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// Copyright 2018 Google LLC
//
// 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 host
import (
"sync"
"syscall"
"gvisor.googlesource.com/gvisor/pkg/abi/linux"
"gvisor.googlesource.com/gvisor/pkg/fd"
"gvisor.googlesource.com/gvisor/pkg/secio"
"gvisor.googlesource.com/gvisor/pkg/sentry/context"
"gvisor.googlesource.com/gvisor/pkg/sentry/device"
"gvisor.googlesource.com/gvisor/pkg/sentry/fs"
"gvisor.googlesource.com/gvisor/pkg/sentry/fs/fsutil"
"gvisor.googlesource.com/gvisor/pkg/sentry/memmap"
"gvisor.googlesource.com/gvisor/pkg/sentry/safemem"
"gvisor.googlesource.com/gvisor/pkg/sentry/socket/unix/transport"
"gvisor.googlesource.com/gvisor/pkg/syserror"
"gvisor.googlesource.com/gvisor/pkg/waiter"
)
// inodeOperations implements fs.InodeOperations for an fs.Inodes backed
// by a host file descriptor.
//
// +stateify savable
type inodeOperations struct {
fsutil.InodeNotVirtual `state:"nosave"`
fsutil.InodeNoExtendedAttributes `state:"nosave"`
// fileState implements fs.CachedFileObject. It exists
// to break a circular load dependency between inodeOperations
// and cachingInodeOps (below).
fileState *inodeFileState `state:"wait"`
// cachedInodeOps implements memmap.Mappable.
cachingInodeOps *fsutil.CachingInodeOperations
// readdirMu protects the file offset on the host FD. This is needed
// for readdir because getdents must use the kernel offset, so
// concurrent readdirs must be exclusive.
//
// All read/write functions pass the offset directly to the kernel and
// thus don't need a lock.
readdirMu sync.Mutex `state:"nosave"`
}
// inodeFileState implements fs.CachedFileObject and otherwise fully
// encapsulates state that needs to be manually loaded on restore for
// this file object.
//
// This unfortunate structure exists because fs.CachingInodeOperations
// defines afterLoad and therefore cannot be lazily loaded (to break a
// circular load dependency between it and inodeOperations). Even with
// lazy loading, this approach defines the dependencies between objects
// and the expected load behavior more concretely.
//
// +stateify savable
type inodeFileState struct {
// Common file system state.
mops *superOperations `state:"wait"`
// descriptor is the backing host FD.
descriptor *descriptor `state:"wait"`
// Event queue for blocking operations.
queue waiter.Queue `state:"zerovalue"`
// sattr is used to restore the inodeOperations.
sattr fs.StableAttr `state:"wait"`
// savedUAttr is only allocated during S/R. It points to the save-time
// unstable attributes and is used to validate restore-time ones.
//
// Note that these unstable attributes are only used to detect cross-S/R
// external file system metadata changes. They may differ from the
// cached unstable attributes in cachingInodeOps, as that might differ
// from the external file system attributes if there had been WriteOut
// failures. S/R is transparent to Sentry and the latter will continue
// using its cached values after restore.
savedUAttr *fs.UnstableAttr
}
// ReadToBlocksAt implements fsutil.CachedFileObject.ReadToBlocksAt.
func (i *inodeFileState) ReadToBlocksAt(ctx context.Context, dsts safemem.BlockSeq, offset uint64) (uint64, error) {
// TODO: Using safemem.FromIOReader here is wasteful for two
// reasons:
//
// - Using preadv instead of iterated preads saves on host system calls.
//
// - Host system calls can handle destination memory that would fault in
// gr3 (i.e. they can accept safemem.Blocks with NeedSafecopy() == true),
// so the buffering performed by FromIOReader is unnecessary.
//
// This also applies to the write path below.
return safemem.FromIOReader{secio.NewOffsetReader(fd.NewReadWriter(i.FD()), int64(offset))}.ReadToBlocks(dsts)
}
// WriteFromBlocksAt implements fsutil.CachedFileObject.WriteFromBlocksAt.
func (i *inodeFileState) WriteFromBlocksAt(ctx context.Context, srcs safemem.BlockSeq, offset uint64) (uint64, error) {
return safemem.FromIOWriter{secio.NewOffsetWriter(fd.NewReadWriter(i.FD()), int64(offset))}.WriteFromBlocks(srcs)
}
// SetMaskedAttributes implements fsutil.CachedFileObject.SetMaskedAttributes.
func (i *inodeFileState) SetMaskedAttributes(ctx context.Context, mask fs.AttrMask, attr fs.UnstableAttr) error {
if mask.Empty() {
return nil
}
if mask.UID || mask.GID {
return syserror.EPERM
}
if mask.Perms {
if err := syscall.Fchmod(i.FD(), uint32(attr.Perms.LinuxMode())); err != nil {
return err
}
}
if mask.Size {
if err := syscall.Ftruncate(i.FD(), attr.Size); err != nil {
return err
}
}
if mask.AccessTime || mask.ModificationTime {
ts := fs.TimeSpec{
ATime: attr.AccessTime,
ATimeOmit: !mask.AccessTime,
MTime: attr.ModificationTime,
MTimeOmit: !mask.ModificationTime,
}
if err := setTimestamps(i.FD(), ts); err != nil {
return err
}
}
return nil
}
// Sync implements fsutil.CachedFileObject.Sync.
func (i *inodeFileState) Sync(ctx context.Context) error {
return syscall.Fsync(i.FD())
}
// FD implements fsutil.CachedFileObject.FD.
func (i *inodeFileState) FD() int {
return i.descriptor.value
}
func (i *inodeFileState) unstableAttr(ctx context.Context) (fs.UnstableAttr, error) {
var s syscall.Stat_t
if err := syscall.Fstat(i.FD(), &s); err != nil {
return fs.UnstableAttr{}, err
}
return unstableAttr(i.mops, &s), nil
}
// inodeOperations implements fs.InodeOperations.
var _ fs.InodeOperations = (*inodeOperations)(nil)
// newInode returns a new fs.Inode backed by the host FD.
func newInode(ctx context.Context, msrc *fs.MountSource, fd int, saveable bool, donated bool) (*fs.Inode, error) {
// Retrieve metadata.
var s syscall.Stat_t
err := syscall.Fstat(fd, &s)
if err != nil {
return nil, err
}
fileState := &inodeFileState{
mops: msrc.MountSourceOperations.(*superOperations),
sattr: stableAttr(&s),
}
// Initialize the wrapped host file descriptor.
fileState.descriptor, err = newDescriptor(
fd,
donated,
saveable,
wouldBlock(&s),
&fileState.queue,
)
if err != nil {
return nil, err
}
// Build the fs.InodeOperations.
uattr := unstableAttr(msrc.MountSourceOperations.(*superOperations), &s)
iops := &inodeOperations{
fileState: fileState,
cachingInodeOps: fsutil.NewCachingInodeOperations(ctx, fileState, uattr, msrc.Flags.ForcePageCache),
}
// Return the fs.Inode.
return fs.NewInode(iops, msrc, fileState.sattr), nil
}
// Mappable implements fs.InodeOperations.Mappable.
func (i *inodeOperations) Mappable(inode *fs.Inode) memmap.Mappable {
if !canMap(inode) {
return nil
}
return i.cachingInodeOps
}
// ReturnsWouldBlock returns true if this host FD can return EWOULDBLOCK for
// operations that would block.
func (i *inodeOperations) ReturnsWouldBlock() bool {
return i.fileState.descriptor.wouldBlock
}
// Release implements fs.InodeOperations.Release.
func (i *inodeOperations) Release(context.Context) {
i.fileState.descriptor.Release()
i.cachingInodeOps.Release()
}
// Lookup implements fs.InodeOperations.Lookup.
func (i *inodeOperations) Lookup(ctx context.Context, dir *fs.Inode, name string) (*fs.Dirent, error) {
// Get a new FD relative to i at name.
fd, err := open(i, name)
if err != nil {
if err == syserror.ENOENT {
return nil, syserror.ENOENT
}
return nil, err
}
inode, err := newInode(ctx, dir.MountSource, fd, false /* saveable */, false /* donated */)
if err != nil {
return nil, err
}
// Return the fs.Dirent.
return fs.NewDirent(inode, name), nil
}
// Create implements fs.InodeOperations.Create.
func (i *inodeOperations) Create(ctx context.Context, dir *fs.Inode, name string, flags fs.FileFlags, perm fs.FilePermissions) (*fs.File, error) {
// Create a file relative to i at name.
//
// N.B. We always open this file O_RDWR regardless of flags because a
// future GetFile might want more access. Open allows this regardless
// of perm.
fd, err := openAt(i, name, syscall.O_RDWR|syscall.O_CREAT|syscall.O_EXCL, perm.LinuxMode())
if err != nil {
return nil, err
}
inode, err := newInode(ctx, dir.MountSource, fd, false /* saveable */, false /* donated */)
if err != nil {
return nil, err
}
d := fs.NewDirent(inode, name)
defer d.DecRef()
return inode.GetFile(ctx, d, flags)
}
// CreateDirectory implements fs.InodeOperations.CreateDirectory.
func (i *inodeOperations) CreateDirectory(ctx context.Context, dir *fs.Inode, name string, perm fs.FilePermissions) error {
return syscall.Mkdirat(i.fileState.FD(), name, uint32(perm.LinuxMode()))
}
// CreateLink implements fs.InodeOperations.CreateLink.
func (i *inodeOperations) CreateLink(ctx context.Context, dir *fs.Inode, oldname string, newname string) error {
return createLink(i.fileState.FD(), oldname, newname)
}
// CreateHardLink implements fs.InodeOperations.CreateHardLink.
func (*inodeOperations) CreateHardLink(context.Context, *fs.Inode, *fs.Inode, string) error {
return syserror.EPERM
}
// CreateFifo implements fs.InodeOperations.CreateFifo.
func (*inodeOperations) CreateFifo(context.Context, *fs.Inode, string, fs.FilePermissions) error {
return syserror.EOPNOTSUPP
}
// Remove implements fs.InodeOperations.Remove.
func (i *inodeOperations) Remove(ctx context.Context, dir *fs.Inode, name string) error {
return unlinkAt(i.fileState.FD(), name, false /* dir */)
}
// RemoveDirectory implements fs.InodeOperations.RemoveDirectory.
func (i *inodeOperations) RemoveDirectory(ctx context.Context, dir *fs.Inode, name string) error {
return unlinkAt(i.fileState.FD(), name, true /* dir */)
}
// Rename implements fs.InodeOperations.Rename.
func (i *inodeOperations) Rename(ctx context.Context, oldParent *fs.Inode, oldName string, newParent *fs.Inode, newName string) error {
op, ok := oldParent.InodeOperations.(*inodeOperations)
if !ok {
return syscall.EXDEV
}
np, ok := newParent.InodeOperations.(*inodeOperations)
if !ok {
return syscall.EXDEV
}
return syscall.Renameat(op.fileState.FD(), oldName, np.fileState.FD(), newName)
}
// Bind implements fs.InodeOperations.Bind.
func (i *inodeOperations) Bind(ctx context.Context, dir *fs.Inode, name string, data transport.BoundEndpoint, perm fs.FilePermissions) (*fs.Dirent, error) {
return nil, syserror.EOPNOTSUPP
}
// BoundEndpoint implements fs.InodeOperations.BoundEndpoint.
func (i *inodeOperations) BoundEndpoint(inode *fs.Inode, path string) transport.BoundEndpoint {
return nil
}
// GetFile implements fs.InodeOperations.GetFile.
func (i *inodeOperations) GetFile(ctx context.Context, d *fs.Dirent, flags fs.FileFlags) (*fs.File, error) {
return newFile(ctx, d, flags, i), nil
}
// canMap returns true if this fs.Inode can be memory mapped.
func canMap(inode *fs.Inode) bool {
// FIXME: Some obscure character devices can be mapped.
return fs.IsFile(inode.StableAttr)
}
// UnstableAttr implements fs.InodeOperations.UnstableAttr.
func (i *inodeOperations) UnstableAttr(ctx context.Context, inode *fs.Inode) (fs.UnstableAttr, error) {
// When the kernel supports mapping host FDs, we do so to take
// advantage of the host page cache. We forego updating fs.Inodes
// because the host manages consistency of its own inode structures.
//
// For fs.Inodes that can never be mapped we take advantage of
// synchronizing metadata updates through host caches.
//
// So can we use host kernel metadata caches?
if !inode.MountSource.Flags.ForcePageCache || !canMap(inode) {
// Then just obtain the attributes.
return i.fileState.unstableAttr(ctx)
}
// No, we're maintaining consistency of metadata ourselves.
return i.cachingInodeOps.UnstableAttr(ctx, inode)
}
// Check implements fs.InodeOperations.Check.
func (i *inodeOperations) Check(ctx context.Context, inode *fs.Inode, p fs.PermMask) bool {
return fs.ContextCanAccessFile(ctx, inode, p)
}
// SetOwner implements fs.InodeOperations.SetOwner.
func (i *inodeOperations) SetOwner(context.Context, *fs.Inode, fs.FileOwner) error {
return syserror.EPERM
}
// SetPermissions implements fs.InodeOperations.SetPermissions.
func (i *inodeOperations) SetPermissions(ctx context.Context, inode *fs.Inode, f fs.FilePermissions) bool {
// Can we use host kernel metadata caches?
if !inode.MountSource.Flags.ForcePageCache || !canMap(inode) {
// Then just change the timestamps on the FD, the host
// will synchronize the metadata update with any host
// inode and page cache.
return syscall.Fchmod(i.fileState.FD(), uint32(f.LinuxMode())) == nil
}
// Otherwise update our cached metadata.
return i.cachingInodeOps.SetPermissions(ctx, inode, f)
}
// SetTimestamps implements fs.InodeOperations.SetTimestamps.
func (i *inodeOperations) SetTimestamps(ctx context.Context, inode *fs.Inode, ts fs.TimeSpec) error {
// Can we use host kernel metadata caches?
if !inode.MountSource.Flags.ForcePageCache || !canMap(inode) {
// Then just change the timestamps on the FD, the host
// will synchronize the metadata update with any host
// inode and page cache.
return setTimestamps(i.fileState.FD(), ts)
}
// Otherwise update our cached metadata.
return i.cachingInodeOps.SetTimestamps(ctx, inode, ts)
}
// Truncate implements fs.InodeOperations.Truncate.
func (i *inodeOperations) Truncate(ctx context.Context, inode *fs.Inode, size int64) error {
// Is the file not memory-mappable?
if !canMap(inode) {
// Then just change the file size on the FD, the host
// will synchronize the metadata update with any host
// inode and page cache.
return syscall.Ftruncate(i.fileState.FD(), size)
}
// Otherwise we need to go through cachingInodeOps, even if the host page
// cache is in use, to invalidate private copies of truncated pages.
return i.cachingInodeOps.Truncate(ctx, inode, size)
}
// WriteOut implements fs.InodeOperations.WriteOut.
func (i *inodeOperations) WriteOut(ctx context.Context, inode *fs.Inode) error {
// Have we been using host kernel metadata caches?
if !inode.MountSource.Flags.ForcePageCache || !canMap(inode) {
// Then the metadata is already up to date on the host.
return nil
}
// Otherwise we need to write out cached pages and attributes
// that are dirty.
return i.cachingInodeOps.WriteOut(ctx, inode)
}
// Readlink implements fs.InodeOperations.Readlink.
func (i *inodeOperations) Readlink(ctx context.Context, inode *fs.Inode) (string, error) {
return readLink(i.fileState.FD())
}
// Getlink implements fs.InodeOperations.Getlink.
func (i *inodeOperations) Getlink(context.Context, *fs.Inode) (*fs.Dirent, error) {
if !fs.IsSymlink(i.fileState.sattr) {
return nil, syserror.ENOLINK
}
return nil, fs.ErrResolveViaReadlink
}
// StatFS implements fs.InodeOperations.StatFS.
func (i *inodeOperations) StatFS(context.Context) (fs.Info, error) {
return fs.Info{}, syserror.ENOSYS
}
// AddLink implements fs.InodeOperations.AddLink.
// FIXME: Remove this from InodeOperations altogether.
func (i *inodeOperations) AddLink() {}
// DropLink implements fs.InodeOperations.DropLink.
// FIXME: Remove this from InodeOperations altogether.
func (i *inodeOperations) DropLink() {}
// NotifyStatusChange implements fs.InodeOperations.NotifyStatusChange.
// FIXME: Remove this from InodeOperations altogether.
func (i *inodeOperations) NotifyStatusChange(ctx context.Context) {}
// readdirAll returns all of the directory entries in i.
func (i *inodeOperations) readdirAll(d *dirInfo) (map[string]fs.DentAttr, error) {
i.readdirMu.Lock()
defer i.readdirMu.Unlock()
fd := i.fileState.FD()
// syscall.ReadDirent will use getdents, which will seek the file past
// the last directory entry. To read the directory entries a second
// time, we need to seek back to the beginning.
if _, err := syscall.Seek(fd, 0, 0); err != nil {
if err == syscall.ESPIPE {
// All directories should be seekable. If this file
// isn't seekable, it is not a directory and we should
// return that more sane error.
err = syscall.ENOTDIR
}
return nil, err
}
names := make([]string, 0, 100)
for {
// Refill the buffer if necessary
if d.bufp >= d.nbuf {
d.bufp = 0
// ReadDirent will just do a sys_getdents64 to the kernel.
n, err := syscall.ReadDirent(fd, d.buf)
if err != nil {
return nil, err
}
if n == 0 {
break // EOF
}
d.nbuf = n
}
var nb int
// Parse the dirent buffer we just get and return the directory names along
// with the number of bytes consumed in the buffer.
nb, _, names = syscall.ParseDirent(d.buf[d.bufp:d.nbuf], -1, names)
d.bufp += nb
}
entries := make(map[string]fs.DentAttr)
for _, filename := range names {
// Lookup the type and host device and inode.
stat, lerr := fstatat(fd, filename, linux.AT_SYMLINK_NOFOLLOW)
if lerr == syscall.ENOENT {
// File disappeared between readdir and lstat.
// Just treat it as if it didn't exist.
continue
}
// There was a serious problem, we should probably report it.
if lerr != nil {
return nil, lerr
}
entries[filename] = fs.DentAttr{
Type: nodeType(&stat),
InodeID: hostFileDevice.Map(device.MultiDeviceKey{
Device: stat.Dev,
Inode: stat.Ino,
}),
}
}
return entries, nil
}
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