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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 gofer provides a filesystem implementation that is backed by a 9p
// server, interchangably referred to as "gofers" throughout this package.
//
// Lock order:
// regularFileFD/directoryFD.mu
// filesystem.renameMu
// dentry.dirMu
// filesystem.syncMu
// dentry.metadataMu
// *** "memmap.Mappable locks" below this point
// dentry.mapsMu
// *** "memmap.Mappable locks taken by Translate" below this point
// dentry.handleMu
// dentry.dataMu
//
// Locking dentry.dirMu in multiple dentries requires that either ancestor
// dentries are locked before descendant dentries, or that filesystem.renameMu
// is locked for writing.
package gofer
import (
"fmt"
"strconv"
"strings"
"sync"
"sync/atomic"
"syscall"
"gvisor.dev/gvisor/pkg/abi/linux"
"gvisor.dev/gvisor/pkg/context"
"gvisor.dev/gvisor/pkg/log"
"gvisor.dev/gvisor/pkg/p9"
"gvisor.dev/gvisor/pkg/sentry/fs/fsutil"
fslock "gvisor.dev/gvisor/pkg/sentry/fs/lock"
"gvisor.dev/gvisor/pkg/sentry/kernel/auth"
"gvisor.dev/gvisor/pkg/sentry/kernel/pipe"
ktime "gvisor.dev/gvisor/pkg/sentry/kernel/time"
"gvisor.dev/gvisor/pkg/sentry/memmap"
"gvisor.dev/gvisor/pkg/sentry/pgalloc"
"gvisor.dev/gvisor/pkg/sentry/socket/unix/transport"
"gvisor.dev/gvisor/pkg/sentry/vfs"
"gvisor.dev/gvisor/pkg/sentry/vfs/lock"
"gvisor.dev/gvisor/pkg/syserror"
"gvisor.dev/gvisor/pkg/unet"
"gvisor.dev/gvisor/pkg/usermem"
)
// Name is the default filesystem name.
const Name = "9p"
// FilesystemType implements vfs.FilesystemType.
type FilesystemType struct{}
// filesystem implements vfs.FilesystemImpl.
type filesystem struct {
vfsfs vfs.Filesystem
// mfp is used to allocate memory that caches regular file contents. mfp is
// immutable.
mfp pgalloc.MemoryFileProvider
// Immutable options.
opts filesystemOptions
iopts InternalFilesystemOptions
// client is the client used by this filesystem. client is immutable.
client *p9.Client
// clock is a realtime clock used to set timestamps in file operations.
clock ktime.Clock
// devMinor is the filesystem's minor device number. devMinor is immutable.
devMinor uint32
// renameMu serves two purposes:
//
// - It synchronizes path resolution with renaming initiated by this
// client.
//
// - It is held by path resolution to ensure that reachable dentries remain
// valid. A dentry is reachable by path resolution if it has a non-zero
// reference count (such that it is usable as vfs.ResolvingPath.Start() or
// is reachable from its children), or if it is a child dentry (such that
// it is reachable from its parent).
renameMu sync.RWMutex
// cachedDentries contains all dentries with 0 references. (Due to race
// conditions, it may also contain dentries with non-zero references.)
// cachedDentriesLen is the number of dentries in cachedDentries. These
// fields are protected by renameMu.
cachedDentries dentryList
cachedDentriesLen uint64
// syncableDentries contains all dentries in this filesystem for which
// !dentry.file.isNil(). specialFileFDs contains all open specialFileFDs.
// These fields are protected by syncMu.
syncMu sync.Mutex
syncableDentries map[*dentry]struct{}
specialFileFDs map[*specialFileFD]struct{}
}
type filesystemOptions struct {
// "Standard" 9P options.
fd int
aname string
interop InteropMode // derived from the "cache" mount option
dfltuid auth.KUID
dfltgid auth.KGID
msize uint32
version string
// maxCachedDentries is the maximum number of dentries with 0 references
// retained by the client.
maxCachedDentries uint64
// If forcePageCache is true, host FDs may not be used for application
// memory mappings even if available; instead, the client must perform its
// own caching of regular file pages. This is primarily useful for testing.
forcePageCache bool
// If limitHostFDTranslation is true, apply maxFillRange() constraints to
// host FD mappings returned by dentry.(memmap.Mappable).Translate(). This
// makes memory accounting behavior more consistent between cases where
// host FDs are / are not available, but may increase the frequency of
// sentry-handled page faults on files for which a host FD is available.
limitHostFDTranslation bool
// If overlayfsStaleRead is true, O_RDONLY host FDs provided by the remote
// filesystem may not be coherent with writable host FDs opened later, so
// all uses of the former must be replaced by uses of the latter. This is
// usually only the case when the remote filesystem is a Linux overlayfs
// mount. (Prior to Linux 4.18, patch series centered on commit
// d1d04ef8572b "ovl: stack file ops", both I/O and memory mappings were
// incoherent between pre-copy-up and post-copy-up FDs; after that patch
// series, only memory mappings are incoherent.)
overlayfsStaleRead bool
// If regularFilesUseSpecialFileFD is true, application FDs representing
// regular files will use distinct file handles for each FD, in the same
// way that application FDs representing "special files" such as sockets
// do. Note that this disables client caching and mmap for regular files.
regularFilesUseSpecialFileFD bool
}
// InteropMode controls the client's interaction with other remote filesystem
// users.
type InteropMode uint32
const (
// InteropModeExclusive is appropriate when the filesystem client is the
// only user of the remote filesystem.
//
// - The client may cache arbitrary filesystem state (file data, metadata,
// filesystem structure, etc.).
//
// - Client changes to filesystem state may be sent to the remote
// filesystem asynchronously, except when server permission checks are
// necessary.
//
// - File timestamps are based on client clocks. This ensures that users of
// the client observe timestamps that are coherent with their own clocks
// and consistent with Linux's semantics. However, since it is not always
// possible for clients to set arbitrary atimes and mtimes, and never
// possible for clients to set arbitrary ctimes, file timestamp changes are
// stored in the client only and never sent to the remote filesystem.
InteropModeExclusive InteropMode = iota
// InteropModeWritethrough is appropriate when there are read-only users of
// the remote filesystem that expect to observe changes made by the
// filesystem client.
//
// - The client may cache arbitrary filesystem state.
//
// - Client changes to filesystem state must be sent to the remote
// filesystem synchronously.
//
// - File timestamps are based on client clocks. As a corollary, access
// timestamp changes from other remote filesystem users will not be visible
// to the client.
InteropModeWritethrough
// InteropModeShared is appropriate when there are users of the remote
// filesystem that may mutate its state other than the client.
//
// - The client must verify ("revalidate") cached filesystem state before
// using it.
//
// - Client changes to filesystem state must be sent to the remote
// filesystem synchronously.
//
// - File timestamps are based on server clocks. This is necessary to
// ensure that timestamp changes are synchronized between remote filesystem
// users.
//
// Note that the correctness of InteropModeShared depends on the server
// correctly implementing 9P fids (i.e. each fid immutably represents a
// single filesystem object), even in the presence of remote filesystem
// mutations from other users. If this is violated, the behavior of the
// client is undefined.
InteropModeShared
)
// InternalFilesystemOptions may be passed as
// vfs.GetFilesystemOptions.InternalData to FilesystemType.GetFilesystem.
type InternalFilesystemOptions struct {
// If LeakConnection is true, do not close the connection to the server
// when the Filesystem is released. This is necessary for deployments in
// which servers can handle only a single client and report failure if that
// client disconnects.
LeakConnection bool
// If OpenSocketsByConnecting is true, silently translate attempts to open
// files identifying as sockets to connect RPCs.
OpenSocketsByConnecting bool
}
// _V9FS_DEFUID and _V9FS_DEFGID (from Linux's fs/9p/v9fs.h) are the default
// UIDs and GIDs used for files that do not provide a specific owner or group
// respectively.
const (
// uint32(-2) doesn't work in Go.
_V9FS_DEFUID = auth.KUID(4294967294)
_V9FS_DEFGID = auth.KGID(4294967294)
)
// Name implements vfs.FilesystemType.Name.
func (FilesystemType) Name() string {
return Name
}
// GetFilesystem implements vfs.FilesystemType.GetFilesystem.
func (fstype FilesystemType) GetFilesystem(ctx context.Context, vfsObj *vfs.VirtualFilesystem, creds *auth.Credentials, source string, opts vfs.GetFilesystemOptions) (*vfs.Filesystem, *vfs.Dentry, error) {
mfp := pgalloc.MemoryFileProviderFromContext(ctx)
if mfp == nil {
ctx.Warningf("gofer.FilesystemType.GetFilesystem: context does not provide a pgalloc.MemoryFileProvider")
return nil, nil, syserror.EINVAL
}
mopts := vfs.GenericParseMountOptions(opts.Data)
var fsopts filesystemOptions
// Check that the transport is "fd".
trans, ok := mopts["trans"]
if !ok {
ctx.Warningf("gofer.FilesystemType.GetFilesystem: transport must be specified as 'trans=fd'")
return nil, nil, syserror.EINVAL
}
delete(mopts, "trans")
if trans != "fd" {
ctx.Warningf("gofer.FilesystemType.GetFilesystem: unsupported transport: trans=%s", trans)
return nil, nil, syserror.EINVAL
}
// Check that read and write FDs are provided and identical.
rfdstr, ok := mopts["rfdno"]
if !ok {
ctx.Warningf("gofer.FilesystemType.GetFilesystem: read FD must be specified as 'rfdno=<file descriptor>")
return nil, nil, syserror.EINVAL
}
delete(mopts, "rfdno")
rfd, err := strconv.Atoi(rfdstr)
if err != nil {
ctx.Warningf("gofer.FilesystemType.GetFilesystem: invalid read FD: rfdno=%s", rfdstr)
return nil, nil, syserror.EINVAL
}
wfdstr, ok := mopts["wfdno"]
if !ok {
ctx.Warningf("gofer.FilesystemType.GetFilesystem: write FD must be specified as 'wfdno=<file descriptor>")
return nil, nil, syserror.EINVAL
}
delete(mopts, "wfdno")
wfd, err := strconv.Atoi(wfdstr)
if err != nil {
ctx.Warningf("gofer.FilesystemType.GetFilesystem: invalid write FD: wfdno=%s", wfdstr)
return nil, nil, syserror.EINVAL
}
if rfd != wfd {
ctx.Warningf("gofer.FilesystemType.GetFilesystem: read FD (%d) and write FD (%d) must be equal", rfd, wfd)
return nil, nil, syserror.EINVAL
}
fsopts.fd = rfd
// Get the attach name.
fsopts.aname = "/"
if aname, ok := mopts["aname"]; ok {
delete(mopts, "aname")
fsopts.aname = aname
}
// Parse the cache policy. For historical reasons, this defaults to the
// least generally-applicable option, InteropModeExclusive.
fsopts.interop = InteropModeExclusive
if cache, ok := mopts["cache"]; ok {
delete(mopts, "cache")
switch cache {
case "fscache":
fsopts.interop = InteropModeExclusive
case "fscache_writethrough":
fsopts.interop = InteropModeWritethrough
case "none":
fsopts.regularFilesUseSpecialFileFD = true
fallthrough
case "remote_revalidating":
fsopts.interop = InteropModeShared
default:
ctx.Warningf("gofer.FilesystemType.GetFilesystem: invalid cache policy: cache=%s", cache)
return nil, nil, syserror.EINVAL
}
}
// Parse the default UID and GID.
fsopts.dfltuid = _V9FS_DEFUID
if dfltuidstr, ok := mopts["dfltuid"]; ok {
delete(mopts, "dfltuid")
dfltuid, err := strconv.ParseUint(dfltuidstr, 10, 32)
if err != nil {
ctx.Warningf("gofer.FilesystemType.GetFilesystem: invalid default UID: dfltuid=%s", dfltuidstr)
return nil, nil, syserror.EINVAL
}
// In Linux, dfltuid is interpreted as a UID and is converted to a KUID
// in the caller's user namespace, but goferfs isn't
// application-mountable.
fsopts.dfltuid = auth.KUID(dfltuid)
}
fsopts.dfltgid = _V9FS_DEFGID
if dfltgidstr, ok := mopts["dfltgid"]; ok {
delete(mopts, "dfltgid")
dfltgid, err := strconv.ParseUint(dfltgidstr, 10, 32)
if err != nil {
ctx.Warningf("gofer.FilesystemType.GetFilesystem: invalid default UID: dfltgid=%s", dfltgidstr)
return nil, nil, syserror.EINVAL
}
fsopts.dfltgid = auth.KGID(dfltgid)
}
// Parse the 9P message size.
fsopts.msize = 1024 * 1024 // 1M, tested to give good enough performance up to 64M
if msizestr, ok := mopts["msize"]; ok {
delete(mopts, "msize")
msize, err := strconv.ParseUint(msizestr, 10, 32)
if err != nil {
ctx.Warningf("gofer.FilesystemType.GetFilesystem: invalid message size: msize=%s", msizestr)
return nil, nil, syserror.EINVAL
}
fsopts.msize = uint32(msize)
}
// Parse the 9P protocol version.
fsopts.version = p9.HighestVersionString()
if version, ok := mopts["version"]; ok {
delete(mopts, "version")
fsopts.version = version
}
// Parse the dentry cache limit.
fsopts.maxCachedDentries = 1000
if str, ok := mopts["dentry_cache_limit"]; ok {
delete(mopts, "dentry_cache_limit")
maxCachedDentries, err := strconv.ParseUint(str, 10, 64)
if err != nil {
ctx.Warningf("gofer.FilesystemType.GetFilesystem: invalid dentry cache limit: dentry_cache_limit=%s", str)
return nil, nil, syserror.EINVAL
}
fsopts.maxCachedDentries = maxCachedDentries
}
// Handle simple flags.
if _, ok := mopts["force_page_cache"]; ok {
delete(mopts, "force_page_cache")
fsopts.forcePageCache = true
}
if _, ok := mopts["limit_host_fd_translation"]; ok {
delete(mopts, "limit_host_fd_translation")
fsopts.limitHostFDTranslation = true
}
if _, ok := mopts["overlayfs_stale_read"]; ok {
delete(mopts, "overlayfs_stale_read")
fsopts.overlayfsStaleRead = true
}
// fsopts.regularFilesUseSpecialFileFD can only be enabled by specifying
// "cache=none".
// Check for unparsed options.
if len(mopts) != 0 {
ctx.Warningf("gofer.FilesystemType.GetFilesystem: unknown options: %v", mopts)
return nil, nil, syserror.EINVAL
}
// Handle internal options.
iopts, ok := opts.InternalData.(InternalFilesystemOptions)
if opts.InternalData != nil && !ok {
ctx.Warningf("gofer.FilesystemType.GetFilesystem: GetFilesystemOptions.InternalData has type %T, wanted gofer.InternalFilesystemOptions", opts.InternalData)
return nil, nil, syserror.EINVAL
}
// If !ok, iopts being the zero value is correct.
// Establish a connection with the server.
conn, err := unet.NewSocket(fsopts.fd)
if err != nil {
return nil, nil, err
}
// Perform version negotiation with the server.
ctx.UninterruptibleSleepStart(false)
client, err := p9.NewClient(conn, fsopts.msize, fsopts.version)
ctx.UninterruptibleSleepFinish(false)
if err != nil {
conn.Close()
return nil, nil, err
}
// Ownership of conn has been transferred to client.
// Perform attach to obtain the filesystem root.
ctx.UninterruptibleSleepStart(false)
attached, err := client.Attach(fsopts.aname)
ctx.UninterruptibleSleepFinish(false)
if err != nil {
client.Close()
return nil, nil, err
}
attachFile := p9file{attached}
qid, attrMask, attr, err := attachFile.getAttr(ctx, dentryAttrMask())
if err != nil {
attachFile.close(ctx)
client.Close()
return nil, nil, err
}
// Construct the filesystem object.
devMinor, err := vfsObj.GetAnonBlockDevMinor()
if err != nil {
attachFile.close(ctx)
client.Close()
return nil, nil, err
}
fs := &filesystem{
mfp: mfp,
opts: fsopts,
iopts: iopts,
client: client,
clock: ktime.RealtimeClockFromContext(ctx),
devMinor: devMinor,
syncableDentries: make(map[*dentry]struct{}),
specialFileFDs: make(map[*specialFileFD]struct{}),
}
fs.vfsfs.Init(vfsObj, &fstype, fs)
// Construct the root dentry.
root, err := fs.newDentry(ctx, attachFile, qid, attrMask, &attr)
if err != nil {
attachFile.close(ctx)
fs.vfsfs.DecRef()
return nil, nil, err
}
// Set the root's reference count to 2. One reference is returned to the
// caller, and the other is deliberately leaked to prevent the root from
// being "cached" and subsequently evicted. Its resources will still be
// cleaned up by fs.Release().
root.refs = 2
return &fs.vfsfs, &root.vfsd, nil
}
// Release implements vfs.FilesystemImpl.Release.
func (fs *filesystem) Release() {
ctx := context.Background()
mf := fs.mfp.MemoryFile()
fs.syncMu.Lock()
for d := range fs.syncableDentries {
d.handleMu.Lock()
d.dataMu.Lock()
if d.handleWritable {
// Write dirty cached data to the remote file.
if err := fsutil.SyncDirtyAll(ctx, &d.cache, &d.dirty, d.size, fs.mfp.MemoryFile(), d.handle.writeFromBlocksAt); err != nil {
log.Warningf("gofer.filesystem.Release: failed to flush dentry: %v", err)
}
// TODO(jamieliu): Do we need to flushf/fsync d?
}
// Discard cached pages.
d.cache.DropAll(mf)
d.dirty.RemoveAll()
d.dataMu.Unlock()
// Close the host fd if one exists.
if d.handle.fd >= 0 {
syscall.Close(int(d.handle.fd))
d.handle.fd = -1
}
d.handleMu.Unlock()
}
// There can't be any specialFileFDs still using fs, since each such
// FileDescription would hold a reference on a Mount holding a reference on
// fs.
fs.syncMu.Unlock()
if !fs.iopts.LeakConnection {
// Close the connection to the server. This implicitly clunks all fids.
fs.client.Close()
}
fs.vfsfs.VirtualFilesystem().PutAnonBlockDevMinor(fs.devMinor)
}
// dentry implements vfs.DentryImpl.
type dentry struct {
vfsd vfs.Dentry
// refs is the reference count. Each dentry holds a reference on its
// parent, even if disowned. An additional reference is held on all
// synthetic dentries until they are unlinked or invalidated. When refs
// reaches 0, the dentry may be added to the cache or destroyed. If refs ==
// -1, the dentry has already been destroyed. refs is accessed using atomic
// memory operations.
refs int64
// fs is the owning filesystem. fs is immutable.
fs *filesystem
// parent is this dentry's parent directory. Each dentry holds a reference
// on its parent. If this dentry is a filesystem root, parent is nil.
// parent is protected by filesystem.renameMu.
parent *dentry
// name is the name of this dentry in its parent. If this dentry is a
// filesystem root, name is the empty string. name is protected by
// filesystem.renameMu.
name string
// We don't support hard links, so each dentry maps 1:1 to an inode.
// file is the unopened p9.File that backs this dentry. file is immutable.
//
// If file.isNil(), this dentry represents a synthetic file, i.e. a file
// that does not exist on the remote filesystem. As of this writing, the
// only files that can be synthetic are sockets, pipes, and directories.
file p9file
// If deleted is non-zero, the file represented by this dentry has been
// deleted. deleted is accessed using atomic memory operations.
deleted uint32
// If cached is true, dentryEntry links dentry into
// filesystem.cachedDentries. cached and dentryEntry are protected by
// filesystem.renameMu.
cached bool
dentryEntry
dirMu sync.Mutex
// If this dentry represents a directory, children contains:
//
// - Mappings of child filenames to dentries representing those children.
//
// - Mappings of child filenames that are known not to exist to nil
// dentries (only if InteropModeShared is not in effect and the directory
// is not synthetic).
//
// children is protected by dirMu.
children map[string]*dentry
// If this dentry represents a directory, syntheticChildren is the number
// of child dentries for which dentry.isSynthetic() == true.
// syntheticChildren is protected by dirMu.
syntheticChildren int
// If this dentry represents a directory,
// dentry.cachedMetadataAuthoritative() == true, and dirents is not nil, it
// is a cache of all entries in the directory, in the order they were
// returned by the server. dirents is protected by dirMu.
dirents []vfs.Dirent
// Cached metadata; protected by metadataMu and accessed using atomic
// memory operations unless otherwise specified.
metadataMu sync.Mutex
ino uint64 // immutable
mode uint32 // type is immutable, perms are mutable
uid uint32 // auth.KUID, but stored as raw uint32 for sync/atomic
gid uint32 // auth.KGID, but ...
blockSize uint32 // 0 if unknown
// Timestamps, all nsecs from the Unix epoch.
atime int64
mtime int64
ctime int64
btime int64
// File size, protected by both metadataMu and dataMu (i.e. both must be
// locked to mutate it).
size uint64
// nlink counts the number of hard links to this dentry. It's updated and
// accessed using atomic operations. It's not protected by metadataMu like the
// other metadata fields.
nlink uint32
mapsMu sync.Mutex
// If this dentry represents a regular file, mappings tracks mappings of
// the file into memmap.MappingSpaces. mappings is protected by mapsMu.
mappings memmap.MappingSet
// If this dentry represents a regular file or directory:
//
// - handle is the I/O handle used by all regularFileFDs/directoryFDs
// representing this dentry.
//
// - handleReadable is true if handle is readable.
//
// - handleWritable is true if handle is writable.
//
// Invariants:
//
// - If handleReadable == handleWritable == false, then handle.file == nil
// (i.e. there is no open handle). Conversely, if handleReadable ||
// handleWritable == true, then handle.file != nil (i.e. there is an open
// handle).
//
// - handleReadable and handleWritable cannot transition from true to false
// (i.e. handles may not be downgraded).
//
// These fields are protected by handleMu.
handleMu sync.RWMutex
handle handle
handleReadable bool
handleWritable bool
dataMu sync.RWMutex
// If this dentry represents a regular file that is client-cached, cache
// maps offsets into the cached file to offsets into
// filesystem.mfp.MemoryFile() that store the file's data. cache is
// protected by dataMu.
cache fsutil.FileRangeSet
// If this dentry represents a regular file that is client-cached, dirty
// tracks dirty segments in cache. dirty is protected by dataMu.
dirty fsutil.DirtySet
// pf implements platform.File for mappings of handle.fd.
pf dentryPlatformFile
// If this dentry represents a symbolic link, InteropModeShared is not in
// effect, and haveTarget is true, target is the symlink target. haveTarget
// and target are protected by dataMu.
haveTarget bool
target string
// If this dentry represents a synthetic socket file, endpoint is the
// transport endpoint bound to this file.
endpoint transport.BoundEndpoint
// If this dentry represents a synthetic named pipe, pipe is the pipe
// endpoint bound to this file.
pipe *pipe.VFSPipe
locks lock.FileLocks
}
// dentryAttrMask returns a p9.AttrMask enabling all attributes used by the
// gofer client.
func dentryAttrMask() p9.AttrMask {
return p9.AttrMask{
Mode: true,
UID: true,
GID: true,
ATime: true,
MTime: true,
CTime: true,
Size: true,
BTime: true,
}
}
// newDentry creates a new dentry representing the given file. The dentry
// initially has no references, but is not cached; it is the caller's
// responsibility to set the dentry's reference count and/or call
// dentry.checkCachingLocked() as appropriate.
//
// Preconditions: !file.isNil().
func (fs *filesystem) newDentry(ctx context.Context, file p9file, qid p9.QID, mask p9.AttrMask, attr *p9.Attr) (*dentry, error) {
if !mask.Mode {
ctx.Warningf("can't create gofer.dentry without file type")
return nil, syserror.EIO
}
if attr.Mode.FileType() == p9.ModeRegular && !mask.Size {
ctx.Warningf("can't create regular file gofer.dentry without file size")
return nil, syserror.EIO
}
d := &dentry{
fs: fs,
file: file,
ino: qid.Path,
mode: uint32(attr.Mode),
uid: uint32(fs.opts.dfltuid),
gid: uint32(fs.opts.dfltgid),
blockSize: usermem.PageSize,
handle: handle{
fd: -1,
},
}
d.pf.dentry = d
if mask.UID {
d.uid = dentryUIDFromP9UID(attr.UID)
}
if mask.GID {
d.gid = dentryGIDFromP9GID(attr.GID)
}
if mask.Size {
d.size = attr.Size
}
if attr.BlockSize != 0 {
d.blockSize = uint32(attr.BlockSize)
}
if mask.ATime {
d.atime = dentryTimestampFromP9(attr.ATimeSeconds, attr.ATimeNanoSeconds)
}
if mask.MTime {
d.mtime = dentryTimestampFromP9(attr.MTimeSeconds, attr.MTimeNanoSeconds)
}
if mask.CTime {
d.ctime = dentryTimestampFromP9(attr.CTimeSeconds, attr.CTimeNanoSeconds)
}
if mask.BTime {
d.btime = dentryTimestampFromP9(attr.BTimeSeconds, attr.BTimeNanoSeconds)
}
if mask.NLink {
d.nlink = uint32(attr.NLink)
}
d.vfsd.Init(d)
fs.syncMu.Lock()
fs.syncableDentries[d] = struct{}{}
fs.syncMu.Unlock()
return d, nil
}
func (d *dentry) isSynthetic() bool {
return d.file.isNil()
}
func (d *dentry) cachedMetadataAuthoritative() bool {
return d.fs.opts.interop != InteropModeShared || d.isSynthetic()
}
// updateFromP9Attrs is called to update d's metadata after an update from the
// remote filesystem.
func (d *dentry) updateFromP9Attrs(mask p9.AttrMask, attr *p9.Attr) {
d.metadataMu.Lock()
if mask.Mode {
if got, want := uint32(attr.Mode.FileType()), d.fileType(); got != want {
d.metadataMu.Unlock()
panic(fmt.Sprintf("gofer.dentry file type changed from %#o to %#o", want, got))
}
atomic.StoreUint32(&d.mode, uint32(attr.Mode))
}
if mask.UID {
atomic.StoreUint32(&d.uid, dentryUIDFromP9UID(attr.UID))
}
if mask.GID {
atomic.StoreUint32(&d.gid, dentryGIDFromP9GID(attr.GID))
}
// There is no P9_GETATTR_* bit for I/O block size.
if attr.BlockSize != 0 {
atomic.StoreUint32(&d.blockSize, uint32(attr.BlockSize))
}
if mask.ATime {
atomic.StoreInt64(&d.atime, dentryTimestampFromP9(attr.ATimeSeconds, attr.ATimeNanoSeconds))
}
if mask.MTime {
atomic.StoreInt64(&d.mtime, dentryTimestampFromP9(attr.MTimeSeconds, attr.MTimeNanoSeconds))
}
if mask.CTime {
atomic.StoreInt64(&d.ctime, dentryTimestampFromP9(attr.CTimeSeconds, attr.CTimeNanoSeconds))
}
if mask.BTime {
atomic.StoreInt64(&d.btime, dentryTimestampFromP9(attr.BTimeSeconds, attr.BTimeNanoSeconds))
}
if mask.NLink {
atomic.StoreUint32(&d.nlink, uint32(attr.NLink))
}
if mask.Size {
d.dataMu.Lock()
atomic.StoreUint64(&d.size, attr.Size)
d.dataMu.Unlock()
}
d.metadataMu.Unlock()
}
// Preconditions: !d.isSynthetic()
func (d *dentry) updateFromGetattr(ctx context.Context) error {
// Use d.handle.file, which represents a 9P fid that has been opened, in
// preference to d.file, which represents a 9P fid that has not. This may
// be significantly more efficient in some implementations.
var (
file p9file
handleMuRLocked bool
)
d.handleMu.RLock()
if !d.handle.file.isNil() {
file = d.handle.file
handleMuRLocked = true
} else {
file = d.file
d.handleMu.RUnlock()
}
_, attrMask, attr, err := file.getAttr(ctx, dentryAttrMask())
if handleMuRLocked {
d.handleMu.RUnlock()
}
if err != nil {
return err
}
d.updateFromP9Attrs(attrMask, &attr)
return nil
}
func (d *dentry) fileType() uint32 {
return atomic.LoadUint32(&d.mode) & linux.S_IFMT
}
func (d *dentry) statTo(stat *linux.Statx) {
stat.Mask = linux.STATX_TYPE | linux.STATX_MODE | linux.STATX_NLINK | linux.STATX_UID | linux.STATX_GID | linux.STATX_ATIME | linux.STATX_MTIME | linux.STATX_CTIME | linux.STATX_INO | linux.STATX_SIZE | linux.STATX_BLOCKS | linux.STATX_BTIME
stat.Blksize = atomic.LoadUint32(&d.blockSize)
stat.Nlink = atomic.LoadUint32(&d.nlink)
if stat.Nlink == 0 {
// The remote filesystem doesn't support link count; just make
// something up. This is consistent with Linux, where
// fs/inode.c:inode_init_always() initializes link count to 1, and
// fs/9p/vfs_inode_dotl.c:v9fs_stat2inode_dotl() doesn't touch it if
// it's not provided by the remote filesystem.
stat.Nlink = 1
}
stat.UID = atomic.LoadUint32(&d.uid)
stat.GID = atomic.LoadUint32(&d.gid)
stat.Mode = uint16(atomic.LoadUint32(&d.mode))
stat.Ino = d.ino
stat.Size = atomic.LoadUint64(&d.size)
// This is consistent with regularFileFD.Seek(), which treats regular files
// as having no holes.
stat.Blocks = (stat.Size + 511) / 512
stat.Atime = statxTimestampFromDentry(atomic.LoadInt64(&d.atime))
stat.Btime = statxTimestampFromDentry(atomic.LoadInt64(&d.btime))
stat.Ctime = statxTimestampFromDentry(atomic.LoadInt64(&d.ctime))
stat.Mtime = statxTimestampFromDentry(atomic.LoadInt64(&d.mtime))
stat.DevMajor = linux.UNNAMED_MAJOR
stat.DevMinor = d.fs.devMinor
}
func (d *dentry) setStat(ctx context.Context, creds *auth.Credentials, stat *linux.Statx, mnt *vfs.Mount) error {
if stat.Mask == 0 {
return nil
}
if stat.Mask&^(linux.STATX_MODE|linux.STATX_UID|linux.STATX_GID|linux.STATX_ATIME|linux.STATX_MTIME|linux.STATX_SIZE) != 0 {
return syserror.EPERM
}
mode := linux.FileMode(atomic.LoadUint32(&d.mode))
if err := vfs.CheckSetStat(ctx, creds, stat, mode, auth.KUID(atomic.LoadUint32(&d.uid)), auth.KGID(atomic.LoadUint32(&d.gid))); err != nil {
return err
}
if err := mnt.CheckBeginWrite(); err != nil {
return err
}
defer mnt.EndWrite()
setLocalAtime := false
setLocalMtime := false
if d.cachedMetadataAuthoritative() {
// Timestamp updates will be handled locally.
setLocalAtime = stat.Mask&linux.STATX_ATIME != 0
setLocalMtime = stat.Mask&linux.STATX_MTIME != 0
stat.Mask &^= linux.STATX_ATIME | linux.STATX_MTIME
// Prepare for truncate.
if stat.Mask&linux.STATX_SIZE != 0 {
switch d.mode & linux.S_IFMT {
case linux.S_IFREG:
if !setLocalMtime {
// Truncate updates mtime.
setLocalMtime = true
stat.Mtime.Nsec = linux.UTIME_NOW
}
case linux.S_IFDIR:
return syserror.EISDIR
default:
return syserror.EINVAL
}
}
}
d.metadataMu.Lock()
defer d.metadataMu.Unlock()
if !d.isSynthetic() {
if stat.Mask != 0 {
if err := d.file.setAttr(ctx, p9.SetAttrMask{
Permissions: stat.Mask&linux.STATX_MODE != 0,
UID: stat.Mask&linux.STATX_UID != 0,
GID: stat.Mask&linux.STATX_GID != 0,
Size: stat.Mask&linux.STATX_SIZE != 0,
ATime: stat.Mask&linux.STATX_ATIME != 0,
MTime: stat.Mask&linux.STATX_MTIME != 0,
ATimeNotSystemTime: stat.Mask&linux.STATX_ATIME != 0 && stat.Atime.Nsec != linux.UTIME_NOW,
MTimeNotSystemTime: stat.Mask&linux.STATX_MTIME != 0 && stat.Mtime.Nsec != linux.UTIME_NOW,
}, p9.SetAttr{
Permissions: p9.FileMode(stat.Mode),
UID: p9.UID(stat.UID),
GID: p9.GID(stat.GID),
Size: stat.Size,
ATimeSeconds: uint64(stat.Atime.Sec),
ATimeNanoSeconds: uint64(stat.Atime.Nsec),
MTimeSeconds: uint64(stat.Mtime.Sec),
MTimeNanoSeconds: uint64(stat.Mtime.Nsec),
}); err != nil {
return err
}
}
if d.fs.opts.interop == InteropModeShared {
// There's no point to updating d's metadata in this case since
// it'll be overwritten by revalidation before the next time it's
// used anyway. (InteropModeShared inhibits client caching of
// regular file data, so there's no cache to truncate either.)
return nil
}
}
now := d.fs.clock.Now().Nanoseconds()
if stat.Mask&linux.STATX_MODE != 0 {
atomic.StoreUint32(&d.mode, d.fileType()|uint32(stat.Mode))
}
if stat.Mask&linux.STATX_UID != 0 {
atomic.StoreUint32(&d.uid, stat.UID)
}
if stat.Mask&linux.STATX_GID != 0 {
atomic.StoreUint32(&d.gid, stat.GID)
}
if setLocalAtime {
if stat.Atime.Nsec == linux.UTIME_NOW {
atomic.StoreInt64(&d.atime, now)
} else {
atomic.StoreInt64(&d.atime, dentryTimestampFromStatx(stat.Atime))
}
}
if setLocalMtime {
if stat.Mtime.Nsec == linux.UTIME_NOW {
atomic.StoreInt64(&d.mtime, now)
} else {
atomic.StoreInt64(&d.mtime, dentryTimestampFromStatx(stat.Mtime))
}
}
atomic.StoreInt64(&d.ctime, now)
if stat.Mask&linux.STATX_SIZE != 0 {
d.dataMu.Lock()
oldSize := d.size
d.size = stat.Size
// d.dataMu must be unlocked to lock d.mapsMu and invalidate mappings
// below. This allows concurrent calls to Read/Translate/etc. These
// functions synchronize with truncation by refusing to use cache
// contents beyond the new d.size. (We are still holding d.metadataMu,
// so we can't race with Write or another truncate.)
d.dataMu.Unlock()
if d.size < oldSize {
oldpgend, _ := usermem.PageRoundUp(oldSize)
newpgend, _ := usermem.PageRoundUp(d.size)
if oldpgend != newpgend {
d.mapsMu.Lock()
d.mappings.Invalidate(memmap.MappableRange{newpgend, oldpgend}, memmap.InvalidateOpts{
// Compare Linux's mm/truncate.c:truncate_setsize() =>
// truncate_pagecache() =>
// mm/memory.c:unmap_mapping_range(evencows=1).
InvalidatePrivate: true,
})
d.mapsMu.Unlock()
}
// We are now guaranteed that there are no translations of
// truncated pages, and can remove them from the cache. Since
// truncated pages have been removed from the remote file, they
// should be dropped without being written back.
d.dataMu.Lock()
d.cache.Truncate(d.size, d.fs.mfp.MemoryFile())
d.dirty.KeepClean(memmap.MappableRange{d.size, oldpgend})
d.dataMu.Unlock()
}
}
return nil
}
func (d *dentry) checkPermissions(creds *auth.Credentials, ats vfs.AccessTypes) error {
return vfs.GenericCheckPermissions(creds, ats, linux.FileMode(atomic.LoadUint32(&d.mode)), auth.KUID(atomic.LoadUint32(&d.uid)), auth.KGID(atomic.LoadUint32(&d.gid)))
}
func dentryUIDFromP9UID(uid p9.UID) uint32 {
if !uid.Ok() {
return uint32(auth.OverflowUID)
}
return uint32(uid)
}
func dentryGIDFromP9GID(gid p9.GID) uint32 {
if !gid.Ok() {
return uint32(auth.OverflowGID)
}
return uint32(gid)
}
// IncRef implements vfs.DentryImpl.IncRef.
func (d *dentry) IncRef() {
// d.refs may be 0 if d.fs.renameMu is locked, which serializes against
// d.checkCachingLocked().
atomic.AddInt64(&d.refs, 1)
}
// TryIncRef implements vfs.DentryImpl.TryIncRef.
func (d *dentry) TryIncRef() bool {
for {
refs := atomic.LoadInt64(&d.refs)
if refs <= 0 {
return false
}
if atomic.CompareAndSwapInt64(&d.refs, refs, refs+1) {
return true
}
}
}
// DecRef implements vfs.DentryImpl.DecRef.
func (d *dentry) DecRef() {
if refs := atomic.AddInt64(&d.refs, -1); refs == 0 {
d.fs.renameMu.Lock()
d.checkCachingLocked()
d.fs.renameMu.Unlock()
} else if refs < 0 {
panic("gofer.dentry.DecRef() called without holding a reference")
}
}
// decRefLocked decrements d's reference count without calling
// d.checkCachingLocked, even if d's reference count reaches 0; callers are
// responsible for ensuring that d.checkCachingLocked will be called later.
func (d *dentry) decRefLocked() {
if refs := atomic.AddInt64(&d.refs, -1); refs < 0 {
panic("gofer.dentry.decRefLocked() called without holding a reference")
}
}
// InotifyWithParent implements vfs.DentryImpl.InotifyWithParent.
//
// TODO(gvisor.dev/issue/1479): Implement inotify.
func (d *dentry) InotifyWithParent(events uint32, cookie uint32, et vfs.EventType) {}
// Watches implements vfs.DentryImpl.Watches.
//
// TODO(gvisor.dev/issue/1479): Implement inotify.
func (d *dentry) Watches() *vfs.Watches {
return nil
}
// checkCachingLocked should be called after d's reference count becomes 0 or it
// becomes disowned.
//
// It may be called on a destroyed dentry. For example,
// renameMu[R]UnlockAndCheckCaching may call checkCachingLocked multiple times
// for the same dentry when the dentry is visited more than once in the same
// operation. One of the calls may destroy the dentry, so subsequent calls will
// do nothing.
//
// Preconditions: d.fs.renameMu must be locked for writing.
func (d *dentry) checkCachingLocked() {
// Dentries with a non-zero reference count must be retained. (The only way
// to obtain a reference on a dentry with zero references is via path
// resolution, which requires renameMu, so if d.refs is zero then it will
// remain zero while we hold renameMu for writing.)
refs := atomic.LoadInt64(&d.refs)
if refs > 0 {
if d.cached {
d.fs.cachedDentries.Remove(d)
d.fs.cachedDentriesLen--
d.cached = false
}
return
}
if refs == -1 {
// Dentry has already been destroyed.
return
}
// Deleted and invalidated dentries with zero references are no longer
// reachable by path resolution and should be dropped immediately.
if d.vfsd.IsDead() {
if d.cached {
d.fs.cachedDentries.Remove(d)
d.fs.cachedDentriesLen--
d.cached = false
}
d.destroyLocked()
return
}
// If d is already cached, just move it to the front of the LRU.
if d.cached {
d.fs.cachedDentries.Remove(d)
d.fs.cachedDentries.PushFront(d)
return
}
// Cache the dentry, then evict the least recently used cached dentry if
// the cache becomes over-full.
d.fs.cachedDentries.PushFront(d)
d.fs.cachedDentriesLen++
d.cached = true
if d.fs.cachedDentriesLen > d.fs.opts.maxCachedDentries {
victim := d.fs.cachedDentries.Back()
d.fs.cachedDentries.Remove(victim)
d.fs.cachedDentriesLen--
victim.cached = false
// victim.refs may have become non-zero from an earlier path resolution
// since it was inserted into fs.cachedDentries.
if atomic.LoadInt64(&victim.refs) == 0 {
if victim.parent != nil {
victim.parent.dirMu.Lock()
if !victim.vfsd.IsDead() {
// Note that victim can't be a mount point (in any mount
// namespace), since VFS holds references on mount points.
d.fs.vfsfs.VirtualFilesystem().InvalidateDentry(&victim.vfsd)
delete(victim.parent.children, victim.name)
// We're only deleting the dentry, not the file it
// represents, so we don't need to update
// victimParent.dirents etc.
}
victim.parent.dirMu.Unlock()
}
victim.destroyLocked()
}
// Whether or not victim was destroyed, we brought fs.cachedDentriesLen
// back down to fs.opts.maxCachedDentries, so we don't loop.
}
}
// destroyLocked destroys the dentry. It may flushes dirty pages from cache,
// close p9 file and remove reference on parent dentry.
//
// Preconditions: d.fs.renameMu must be locked for writing. d.refs == 0. d is
// not a child dentry.
func (d *dentry) destroyLocked() {
switch atomic.LoadInt64(&d.refs) {
case 0:
// Mark the dentry destroyed.
atomic.StoreInt64(&d.refs, -1)
case -1:
panic("dentry.destroyLocked() called on already destroyed dentry")
default:
panic("dentry.destroyLocked() called with references on the dentry")
}
ctx := context.Background()
d.handleMu.Lock()
if !d.handle.file.isNil() {
mf := d.fs.mfp.MemoryFile()
d.dataMu.Lock()
// Write dirty pages back to the remote filesystem.
if d.handleWritable {
if err := fsutil.SyncDirtyAll(ctx, &d.cache, &d.dirty, d.size, mf, d.handle.writeFromBlocksAt); err != nil {
log.Warningf("gofer.dentry.DecRef: failed to write dirty data back: %v", err)
}
}
// Discard cached data.
d.cache.DropAll(mf)
d.dirty.RemoveAll()
d.dataMu.Unlock()
// Clunk open fids and close open host FDs.
d.handle.close(ctx)
}
d.handleMu.Unlock()
if !d.file.isNil() {
d.file.close(ctx)
d.file = p9file{}
// Remove d from the set of syncable dentries.
d.fs.syncMu.Lock()
delete(d.fs.syncableDentries, d)
d.fs.syncMu.Unlock()
}
// Drop the reference held by d on its parent without recursively locking
// d.fs.renameMu.
if d.parent != nil {
if refs := atomic.AddInt64(&d.parent.refs, -1); refs == 0 {
d.parent.checkCachingLocked()
} else if refs < 0 {
panic("gofer.dentry.DecRef() called without holding a reference")
}
}
}
func (d *dentry) isDeleted() bool {
return atomic.LoadUint32(&d.deleted) != 0
}
func (d *dentry) setDeleted() {
atomic.StoreUint32(&d.deleted, 1)
}
// We only support xattrs prefixed with "user." (see b/148380782). Currently,
// there is no need to expose any other xattrs through a gofer.
func (d *dentry) listxattr(ctx context.Context, creds *auth.Credentials, size uint64) ([]string, error) {
if d.file.isNil() {
return nil, nil
}
xattrMap, err := d.file.listXattr(ctx, size)
if err != nil {
return nil, err
}
xattrs := make([]string, 0, len(xattrMap))
for x := range xattrMap {
if strings.HasPrefix(x, linux.XATTR_USER_PREFIX) {
xattrs = append(xattrs, x)
}
}
return xattrs, nil
}
func (d *dentry) getxattr(ctx context.Context, creds *auth.Credentials, opts *vfs.GetxattrOptions) (string, error) {
if d.file.isNil() {
return "", syserror.ENODATA
}
if err := d.checkPermissions(creds, vfs.MayRead); err != nil {
return "", err
}
if !strings.HasPrefix(opts.Name, linux.XATTR_USER_PREFIX) {
return "", syserror.EOPNOTSUPP
}
return d.file.getXattr(ctx, opts.Name, opts.Size)
}
func (d *dentry) setxattr(ctx context.Context, creds *auth.Credentials, opts *vfs.SetxattrOptions) error {
if d.file.isNil() {
return syserror.EPERM
}
if err := d.checkPermissions(creds, vfs.MayWrite); err != nil {
return err
}
if !strings.HasPrefix(opts.Name, linux.XATTR_USER_PREFIX) {
return syserror.EOPNOTSUPP
}
return d.file.setXattr(ctx, opts.Name, opts.Value, opts.Flags)
}
func (d *dentry) removexattr(ctx context.Context, creds *auth.Credentials, name string) error {
if d.file.isNil() {
return syserror.EPERM
}
if err := d.checkPermissions(creds, vfs.MayWrite); err != nil {
return err
}
if !strings.HasPrefix(name, linux.XATTR_USER_PREFIX) {
return syserror.EOPNOTSUPP
}
return d.file.removeXattr(ctx, name)
}
// Preconditions: !d.isSynthetic(). d.isRegularFile() || d.isDirectory().
func (d *dentry) ensureSharedHandle(ctx context.Context, read, write, trunc bool) error {
// O_TRUNC unconditionally requires us to obtain a new handle (opened with
// O_TRUNC).
if !trunc {
d.handleMu.RLock()
if (!read || d.handleReadable) && (!write || d.handleWritable) {
// The current handle is sufficient.
d.handleMu.RUnlock()
return nil
}
d.handleMu.RUnlock()
}
haveOldFD := false
d.handleMu.Lock()
if (read && !d.handleReadable) || (write && !d.handleWritable) || trunc {
// Get a new handle.
wantReadable := d.handleReadable || read
wantWritable := d.handleWritable || write
h, err := openHandle(ctx, d.file, wantReadable, wantWritable, trunc)
if err != nil {
d.handleMu.Unlock()
return err
}
if !d.handle.file.isNil() {
// Check that old and new handles are compatible: If the old handle
// includes a host file descriptor but the new one does not, or
// vice versa, old and new memory mappings may be incoherent.
haveOldFD = d.handle.fd >= 0
haveNewFD := h.fd >= 0
if haveOldFD != haveNewFD {
d.handleMu.Unlock()
ctx.Warningf("gofer.dentry.ensureSharedHandle: can't change host FD availability from %v to %v across dentry handle upgrade", haveOldFD, haveNewFD)
h.close(ctx)
return syserror.EIO
}
if haveOldFD {
// We may have raced with callers of d.pf.FD() that are now
// using the old file descriptor, preventing us from safely
// closing it. We could handle this by invalidating existing
// memmap.Translations, but this is expensive. Instead, use
// dup3 to make the old file descriptor refer to the new file
// description, then close the new file descriptor (which is no
// longer needed). Racing callers may use the old or new file
// description, but this doesn't matter since they refer to the
// same file (unless d.fs.opts.overlayfsStaleRead is true,
// which we handle separately).
if err := syscall.Dup3(int(h.fd), int(d.handle.fd), syscall.O_CLOEXEC); err != nil {
d.handleMu.Unlock()
ctx.Warningf("gofer.dentry.ensureSharedHandle: failed to dup fd %d to fd %d: %v", h.fd, d.handle.fd, err)
h.close(ctx)
return err
}
syscall.Close(int(h.fd))
h.fd = d.handle.fd
if d.fs.opts.overlayfsStaleRead {
// Replace sentry mappings of the old FD with mappings of
// the new FD, since the two are not necessarily coherent.
if err := d.pf.hostFileMapper.RegenerateMappings(int(h.fd)); err != nil {
d.handleMu.Unlock()
ctx.Warningf("gofer.dentry.ensureSharedHandle: failed to replace sentry mappings of old FD with mappings of new FD: %v", err)
h.close(ctx)
return err
}
}
// Clunk the old fid before making the new handle visible (by
// unlocking d.handleMu).
d.handle.file.close(ctx)
}
}
// Switch to the new handle.
d.handle = h
d.handleReadable = wantReadable
d.handleWritable = wantWritable
}
d.handleMu.Unlock()
if d.fs.opts.overlayfsStaleRead && haveOldFD {
// Invalidate application mappings that may be using the old FD; they
// will be replaced with mappings using the new FD after future calls
// to d.Translate(). This requires holding d.mapsMu, which precedes
// d.handleMu in the lock order.
d.mapsMu.Lock()
d.mappings.InvalidateAll(memmap.InvalidateOpts{})
d.mapsMu.Unlock()
}
return nil
}
// incLinks increments link count.
func (d *dentry) incLinks() {
if atomic.LoadUint32(&d.nlink) == 0 {
// The remote filesystem doesn't support link count.
return
}
atomic.AddUint32(&d.nlink, 1)
}
// decLinks decrements link count.
func (d *dentry) decLinks() {
if atomic.LoadUint32(&d.nlink) == 0 {
// The remote filesystem doesn't support link count.
return
}
atomic.AddUint32(&d.nlink, ^uint32(0))
}
// fileDescription is embedded by gofer implementations of
// vfs.FileDescriptionImpl.
type fileDescription struct {
vfsfd vfs.FileDescription
vfs.FileDescriptionDefaultImpl
vfs.LockFD
lockLogging sync.Once
}
func (fd *fileDescription) filesystem() *filesystem {
return fd.vfsfd.Mount().Filesystem().Impl().(*filesystem)
}
func (fd *fileDescription) dentry() *dentry {
return fd.vfsfd.Dentry().Impl().(*dentry)
}
// Stat implements vfs.FileDescriptionImpl.Stat.
func (fd *fileDescription) Stat(ctx context.Context, opts vfs.StatOptions) (linux.Statx, error) {
d := fd.dentry()
const validMask = uint32(linux.STATX_MODE | linux.STATX_UID | linux.STATX_GID | linux.STATX_ATIME | linux.STATX_MTIME | linux.STATX_CTIME | linux.STATX_SIZE | linux.STATX_BLOCKS | linux.STATX_BTIME)
if !d.cachedMetadataAuthoritative() && opts.Mask&validMask != 0 && opts.Sync != linux.AT_STATX_DONT_SYNC {
// TODO(jamieliu): Use specialFileFD.handle.file for the getattr if
// available?
if err := d.updateFromGetattr(ctx); err != nil {
return linux.Statx{}, err
}
}
var stat linux.Statx
d.statTo(&stat)
return stat, nil
}
// SetStat implements vfs.FileDescriptionImpl.SetStat.
func (fd *fileDescription) SetStat(ctx context.Context, opts vfs.SetStatOptions) error {
return fd.dentry().setStat(ctx, auth.CredentialsFromContext(ctx), &opts.Stat, fd.vfsfd.Mount())
}
// Listxattr implements vfs.FileDescriptionImpl.Listxattr.
func (fd *fileDescription) Listxattr(ctx context.Context, size uint64) ([]string, error) {
return fd.dentry().listxattr(ctx, auth.CredentialsFromContext(ctx), size)
}
// Getxattr implements vfs.FileDescriptionImpl.Getxattr.
func (fd *fileDescription) Getxattr(ctx context.Context, opts vfs.GetxattrOptions) (string, error) {
return fd.dentry().getxattr(ctx, auth.CredentialsFromContext(ctx), &opts)
}
// Setxattr implements vfs.FileDescriptionImpl.Setxattr.
func (fd *fileDescription) Setxattr(ctx context.Context, opts vfs.SetxattrOptions) error {
return fd.dentry().setxattr(ctx, auth.CredentialsFromContext(ctx), &opts)
}
// Removexattr implements vfs.FileDescriptionImpl.Removexattr.
func (fd *fileDescription) Removexattr(ctx context.Context, name string) error {
return fd.dentry().removexattr(ctx, auth.CredentialsFromContext(ctx), name)
}
// LockBSD implements vfs.FileDescriptionImpl.LockBSD.
func (fd *fileDescription) LockBSD(ctx context.Context, uid fslock.UniqueID, t fslock.LockType, block fslock.Blocker) error {
fd.lockLogging.Do(func() {
log.Infof("File lock using gofer file handled internally.")
})
return fd.LockFD.LockBSD(ctx, uid, t, block)
}
// LockPOSIX implements vfs.FileDescriptionImpl.LockPOSIX.
func (fd *fileDescription) LockPOSIX(ctx context.Context, uid fslock.UniqueID, t fslock.LockType, rng fslock.LockRange, block fslock.Blocker) error {
fd.lockLogging.Do(func() {
log.Infof("Range lock using gofer file handled internally.")
})
return fd.LockFD.LockPOSIX(ctx, uid, t, rng, block)
}
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