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|
// Copyright 2019 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 vfs
import (
"bytes"
"fmt"
"math"
"sort"
"strings"
"sync/atomic"
"gvisor.dev/gvisor/pkg/abi/linux"
"gvisor.dev/gvisor/pkg/context"
"gvisor.dev/gvisor/pkg/refsvfs2"
"gvisor.dev/gvisor/pkg/sentry/kernel/auth"
"gvisor.dev/gvisor/pkg/syserror"
)
// A Mount is a replacement of a Dentry (Mount.key.point) from one Filesystem
// (Mount.key.parent.fs) with a Dentry (Mount.root) from another Filesystem
// (Mount.fs), which applies to path resolution in the context of a particular
// Mount (Mount.key.parent).
//
// Mounts are reference-counted. Unless otherwise specified, all Mount methods
// require that a reference is held.
//
// Mount and Filesystem are distinct types because it's possible for a single
// Filesystem to be mounted at multiple locations and/or in multiple mount
// namespaces.
//
// Mount is analogous to Linux's struct mount. (gVisor does not distinguish
// between struct mount and struct vfsmount.)
//
// +stateify savable
type Mount struct {
// vfs, fs, root are immutable. References are held on fs and root.
// Note that for a disconnected mount, root may be nil.
//
// Invariant: if not nil, root belongs to fs.
vfs *VirtualFilesystem
fs *Filesystem
root *Dentry
// ID is the immutable mount ID.
ID uint64
// Flags contains settings as specified for mount(2), e.g. MS_NOEXEC, except
// for MS_RDONLY which is tracked in "writers". Immutable.
Flags MountFlags
// key is protected by VirtualFilesystem.mountMu and
// VirtualFilesystem.mounts.seq, and may be nil. References are held on
// key.parent and key.point if they are not nil.
//
// Invariant: key.parent != nil iff key.point != nil. key.point belongs to
// key.parent.fs.
key mountKey `state:".(VirtualDentry)"`
// ns is the namespace in which this Mount was mounted. ns is protected by
// VirtualFilesystem.mountMu.
ns *MountNamespace
// The lower 63 bits of refs are a reference count. The MSB of refs is set
// if the Mount has been eagerly umounted, as by umount(2) without the
// MNT_DETACH flag. refs is accessed using atomic memory operations.
refs int64
// children is the set of all Mounts for which Mount.key.parent is this
// Mount. children is protected by VirtualFilesystem.mountMu.
children map[*Mount]struct{}
// umounted is true if VFS.umountRecursiveLocked() has been called on this
// Mount. VirtualFilesystem does not hold a reference on Mounts for which
// umounted is true. umounted is protected by VirtualFilesystem.mountMu.
umounted bool
// The lower 63 bits of writers is the number of calls to
// Mount.CheckBeginWrite() that have not yet been paired with a call to
// Mount.EndWrite(). The MSB of writers is set if MS_RDONLY is in effect.
// writers is accessed using atomic memory operations.
writers int64
}
func newMount(vfs *VirtualFilesystem, fs *Filesystem, root *Dentry, mntns *MountNamespace, opts *MountOptions) *Mount {
mnt := &Mount{
ID: atomic.AddUint64(&vfs.lastMountID, 1),
Flags: opts.Flags,
vfs: vfs,
fs: fs,
root: root,
ns: mntns,
refs: 1,
}
if opts.ReadOnly {
mnt.setReadOnlyLocked(true)
}
refsvfs2.Register(mnt)
return mnt
}
// Options returns a copy of the MountOptions currently applicable to mnt.
func (mnt *Mount) Options() MountOptions {
mnt.vfs.mountMu.Lock()
defer mnt.vfs.mountMu.Unlock()
return MountOptions{
Flags: mnt.Flags,
ReadOnly: mnt.ReadOnly(),
}
}
// A MountNamespace is a collection of Mounts.//
// MountNamespaces are reference-counted. Unless otherwise specified, all
// MountNamespace methods require that a reference is held.
//
// MountNamespace is analogous to Linux's struct mnt_namespace.
//
// +stateify savable
type MountNamespace struct {
MountNamespaceRefs
// Owner is the usernamespace that owns this mount namespace.
Owner *auth.UserNamespace
// root is the MountNamespace's root mount. root is immutable.
root *Mount
// mountpoints maps all Dentries which are mount points in this namespace
// to the number of Mounts for which they are mount points. mountpoints is
// protected by VirtualFilesystem.mountMu.
//
// mountpoints is used to determine if a Dentry can be moved or removed
// (which requires that the Dentry is not a mount point in the calling
// namespace).
//
// mountpoints is maintained even if there are no references held on the
// MountNamespace; this is required to ensure that
// VFS.PrepareDeleteDentry() and VFS.PrepareRemoveDentry() operate
// correctly on unreferenced MountNamespaces.
mountpoints map[*Dentry]uint32
}
// NewMountNamespace returns a new mount namespace with a root filesystem
// configured by the given arguments. A reference is taken on the returned
// MountNamespace.
func (vfs *VirtualFilesystem) NewMountNamespace(ctx context.Context, creds *auth.Credentials, source, fsTypeName string, opts *MountOptions) (*MountNamespace, error) {
rft := vfs.getFilesystemType(fsTypeName)
if rft == nil {
ctx.Warningf("Unknown filesystem type: %s", fsTypeName)
return nil, syserror.ENODEV
}
fs, root, err := rft.fsType.GetFilesystem(ctx, vfs, creds, source, opts.GetFilesystemOptions)
if err != nil {
return nil, err
}
mntns := &MountNamespace{
Owner: creds.UserNamespace,
mountpoints: make(map[*Dentry]uint32),
}
mntns.InitRefs()
mntns.root = newMount(vfs, fs, root, mntns, opts)
return mntns, nil
}
// NewDisconnectedMount returns a Mount representing fs with the given root
// (which may be nil). The new Mount is not associated with any MountNamespace
// and is not connected to any other Mounts. References are taken on fs and
// root.
func (vfs *VirtualFilesystem) NewDisconnectedMount(fs *Filesystem, root *Dentry, opts *MountOptions) (*Mount, error) {
fs.IncRef()
if root != nil {
root.IncRef()
}
return newMount(vfs, fs, root, nil /* mntns */, opts), nil
}
// MountDisconnected creates a Filesystem configured by the given arguments,
// then returns a Mount representing it. The new Mount is not associated with
// any MountNamespace and is not connected to any other Mounts.
func (vfs *VirtualFilesystem) MountDisconnected(ctx context.Context, creds *auth.Credentials, source string, fsTypeName string, opts *MountOptions) (*Mount, error) {
rft := vfs.getFilesystemType(fsTypeName)
if rft == nil {
return nil, syserror.ENODEV
}
if !opts.InternalMount && !rft.opts.AllowUserMount {
return nil, syserror.ENODEV
}
fs, root, err := rft.fsType.GetFilesystem(ctx, vfs, creds, source, opts.GetFilesystemOptions)
if err != nil {
return nil, err
}
defer root.DecRef(ctx)
defer fs.DecRef(ctx)
return vfs.NewDisconnectedMount(fs, root, opts)
}
// ConnectMountAt connects mnt at the path represented by target.
//
// Preconditions: mnt must be disconnected.
func (vfs *VirtualFilesystem) ConnectMountAt(ctx context.Context, creds *auth.Credentials, mnt *Mount, target *PathOperation) error {
// We can't hold vfs.mountMu while calling FilesystemImpl methods due to
// lock ordering.
vd, err := vfs.GetDentryAt(ctx, creds, target, &GetDentryOptions{})
if err != nil {
return err
}
vfs.mountMu.Lock()
vd.dentry.mu.Lock()
for {
if vd.dentry.dead {
vd.dentry.mu.Unlock()
vfs.mountMu.Unlock()
vd.DecRef(ctx)
return syserror.ENOENT
}
// vd might have been mounted over between vfs.GetDentryAt() and
// vfs.mountMu.Lock().
if !vd.dentry.isMounted() {
break
}
nextmnt := vfs.mounts.Lookup(vd.mount, vd.dentry)
if nextmnt == nil {
break
}
// It's possible that nextmnt has been umounted but not disconnected,
// in which case vfs no longer holds a reference on it, and the last
// reference may be concurrently dropped even though we're holding
// vfs.mountMu.
if !nextmnt.tryIncMountedRef() {
break
}
// This can't fail since we're holding vfs.mountMu.
nextmnt.root.IncRef()
vd.dentry.mu.Unlock()
vd.DecRef(ctx)
vd = VirtualDentry{
mount: nextmnt,
dentry: nextmnt.root,
}
vd.dentry.mu.Lock()
}
// TODO(gvisor.dev/issue/1035): Linux requires that either both the mount
// point and the mount root are directories, or neither are, and returns
// ENOTDIR if this is not the case.
mntns := vd.mount.ns
vfs.mounts.seq.BeginWrite()
vfs.connectLocked(mnt, vd, mntns)
vfs.mounts.seq.EndWrite()
vd.dentry.mu.Unlock()
vfs.mountMu.Unlock()
return nil
}
// MountAt creates and mounts a Filesystem configured by the given arguments.
// The VirtualFilesystem will hold a reference to the Mount until it is unmounted.
//
// This method returns the mounted Mount without a reference, for convenience
// during VFS setup when there is no chance of racing with unmount.
func (vfs *VirtualFilesystem) MountAt(ctx context.Context, creds *auth.Credentials, source string, target *PathOperation, fsTypeName string, opts *MountOptions) (*Mount, error) {
mnt, err := vfs.MountDisconnected(ctx, creds, source, fsTypeName, opts)
if err != nil {
return nil, err
}
defer mnt.DecRef(ctx)
if err := vfs.ConnectMountAt(ctx, creds, mnt, target); err != nil {
return nil, err
}
return mnt, nil
}
// UmountAt removes the Mount at the given path.
func (vfs *VirtualFilesystem) UmountAt(ctx context.Context, creds *auth.Credentials, pop *PathOperation, opts *UmountOptions) error {
if opts.Flags&^(linux.MNT_FORCE|linux.MNT_DETACH) != 0 {
return syserror.EINVAL
}
// MNT_FORCE is currently unimplemented except for the permission check.
// Force unmounting specifically requires CAP_SYS_ADMIN in the root user
// namespace, and not in the owner user namespace for the target mount. See
// fs/namespace.c:SYSCALL_DEFINE2(umount, ...)
if opts.Flags&linux.MNT_FORCE != 0 && creds.HasCapabilityIn(linux.CAP_SYS_ADMIN, creds.UserNamespace.Root()) {
return syserror.EPERM
}
vd, err := vfs.GetDentryAt(ctx, creds, pop, &GetDentryOptions{})
if err != nil {
return err
}
defer vd.DecRef(ctx)
if vd.dentry != vd.mount.root {
return syserror.EINVAL
}
vfs.mountMu.Lock()
if mntns := MountNamespaceFromContext(ctx); mntns != nil {
defer mntns.DecRef(ctx)
if mntns != vd.mount.ns {
vfs.mountMu.Unlock()
return syserror.EINVAL
}
if vd.mount == vd.mount.ns.root {
vfs.mountMu.Unlock()
return syserror.EINVAL
}
}
// TODO(gvisor.dev/issue/1035): Linux special-cases umount of the caller's
// root, which we don't implement yet (we'll just fail it since the caller
// holds a reference on it).
vfs.mounts.seq.BeginWrite()
if opts.Flags&linux.MNT_DETACH == 0 {
if len(vd.mount.children) != 0 {
vfs.mounts.seq.EndWrite()
vfs.mountMu.Unlock()
return syserror.EBUSY
}
// We are holding a reference on vd.mount.
expectedRefs := int64(1)
if !vd.mount.umounted {
expectedRefs = 2
}
if atomic.LoadInt64(&vd.mount.refs)&^math.MinInt64 != expectedRefs { // mask out MSB
vfs.mounts.seq.EndWrite()
vfs.mountMu.Unlock()
return syserror.EBUSY
}
}
vdsToDecRef, mountsToDecRef := vfs.umountRecursiveLocked(vd.mount, &umountRecursiveOptions{
eager: opts.Flags&linux.MNT_DETACH == 0,
disconnectHierarchy: true,
}, nil, nil)
vfs.mounts.seq.EndWrite()
vfs.mountMu.Unlock()
for _, vd := range vdsToDecRef {
vd.DecRef(ctx)
}
for _, mnt := range mountsToDecRef {
mnt.DecRef(ctx)
}
return nil
}
// +stateify savable
type umountRecursiveOptions struct {
// If eager is true, ensure that future calls to Mount.tryIncMountedRef()
// on umounted mounts fail.
//
// eager is analogous to Linux's UMOUNT_SYNC.
eager bool
// If disconnectHierarchy is true, Mounts that are umounted hierarchically
// should be disconnected from their parents. (Mounts whose parents are not
// umounted, which in most cases means the Mount passed to the initial call
// to umountRecursiveLocked, are unconditionally disconnected for
// consistency with Linux.)
//
// disconnectHierarchy is analogous to Linux's !UMOUNT_CONNECTED.
disconnectHierarchy bool
}
// umountRecursiveLocked marks mnt and its descendants as umounted. It does not
// release mount or dentry references; instead, it appends VirtualDentries and
// Mounts on which references must be dropped to vdsToDecRef and mountsToDecRef
// respectively, and returns updated slices. (This is necessary because
// filesystem locks possibly taken by DentryImpl.DecRef() may precede
// vfs.mountMu in the lock order, and Mount.DecRef() may lock vfs.mountMu.)
//
// umountRecursiveLocked is analogous to Linux's fs/namespace.c:umount_tree().
//
// Preconditions:
// * vfs.mountMu must be locked.
// * vfs.mounts.seq must be in a writer critical section.
func (vfs *VirtualFilesystem) umountRecursiveLocked(mnt *Mount, opts *umountRecursiveOptions, vdsToDecRef []VirtualDentry, mountsToDecRef []*Mount) ([]VirtualDentry, []*Mount) {
if !mnt.umounted {
mnt.umounted = true
mountsToDecRef = append(mountsToDecRef, mnt)
if parent := mnt.parent(); parent != nil && (opts.disconnectHierarchy || !parent.umounted) {
vdsToDecRef = append(vdsToDecRef, vfs.disconnectLocked(mnt))
}
}
if opts.eager {
for {
refs := atomic.LoadInt64(&mnt.refs)
if refs < 0 {
break
}
if atomic.CompareAndSwapInt64(&mnt.refs, refs, refs|math.MinInt64) {
break
}
}
}
for child := range mnt.children {
vdsToDecRef, mountsToDecRef = vfs.umountRecursiveLocked(child, opts, vdsToDecRef, mountsToDecRef)
}
return vdsToDecRef, mountsToDecRef
}
// connectLocked makes vd the mount parent/point for mnt. It consumes
// references held by vd.
//
// Preconditions:
// * vfs.mountMu must be locked.
// * vfs.mounts.seq must be in a writer critical section.
// * d.mu must be locked.
// * mnt.parent() == nil, i.e. mnt must not already be connected.
func (vfs *VirtualFilesystem) connectLocked(mnt *Mount, vd VirtualDentry, mntns *MountNamespace) {
if checkInvariants {
if mnt.parent() != nil {
panic("VFS.connectLocked called on connected mount")
}
}
mnt.IncRef() // dropped by callers of umountRecursiveLocked
mnt.setKey(vd)
if vd.mount.children == nil {
vd.mount.children = make(map[*Mount]struct{})
}
vd.mount.children[mnt] = struct{}{}
atomic.AddUint32(&vd.dentry.mounts, 1)
mnt.ns = mntns
mntns.mountpoints[vd.dentry]++
vfs.mounts.insertSeqed(mnt)
vfsmpmounts, ok := vfs.mountpoints[vd.dentry]
if !ok {
vfsmpmounts = make(map[*Mount]struct{})
vfs.mountpoints[vd.dentry] = vfsmpmounts
}
vfsmpmounts[mnt] = struct{}{}
}
// disconnectLocked makes vd have no mount parent/point and returns its old
// mount parent/point with a reference held.
//
// Preconditions:
// * vfs.mountMu must be locked.
// * vfs.mounts.seq must be in a writer critical section.
// * mnt.parent() != nil.
func (vfs *VirtualFilesystem) disconnectLocked(mnt *Mount) VirtualDentry {
vd := mnt.getKey()
if checkInvariants {
if vd.mount != nil {
panic("VFS.disconnectLocked called on disconnected mount")
}
}
mnt.loadKey(VirtualDentry{})
delete(vd.mount.children, mnt)
atomic.AddUint32(&vd.dentry.mounts, math.MaxUint32) // -1
mnt.ns.mountpoints[vd.dentry]--
if mnt.ns.mountpoints[vd.dentry] == 0 {
delete(mnt.ns.mountpoints, vd.dentry)
}
vfs.mounts.removeSeqed(mnt)
vfsmpmounts := vfs.mountpoints[vd.dentry]
delete(vfsmpmounts, mnt)
if len(vfsmpmounts) == 0 {
delete(vfs.mountpoints, vd.dentry)
}
return vd
}
// tryIncMountedRef increments mnt's reference count and returns true. If mnt's
// reference count is already zero, or has been eagerly umounted,
// tryIncMountedRef does nothing and returns false.
//
// tryIncMountedRef does not require that a reference is held on mnt.
func (mnt *Mount) tryIncMountedRef() bool {
for {
r := atomic.LoadInt64(&mnt.refs)
if r <= 0 { // r < 0 => MSB set => eagerly unmounted
return false
}
if atomic.CompareAndSwapInt64(&mnt.refs, r, r+1) {
if mnt.LogRefs() {
refsvfs2.LogTryIncRef(mnt, r+1)
}
return true
}
}
}
// IncRef increments mnt's reference count.
func (mnt *Mount) IncRef() {
// In general, negative values for mnt.refs are valid because the MSB is
// the eager-unmount bit.
r := atomic.AddInt64(&mnt.refs, 1)
if mnt.LogRefs() {
refsvfs2.LogIncRef(mnt, r)
}
}
// DecRef decrements mnt's reference count.
func (mnt *Mount) DecRef(ctx context.Context) {
r := atomic.AddInt64(&mnt.refs, -1)
if mnt.LogRefs() {
refsvfs2.LogDecRef(mnt, r)
}
if r&^math.MinInt64 == 0 { // mask out MSB
refsvfs2.Unregister(mnt)
mnt.destroy(ctx)
}
}
func (mnt *Mount) destroy(ctx context.Context) {
var vd VirtualDentry
if mnt.parent() != nil {
mnt.vfs.mountMu.Lock()
mnt.vfs.mounts.seq.BeginWrite()
vd = mnt.vfs.disconnectLocked(mnt)
mnt.vfs.mounts.seq.EndWrite()
mnt.vfs.mountMu.Unlock()
}
if mnt.root != nil {
mnt.root.DecRef(ctx)
}
mnt.fs.DecRef(ctx)
if vd.Ok() {
vd.DecRef(ctx)
}
}
// RefType implements refsvfs2.CheckedObject.Type.
func (mnt *Mount) RefType() string {
return "vfs.Mount"
}
// LeakMessage implements refsvfs2.CheckedObject.LeakMessage.
func (mnt *Mount) LeakMessage() string {
return fmt.Sprintf("[vfs.Mount %p] reference count of %d instead of 0", mnt, atomic.LoadInt64(&mnt.refs))
}
// LogRefs implements refsvfs2.CheckedObject.LogRefs.
//
// This should only be set to true for debugging purposes, as it can generate an
// extremely large amount of output and drastically degrade performance.
func (mnt *Mount) LogRefs() bool {
return false
}
// DecRef decrements mntns' reference count.
func (mntns *MountNamespace) DecRef(ctx context.Context) {
vfs := mntns.root.fs.VirtualFilesystem()
mntns.MountNamespaceRefs.DecRef(func() {
vfs.mountMu.Lock()
vfs.mounts.seq.BeginWrite()
vdsToDecRef, mountsToDecRef := vfs.umountRecursiveLocked(mntns.root, &umountRecursiveOptions{
disconnectHierarchy: true,
}, nil, nil)
vfs.mounts.seq.EndWrite()
vfs.mountMu.Unlock()
for _, vd := range vdsToDecRef {
vd.DecRef(ctx)
}
for _, mnt := range mountsToDecRef {
mnt.DecRef(ctx)
}
})
}
// getMountAt returns the last Mount in the stack mounted at (mnt, d). It takes
// a reference on the returned Mount. If (mnt, d) is not a mount point,
// getMountAt returns nil.
//
// getMountAt is analogous to Linux's fs/namei.c:follow_mount().
//
// Preconditions: References are held on mnt and d.
func (vfs *VirtualFilesystem) getMountAt(ctx context.Context, mnt *Mount, d *Dentry) *Mount {
// The first mount is special-cased:
//
// - The caller is assumed to have checked d.isMounted() already. (This
// isn't a precondition because it doesn't matter for correctness.)
//
// - We return nil, instead of mnt, if there is no mount at (mnt, d).
//
// - We don't drop the caller's references on mnt and d.
retryFirst:
next := vfs.mounts.Lookup(mnt, d)
if next == nil {
return nil
}
if !next.tryIncMountedRef() {
// Raced with umount.
goto retryFirst
}
mnt = next
d = next.root
// We don't need to take Dentry refs anywhere in this function because
// Mounts hold references on Mount.root, which is immutable.
for d.isMounted() {
next := vfs.mounts.Lookup(mnt, d)
if next == nil {
break
}
if !next.tryIncMountedRef() {
// Raced with umount.
continue
}
mnt.DecRef(ctx)
mnt = next
d = next.root
}
return mnt
}
// getMountpointAt returns the mount point for the stack of Mounts including
// mnt. It takes a reference on the returned VirtualDentry. If no such mount
// point exists (i.e. mnt is a root mount), getMountpointAt returns (nil, nil).
//
// Preconditions:
// * References are held on mnt and root.
// * vfsroot is not (mnt, mnt.root).
func (vfs *VirtualFilesystem) getMountpointAt(ctx context.Context, mnt *Mount, vfsroot VirtualDentry) VirtualDentry {
// The first mount is special-cased:
//
// - The caller must have already checked mnt against vfsroot.
//
// - We return nil, instead of mnt, if there is no mount point for mnt.
//
// - We don't drop the caller's reference on mnt.
retryFirst:
epoch := vfs.mounts.seq.BeginRead()
parent, point := mnt.parent(), mnt.point()
if !vfs.mounts.seq.ReadOk(epoch) {
goto retryFirst
}
if parent == nil {
return VirtualDentry{}
}
if !parent.tryIncMountedRef() {
// Raced with umount.
goto retryFirst
}
if !point.TryIncRef() {
// Since Mount holds a reference on Mount.key.point, this can only
// happen due to a racing change to Mount.key.
parent.DecRef(ctx)
goto retryFirst
}
if !vfs.mounts.seq.ReadOk(epoch) {
point.DecRef(ctx)
parent.DecRef(ctx)
goto retryFirst
}
mnt = parent
d := point
for {
if mnt == vfsroot.mount && d == vfsroot.dentry {
break
}
if d != mnt.root {
break
}
retryNotFirst:
epoch := vfs.mounts.seq.BeginRead()
parent, point := mnt.parent(), mnt.point()
if !vfs.mounts.seq.ReadOk(epoch) {
goto retryNotFirst
}
if parent == nil {
break
}
if !parent.tryIncMountedRef() {
// Raced with umount.
goto retryNotFirst
}
if !point.TryIncRef() {
// Since Mount holds a reference on Mount.key.point, this can
// only happen due to a racing change to Mount.key.
parent.DecRef(ctx)
goto retryNotFirst
}
if !vfs.mounts.seq.ReadOk(epoch) {
point.DecRef(ctx)
parent.DecRef(ctx)
goto retryNotFirst
}
d.DecRef(ctx)
mnt.DecRef(ctx)
mnt = parent
d = point
}
return VirtualDentry{mnt, d}
}
// SetMountReadOnly sets the mount as ReadOnly.
func (vfs *VirtualFilesystem) SetMountReadOnly(mnt *Mount, ro bool) error {
vfs.mountMu.Lock()
defer vfs.mountMu.Unlock()
return mnt.setReadOnlyLocked(ro)
}
// CheckBeginWrite increments the counter of in-progress write operations on
// mnt. If mnt is mounted MS_RDONLY, CheckBeginWrite does nothing and returns
// EROFS.
//
// If CheckBeginWrite succeeds, EndWrite must be called when the write
// operation is finished.
func (mnt *Mount) CheckBeginWrite() error {
if atomic.AddInt64(&mnt.writers, 1) < 0 {
atomic.AddInt64(&mnt.writers, -1)
return syserror.EROFS
}
return nil
}
// EndWrite indicates that a write operation signaled by a previous successful
// call to CheckBeginWrite has finished.
func (mnt *Mount) EndWrite() {
atomic.AddInt64(&mnt.writers, -1)
}
// Preconditions: VirtualFilesystem.mountMu must be locked.
func (mnt *Mount) setReadOnlyLocked(ro bool) error {
if oldRO := atomic.LoadInt64(&mnt.writers) < 0; oldRO == ro {
return nil
}
if ro {
if !atomic.CompareAndSwapInt64(&mnt.writers, 0, math.MinInt64) {
return syserror.EBUSY
}
return nil
}
// Unset MSB without dropping any temporary increments from failed calls to
// mnt.CheckBeginWrite().
atomic.AddInt64(&mnt.writers, math.MinInt64)
return nil
}
// ReadOnly returns true if mount is readonly.
func (mnt *Mount) ReadOnly() bool {
return atomic.LoadInt64(&mnt.writers) < 0
}
// Filesystem returns the mounted Filesystem. It does not take a reference on
// the returned Filesystem.
func (mnt *Mount) Filesystem() *Filesystem {
return mnt.fs
}
// submountsLocked returns this Mount and all Mounts that are descendents of
// it.
//
// Precondition: mnt.vfs.mountMu must be held.
func (mnt *Mount) submountsLocked() []*Mount {
mounts := []*Mount{mnt}
for m := range mnt.children {
mounts = append(mounts, m.submountsLocked()...)
}
return mounts
}
// Root returns the mount's root. It does not take a reference on the returned
// Dentry.
func (mnt *Mount) Root() *Dentry {
return mnt.root
}
// Root returns mntns' root. It does not take a reference on the returned Dentry.
func (mntns *MountNamespace) Root() VirtualDentry {
vd := VirtualDentry{
mount: mntns.root,
dentry: mntns.root.root,
}
return vd
}
// GenerateProcMounts emits the contents of /proc/[pid]/mounts for vfs to buf.
//
// Preconditions: taskRootDir.Ok().
func (vfs *VirtualFilesystem) GenerateProcMounts(ctx context.Context, taskRootDir VirtualDentry, buf *bytes.Buffer) {
rootMnt := taskRootDir.mount
vfs.mountMu.Lock()
mounts := rootMnt.submountsLocked()
// Take a reference on mounts since we need to drop vfs.mountMu before
// calling vfs.PathnameReachable() (=> FilesystemImpl.PrependPath()).
for _, mnt := range mounts {
mnt.IncRef()
}
vfs.mountMu.Unlock()
defer func() {
for _, mnt := range mounts {
mnt.DecRef(ctx)
}
}()
sort.Slice(mounts, func(i, j int) bool { return mounts[i].ID < mounts[j].ID })
for _, mnt := range mounts {
// Get the path to this mount relative to task root.
mntRootVD := VirtualDentry{
mount: mnt,
dentry: mnt.root,
}
path, err := vfs.PathnameReachable(ctx, taskRootDir, mntRootVD)
if err != nil {
// For some reason we didn't get a path. Log a warning
// and run with empty path.
ctx.Warningf("VFS.GenerateProcMounts: error getting pathname for mount root %+v: %v", mnt.root, err)
path = ""
}
if path == "" {
// Either an error occurred, or path is not reachable
// from root.
break
}
opts := "rw"
if mnt.ReadOnly() {
opts = "ro"
}
if mnt.Flags.NoATime {
opts = ",noatime"
}
if mnt.Flags.NoExec {
opts += ",noexec"
}
// Format:
// <special device or remote filesystem> <mount point> <filesystem type> <mount options> <needs dump> <fsck order>
//
// The "needs dump" and "fsck order" flags are always 0, which
// is allowed.
fmt.Fprintf(buf, "%s %s %s %s %d %d\n", "none", path, mnt.fs.FilesystemType().Name(), opts, 0, 0)
}
}
// GenerateProcMountInfo emits the contents of /proc/[pid]/mountinfo for vfs to
// buf.
//
// Preconditions: taskRootDir.Ok().
func (vfs *VirtualFilesystem) GenerateProcMountInfo(ctx context.Context, taskRootDir VirtualDentry, buf *bytes.Buffer) {
rootMnt := taskRootDir.mount
vfs.mountMu.Lock()
mounts := rootMnt.submountsLocked()
// Take a reference on mounts since we need to drop vfs.mountMu before
// calling vfs.PathnameReachable() (=> FilesystemImpl.PrependPath()) or
// vfs.StatAt() (=> FilesystemImpl.StatAt()).
for _, mnt := range mounts {
mnt.IncRef()
}
vfs.mountMu.Unlock()
defer func() {
for _, mnt := range mounts {
mnt.DecRef(ctx)
}
}()
sort.Slice(mounts, func(i, j int) bool { return mounts[i].ID < mounts[j].ID })
creds := auth.CredentialsFromContext(ctx)
for _, mnt := range mounts {
// Get the path to this mount relative to task root.
mntRootVD := VirtualDentry{
mount: mnt,
dentry: mnt.root,
}
path, err := vfs.PathnameReachable(ctx, taskRootDir, mntRootVD)
if err != nil {
// For some reason we didn't get a path. Log a warning
// and run with empty path.
ctx.Warningf("VFS.GenerateProcMountInfo: error getting pathname for mount root %+v: %v", mnt.root, err)
path = ""
}
if path == "" {
// Either an error occurred, or path is not reachable
// from root.
break
}
// Stat the mount root to get the major/minor device numbers.
pop := &PathOperation{
Root: mntRootVD,
Start: mntRootVD,
}
statx, err := vfs.StatAt(ctx, creds, pop, &StatOptions{})
if err != nil {
// Well that's not good. Ignore this mount.
ctx.Warningf("VFS.GenerateProcMountInfo: failed to stat mount root %+v: %v", mnt.root, err)
break
}
// Format:
// 36 35 98:0 /mnt1 /mnt2 rw,noatime master:1 - ext3 /dev/root rw,errors=continue
// (1)(2)(3) (4) (5) (6) (7) (8) (9) (10) (11)
// (1) Mount ID.
fmt.Fprintf(buf, "%d ", mnt.ID)
// (2) Parent ID (or this ID if there is no parent).
// Note that even if the call to mnt.parent() races with Mount
// destruction (which is possible since we're not holding vfs.mountMu),
// its Mount.ID will still be valid.
pID := mnt.ID
if p := mnt.parent(); p != nil {
pID = p.ID
}
fmt.Fprintf(buf, "%d ", pID)
// (3) Major:Minor device ID. We don't have a superblock, so we
// just use the root inode device number.
fmt.Fprintf(buf, "%d:%d ", statx.DevMajor, statx.DevMinor)
// (4) Root: the pathname of the directory in the filesystem
// which forms the root of this mount.
//
// NOTE(b/78135857): This will always be "/" until we implement
// bind mounts.
fmt.Fprintf(buf, "/ ")
// (5) Mount point (relative to process root).
fmt.Fprintf(buf, "%s ", manglePath(path))
// (6) Mount options.
opts := "rw"
if mnt.ReadOnly() {
opts = "ro"
}
if mnt.Flags.NoATime {
opts = ",noatime"
}
if mnt.Flags.NoExec {
opts += ",noexec"
}
fmt.Fprintf(buf, "%s ", opts)
// (7) Optional fields: zero or more fields of the form "tag[:value]".
// (8) Separator: the end of the optional fields is marked by a single hyphen.
fmt.Fprintf(buf, "- ")
// (9) Filesystem type.
fmt.Fprintf(buf, "%s ", mnt.fs.FilesystemType().Name())
// (10) Mount source: filesystem-specific information or "none".
fmt.Fprintf(buf, "none ")
// (11) Superblock options, and final newline.
fmt.Fprintf(buf, "%s\n", superBlockOpts(path, mnt))
}
}
// manglePath replaces ' ', '\t', '\n', and '\\' with their octal equivalents.
// See Linux fs/seq_file.c:mangle_path.
func manglePath(p string) string {
r := strings.NewReplacer(" ", "\\040", "\t", "\\011", "\n", "\\012", "\\", "\\134")
return r.Replace(p)
}
// superBlockOpts returns the super block options string for the the mount at
// the given path.
func superBlockOpts(mountPath string, mnt *Mount) string {
// gVisor doesn't (yet) have a concept of super block options, so we
// use the ro/rw bit from the mount flag.
opts := "rw"
if mnt.ReadOnly() {
opts = "ro"
}
// NOTE(b/147673608): If the mount is a cgroup, we also need to include
// the cgroup name in the options. For now we just read that from the
// path.
//
// TODO(gvisor.dev/issue/190): Once gVisor has full cgroup support, we
// should get this value from the cgroup itself, and not rely on the
// path.
if mnt.fs.FilesystemType().Name() == "cgroup" {
splitPath := strings.Split(mountPath, "/")
cgroupType := splitPath[len(splitPath)-1]
opts += "," + cgroupType
}
return opts
}
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