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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 kernfs provides the tools to implement inode-based filesystems.
// Kernfs has two main features:
//
// 1. The Inode interface, which maps VFS2's path-based filesystem operations to
// specific filesystem nodes. Kernfs uses the Inode interface to provide a
// blanket implementation for the vfs.FilesystemImpl. Kernfs also serves as
// the synchronization mechanism for all filesystem operations by holding a
// filesystem-wide lock across all operations.
//
// 2. Various utility types which provide generic implementations for various
// parts of the Inode and vfs.FileDescription interfaces. Client filesystems
// based on kernfs can embed the appropriate set of these to avoid having to
// reimplement common filesystem operations. See inode_impl_util.go and
// fd_impl_util.go.
//
// Reference Model:
//
// Kernfs dentries represents named pointers to inodes. Dentries and inode have
// independent lifetimes and reference counts. A child dentry unconditionally
// holds a reference on its parent directory's dentry. A dentry also holds a
// reference on the inode it points to. Multiple dentries can point to the same
// inode (for example, in the case of hardlinks). File descriptors hold a
// reference to the dentry they're opened on.
//
// Dentries are guaranteed to exist while holding Filesystem.mu for
// reading. Dropping dentries require holding Filesystem.mu for writing. To
// queue dentries for destruction from a read critical section, see
// Filesystem.deferDecRef.
//
// Lock ordering:
//
// kernfs.Filesystem.mu
// kernfs.Dentry.dirMu
// vfs.VirtualFilesystem.mountMu
// vfs.Dentry.mu
// kernfs.Filesystem.droppedDentriesMu
// (inode implementation locks, if any)
package kernfs
import (
"fmt"
"sync/atomic"
"gvisor.dev/gvisor/pkg/abi/linux"
"gvisor.dev/gvisor/pkg/context"
"gvisor.dev/gvisor/pkg/refs"
"gvisor.dev/gvisor/pkg/sentry/kernel/auth"
"gvisor.dev/gvisor/pkg/sentry/vfs"
"gvisor.dev/gvisor/pkg/sync"
)
// FilesystemType implements vfs.FilesystemType.
type FilesystemType struct{}
// Filesystem mostly implements vfs.FilesystemImpl for a generic in-memory
// filesystem. Concrete implementations are expected to embed this in their own
// Filesystem type.
type Filesystem struct {
vfsfs vfs.Filesystem
droppedDentriesMu sync.Mutex
// droppedDentries is a list of dentries waiting to be DecRef()ed. This is
// used to defer dentry destruction until mu can be acquired for
// writing. Protected by droppedDentriesMu.
droppedDentries []*vfs.Dentry
// mu synchronizes the lifetime of Dentries on this filesystem. Holding it
// for reading guarantees continued existence of any resolved dentries, but
// the dentry tree may be modified.
//
// Kernfs dentries can only be DecRef()ed while holding mu for writing. For
// example:
//
// fs.mu.Lock()
// defer fs.mu.Unlock()
// ...
// dentry1.DecRef()
// defer dentry2.DecRef() // Ok, will run before Unlock.
//
// If discarding dentries in a read context, use Filesystem.deferDecRef. For
// example:
//
// fs.mu.RLock()
// fs.mu.processDeferredDecRefs()
// defer fs.mu.RUnlock()
// ...
// fs.deferDecRef(dentry)
mu sync.RWMutex
// nextInoMinusOne is used to to allocate inode numbers on this
// filesystem. Must be accessed by atomic operations.
nextInoMinusOne uint64
}
// deferDecRef defers dropping a dentry ref until the next call to
// processDeferredDecRefs{,Locked}. See comment on Filesystem.mu.
//
// Precondition: d must not already be pending destruction.
func (fs *Filesystem) deferDecRef(d *vfs.Dentry) {
fs.droppedDentriesMu.Lock()
fs.droppedDentries = append(fs.droppedDentries, d)
fs.droppedDentriesMu.Unlock()
}
// processDeferredDecRefs calls vfs.Dentry.DecRef on all dentries in the
// droppedDentries list. See comment on Filesystem.mu.
func (fs *Filesystem) processDeferredDecRefs() {
fs.mu.Lock()
fs.processDeferredDecRefsLocked()
fs.mu.Unlock()
}
// Precondition: fs.mu must be held for writing.
func (fs *Filesystem) processDeferredDecRefsLocked() {
fs.droppedDentriesMu.Lock()
for _, d := range fs.droppedDentries {
d.DecRef()
}
fs.droppedDentries = fs.droppedDentries[:0] // Keep slice memory for reuse.
fs.droppedDentriesMu.Unlock()
}
// Init initializes a kernfs filesystem. This should be called from during
// vfs.FilesystemType.NewFilesystem for the concrete filesystem embedding
// kernfs.
func (fs *Filesystem) Init(vfsObj *vfs.VirtualFilesystem) {
fs.vfsfs.Init(vfsObj, fs)
}
// VFSFilesystem returns the generic vfs filesystem object.
func (fs *Filesystem) VFSFilesystem() *vfs.Filesystem {
return &fs.vfsfs
}
// NextIno allocates a new inode number on this filesystem.
func (fs *Filesystem) NextIno() uint64 {
return atomic.AddUint64(&fs.nextInoMinusOne, 1)
}
// These consts are used in the Dentry.flags field.
const (
// Dentry points to a directory inode.
dflagsIsDir = 1 << iota
// Dentry points to a symlink inode.
dflagsIsSymlink
)
// Dentry implements vfs.DentryImpl.
//
// A kernfs dentry is similar to a dentry in a traditional filesystem: it's a
// named reference to an inode. A dentry generally lives as long as it's part of
// a mounted filesystem tree. Kernfs doesn't cache dentries once all references
// to them are removed. Dentries hold a single reference to the inode they point
// to, and child dentries hold a reference on their parent.
//
// Must be initialized by Init prior to first use.
type Dentry struct {
refs.AtomicRefCount
vfsd vfs.Dentry
inode Inode
// flags caches useful information about the dentry from the inode. See the
// dflags* consts above. Must be accessed by atomic ops.
flags uint32
// dirMu protects vfsd.children for directory dentries.
dirMu sync.Mutex
}
// Init initializes this dentry.
//
// Precondition: Caller must hold a reference on inode.
//
// Postcondition: Caller's reference on inode is transferred to the dentry.
func (d *Dentry) Init(inode Inode) {
d.vfsd.Init(d)
d.inode = inode
ftype := inode.Mode().FileType()
if ftype == linux.ModeDirectory {
d.flags |= dflagsIsDir
}
if ftype == linux.ModeSymlink {
d.flags |= dflagsIsSymlink
}
}
// VFSDentry returns the generic vfs dentry for this kernfs dentry.
func (d *Dentry) VFSDentry() *vfs.Dentry {
return &d.vfsd
}
// isDir checks whether the dentry points to a directory inode.
func (d *Dentry) isDir() bool {
return atomic.LoadUint32(&d.flags)&dflagsIsDir != 0
}
// isSymlink checks whether the dentry points to a symlink inode.
func (d *Dentry) isSymlink() bool {
return atomic.LoadUint32(&d.flags)&dflagsIsSymlink != 0
}
// DecRef implements vfs.DentryImpl.DecRef.
func (d *Dentry) DecRef() {
d.AtomicRefCount.DecRefWithDestructor(d.destroy)
}
// Precondition: Dentry must be removed from VFS' dentry cache.
func (d *Dentry) destroy() {
d.inode.DecRef() // IncRef from Init.
d.inode = nil
if parent := d.vfsd.Parent(); parent != nil {
parent.DecRef() // IncRef from Dentry.InsertChild.
}
}
// InsertChild inserts child into the vfs dentry cache with the given name under
// this dentry. This does not update the directory inode, so calling this on
// it's own isn't sufficient to insert a child into a directory. InsertChild
// updates the link count on d if required.
//
// Precondition: d must represent a directory inode.
func (d *Dentry) InsertChild(name string, child *vfs.Dentry) {
d.dirMu.Lock()
d.insertChildLocked(name, child)
d.dirMu.Unlock()
}
// insertChildLocked is equivalent to InsertChild, with additional
// preconditions.
//
// Precondition: d.dirMu must be locked.
func (d *Dentry) insertChildLocked(name string, child *vfs.Dentry) {
if !d.isDir() {
panic(fmt.Sprintf("InsertChild called on non-directory Dentry: %+v.", d))
}
vfsDentry := d.VFSDentry()
vfsDentry.IncRef() // DecRef in child's Dentry.destroy.
vfsDentry.InsertChild(child, name)
}
// The Inode interface maps filesystem-level operations that operate on paths to
// equivalent operations on specific filesystem nodes.
//
// The interface methods are groups into logical categories as sub interfaces
// below. Generally, an implementation for each sub interface can be provided by
// embedding an appropriate type from inode_impl_utils.go. The sub interfaces
// are purely organizational. Methods declared directly in the main interface
// have no generic implementations, and should be explicitly provided by the
// client filesystem.
//
// Generally, implementations are not responsible for tasks that are common to
// all filesystems. These include:
//
// - Checking that dentries passed to methods are of the appropriate file type.
// - Checking permissions.
// - Updating link and reference counts.
//
// Specific responsibilities of implementations are documented below.
type Inode interface {
// Methods related to reference counting. A generic implementation is
// provided by InodeNoopRefCount. These methods are generally called by the
// equivalent Dentry methods.
inodeRefs
// Methods related to node metadata. A generic implementation is provided by
// InodeAttrs.
inodeMetadata
// Method for inodes that represent symlink. InodeNotSymlink provides a
// blanket implementation for all non-symlink inodes.
inodeSymlink
// Method for inodes that represent directories. InodeNotDirectory provides
// a blanket implementation for all non-directory inodes.
inodeDirectory
// Method for inodes that represent dynamic directories and their
// children. InodeNoDynamicLookup provides a blanket implementation for all
// non-dynamic-directory inodes.
inodeDynamicLookup
// Open creates a file description for the filesystem object represented by
// this inode. The returned file description should hold a reference on the
// inode for its lifetime.
//
// Precondition: rp.Done(). vfsd.Impl() must be the kernfs Dentry containing
// the inode on which Open() is being called.
Open(rp *vfs.ResolvingPath, vfsd *vfs.Dentry, opts vfs.OpenOptions) (*vfs.FileDescription, error)
}
type inodeRefs interface {
IncRef()
DecRef()
TryIncRef() bool
// Destroy is called when the inode reaches zero references. Destroy release
// all resources (references) on objects referenced by the inode, including
// any child dentries.
Destroy()
}
type inodeMetadata interface {
// CheckPermissions checks that creds may access this inode for the
// requested access type, per the the rules of
// fs/namei.c:generic_permission().
CheckPermissions(ctx context.Context, creds *auth.Credentials, ats vfs.AccessTypes) error
// Mode returns the (struct stat)::st_mode value for this inode. This is
// separated from Stat for performance.
Mode() linux.FileMode
// Stat returns the metadata for this inode. This corresponds to
// vfs.FilesystemImpl.StatAt.
Stat(fs *vfs.Filesystem, opts vfs.StatOptions) (linux.Statx, error)
// SetStat updates the metadata for this inode. This corresponds to
// vfs.FilesystemImpl.SetStatAt. Implementations are responsible for checking
// if the operation can be performed (see vfs.CheckSetStat() for common
// checks).
SetStat(fs *vfs.Filesystem, creds *auth.Credentials, opts vfs.SetStatOptions) error
}
// Precondition: All methods in this interface may only be called on directory
// inodes.
type inodeDirectory interface {
// The New{File,Dir,Node,Symlink} methods below should return a new inode
// hashed into this inode.
//
// These inode constructors are inode-level operations rather than
// filesystem-level operations to allow client filesystems to mix different
// implementations based on the new node's location in the
// filesystem.
// HasChildren returns true if the directory inode has any children.
HasChildren() bool
// NewFile creates a new regular file inode.
NewFile(ctx context.Context, name string, opts vfs.OpenOptions) (*vfs.Dentry, error)
// NewDir creates a new directory inode.
NewDir(ctx context.Context, name string, opts vfs.MkdirOptions) (*vfs.Dentry, error)
// NewLink creates a new hardlink to a specified inode in this
// directory. Implementations should create a new kernfs Dentry pointing to
// target, and update target's link count.
NewLink(ctx context.Context, name string, target Inode) (*vfs.Dentry, error)
// NewSymlink creates a new symbolic link inode.
NewSymlink(ctx context.Context, name, target string) (*vfs.Dentry, error)
// NewNode creates a new filesystem node for a mknod syscall.
NewNode(ctx context.Context, name string, opts vfs.MknodOptions) (*vfs.Dentry, error)
// Unlink removes a child dentry from this directory inode.
Unlink(ctx context.Context, name string, child *vfs.Dentry) error
// RmDir removes an empty child directory from this directory
// inode. Implementations must update the parent directory's link count,
// if required. Implementations are not responsible for checking that child
// is a directory, checking for an empty directory.
RmDir(ctx context.Context, name string, child *vfs.Dentry) error
// Rename is called on the source directory containing an inode being
// renamed. child should point to the resolved child in the source
// directory. If Rename replaces a dentry in the destination directory, it
// should return the replaced dentry or nil otherwise.
//
// Precondition: Caller must serialize concurrent calls to Rename.
Rename(ctx context.Context, oldname, newname string, child, dstDir *vfs.Dentry) (replaced *vfs.Dentry, err error)
}
type inodeDynamicLookup interface {
// Lookup should return an appropriate dentry if name should resolve to a
// child of this dynamic directory inode. This gives the directory an
// opportunity on every lookup to resolve additional entries that aren't
// hashed into the directory. This is only called when the inode is a
// directory. If the inode is not a directory, or if the directory only
// contains a static set of children, the implementer can unconditionally
// return an appropriate error (ENOTDIR and ENOENT respectively).
//
// The child returned by Lookup will be hashed into the VFS dentry tree. Its
// lifetime can be controlled by the filesystem implementation with an
// appropriate implementation of Valid.
//
// Lookup returns the child with an extra reference and the caller owns this
// reference.
Lookup(ctx context.Context, name string) (*vfs.Dentry, error)
// Valid should return true if this inode is still valid, or needs to
// be resolved again by a call to Lookup.
Valid(ctx context.Context) bool
// IterDirents is used to iterate over dynamically created entries. It invokes
// cb on each entry in the directory represented by the FileDescription.
// 'offset' is the offset for the entire IterDirents call, which may include
// results from the caller. 'relOffset' is the offset inside the entries
// returned by this IterDirents invocation. In other words,
// 'offset+relOffset+1' is the value that should be set in vfs.Dirent.NextOff,
// while 'relOffset' is the place where iteration should start from.
IterDirents(ctx context.Context, callback vfs.IterDirentsCallback, offset, relOffset int64) (newOffset int64, err error)
}
type inodeSymlink interface {
// Readlink resolves the target of a symbolic link. If an inode is not a
// symlink, the implementation should return EINVAL.
Readlink(ctx context.Context) (string, error)
}
|