// Copyright 2018 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 fs import ( "gvisor.dev/gvisor/pkg/abi/linux" "gvisor.dev/gvisor/pkg/context" "gvisor.dev/gvisor/pkg/log" "gvisor.dev/gvisor/pkg/metric" "gvisor.dev/gvisor/pkg/refs" "gvisor.dev/gvisor/pkg/sentry/fs/lock" "gvisor.dev/gvisor/pkg/sentry/kernel/auth" "gvisor.dev/gvisor/pkg/sentry/memmap" "gvisor.dev/gvisor/pkg/sentry/socket/unix/transport" "gvisor.dev/gvisor/pkg/sync" "gvisor.dev/gvisor/pkg/syserror" ) var opens = metric.MustCreateNewUint64Metric("/fs/opens", false /* sync */, "Number of file opens.") // Inode is a file system object that can be simultaneously referenced by different // components of the VFS (Dirent, fs.File, etc). // // +stateify savable type Inode struct { // AtomicRefCount is our reference count. refs.AtomicRefCount // InodeOperations is the file system specific behavior of the Inode. InodeOperations InodeOperations // StableAttr are stable cached attributes of the Inode. StableAttr StableAttr // LockCtx is the file lock context. It manages its own sychronization and tracks // regions of the Inode that have locks held. LockCtx LockCtx // Watches is the set of inotify watches for this inode. Watches *Watches // MountSource is the mount source this Inode is a part of. MountSource *MountSource // overlay is the overlay entry for this Inode. overlay *overlayEntry // appendMu is used to synchronize write operations into files which // have been opened with O_APPEND. Operations which change a file size // have to take this lock for read. Write operations to files with // O_APPEND have to take this lock for write. appendMu sync.RWMutex `state:"nosave"` } // LockCtx is an Inode's lock context and contains different personalities of locks; both // Posix and BSD style locks are supported. // // Note that in Linux fcntl(2) and flock(2) locks are _not_ cooperative, because race and // deadlock conditions make merging them prohibitive. We do the same and keep them oblivious // to each other but provide a "context" as a convenient container. // // +stateify savable type LockCtx struct { // Posix is a set of POSIX-style regional advisory locks, see fcntl(2). Posix lock.Locks // BSD is a set of BSD-style advisory file wide locks, see flock(2). BSD lock.Locks } // NewInode constructs an Inode from InodeOperations, a MountSource, and stable attributes. // // NewInode takes a reference on msrc. func NewInode(ctx context.Context, iops InodeOperations, msrc *MountSource, sattr StableAttr) *Inode { msrc.IncRef() i := Inode{ InodeOperations: iops, StableAttr: sattr, Watches: newWatches(), MountSource: msrc, } i.EnableLeakCheck("fs.Inode") return &i } // DecRef drops a reference on the Inode. func (i *Inode) DecRef(ctx context.Context) { i.DecRefWithDestructor(ctx, i.destroy) } // destroy releases the Inode and releases the msrc reference taken. func (i *Inode) destroy(ctx context.Context) { if err := i.WriteOut(ctx); err != nil { // FIXME(b/65209558): Mark as warning again once noatime is // properly supported. log.Debugf("Inode %+v, failed to sync all metadata: %v", i.StableAttr, err) } // If this inode is being destroyed because it was unlinked, queue a // deletion event. This may not be the case for inodes being revalidated. if i.Watches.unlinked { i.Watches.Notify("", linux.IN_DELETE_SELF, 0) } // Remove references from the watch owners to the watches on this inode, // since the watches are about to be GCed. Note that we don't need to worry // about the watch pins since if there were any active pins, this inode // wouldn't be in the destructor. i.Watches.targetDestroyed() if i.overlay != nil { i.overlay.release(ctx) } else { i.InodeOperations.Release(ctx) } i.MountSource.DecRef(ctx) } // Mappable calls i.InodeOperations.Mappable. func (i *Inode) Mappable() memmap.Mappable { if i.overlay != nil { // In an overlay, Mappable is always implemented by // the overlayEntry metadata to synchronize memory // access of files with copy up. But first check if // the Inodes involved would be mappable in the first // place. i.overlay.copyMu.RLock() ok := i.overlay.isMappableLocked() i.overlay.copyMu.RUnlock() if !ok { return nil } return i.overlay } return i.InodeOperations.Mappable(i) } // WriteOut calls i.InodeOperations.WriteOut with i as the Inode. func (i *Inode) WriteOut(ctx context.Context) error { if i.overlay != nil { return overlayWriteOut(ctx, i.overlay) } return i.InodeOperations.WriteOut(ctx, i) } // Lookup calls i.InodeOperations.Lookup with i as the directory. func (i *Inode) Lookup(ctx context.Context, name string) (*Dirent, error) { if i.overlay != nil { d, _, err := overlayLookup(ctx, i.overlay, i, name) return d, err } return i.InodeOperations.Lookup(ctx, i, name) } // Create calls i.InodeOperations.Create with i as the directory. func (i *Inode) Create(ctx context.Context, d *Dirent, name string, flags FileFlags, perm FilePermissions) (*File, error) { if i.overlay != nil { return overlayCreate(ctx, i.overlay, d, name, flags, perm) } return i.InodeOperations.Create(ctx, i, name, flags, perm) } // CreateDirectory calls i.InodeOperations.CreateDirectory with i as the directory. func (i *Inode) CreateDirectory(ctx context.Context, d *Dirent, name string, perm FilePermissions) error { if i.overlay != nil { return overlayCreateDirectory(ctx, i.overlay, d, name, perm) } return i.InodeOperations.CreateDirectory(ctx, i, name, perm) } // CreateLink calls i.InodeOperations.CreateLink with i as the directory. func (i *Inode) CreateLink(ctx context.Context, d *Dirent, oldname string, newname string) error { if i.overlay != nil { return overlayCreateLink(ctx, i.overlay, d, oldname, newname) } return i.InodeOperations.CreateLink(ctx, i, oldname, newname) } // CreateHardLink calls i.InodeOperations.CreateHardLink with i as the directory. func (i *Inode) CreateHardLink(ctx context.Context, d *Dirent, target *Dirent, name string) error { if i.overlay != nil { return overlayCreateHardLink(ctx, i.overlay, d, target, name) } return i.InodeOperations.CreateHardLink(ctx, i, target.Inode, name) } // CreateFifo calls i.InodeOperations.CreateFifo with i as the directory. func (i *Inode) CreateFifo(ctx context.Context, d *Dirent, name string, perm FilePermissions) error { if i.overlay != nil { return overlayCreateFifo(ctx, i.overlay, d, name, perm) } return i.InodeOperations.CreateFifo(ctx, i, name, perm) } // Remove calls i.InodeOperations.Remove/RemoveDirectory with i as the directory. func (i *Inode) Remove(ctx context.Context, d *Dirent, remove *Dirent) error { if i.overlay != nil { return overlayRemove(ctx, i.overlay, d, remove) } switch remove.Inode.StableAttr.Type { case Directory, SpecialDirectory: return i.InodeOperations.RemoveDirectory(ctx, i, remove.name) default: return i.InodeOperations.Remove(ctx, i, remove.name) } } // Rename calls i.InodeOperations.Rename with the given arguments. func (i *Inode) Rename(ctx context.Context, oldParent *Dirent, renamed *Dirent, newParent *Dirent, newName string, replacement bool) error { if i.overlay != nil { return overlayRename(ctx, i.overlay, oldParent, renamed, newParent, newName, replacement) } return i.InodeOperations.Rename(ctx, renamed.Inode, oldParent.Inode, renamed.name, newParent.Inode, newName, replacement) } // Bind calls i.InodeOperations.Bind with i as the directory. func (i *Inode) Bind(ctx context.Context, parent *Dirent, name string, data transport.BoundEndpoint, perm FilePermissions) (*Dirent, error) { if i.overlay != nil { return overlayBind(ctx, i.overlay, parent, name, data, perm) } return i.InodeOperations.Bind(ctx, i, name, data, perm) } // BoundEndpoint calls i.InodeOperations.BoundEndpoint with i as the Inode. func (i *Inode) BoundEndpoint(path string) transport.BoundEndpoint { if i.overlay != nil { return overlayBoundEndpoint(i.overlay, path) } return i.InodeOperations.BoundEndpoint(i, path) } // GetFile calls i.InodeOperations.GetFile with the given arguments. func (i *Inode) GetFile(ctx context.Context, d *Dirent, flags FileFlags) (*File, error) { if i.overlay != nil { return overlayGetFile(ctx, i.overlay, d, flags) } opens.Increment() return i.InodeOperations.GetFile(ctx, d, flags) } // UnstableAttr calls i.InodeOperations.UnstableAttr with i as the Inode. func (i *Inode) UnstableAttr(ctx context.Context) (UnstableAttr, error) { if i.overlay != nil { return overlayUnstableAttr(ctx, i.overlay) } return i.InodeOperations.UnstableAttr(ctx, i) } // GetXattr calls i.InodeOperations.GetXattr with i as the Inode. func (i *Inode) GetXattr(ctx context.Context, name string, size uint64) (string, error) { if i.overlay != nil { return overlayGetXattr(ctx, i.overlay, name, size) } return i.InodeOperations.GetXattr(ctx, i, name, size) } // SetXattr calls i.InodeOperations.SetXattr with i as the Inode. func (i *Inode) SetXattr(ctx context.Context, d *Dirent, name, value string, flags uint32) error { if i.overlay != nil { return overlaySetXattr(ctx, i.overlay, d, name, value, flags) } return i.InodeOperations.SetXattr(ctx, i, name, value, flags) } // ListXattr calls i.InodeOperations.ListXattr with i as the Inode. func (i *Inode) ListXattr(ctx context.Context, size uint64) (map[string]struct{}, error) { if i.overlay != nil { return overlayListXattr(ctx, i.overlay, size) } return i.InodeOperations.ListXattr(ctx, i, size) } // RemoveXattr calls i.InodeOperations.RemoveXattr with i as the Inode. func (i *Inode) RemoveXattr(ctx context.Context, d *Dirent, name string) error { if i.overlay != nil { return overlayRemoveXattr(ctx, i.overlay, d, name) } return i.InodeOperations.RemoveXattr(ctx, i, name) } // CheckPermission will check if the caller may access this file in the // requested way for reading, writing, or executing. // // CheckPermission is like Linux's fs/namei.c:inode_permission. It // - checks file system mount flags, // - and utilizes InodeOperations.Check to check capabilities and modes. func (i *Inode) CheckPermission(ctx context.Context, p PermMask) error { // First check the outer-most mounted filesystem. if p.Write && i.MountSource.Flags.ReadOnly { return syserror.EROFS } if i.overlay != nil { // CheckPermission requires some special handling for // an overlay. // // Writes will always be redirected to an upper filesystem, // so ignore all lower layers being read-only. // // But still honor the upper-most filesystem's mount flags; // we should not attempt to modify the writable layer if it // is mounted read-only. if p.Write && overlayUpperMountSource(i.MountSource).Flags.ReadOnly { return syserror.EROFS } } return i.check(ctx, p) } func (i *Inode) check(ctx context.Context, p PermMask) error { if i.overlay != nil { return overlayCheck(ctx, i.overlay, p) } if !i.InodeOperations.Check(ctx, i, p) { return syserror.EACCES } return nil } // SetPermissions calls i.InodeOperations.SetPermissions with i as the Inode. func (i *Inode) SetPermissions(ctx context.Context, d *Dirent, f FilePermissions) bool { if i.overlay != nil { return overlaySetPermissions(ctx, i.overlay, d, f) } return i.InodeOperations.SetPermissions(ctx, i, f) } // SetOwner calls i.InodeOperations.SetOwner with i as the Inode. func (i *Inode) SetOwner(ctx context.Context, d *Dirent, o FileOwner) error { if i.overlay != nil { return overlaySetOwner(ctx, i.overlay, d, o) } return i.InodeOperations.SetOwner(ctx, i, o) } // SetTimestamps calls i.InodeOperations.SetTimestamps with i as the Inode. func (i *Inode) SetTimestamps(ctx context.Context, d *Dirent, ts TimeSpec) error { if i.overlay != nil { return overlaySetTimestamps(ctx, i.overlay, d, ts) } return i.InodeOperations.SetTimestamps(ctx, i, ts) } // Truncate calls i.InodeOperations.Truncate with i as the Inode. func (i *Inode) Truncate(ctx context.Context, d *Dirent, size int64) error { if IsDir(i.StableAttr) { return syserror.EISDIR } if i.overlay != nil { return overlayTruncate(ctx, i.overlay, d, size) } i.appendMu.RLock() defer i.appendMu.RUnlock() return i.InodeOperations.Truncate(ctx, i, size) } func (i *Inode) Allocate(ctx context.Context, d *Dirent, offset int64, length int64) error { if i.overlay != nil { return overlayAllocate(ctx, i.overlay, d, offset, length) } return i.InodeOperations.Allocate(ctx, i, offset, length) } // Readlink calls i.InodeOperations.Readlnk with i as the Inode. func (i *Inode) Readlink(ctx context.Context) (string, error) { if i.overlay != nil { return overlayReadlink(ctx, i.overlay) } return i.InodeOperations.Readlink(ctx, i) } // Getlink calls i.InodeOperations.Getlink. func (i *Inode) Getlink(ctx context.Context) (*Dirent, error) { if i.overlay != nil { return overlayGetlink(ctx, i.overlay) } return i.InodeOperations.Getlink(ctx, i) } // AddLink calls i.InodeOperations.AddLink. func (i *Inode) AddLink() { if i.overlay != nil { // This interface is only used by ramfs to update metadata of // children. These filesystems should _never_ have overlay // Inodes cached as children. So explicitly disallow this // scenario and avoid plumbing Dirents through to do copy up. panic("overlay Inodes cached in ramfs directories are not supported") } i.InodeOperations.AddLink() } // DropLink calls i.InodeOperations.DropLink. func (i *Inode) DropLink() { if i.overlay != nil { // Same as AddLink. panic("overlay Inodes cached in ramfs directories are not supported") } i.InodeOperations.DropLink() } // IsVirtual calls i.InodeOperations.IsVirtual. func (i *Inode) IsVirtual() bool { if i.overlay != nil { // An overlay configuration does not support virtual files. return false } return i.InodeOperations.IsVirtual() } // StatFS calls i.InodeOperations.StatFS. func (i *Inode) StatFS(ctx context.Context) (Info, error) { if i.overlay != nil { return overlayStatFS(ctx, i.overlay) } return i.InodeOperations.StatFS(ctx) } // CheckOwnership checks whether `ctx` owns this Inode or may act as its owner. // Compare Linux's fs/inode.c:inode_owner_or_capable(). func (i *Inode) CheckOwnership(ctx context.Context) bool { uattr, err := i.UnstableAttr(ctx) if err != nil { return false } creds := auth.CredentialsFromContext(ctx) if uattr.Owner.UID == creds.EffectiveKUID { return true } if creds.HasCapability(linux.CAP_FOWNER) && creds.UserNamespace.MapFromKUID(uattr.Owner.UID).Ok() { return true } return false } // CheckCapability checks whether `ctx` has capability `cp` with respect to // operations on this Inode. // // Compare Linux's kernel/capability.c:capable_wrt_inode_uidgid(). func (i *Inode) CheckCapability(ctx context.Context, cp linux.Capability) bool { uattr, err := i.UnstableAttr(ctx) if err != nil { return false } creds := auth.CredentialsFromContext(ctx) if !creds.UserNamespace.MapFromKUID(uattr.Owner.UID).Ok() { return false } if !creds.UserNamespace.MapFromKGID(uattr.Owner.GID).Ok() { return false } return creds.HasCapability(cp) } func (i *Inode) lockAppendMu(appendMode bool) func() { if appendMode { i.appendMu.Lock() return i.appendMu.Unlock } i.appendMu.RLock() return i.appendMu.RUnlock }