PTRACE_EVENT_VFORK_DONE will still be reported if appropriate).
Untraced bool
// If InheritTracer is true, ptrace-attach the caller's tracer to the new
// task, even if no PTRACE_EVENT_CLONE/FORK/VFORK event would be reported
// for it. If both Untraced and InheritTracer are true, no event will be
// reported, but tracer inheritance will still occur.
InheritTracer bool
}
// Clone implements the clone(2) syscall and returns the thread ID of the new
// task in t's PID namespace. Clone may return both a non-zero thread ID and a
// non-nil error.
//
// Preconditions: The caller must be running Task.doSyscallInvoke on the task
// goroutine.
func (t *Task) Clone(opts *CloneOptions) (ThreadID, *SyscallControl, error) {
// Since signal actions may refer to application signal handlers by virtual
// address, any set of signal handlers must refer to the same address
// space.
if !opts.NewSignalHandlers && opts.NewAddressSpace {
return 0, nil, syserror.EINVAL
}
// In order for the behavior of thread-group-directed signals to be sane,
// all tasks in a thread group must share signal handlers.
if !opts.NewThreadGroup && opts.NewSignalHandlers {
return 0, nil, syserror.EINVAL
}
// All tasks in a thread group must be in the same PID namespace.
if !opts.NewThreadGroup && (opts.NewPIDNamespace || t.childPIDNamespace != nil) {
return 0, nil, syserror.EINVAL
}
// The two different ways of specifying a new PID namespace are
// incompatible.
if opts.NewPIDNamespace && t.childPIDNamespace != nil {
return 0, nil, syserror.EINVAL
}
// Thread groups and FS contexts cannot span user namespaces.
if opts.NewUserNamespace && (!opts.NewThreadGroup || !opts.NewFSContext) {
return 0, nil, syserror.EINVAL
}
// "If CLONE_NEWUSER is specified along with other CLONE_NEW* flags in a
// single clone(2) or unshare(2) call, the user namespace is guaranteed to
// be created first, giving the child (clone(2)) or caller (unshare(2))
// privileges over the remaining namespaces created by the call." -
// user_namespaces(7)
creds := t.Credentials()
var userns *auth.UserNamespace
if opts.NewUserNamespace {
var err error
// "EPERM (since Linux 3.9): CLONE_NEWUSER was specified in flags and
// the caller is in a chroot environment (i.e., the caller's root
// directory does not match the root directory of the mount namespace
// in which it resides)." - clone(2). Neither chroot(2) nor
// user_namespaces(7) document this.
if t.IsChrooted() {
return 0, nil, syserror.EPERM
}
userns, err = creds.NewChildUserNamespace()
if err != nil {
return 0, nil, err
}
}
if (opts.NewPIDNamespace || opts.NewNetworkNamespace || opts.NewUTSNamespace) && !creds.HasCapability(linux.CAP_SYS_ADMIN) {
return 0, nil, syserror.EPERM
}
utsns := t.UTSNamespace()
if opts.NewUTSNamespace {
// Note that this must happen after NewUserNamespace so we get
// the new userns if there is one.
utsns = t.UTSNamespace().Clone(userns)
}
ipcns := t.IPCNamespace()
if opts.NewIPCNamespace {
// Note that "If CLONE_NEWIPC is set, then create the process in a new IPC
// namespace"
ipcns = NewIPCNamespace(userns)
}
tc, err := t.tc.Fork(t, !opts.NewAddressSpace)
if err != nil {
return 0, nil, err
}
// clone() returns 0 in the child.
tc.Arch.SetReturn(0)
if opts.Stack != 0 {
tc.Arch.SetStack(uintptr(opts.Stack))
}
if opts.SetTLS {
tc.Arch.StateData().Regs.Fs_base = uint64(opts.TLS)
}
var fsc *FSContext
if opts.NewFSContext {
fsc = t.fsc.Fork()
} else {
fsc = t.fsc
fsc.IncRef()
}
var fds *FDMap
if opts.NewFiles {
fds = t.fds.Fork()
} else {
fds = t.fds
fds.IncRef()
}
pidns := t.tg.pidns
if t.childPIDNamespace != nil {
pidns = t.childPIDNamespace
} else if opts.NewPIDNamespace {
pidns = pidns.NewChild(userns)
}
tg := t.tg
if opts.NewThreadGroup {
sh := t.tg.signalHandlers
if opts.NewSignalHandlers {
sh = sh.Fork()
}
tg = NewThreadGroup(pidns, sh, opts.TerminationSignal, tg.limits.GetCopy(), t.k.monotonicClock)
}
cfg := &TaskConfig{
Kernel: t.k,
ThreadGroup: tg,
SignalMask: t.SignalMask(),
TaskContext: tc,
FSContext: fsc,
FDMap: fds,
Credentials: creds.Fork(),
Niceness: t.Niceness(),
NetworkNamespaced: t.netns,
AllowedCPUMask: t.CPUMask(),
UTSNamespace: utsns,
IPCNamespace: ipcns,
AbstractSocketNamespace: t.abstractSockets,
ContainerID: t.ContainerID(),
}
if opts.NewThreadGroup {
cfg.Parent = t
} else {
cfg.InheritParent = t
}
if opts.NewNetworkNamespace {
cfg.NetworkNamespaced = true
}
nt, err := t.tg.pidns.owner.NewTask(cfg)
if err != nil {
if opts.NewThreadGroup {
tg.release()
}
return 0, nil, err
}
// "A child process created via fork(2) inherits a copy of its parent's
// alternate signal stack settings" - sigaltstack(2).
//
// However kernel/fork.c:copy_process() adds a limitation to this:
// "sigaltstack should be cleared when sharing the same VM".
if opts.NewAddressSpace || opts.Vfork {
nt.SetSignalStack(t.SignalStack())
}
if userns != nil {
if err := nt.SetUserNamespace(userns); err != nil {
// This shouldn't be possible: userns was created from nt.creds, so
// nt should have CAP_SYS_ADMIN in userns.
panic("Task.Clone: SetUserNamespace failed: " + err.Error())
}
}
// This has to happen last, because e.g. ptraceClone may send a SIGSTOP to
// nt that it must receive before its task goroutine starts running.
tid := nt.k.tasks.Root.IDOfTask(nt)
defer nt.Start(tid)
// "If fork/clone and execve are allowed by @prog, any child processes will
// be constrained to the same filters and system call ABI as the parent." -
// Documentation/prctl/seccomp_filter.txt
if f := t.syscallFilters.Load(); f != nil {
copiedFilters := append([]bpf.Program(nil), f.([]bpf.Program)...)
nt.syscallFilters.Store(copiedFilters)
}
if opts.Vfork {
nt.vforkParent = t
}
if opts.ChildClearTID {
nt.SetClearTID(opts.ChildTID)
}
if opts.ChildSetTID {
// Can't use Task.CopyOut, which assumes AddressSpaceActive.
usermem.CopyObjectOut(t, nt.MemoryManager(), opts.ChildTID, nt.ThreadID(), usermem.IOOpts{})
}
ntid := t.tg.pidns.IDOfTask(nt)
if opts.ParentSetTID {
t.CopyOut(opts.ParentTID, ntid)
}
kind := ptraceCloneKindClone
if opts.Vfork {
kind = ptraceCloneKindVfork
} else if opts.TerminationSignal == linux.SIGCHLD {
kind = ptraceCloneKindFork
}
if t.ptraceClone(kind, nt, opts) {
if opts.Vfork {
return ntid, &SyscallControl{next: &runSyscallAfterPtraceEventClone{vforkChild: nt, vforkChildTID: ntid}}, nil
}
return ntid, &SyscallControl{next: &runSyscallAfterPtraceEventClone{}}, nil
}
if opts.Vfork {
t.maybeBeginVforkStop(nt)
return ntid, &SyscallControl{next: &runSyscallAfterVforkStop{childTID: ntid}}, nil
}
return ntid, nil, nil
}
// maybeBeginVforkStop checks if a previously-started vfork child is still
// running and has not yet released its MM, such that its parent t should enter
// a vforkStop.
//
// Preconditions: The caller must be running on t's task goroutine.
func (t *Task) maybeBeginVforkStop(child *Task) {
t.tg.pidns.owner.mu.RLock()
defer t.tg.pidns.owner.mu.RUnlock()
t.tg.signalHandlers.mu.Lock()
defer t.tg.signalHandlers.mu.Unlock()
if t.killedLocked() {
child.vforkParent = nil
return
}
if child.vforkParent == t {
t.beginInternalStopLocked((*vforkStop)(nil))
}
}
func (t *Task) unstopVforkParent() {
t.tg.pidns.owner.mu.RLock()
defer t.tg.pidns.owner.mu.RUnlock()
if p := t.vforkParent; p != nil {
p.tg.signalHandlers.mu.Lock()
defer p.tg.signalHandlers.mu.Unlock()
if _, ok := p.stop.(*vforkStop); ok {
p.endInternalStopLocked()
}
// Parent no longer needs to be unstopped.
t.vforkParent = nil
}
}
// +stateify savable
type runSyscallAfterPtraceEventClone struct {
vforkChild *Task
// If vforkChild is not nil, vforkChildTID is its thread ID in the parent's
// PID namespace. vforkChildTID must be stored since the child may exit and
// release its TID before the PTRACE_EVENT stop ends.
vforkChildTID ThreadID
}
func (r *runSyscallAfterPtraceEventClone) execute(t *Task) taskRunState {
if r.vforkChild != nil {
t.maybeBeginVforkStop(r.vforkChild)
return &runSyscallAfterVforkStop{r.vforkChildTID}
}
return (*runSyscallExit)(nil)
}
// +stateify savable
type runSyscallAfterVforkStop struct {
// childTID has the same meaning as
// runSyscallAfterPtraceEventClone.vforkChildTID.
childTID ThreadID
}
func (r *runSyscallAfterVforkStop) execute(t *Task) taskRunState {
t.ptraceVforkDone(r.childTID)
return (*runSyscallExit)(nil)
}
// Unshare changes the set of resources t shares with other tasks, as specified
// by opts.
//
// Preconditions: The caller must be running on the task goroutine.
func (t *Task) Unshare(opts *SharingOptions) error {
// In Linux unshare(2), NewThreadGroup implies NewSignalHandlers and
// NewSignalHandlers implies NewAddressSpace. All three flags are no-ops if
// t is the only task using its MM, which due to clone(2)'s rules imply
// that it is also the only task using its signal handlers / in its thread
// group, and cause EINVAL to be returned otherwise.
//
// Since we don't count the number of tasks using each address space or set
// of signal handlers, we reject NewSignalHandlers and NewAddressSpace
// altogether, and interpret NewThreadGroup as requiring that t be the only
// member of its thread group. This seems to be logically coherent, in the
// sense that clone(2) allows a task to share signal handlers and address
// spaces with tasks in other thread groups.
if opts.NewAddressSpace || opts.NewSignalHandlers {
return syserror.EINVAL
}
if opts.NewThreadGroup {
t.tg.signalHandlers.mu.Lock()
if t.tg.tasksCount != 1 {
t.tg.signalHandlers.mu.Unlock()
return syserror.EINVAL
}
t.tg.signalHandlers.mu.Unlock()
// This isn't racy because we're the only living task, and therefore
// the only task capable of creating new ones, in our thread group.
}
if opts.NewUserNamespace {
if t.IsChrooted() {
return syserror.EPERM
}
// This temporary is needed because Go.
creds := t.Credentials()
newUserNS, err := creds.NewChildUserNamespace()
if err != nil {
return err
}
err = t.SetUserNamespace(newUserNS)
if err != nil {
return err
}
}
haveCapSysAdmin := t.HasCapability(linux.CAP_SYS_ADMIN)
if opts.NewPIDNamespace {
if !haveCapSysAdmin {
return syserror.EPERM
}
t.childPIDNamespace = t.tg.pidns.NewChild(t.UserNamespace())
}
t.mu.Lock()
// Can't defer unlock: DecRefs must occur without holding t.mu.
if opts.NewNetworkNamespace {
if !haveCapSysAdmin {
t.mu.Unlock()
return syserror.EPERM
}
t.netns = true
}
if opts.NewUTSNamespace {
if !haveCapSysAdmin {
t.mu.Unlock()
return syserror.EPERM
}
// Note that this must happen after NewUserNamespace, so the
// new user namespace is used if there is one.
t.utsns = t.utsns.Clone(t.creds.UserNamespace)
}
if opts.NewIPCNamespace {
if !haveCapSysAdmin {
t.mu.Unlock()
return syserror.EPERM
}
// Note that "If CLONE_NEWIPC is set, then create the process in a new IPC
// namespace"
t.ipcns = NewIPCNamespace(t.creds.UserNamespace)
}
var oldfds *FDMap
if opts.NewFiles {
oldfds = t.fds
t.fds = oldfds.Fork()
}
var oldfsc *FSContext
if opts.NewFSContext {
oldfsc = t.fsc
t.fsc = oldfsc.Fork()
}
t.mu.Unlock()
if oldfds != nil {
oldfds.DecRef()
}
if oldfsc != nil {
oldfsc.DecRef()
}
return nil
}
// vforkStop is a TaskStop imposed on a task that creates a child with
// CLONE_VFORK or vfork(2), that ends when the child task ceases to use its
// current MM. (Normally, CLONE_VFORK is used in conjunction with CLONE_VM, so
// that the child and parent share mappings until the child execve()s into a
// new process image or exits.)
//
// +stateify savable
type vforkStop struct{}
// StopIgnoresKill implements TaskStop.Killable.
func (*vforkStop) Killable() bool { return true }
|