// 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 tmpfs provides an in-memory filesystem whose contents are // application-mutable, consistent with Linux's tmpfs. // // Lock order: // // filesystem.mu // inode.mu // regularFileFD.offMu // *** "memmap.Mappable locks" below this point // regularFile.mapsMu // *** "memmap.Mappable locks taken by Translate" below this point // regularFile.dataMu // directory.iterMu package tmpfs import ( "fmt" "math" "strconv" "strings" "sync/atomic" "gvisor.dev/gvisor/pkg/abi/linux" "gvisor.dev/gvisor/pkg/context" fslock "gvisor.dev/gvisor/pkg/sentry/fs/lock" "gvisor.dev/gvisor/pkg/sentry/kernel/auth" "gvisor.dev/gvisor/pkg/sentry/kernel/time" "gvisor.dev/gvisor/pkg/sentry/pgalloc" "gvisor.dev/gvisor/pkg/sentry/vfs" "gvisor.dev/gvisor/pkg/sentry/vfs/memxattr" "gvisor.dev/gvisor/pkg/sync" "gvisor.dev/gvisor/pkg/syserror" "gvisor.dev/gvisor/pkg/usermem" ) // Name is the default filesystem name. const Name = "tmpfs" // FilesystemType implements vfs.FilesystemType. type FilesystemType struct{} // filesystem implements vfs.FilesystemImpl. type filesystem struct { vfsfs vfs.Filesystem // memFile is used to allocate pages to for regular files. memFile *pgalloc.MemoryFile // clock is a realtime clock used to set timestamps in file operations. clock time.Clock // devMinor is the filesystem's minor device number. devMinor is immutable. devMinor uint32 // mu serializes changes to the Dentry tree. mu sync.RWMutex nextInoMinusOne uint64 // accessed using atomic memory operations } // Name implements vfs.FilesystemType.Name. func (FilesystemType) Name() string { return Name } // FilesystemOpts is used to pass configuration data to tmpfs. type FilesystemOpts struct { // RootFileType is the FileType of the filesystem root. Valid values // are: S_IFDIR, S_IFREG, and S_IFLNK. Defaults to S_IFDIR. RootFileType uint16 // RootSymlinkTarget is the target of the root symlink. Only valid if // RootFileType == S_IFLNK. RootSymlinkTarget string // FilesystemType allows setting a different FilesystemType for this // tmpfs filesystem. This allows tmpfs to "impersonate" other // filesystems, like ramdiskfs and cgroupfs. FilesystemType vfs.FilesystemType } // GetFilesystem implements vfs.FilesystemType.GetFilesystem. func (fstype FilesystemType) GetFilesystem(ctx context.Context, vfsObj *vfs.VirtualFilesystem, creds *auth.Credentials, _ string, opts vfs.GetFilesystemOptions) (*vfs.Filesystem, *vfs.Dentry, error) { memFileProvider := pgalloc.MemoryFileProviderFromContext(ctx) if memFileProvider == nil { panic("MemoryFileProviderFromContext returned nil") } rootFileType := uint16(linux.S_IFDIR) newFSType := vfs.FilesystemType(&fstype) tmpfsOpts, ok := opts.InternalData.(FilesystemOpts) if ok { if tmpfsOpts.RootFileType != 0 { rootFileType = tmpfsOpts.RootFileType } if tmpfsOpts.FilesystemType != nil { newFSType = tmpfsOpts.FilesystemType } } mopts := vfs.GenericParseMountOptions(opts.Data) rootMode := linux.FileMode(0777) if rootFileType == linux.S_IFDIR { rootMode = 01777 } modeStr, ok := mopts["mode"] if ok { delete(mopts, "mode") mode, err := strconv.ParseUint(modeStr, 8, 32) if err != nil { ctx.Warningf("tmpfs.FilesystemType.GetFilesystem: invalid mode: %q", modeStr) return nil, nil, syserror.EINVAL } rootMode = linux.FileMode(mode & 07777) } rootKUID := creds.EffectiveKUID uidStr, ok := mopts["uid"] if ok { delete(mopts, "uid") uid, err := strconv.ParseUint(uidStr, 10, 32) if err != nil { ctx.Warningf("tmpfs.FilesystemType.GetFilesystem: invalid uid: %q", uidStr) return nil, nil, syserror.EINVAL } kuid := creds.UserNamespace.MapToKUID(auth.UID(uid)) if !kuid.Ok() { ctx.Warningf("tmpfs.FilesystemType.GetFilesystem: unmapped uid: %d", uid) return nil, nil, syserror.EINVAL } rootKUID = kuid } rootKGID := creds.EffectiveKGID gidStr, ok := mopts["gid"] if ok { delete(mopts, "gid") gid, err := strconv.ParseUint(gidStr, 10, 32) if err != nil { ctx.Warningf("tmpfs.FilesystemType.GetFilesystem: invalid gid: %q", gidStr) return nil, nil, syserror.EINVAL } kgid := creds.UserNamespace.MapToKGID(auth.GID(gid)) if !kgid.Ok() { ctx.Warningf("tmpfs.FilesystemType.GetFilesystem: unmapped gid: %d", gid) return nil, nil, syserror.EINVAL } rootKGID = kgid } if len(mopts) != 0 { ctx.Warningf("tmpfs.FilesystemType.GetFilesystem: unknown options: %v", mopts) return nil, nil, syserror.EINVAL } devMinor, err := vfsObj.GetAnonBlockDevMinor() if err != nil { return nil, nil, err } clock := time.RealtimeClockFromContext(ctx) fs := filesystem{ memFile: memFileProvider.MemoryFile(), clock: clock, devMinor: devMinor, } fs.vfsfs.Init(vfsObj, newFSType, &fs) var root *dentry switch rootFileType { case linux.S_IFREG: root = fs.newDentry(fs.newRegularFile(rootKUID, rootKGID, rootMode)) case linux.S_IFLNK: root = fs.newDentry(fs.newSymlink(rootKUID, rootKGID, rootMode, tmpfsOpts.RootSymlinkTarget)) case linux.S_IFDIR: root = &fs.newDirectory(rootKUID, rootKGID, rootMode).dentry default: fs.vfsfs.DecRef() return nil, nil, fmt.Errorf("invalid tmpfs root file type: %#o", rootFileType) } return &fs.vfsfs, &root.vfsd, nil } // NewFilesystem returns a new tmpfs filesystem. func NewFilesystem(ctx context.Context, vfsObj *vfs.VirtualFilesystem, creds *auth.Credentials) (*vfs.Filesystem, *vfs.Dentry, error) { return FilesystemType{}.GetFilesystem(ctx, vfsObj, creds, "", vfs.GetFilesystemOptions{}) } // Release implements vfs.FilesystemImpl.Release. func (fs *filesystem) Release() { fs.vfsfs.VirtualFilesystem().PutAnonBlockDevMinor(fs.devMinor) } // dentry implements vfs.DentryImpl. type dentry struct { vfsd vfs.Dentry // parent is this dentry's parent directory. Each referenced dentry holds a // reference on parent.dentry. If this dentry is a filesystem root, parent // is nil. parent is protected by filesystem.mu. 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.mu. name string // dentryEntry (ugh) links dentries into their parent directory.childList. dentryEntry // inode is the inode represented by this dentry. Multiple Dentries may // share a single non-directory inode (with hard links). inode is // immutable. // // tmpfs doesn't count references on dentries; because the dentry tree is // the sole source of truth, it is by definition always consistent with the // state of the filesystem. However, it does count references on inodes, // because inode resources are released when all references are dropped. // dentry therefore forwards reference counting directly to inode. inode *inode } func (fs *filesystem) newDentry(inode *inode) *dentry { d := &dentry{ inode: inode, } d.vfsd.Init(d) return d } // IncRef implements vfs.DentryImpl.IncRef. func (d *dentry) IncRef() { d.inode.incRef() } // TryIncRef implements vfs.DentryImpl.TryIncRef. func (d *dentry) TryIncRef() bool { return d.inode.tryIncRef() } // DecRef implements vfs.DentryImpl.DecRef. func (d *dentry) DecRef() { d.inode.decRef() } // InotifyWithParent implements vfs.DentryImpl.InotifyWithParent. func (d *dentry) InotifyWithParent(events, cookie uint32, et vfs.EventType) { if d.inode.isDir() { events |= linux.IN_ISDIR } // tmpfs never calls VFS.InvalidateDentry(), so d.vfsd.IsDead() indicates // that d was deleted. deleted := d.vfsd.IsDead() d.inode.fs.mu.RLock() // The ordering below is important, Linux always notifies the parent first. if d.parent != nil { d.parent.inode.watches.Notify(d.name, events, cookie, et, deleted) } d.inode.watches.Notify("", events, cookie, et, deleted) d.inode.fs.mu.RUnlock() } // Watches implements vfs.DentryImpl.Watches. func (d *dentry) Watches() *vfs.Watches { return &d.inode.watches } // OnZeroWatches implements vfs.Dentry.OnZeroWatches. func (d *dentry) OnZeroWatches() {} // inode represents a filesystem object. type inode struct { // fs is the owning filesystem. fs is immutable. fs *filesystem // refs is a reference count. refs is accessed using atomic memory // operations. // // A reference is held on all inodes as long as they are reachable in the // filesystem tree, i.e. nlink is nonzero. This reference is dropped when // nlink reaches 0. refs int64 // xattrs implements extended attributes. // // TODO(b/148380782): Support xattrs other than user.* xattrs memxattr.SimpleExtendedAttributes // Inode metadata. Writing multiple fields atomically requires holding // mu, othewise atomic operations can be used. mu sync.Mutex mode uint32 // file type and mode nlink uint32 // protected by filesystem.mu instead of inode.mu uid uint32 // auth.KUID, but stored as raw uint32 for sync/atomic gid uint32 // auth.KGID, but ... ino uint64 // immutable // Linux's tmpfs has no concept of btime. atime int64 // nanoseconds ctime int64 // nanoseconds mtime int64 // nanoseconds locks vfs.FileLocks // Inotify watches for this inode. watches vfs.Watches impl interface{} // immutable } const maxLinks = math.MaxUint32 func (i *inode) init(impl interface{}, fs *filesystem, kuid auth.KUID, kgid auth.KGID, mode linux.FileMode) { if mode.FileType() == 0 { panic("file type is required in FileMode") } i.fs = fs i.refs = 1 i.mode = uint32(mode) i.uid = uint32(kuid) i.gid = uint32(kgid) i.ino = atomic.AddUint64(&fs.nextInoMinusOne, 1) // Tmpfs creation sets atime, ctime, and mtime to current time. now := fs.clock.Now().Nanoseconds() i.atime = now i.ctime = now i.mtime = now // i.nlink initialized by caller i.impl = impl } // incLinksLocked increments i's link count. // // Preconditions: filesystem.mu must be locked for writing. i.nlink != 0. // i.nlink < maxLinks. func (i *inode) incLinksLocked() { if i.nlink == 0 { panic("tmpfs.inode.incLinksLocked() called with no existing links") } if i.nlink == maxLinks { panic("tmpfs.inode.incLinksLocked() called with maximum link count") } atomic.AddUint32(&i.nlink, 1) } // decLinksLocked decrements i's link count. If the link count reaches 0, we // remove a reference on i as well. // // Preconditions: filesystem.mu must be locked for writing. i.nlink != 0. func (i *inode) decLinksLocked() { if i.nlink == 0 { panic("tmpfs.inode.decLinksLocked() called with no existing links") } if atomic.AddUint32(&i.nlink, ^uint32(0)) == 0 { i.decRef() } } func (i *inode) incRef() { if atomic.AddInt64(&i.refs, 1) <= 1 { panic("tmpfs.inode.incRef() called without holding a reference") } } func (i *inode) tryIncRef() bool { for { refs := atomic.LoadInt64(&i.refs) if refs == 0 { return false } if atomic.CompareAndSwapInt64(&i.refs, refs, refs+1) { return true } } } func (i *inode) decRef() { if refs := atomic.AddInt64(&i.refs, -1); refs == 0 { i.watches.HandleDeletion() if regFile, ok := i.impl.(*regularFile); ok { // Release memory used by regFile to store data. Since regFile is // no longer usable, we don't need to grab any locks or update any // metadata. regFile.data.DropAll(regFile.memFile) } } else if refs < 0 { panic("tmpfs.inode.decRef() called without holding a reference") } } func (i *inode) checkPermissions(creds *auth.Credentials, ats vfs.AccessTypes) error { mode := linux.FileMode(atomic.LoadUint32(&i.mode)) return vfs.GenericCheckPermissions(creds, ats, mode, auth.KUID(atomic.LoadUint32(&i.uid)), auth.KGID(atomic.LoadUint32(&i.gid))) } // Go won't inline this function, and returning linux.Statx (which is quite // big) means spending a lot of time in runtime.duffcopy(), so instead it's an // output parameter. // // Note that Linux does not guarantee to return consistent data (in the case of // a concurrent modification), so we do not require holding inode.mu. func (i *inode) statTo(stat *linux.Statx) { stat.Mask = linux.STATX_TYPE | linux.STATX_MODE | linux.STATX_NLINK | linux.STATX_UID | linux.STATX_GID | linux.STATX_INO | linux.STATX_SIZE | linux.STATX_BLOCKS | linux.STATX_ATIME | linux.STATX_CTIME | linux.STATX_MTIME stat.Blksize = usermem.PageSize stat.Nlink = atomic.LoadUint32(&i.nlink) stat.UID = atomic.LoadUint32(&i.uid) stat.GID = atomic.LoadUint32(&i.gid) stat.Mode = uint16(atomic.LoadUint32(&i.mode)) stat.Ino = i.ino stat.Atime = linux.NsecToStatxTimestamp(i.atime) stat.Ctime = linux.NsecToStatxTimestamp(i.ctime) stat.Mtime = linux.NsecToStatxTimestamp(i.mtime) stat.DevMajor = linux.UNNAMED_MAJOR stat.DevMinor = i.fs.devMinor switch impl := i.impl.(type) { case *regularFile: stat.Mask |= linux.STATX_SIZE | linux.STATX_BLOCKS stat.Size = uint64(atomic.LoadUint64(&impl.size)) // TODO(jamieliu): This should be impl.data.Span() / 512, but this is // too expensive to compute here. Cache it in regularFile. stat.Blocks = allocatedBlocksForSize(stat.Size) case *directory: // "20" is mm/shmem.c:BOGO_DIRENT_SIZE. stat.Size = 20 * (2 + uint64(atomic.LoadInt64(&impl.numChildren))) // stat.Blocks is 0. case *symlink: stat.Size = uint64(len(impl.target)) // stat.Blocks is 0. case *namedPipe, *socketFile: // stat.Size and stat.Blocks are 0. case *deviceFile: // stat.Size and stat.Blocks are 0. stat.RdevMajor = impl.major stat.RdevMinor = impl.minor default: panic(fmt.Sprintf("unknown inode type: %T", i.impl)) } } func (i *inode) setStat(ctx context.Context, creds *auth.Credentials, stat *linux.Statx) 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_CTIME|linux.STATX_SIZE) != 0 { return syserror.EPERM } mode := linux.FileMode(atomic.LoadUint32(&i.mode)) if err := vfs.CheckSetStat(ctx, creds, stat, mode, auth.KUID(atomic.LoadUint32(&i.uid)), auth.KGID(atomic.LoadUint32(&i.gid))); err != nil { return err } i.mu.Lock() defer i.mu.Unlock() var ( needsMtimeBump bool needsCtimeBump bool ) mask := stat.Mask if mask&linux.STATX_MODE != 0 { ft := atomic.LoadUint32(&i.mode) & linux.S_IFMT atomic.StoreUint32(&i.mode, ft|uint32(stat.Mode&^linux.S_IFMT)) needsCtimeBump = true } if mask&linux.STATX_UID != 0 { atomic.StoreUint32(&i.uid, stat.UID) needsCtimeBump = true } if mask&linux.STATX_GID != 0 { atomic.StoreUint32(&i.gid, stat.GID) needsCtimeBump = true } if mask&linux.STATX_SIZE != 0 { switch impl := i.impl.(type) { case *regularFile: updated, err := impl.truncateLocked(stat.Size) if err != nil { return err } if updated { needsMtimeBump = true needsCtimeBump = true } case *directory: return syserror.EISDIR default: return syserror.EINVAL } } now := i.fs.clock.Now().Nanoseconds() if mask&linux.STATX_ATIME != 0 { if stat.Atime.Nsec == linux.UTIME_NOW { atomic.StoreInt64(&i.atime, now) } else { atomic.StoreInt64(&i.atime, stat.Atime.ToNsecCapped()) } needsCtimeBump = true } if mask&linux.STATX_MTIME != 0 { if stat.Mtime.Nsec == linux.UTIME_NOW { atomic.StoreInt64(&i.mtime, now) } else { atomic.StoreInt64(&i.mtime, stat.Mtime.ToNsecCapped()) } needsCtimeBump = true // Ignore the mtime bump, since we just set it ourselves. needsMtimeBump = false } if mask&linux.STATX_CTIME != 0 { if stat.Ctime.Nsec == linux.UTIME_NOW { atomic.StoreInt64(&i.ctime, now) } else { atomic.StoreInt64(&i.ctime, stat.Ctime.ToNsecCapped()) } // Ignore the ctime bump, since we just set it ourselves. needsCtimeBump = false } if needsMtimeBump { atomic.StoreInt64(&i.mtime, now) } if needsCtimeBump { atomic.StoreInt64(&i.ctime, now) } return nil } // allocatedBlocksForSize returns the number of 512B blocks needed to // accommodate the given size in bytes, as appropriate for struct // stat::st_blocks and struct statx::stx_blocks. (Note that this 512B block // size is independent of the "preferred block size for I/O", struct // stat::st_blksize and struct statx::stx_blksize.) func allocatedBlocksForSize(size uint64) uint64 { return (size + 511) / 512 } func (i *inode) direntType() uint8 { switch impl := i.impl.(type) { case *regularFile: return linux.DT_REG case *directory: return linux.DT_DIR case *symlink: return linux.DT_LNK case *socketFile: return linux.DT_SOCK case *deviceFile: switch impl.kind { case vfs.BlockDevice: return linux.DT_BLK case vfs.CharDevice: return linux.DT_CHR default: panic(fmt.Sprintf("unknown vfs.DeviceKind: %v", impl.kind)) } default: panic(fmt.Sprintf("unknown inode type: %T", i.impl)) } } func (i *inode) isDir() bool { return linux.FileMode(i.mode).FileType() == linux.S_IFDIR } func (i *inode) touchAtime(mnt *vfs.Mount) { if mnt.Flags.NoATime { return } if err := mnt.CheckBeginWrite(); err != nil { return } now := i.fs.clock.Now().Nanoseconds() i.mu.Lock() atomic.StoreInt64(&i.atime, now) i.mu.Unlock() mnt.EndWrite() } // Preconditions: The caller has called vfs.Mount.CheckBeginWrite(). func (i *inode) touchCtime() { now := i.fs.clock.Now().Nanoseconds() i.mu.Lock() atomic.StoreInt64(&i.ctime, now) i.mu.Unlock() } // Preconditions: The caller has called vfs.Mount.CheckBeginWrite(). func (i *inode) touchCMtime() { now := i.fs.clock.Now().Nanoseconds() i.mu.Lock() atomic.StoreInt64(&i.mtime, now) atomic.StoreInt64(&i.ctime, now) i.mu.Unlock() } // Preconditions: The caller has called vfs.Mount.CheckBeginWrite() and holds // inode.mu. func (i *inode) touchCMtimeLocked() { now := i.fs.clock.Now().Nanoseconds() atomic.StoreInt64(&i.mtime, now) atomic.StoreInt64(&i.ctime, now) } func (i *inode) listxattr(size uint64) ([]string, error) { return i.xattrs.Listxattr(size) } func (i *inode) getxattr(creds *auth.Credentials, opts *vfs.GetxattrOptions) (string, error) { if err := i.checkPermissions(creds, vfs.MayRead); err != nil { return "", err } if !strings.HasPrefix(opts.Name, linux.XATTR_USER_PREFIX) { return "", syserror.EOPNOTSUPP } if !i.userXattrSupported() { return "", syserror.ENODATA } return i.xattrs.Getxattr(opts) } func (i *inode) setxattr(creds *auth.Credentials, opts *vfs.SetxattrOptions) error { if err := i.checkPermissions(creds, vfs.MayWrite); err != nil { return err } if !strings.HasPrefix(opts.Name, linux.XATTR_USER_PREFIX) { return syserror.EOPNOTSUPP } if !i.userXattrSupported() { return syserror.EPERM } return i.xattrs.Setxattr(opts) } func (i *inode) removexattr(creds *auth.Credentials, name string) error { if err := i.checkPermissions(creds, vfs.MayWrite); err != nil { return err } if !strings.HasPrefix(name, linux.XATTR_USER_PREFIX) { return syserror.EOPNOTSUPP } if !i.userXattrSupported() { return syserror.EPERM } return i.xattrs.Removexattr(name) } // Extended attributes in the user.* namespace are only supported for regular // files and directories. func (i *inode) userXattrSupported() bool { filetype := linux.S_IFMT & atomic.LoadUint32(&i.mode) return filetype == linux.S_IFREG || filetype == linux.S_IFDIR } // fileDescription is embedded by tmpfs implementations of // vfs.FileDescriptionImpl. type fileDescription struct { vfsfd vfs.FileDescription vfs.FileDescriptionDefaultImpl vfs.LockFD } func (fd *fileDescription) filesystem() *filesystem { return fd.vfsfd.Mount().Filesystem().Impl().(*filesystem) } func (fd *fileDescription) dentry() *dentry { return fd.vfsfd.Dentry().Impl().(*dentry) } func (fd *fileDescription) inode() *inode { return fd.dentry().inode } // Stat implements vfs.FileDescriptionImpl.Stat. func (fd *fileDescription) Stat(ctx context.Context, opts vfs.StatOptions) (linux.Statx, error) { var stat linux.Statx fd.inode().statTo(&stat) return stat, nil } // SetStat implements vfs.FileDescriptionImpl.SetStat. func (fd *fileDescription) SetStat(ctx context.Context, opts vfs.SetStatOptions) error { creds := auth.CredentialsFromContext(ctx) d := fd.dentry() if err := d.inode.setStat(ctx, creds, &opts.Stat); err != nil { return err } if ev := vfs.InotifyEventFromStatMask(opts.Stat.Mask); ev != 0 { d.InotifyWithParent(ev, 0, vfs.InodeEvent) } return nil } // Listxattr implements vfs.FileDescriptionImpl.Listxattr. func (fd *fileDescription) Listxattr(ctx context.Context, size uint64) ([]string, error) { return fd.inode().listxattr(size) } // Getxattr implements vfs.FileDescriptionImpl.Getxattr. func (fd *fileDescription) Getxattr(ctx context.Context, opts vfs.GetxattrOptions) (string, error) { return fd.inode().getxattr(auth.CredentialsFromContext(ctx), &opts) } // Setxattr implements vfs.FileDescriptionImpl.Setxattr. func (fd *fileDescription) Setxattr(ctx context.Context, opts vfs.SetxattrOptions) error { d := fd.dentry() if err := d.inode.setxattr(auth.CredentialsFromContext(ctx), &opts); err != nil { return err } // Generate inotify events. d.InotifyWithParent(linux.IN_ATTRIB, 0, vfs.InodeEvent) return nil } // Removexattr implements vfs.FileDescriptionImpl.Removexattr. func (fd *fileDescription) Removexattr(ctx context.Context, name string) error { d := fd.dentry() if err := d.inode.removexattr(auth.CredentialsFromContext(ctx), name); err != nil { return err } // Generate inotify events. d.InotifyWithParent(linux.IN_ATTRIB, 0, vfs.InodeEvent) return nil } // NewMemfd creates a new tmpfs regular file and file description that can back // an anonymous fd created by memfd_create. func NewMemfd(mount *vfs.Mount, creds *auth.Credentials, allowSeals bool, name string) (*vfs.FileDescription, error) { fs, ok := mount.Filesystem().Impl().(*filesystem) if !ok { panic("NewMemfd() called with non-tmpfs mount") } // Per Linux, mm/shmem.c:__shmem_file_setup(), memfd inodes are set up with // S_IRWXUGO. inode := fs.newRegularFile(creds.EffectiveKUID, creds.EffectiveKGID, 0777) rf := inode.impl.(*regularFile) if allowSeals { rf.seals = 0 } d := fs.newDentry(inode) defer d.DecRef() d.name = name // Per Linux, mm/shmem.c:__shmem_file_setup(), memfd files are set up with // FMODE_READ | FMODE_WRITE. var fd regularFileFD fd.Init(&inode.locks) flags := uint32(linux.O_RDWR) if err := fd.vfsfd.Init(&fd, flags, mount, &d.vfsd, &vfs.FileDescriptionOptions{}); err != nil { return nil, err } return &fd.vfsfd, nil } // LockPOSIX implements vfs.FileDescriptionImpl.LockPOSIX. func (fd *fileDescription) LockPOSIX(ctx context.Context, uid fslock.UniqueID, t fslock.LockType, start, length uint64, whence int16, block fslock.Blocker) error { return fd.Locks().LockPOSIX(ctx, &fd.vfsfd, uid, t, start, length, whence, block) } // UnlockPOSIX implements vfs.FileDescriptionImpl.UnlockPOSIX. func (fd *fileDescription) UnlockPOSIX(ctx context.Context, uid fslock.UniqueID, start, length uint64, whence int16) error { return fd.Locks().UnlockPOSIX(ctx, &fd.vfsfd, uid, start, length, whence) } // Sync implements vfs.FileDescriptionImpl.Sync. It does nothing because all // filesystem state is in-memory. func (*fileDescription) Sync(context.Context) error { return nil }