// 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 ( "fmt" "sync/atomic" "gvisor.dev/gvisor/pkg/sync" "gvisor.dev/gvisor/pkg/syserror" ) // Dentry represents a node in a Filesystem tree which may represent a file. // // Dentries are reference-counted. Unless otherwise specified, all Dentry // methods require that a reference is held. // // A Dentry transitions through up to 3 different states through its lifetime: // // - Dentries are initially "independent". Independent Dentries have no parent, // and consequently no name. // // - Dentry.InsertChild() causes an independent Dentry to become a "child" of // another Dentry. A child node has a parent node, and a name in that parent, // both of which are mutable by DentryMoveChild(). Each child Dentry's name is // unique within its parent. // // - Dentry.RemoveChild() causes a child Dentry to become "disowned". A // disowned Dentry can still refer to its former parent and its former name in // said parent, but the disowned Dentry is no longer reachable from its parent, // and a new Dentry with the same name may become a child of the parent. (This // is analogous to a struct dentry being "unhashed" in Linux.) // // Dentry is loosely analogous to Linux's struct dentry, but: // // - VFS does not associate Dentries with inodes. gVisor interacts primarily // with filesystems that are accessed through filesystem APIs (as opposed to // raw block devices); many such APIs support only paths and file descriptors, // and not inodes. Furthermore, when parties outside the scope of VFS can // rename inodes on such filesystems, VFS generally cannot "follow" the rename, // both due to synchronization issues and because it may not even be able to // name the destination path; this implies that it would in fact be incorrect // for Dentries to be associated with inodes on such filesystems. Consequently, // operations that are inode operations in Linux are FilesystemImpl methods // and/or FileDescriptionImpl methods in gVisor's VFS. Filesystems that do // support inodes may store appropriate state in implementations of DentryImpl. // // - VFS does not provide synchronization for mutable Dentry fields, other than // mount-related ones. // // - VFS does not require that Dentries are instantiated for all paths accessed // through VFS, only those that are tracked beyond the scope of a single // Filesystem operation. This includes file descriptions, mount points, mount // roots, process working directories, and chroots. This avoids instantiation // of Dentries for operations on mutable remote filesystems that can't actually // cache any state in the Dentry. // // - For the reasons above, VFS is not directly responsible for managing Dentry // lifetime. Dentry reference counts only indicate the extent to which VFS // requires Dentries to exist; Filesystems may elect to cache or discard // Dentries with zero references. // // +stateify savable type Dentry struct { // parent is this Dentry's parent in this Filesystem. If this Dentry is // independent, parent is nil. parent *Dentry // name is this Dentry's name in parent. name string flags uint32 // mounts is the number of Mounts for which this Dentry is Mount.point. // mounts is accessed using atomic memory operations. mounts uint32 // children are child Dentries. children map[string]*Dentry // mu synchronizes disowning and mounting over this Dentry. mu sync.Mutex `state:"nosave"` // impl is the DentryImpl associated with this Dentry. impl is immutable. // This should be the last field in Dentry. impl DentryImpl } const ( // dflagsDisownedMask is set in Dentry.flags if the Dentry has been // disowned. dflagsDisownedMask = 1 << iota ) // Init must be called before first use of d. func (d *Dentry) Init(impl DentryImpl) { d.impl = impl } // Impl returns the DentryImpl associated with d. func (d *Dentry) Impl() DentryImpl { return d.impl } // DentryImpl contains implementation details for a Dentry. Implementations of // DentryImpl should contain their associated Dentry by value as their first // field. type DentryImpl interface { // IncRef increments the Dentry's reference count. A Dentry with a non-zero // reference count must remain coherent with the state of the filesystem. IncRef() // TryIncRef increments the Dentry's reference count and returns true. If // the Dentry's reference count is zero, TryIncRef may do nothing and // return false. (It is also permitted to succeed if it can restore the // guarantee that the Dentry is coherent with the state of the filesystem.) // // TryIncRef does not require that a reference is held on the Dentry. TryIncRef() bool // DecRef decrements the Dentry's reference count. DecRef() } // IsDisowned returns true if d is disowned. func (d *Dentry) IsDisowned() bool { return atomic.LoadUint32(&d.flags)&dflagsDisownedMask != 0 } // Preconditions: !d.IsDisowned(). func (d *Dentry) setDisowned() { atomic.AddUint32(&d.flags, dflagsDisownedMask) } func (d *Dentry) isMounted() bool { return atomic.LoadUint32(&d.mounts) != 0 } // IncRef increments d's reference count. func (d *Dentry) IncRef() { d.impl.IncRef() } // TryIncRef increments d's reference count and returns true. If d's reference // count is zero, TryIncRef may instead do nothing and return false. func (d *Dentry) TryIncRef() bool { return d.impl.TryIncRef() } // DecRef decrements d's reference count. func (d *Dentry) DecRef() { d.impl.DecRef() } // These functions are exported so that filesystem implementations can use // them. The vfs package, and users of VFS, should not call these functions. // Unless otherwise specified, these methods require that there are no // concurrent mutators of d. // Name returns d's name in its parent in its owning Filesystem. If d is // independent, Name returns an empty string. func (d *Dentry) Name() string { return d.name } // Parent returns d's parent in its owning Filesystem. It does not take a // reference on the returned Dentry. If d is independent, Parent returns nil. func (d *Dentry) Parent() *Dentry { return d.parent } // ParentOrSelf is equivalent to Parent, but returns d if d is independent. func (d *Dentry) ParentOrSelf() *Dentry { if d.parent == nil { return d } return d.parent } // Child returns d's child with the given name in its owning Filesystem. It // does not take a reference on the returned Dentry. If no such child exists, // Child returns nil. func (d *Dentry) Child(name string) *Dentry { return d.children[name] } // HasChildren returns true if d has any children. func (d *Dentry) HasChildren() bool { return len(d.children) != 0 } // Children returns a map containing all of d's children. func (d *Dentry) Children() map[string]*Dentry { if !d.HasChildren() { return nil } m := make(map[string]*Dentry) for name, child := range d.children { m[name] = child } return m } // InsertChild makes child a child of d with the given name. // // InsertChild is a mutator of d and child. // // Preconditions: child must be an independent Dentry. d and child must be from // the same Filesystem. d must not already have a child with the given name. func (d *Dentry) InsertChild(child *Dentry, name string) { if checkInvariants { if _, ok := d.children[name]; ok { panic(fmt.Sprintf("parent already contains a child named %q", name)) } if child.parent != nil || child.name != "" { panic(fmt.Sprintf("child is not independent: parent = %v, name = %q", child.parent, child.name)) } } if d.children == nil { d.children = make(map[string]*Dentry) } d.children[name] = child child.parent = d child.name = name } // IsAncestorOf returns true if d is an ancestor of d2; that is, d is either // d2's parent or an ancestor of d2's parent. func (d *Dentry) IsAncestorOf(d2 *Dentry) bool { for d2.parent != nil { if d2.parent == d { return true } d2 = d2.parent } return false } // PrepareDeleteDentry must be called before attempting to delete the file // represented by d. If PrepareDeleteDentry succeeds, the caller must call // AbortDeleteDentry or CommitDeleteDentry depending on the deletion's outcome. // // Preconditions: d is a child Dentry. func (vfs *VirtualFilesystem) PrepareDeleteDentry(mntns *MountNamespace, d *Dentry) error { if checkInvariants { if d.parent == nil { panic("d is independent") } if d.IsDisowned() { panic("d is already disowned") } } vfs.mountMu.Lock() if mntns.mountpoints[d] != 0 { vfs.mountMu.Unlock() return syserror.EBUSY } d.mu.Lock() vfs.mountMu.Unlock() // Return with d.mu locked to block attempts to mount over it; it will be // unlocked by AbortDeleteDentry or CommitDeleteDentry. return nil } // AbortDeleteDentry must be called after PrepareDeleteDentry if the deletion // fails. func (vfs *VirtualFilesystem) AbortDeleteDentry(d *Dentry) { d.mu.Unlock() } // CommitDeleteDentry must be called after the file represented by d is // deleted, and causes d to become disowned. // // CommitDeleteDentry is a mutator of d and d.Parent(). // // Preconditions: PrepareDeleteDentry was previously called on d. func (vfs *VirtualFilesystem) CommitDeleteDentry(d *Dentry) { if d.parent != nil { delete(d.parent.children, d.name) } d.setDisowned() d.mu.Unlock() if d.isMounted() { vfs.forgetDisownedMountpoint(d) } } // ForceDeleteDentry causes d to become disowned. It should only be used in // cases where VFS has no ability to stop the deletion (e.g. d represents the // local state of a file on a remote filesystem on which the file has already // been deleted). // // ForceDeleteDentry is a mutator of d and d.Parent(). // // Preconditions: d is a child Dentry. func (vfs *VirtualFilesystem) ForceDeleteDentry(d *Dentry) { if checkInvariants { if d.parent == nil { panic("d is independent") } if d.IsDisowned() { panic("d is already disowned") } } d.mu.Lock() vfs.CommitDeleteDentry(d) } // PrepareRenameDentry must be called before attempting to rename the file // represented by from. If to is not nil, it represents the file that will be // replaced or exchanged by the rename. If PrepareRenameDentry succeeds, the // caller must call AbortRenameDentry, CommitRenameReplaceDentry, or // CommitRenameExchangeDentry depending on the rename's outcome. // // Preconditions: from is a child Dentry. If to is not nil, it must be a child // Dentry from the same Filesystem. from != to. func (vfs *VirtualFilesystem) PrepareRenameDentry(mntns *MountNamespace, from, to *Dentry) error { if checkInvariants { if from.parent == nil { panic("from is independent") } if from.IsDisowned() { panic("from is already disowned") } if to != nil { if to.parent == nil { panic("to is independent") } if to.IsDisowned() { panic("to is already disowned") } } } vfs.mountMu.Lock() if mntns.mountpoints[from] != 0 { vfs.mountMu.Unlock() return syserror.EBUSY } if to != nil { if mntns.mountpoints[to] != 0 { vfs.mountMu.Unlock() return syserror.EBUSY } to.mu.Lock() } from.mu.Lock() vfs.mountMu.Unlock() // Return with from.mu and to.mu locked, which will be unlocked by // AbortRenameDentry, CommitRenameReplaceDentry, or // CommitRenameExchangeDentry. return nil } // AbortRenameDentry must be called after PrepareRenameDentry if the rename // fails. func (vfs *VirtualFilesystem) AbortRenameDentry(from, to *Dentry) { from.mu.Unlock() if to != nil { to.mu.Unlock() } } // CommitRenameReplaceDentry must be called after the file represented by from // is renamed without RENAME_EXCHANGE. If to is not nil, it represents the file // that was replaced by from. // // CommitRenameReplaceDentry is a mutator of from, to, from.Parent(), and // to.Parent(). // // Preconditions: PrepareRenameDentry was previously called on from and to. // newParent.Child(newName) == to. func (vfs *VirtualFilesystem) CommitRenameReplaceDentry(from, newParent *Dentry, newName string, to *Dentry) { if newParent.children == nil { newParent.children = make(map[string]*Dentry) } newParent.children[newName] = from from.parent = newParent from.name = newName from.mu.Unlock() if to != nil { to.setDisowned() to.mu.Unlock() if to.isMounted() { vfs.forgetDisownedMountpoint(to) } } } // CommitRenameExchangeDentry must be called after the files represented by // from and to are exchanged by rename(RENAME_EXCHANGE). // // CommitRenameExchangeDentry is a mutator of from, to, from.Parent(), and // to.Parent(). // // Preconditions: PrepareRenameDentry was previously called on from and to. func (vfs *VirtualFilesystem) CommitRenameExchangeDentry(from, to *Dentry) { from.parent, to.parent = to.parent, from.parent from.name, to.name = to.name, from.name from.parent.children[from.name] = from to.parent.children[to.name] = to from.mu.Unlock() to.mu.Unlock() } // forgetDisownedMountpoint is called when a mount point is deleted to umount // all mounts using it in all other mount namespaces. // // forgetDisownedMountpoint is analogous to Linux's // fs/namespace.c:__detach_mounts(). func (vfs *VirtualFilesystem) forgetDisownedMountpoint(d *Dentry) { var ( vdsToDecRef []VirtualDentry mountsToDecRef []*Mount ) vfs.mountMu.Lock() vfs.mounts.seq.BeginWrite() for mnt := range vfs.mountpoints[d] { vdsToDecRef, mountsToDecRef = vfs.umountRecursiveLocked(mnt, &umountRecursiveOptions{}, vdsToDecRef, mountsToDecRef) } vfs.mounts.seq.EndWrite() vfs.mountMu.Unlock() for _, vd := range vdsToDecRef { vd.DecRef() } for _, mnt := range mountsToDecRef { mnt.DecRef() } }