60ee6f739f
Refactor pkg/chrootarchive in terms of those utilities. Signed-off-by: Cory Snider <csnider@mirantis.com>
176 lines
6.8 KiB
Go
176 lines
6.8 KiB
Go
//go:build go1.10
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// +build go1.10
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package unshare // import "github.com/docker/docker/internal/unshare"
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import (
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"fmt"
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"os"
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"runtime"
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"golang.org/x/sys/unix"
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)
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func init() {
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// The startup thread of a process is special in a few different ways.
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// Most pertinent to the discussion at hand, any per-thread kernel state
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// reflected in the /proc/[pid]/ directory for a process is taken from
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// the state of the startup thread. Same goes for /proc/self/; it shows
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// the state of the current process' startup thread, no matter which
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// thread the files are being opened from. For most programs this is a
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// distinction without a difference as the kernel state, such as the
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// mount namespace and current working directory, is shared among (and
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// kept synchronized across) all threads of a process. But things start
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// to break down once threads start unsharing and modifying parts of
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// their kernel state.
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//
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// The Go runtime schedules goroutines to execute on the startup thread,
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// same as any other. How this could be problematic is best illustrated
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// with a concrete example. Consider what happens if a call to
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// Go(unix.CLONE_NEWNS, ...) spawned a goroutine which gets scheduled
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// onto the startup thread. The thread's mount namespace will be
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// unshared and modified. The contents of the /proc/[pid]/mountinfo file
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// will then describe the mount tree of the unshared namespace, not the
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// namespace of any other thread. It will remain this way until the
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// process exits. (The startup thread is special in another way: exiting
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// it puts the process into a "non-waitable zombie" state. To avoid this
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// fate, the Go runtime parks the thread instead of exiting if a
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// goroutine returns while locked to the startup thread. More
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// information can be found in the Go runtime sources:
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// `go doc -u -src runtime.mexit`.) The github.com/moby/sys/mountinfo
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// package reads from /proc/self/mountinfo, so will read the mount tree
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// for the wrong namespace if the startup thread has had its mount
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// namespace unshared! The /proc/thread-self/ directory, introduced in
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// Linux 3.17, is one potential solution to this problem, but every
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// package which opens files in /proc/self/ would need to be updated,
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// and fallbacks to /proc/self/task/[tid]/ would be required to support
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// older kernels. Overlooking any reference to /proc/self/ would
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// manifest as stochastically-reproducible bugs, so this is far from an
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// ideal solution.
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//
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// Reading from /proc/self/ would not be a problem if we could prevent
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// the per-thread state of the startup thread from being modified
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// nondeterministically in the first place. We can accomplish this
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// simply by locking the main() function to the startup thread! Doing so
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// excludes any other goroutine from being scheduled on the thread.
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runtime.LockOSThread()
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}
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// reversibleSetnsFlags maps the unshare(2) flags whose effects can be fully
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// reversed using setns(2). The values are the basenames of the corresponding
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// /proc/self/task/[tid]/ns/ magic symlinks to use to save and restore the
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// state.
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var reversibleSetnsFlags = map[int]string{
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unix.CLONE_NEWCGROUP: "cgroup",
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unix.CLONE_NEWNET: "net",
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unix.CLONE_NEWUTS: "uts",
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unix.CLONE_NEWPID: "pid",
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unix.CLONE_NEWTIME: "time",
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// The following CLONE_NEW* flags are not included because they imply
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// another, irreversible flag when used with unshare(2).
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// - unix.CLONE_NEWIPC: implies CLONE_SYSVMEM
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// - unix.CLONE_NEWNS: implies CLONE_FS
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// - unix.CLONE_NEWUSER: implies CLONE_FS since Linux 3.9
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}
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// Go calls the given functions in a new goroutine, locked to an OS thread,
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// which has had the parts of its execution state disassociated from the rest of
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// the current process using [unshare(2)]. It blocks until the new goroutine has
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// started and setupfn has returned. fn is only called if setupfn returns nil. A
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// nil setupfn or fn is equivalent to passing a no-op function.
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//
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// The disassociated execution state and any changes made to it are only visible
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// to the goroutine which the functions are called in. Any other goroutines,
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// including ones started from the function, will see the same execution state
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// as the rest of the process.
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//
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// The acceptable flags are documented in the [unshare(2)] Linux man-page.
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// The corresponding CLONE_* constants are defined in package [unix].
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//
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// # Warning
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//
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// This function may terminate the thread which the new goroutine executed on
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// after fn returns, which could cause subprocesses started with the
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// [syscall.SysProcAttr] Pdeathsig field set to be signaled before process
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// termination. Any subprocess started before this function is called may be
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// affected, in addition to any subprocesses started inside setupfn or fn.
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// There are more details at https://go.dev/issue/27505.
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//
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// [unshare(2)]: https://man7.org/linux/man-pages/man2/unshare.2.html
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func Go(flags int, setupfn func() error, fn func()) error {
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started := make(chan error)
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maskedFlags := flags
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for f := range reversibleSetnsFlags {
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maskedFlags &^= f
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}
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isReversible := maskedFlags == 0
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go func() {
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// Prepare to manipulate per-thread kernel state.
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runtime.LockOSThread()
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// Not all changes to the execution state can be reverted.
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// If an irreversible change to the execution state is made, our
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// only recourse is to have the tampered thread terminated by
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// returning from this function while the goroutine remains
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// wired to the thread. The Go runtime will terminate the thread
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// and replace it with a fresh one as needed.
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if isReversible {
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defer func() {
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if isReversible {
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// All execution state has been restored without error.
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// The thread is once again fungible.
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runtime.UnlockOSThread()
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}
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}()
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tid := unix.Gettid()
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for f, ns := range reversibleSetnsFlags {
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if flags&f != f {
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continue
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}
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// The /proc/thread-self directory was added in Linux 3.17.
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// We are not using it to maximize compatibility.
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pth := fmt.Sprintf("/proc/self/task/%d/ns/%s", tid, ns)
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fd, err := unix.Open(pth, unix.O_RDONLY|unix.O_CLOEXEC, 0)
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if err != nil {
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started <- &os.PathError{Op: "open", Path: pth, Err: err}
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return
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}
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defer func() {
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if isReversible {
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if err := unix.Setns(fd, 0); err != nil {
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isReversible = false
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}
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}
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_ = unix.Close(fd)
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}()
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}
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}
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// Threads are implemented under Linux as processes which share
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// a virtual memory space. Therefore in a multithreaded process
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// unshare(2) disassociates parts of the calling thread's
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// context from the thread it was clone(2)'d from.
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if err := unix.Unshare(flags); err != nil {
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started <- os.NewSyscallError("unshare", err)
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return
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}
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if setupfn != nil {
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if err := setupfn(); err != nil {
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started <- err
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return
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}
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}
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close(started)
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if fn != nil {
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fn()
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}
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}()
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return <-started
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}
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