// Copyright 2018 The gVisor Authors. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. // Package fsgofer implements p9.File giving access to local files using // a simple mapping from a path prefix that is added to the path requested // by the sandbox. Ex: // // prefix: "/docker/imgs/alpine" // app path: /bin/ls => /docker/imgs/alpine/bin/ls package fsgofer import ( "fmt" "io" "math" "os" "path" "path/filepath" "runtime" "strconv" "golang.org/x/sys/unix" "gvisor.dev/gvisor/pkg/abi/linux" "gvisor.dev/gvisor/pkg/cleanup" "gvisor.dev/gvisor/pkg/fd" "gvisor.dev/gvisor/pkg/log" "gvisor.dev/gvisor/pkg/p9" "gvisor.dev/gvisor/pkg/sync" ) const ( // invalidMode is set to a value that doesn't match any other valid // modes to ensure an unopened/closed file fails all mode checks. invalidMode = p9.OpenFlags(math.MaxUint32) openFlags = unix.O_NOFOLLOW | unix.O_CLOEXEC allowedOpenFlags = unix.O_TRUNC ) var ( // Remember the process uid/gid to skip chown calls when file owner/group // doesn't need to be changed. processUID = p9.UID(os.Getuid()) processGID = p9.GID(os.Getgid()) ) // join is equivalent to path.Join() but skips path.Clean() which is expensive. func join(parent, child string) string { if child == "." || child == ".." { panic(fmt.Sprintf("invalid child path %q", child)) } return parent + "/" + child } // Config sets configuration options for each attach point. type Config struct { // ROMount is set to true if this is a readonly mount. ROMount bool // PanicOnWrite panics on attempts to write to RO mounts. PanicOnWrite bool // HostUDS signals whether the gofer can mount a host's UDS. HostUDS bool } type attachPoint struct { prefix string conf Config // attachedMu protects attached. attachedMu sync.Mutex attached bool // deviceMu protects devices and nextDevice. deviceMu sync.Mutex // nextDevice is the next device id that will be allocated. nextDevice uint8 // devices is a map from actual host devices to "small" integers that // can be combined with host inode to form a unique virtual inode id. devices map[uint64]uint8 } // NewAttachPoint creates a new attacher that gives local file // access to all files under 'prefix'. 'prefix' must be an absolute path. func NewAttachPoint(prefix string, c Config) (p9.Attacher, error) { // Sanity check the prefix. if !filepath.IsAbs(prefix) { return nil, fmt.Errorf("attach point prefix must be absolute %q", prefix) } return &attachPoint{ prefix: prefix, conf: c, devices: make(map[uint64]uint8), }, nil } // Attach implements p9.Attacher. func (a *attachPoint) Attach() (p9.File, error) { a.attachedMu.Lock() defer a.attachedMu.Unlock() if a.attached { return nil, fmt.Errorf("attach point already attached, prefix: %s", a.prefix) } f, readable, err := openAnyFile(a.prefix, func(mode int) (*fd.FD, error) { return fd.Open(a.prefix, openFlags|mode, 0) }) if err != nil { return nil, fmt.Errorf("unable to open %q: %v", a.prefix, err) } stat, err := fstat(f.FD()) if err != nil { return nil, fmt.Errorf("unable to stat %q: %v", a.prefix, err) } lf, err := newLocalFile(a, f, a.prefix, readable, &stat) if err != nil { return nil, fmt.Errorf("unable to create localFile %q: %v", a.prefix, err) } a.attached = true return lf, nil } // makeQID returns a unique QID for the given stat buffer. func (a *attachPoint) makeQID(stat *unix.Stat_t) p9.QID { a.deviceMu.Lock() defer a.deviceMu.Unlock() // First map the host device id to a unique 8-bit integer. dev, ok := a.devices[stat.Dev] if !ok { a.devices[stat.Dev] = a.nextDevice dev = a.nextDevice a.nextDevice++ if a.nextDevice < dev { panic(fmt.Sprintf("device id overflow! map: %+v", a.devices)) } } // Construct a "virtual" inode id with the uint8 device number in the // first 8 bits, and the rest of the bits from the host inode id. maskedIno := stat.Ino & 0x00ffffffffffffff if maskedIno != stat.Ino { log.Warningf("first 8 bytes of host inode id %x will be truncated to construct virtual inode id", stat.Ino) } ino := uint64(dev)<<56 | maskedIno return p9.QID{ Type: p9.FileMode(stat.Mode).QIDType(), Path: ino, } } // localFile implements p9.File wrapping a local file. The underlying file // is opened during Walk() and stored in 'file' to be used with other // operations. The file is opened as readonly, unless it's a symlink or there is // no read access, which requires O_PATH. // // The file may be reopened if the requested mode in Open() is not a subset of // current mode. Consequently, 'file' could have a mode wider than requested and // must be verified before read/write operations. Before the file is opened and // after it's closed, 'mode' is set to an invalid value to prevent an unopened // file from being used. // // The reason that the file is not opened initially as read-write is for better // performance with 'overlay2' storage driver. overlay2 eagerly copies the // entire file up when it's opened in write mode, and would perform badly when // multiple files are only being opened for read (esp. startup). // // File operations must use "at" functions whenever possible: // * Local operations must use AT_EMPTY_PATH: // fchownat(fd, "", AT_EMPTY_PATH, ...), instead of chown(fullpath, ...) // * Creation operations must use (fd + name): // mkdirat(fd, name, ...), instead of mkdir(fullpath, ...) // // Apart from being faster, it also adds another layer of defense against // symlink attacks (note that O_NOFOLLOW applies only to the last element in // the path). // // The few exceptions where it cannot be done are: utimensat on symlinks, and // Connect() for the socket address. type localFile struct { p9.DisallowClientCalls // attachPoint is the attachPoint that serves this localFile. attachPoint *attachPoint // hostPath is the full path to the host file. It can be used for logging and // the few cases where full path is required to operation the host file. In // all other cases, use "file" directly. // // Note: it's safely updated by the Renamed hook. hostPath string // file is opened when localFile is created and it's never nil. It may be // reopened if the Open() mode is wider than the mode the file was originally // opened with. file *fd.FD // controlReadable tells whether 'file' was opened with read permissions // during a walk. controlReadable bool // mode is the mode in which the file was opened. Set to invalidMode // if localFile isn't opened. mode p9.OpenFlags // fileType for this file. It is equivalent to: // unix.Stat_t.Mode & unix.S_IFMT fileType uint32 qid p9.QID // readDirMu protects against concurrent Readdir calls. readDirMu sync.Mutex // lastDirentOffset is the last offset returned by Readdir(). If another call // to Readdir is made at the same offset, the file doesn't need to be // repositioned. This is an important optimization because the caller must // always make one extra call to detect EOF (empty result, no error). lastDirentOffset uint64 } var procSelfFD *fd.FD // OpenProcSelfFD opens the /proc/self/fd directory, which will be used to // reopen file descriptors. func OpenProcSelfFD() error { d, err := unix.Open("/proc/self/fd", unix.O_RDONLY|unix.O_DIRECTORY, 0) if err != nil { return fmt.Errorf("error opening /proc/self/fd: %v", err) } procSelfFD = fd.New(d) return nil } func reopenProcFd(f *fd.FD, mode int) (*fd.FD, error) { d, err := unix.Openat(int(procSelfFD.FD()), strconv.Itoa(f.FD()), mode&^unix.O_NOFOLLOW, 0) if err != nil { return nil, err } return fd.New(d), nil } func openAnyFileFromParent(parent *localFile, name string) (*fd.FD, string, bool, error) { pathDebug := join(parent.hostPath, name) f, readable, err := openAnyFile(pathDebug, func(mode int) (*fd.FD, error) { return fd.OpenAt(parent.file, name, openFlags|mode, 0) }) return f, pathDebug, readable, err } // openAnyFile attempts to open the file in O_RDONLY. If it fails, falls back // to O_PATH. 'path' is used for logging messages only. 'fn' is what does the // actual file open and is customizable by the caller. func openAnyFile(pathDebug string, fn func(mode int) (*fd.FD, error)) (*fd.FD, bool, error) { // Attempt to open file in the following mode in order: // 1. RDONLY | NONBLOCK: for all files, directories, ro mounts, FIFOs. // Use non-blocking to prevent getting stuck inside open(2) for // FIFOs. This option has no effect on regular files. // 2. PATH: for symlinks, sockets. options := []struct { mode int readable bool }{ { mode: unix.O_RDONLY | unix.O_NONBLOCK, readable: true, }, { mode: unix.O_PATH, readable: false, }, } var err error for i, option := range options { var file *fd.FD file, err = fn(option.mode) if err == nil { // Succeeded opening the file, we're done. return file, option.readable, nil } switch e := extractErrno(err); e { case unix.ENOENT: // File doesn't exist, no point in retrying. return nil, false, e } // File failed to open. Try again with next mode, preserving 'err' in case // this was the last attempt. log.Debugf("Attempt %d to open file failed, mode: %#x, path: %q, err: %v", i, openFlags|option.mode, pathDebug, err) } // All attempts to open file have failed, return the last error. log.Debugf("Failed to open file, path: %q, err: %v", pathDebug, err) return nil, false, extractErrno(err) } func checkSupportedFileType(mode uint32, permitSocket bool) error { switch mode & unix.S_IFMT { case unix.S_IFREG, unix.S_IFDIR, unix.S_IFLNK: return nil case unix.S_IFSOCK: if !permitSocket { return unix.EPERM } return nil default: return unix.EPERM } } func newLocalFile(a *attachPoint, file *fd.FD, path string, readable bool, stat *unix.Stat_t) (*localFile, error) { if err := checkSupportedFileType(stat.Mode, a.conf.HostUDS); err != nil { return nil, err } return &localFile{ attachPoint: a, hostPath: path, file: file, mode: invalidMode, fileType: stat.Mode & unix.S_IFMT, qid: a.makeQID(stat), controlReadable: readable, }, nil } // newFDMaybe creates a fd.FD from a file, dup'ing the FD and setting it as // non-blocking. If anything fails, returns nil. It's better to have a file // without host FD, than to fail the operation. func newFDMaybe(file *fd.FD) *fd.FD { dupFD, err := unix.Dup(file.FD()) // Technically, the runtime may call the finalizer on file as soon as // FD() returns. runtime.KeepAlive(file) if err != nil { return nil } dup := fd.New(dupFD) // fd is blocking; non-blocking is required. if err := unix.SetNonblock(dup.FD(), true); err != nil { _ = dup.Close() return nil } return dup } func fstat(fd int) (unix.Stat_t, error) { var stat unix.Stat_t if err := unix.Fstat(fd, &stat); err != nil { return unix.Stat_t{}, err } return stat, nil } func fchown(fd int, uid p9.UID, gid p9.GID) error { return unix.Fchownat(fd, "", int(uid), int(gid), linux.AT_EMPTY_PATH|unix.AT_SYMLINK_NOFOLLOW) } // Open implements p9.File. func (l *localFile) Open(flags p9.OpenFlags) (*fd.FD, p9.QID, uint32, error) { if l.isOpen() { panic(fmt.Sprintf("attempting to open already opened file: %q", l.hostPath)) } mode := flags & p9.OpenFlagsModeMask if mode == p9.WriteOnly || mode == p9.ReadWrite || flags&p9.OpenTruncate != 0 { if err := l.checkROMount(); err != nil { return nil, p9.QID{}, 0, err } } // Check if control file can be used or if a new open must be created. var newFile *fd.FD if mode == p9.ReadOnly && l.controlReadable && flags.OSFlags()&allowedOpenFlags == 0 { log.Debugf("Open reusing control file, flags: %v, %q", flags, l.hostPath) newFile = l.file } else { // Ideally reopen would call name_to_handle_at (with empty name) and // open_by_handle_at to reopen the file without using 'hostPath'. However, // name_to_handle_at and open_by_handle_at aren't supported by overlay2. log.Debugf("Open reopening file, flags: %v, %q", flags, l.hostPath) var err error osFlags := flags.OSFlags() & (unix.O_ACCMODE | allowedOpenFlags) newFile, err = reopenProcFd(l.file, openFlags|osFlags) if err != nil { return nil, p9.QID{}, 0, extractErrno(err) } } var fd *fd.FD if l.fileType == unix.S_IFREG { // Donate FD for regular files only. fd = newFDMaybe(newFile) } // Close old file in case a new one was created. if newFile != l.file { if err := l.file.Close(); err != nil { log.Warningf("Error closing file %q: %v", l.hostPath, err) } l.file = newFile } l.mode = mode return fd, l.qid, 0, nil } // Create implements p9.File. func (l *localFile) Create(name string, p9Flags p9.OpenFlags, perm p9.FileMode, uid p9.UID, gid p9.GID) (*fd.FD, p9.File, p9.QID, uint32, error) { if err := l.checkROMount(); err != nil { return nil, nil, p9.QID{}, 0, err } // Set file creation flags, plus allowed open flags from caller. osFlags := openFlags | unix.O_CREAT | unix.O_EXCL osFlags |= p9Flags.OSFlags() & allowedOpenFlags // 'file' may be used for other operations (e.g. Walk), so read access is // always added to flags. Note that resulting file might have a wider mode // than needed for each particular case. mode := p9Flags & p9.OpenFlagsModeMask if mode == p9.WriteOnly { osFlags |= unix.O_RDWR } else { osFlags |= mode.OSFlags() } child, err := fd.OpenAt(l.file, name, osFlags, uint32(perm.Permissions())) if err != nil { return nil, nil, p9.QID{}, 0, extractErrno(err) } cu := cleanup.Make(func() { _ = child.Close() // Best effort attempt to remove the file in case of failure. if err := unix.Unlinkat(l.file.FD(), name, 0); err != nil { log.Warningf("error unlinking file %q after failure: %v", path.Join(l.hostPath, name), err) } }) defer cu.Clean() if uid != processUID || gid != processGID { if err := fchown(child.FD(), uid, gid); err != nil { return nil, nil, p9.QID{}, 0, extractErrno(err) } } stat, err := fstat(child.FD()) if err != nil { return nil, nil, p9.QID{}, 0, extractErrno(err) } c := &localFile{ attachPoint: l.attachPoint, hostPath: join(l.hostPath, name), file: child, mode: mode, fileType: unix.S_IFREG, qid: l.attachPoint.makeQID(&stat), } cu.Release() return newFDMaybe(c.file), c, c.qid, 0, nil } // Mkdir implements p9.File. func (l *localFile) Mkdir(name string, perm p9.FileMode, uid p9.UID, gid p9.GID) (p9.QID, error) { if err := l.checkROMount(); err != nil { return p9.QID{}, err } if err := unix.Mkdirat(l.file.FD(), name, uint32(perm.Permissions())); err != nil { return p9.QID{}, extractErrno(err) } cu := cleanup.Make(func() { // Best effort attempt to remove the dir in case of failure. if err := unix.Unlinkat(l.file.FD(), name, unix.AT_REMOVEDIR); err != nil { log.Warningf("error unlinking dir %q after failure: %v", path.Join(l.hostPath, name), err) } }) defer cu.Clean() // Open directory to change ownership and stat it. flags := unix.O_DIRECTORY | unix.O_RDONLY | openFlags f, err := fd.OpenAt(l.file, name, flags, 0) if err != nil { return p9.QID{}, extractErrno(err) } defer f.Close() if uid != processUID || gid != processGID { if err := fchown(f.FD(), uid, gid); err != nil { return p9.QID{}, extractErrno(err) } } stat, err := fstat(f.FD()) if err != nil { return p9.QID{}, extractErrno(err) } cu.Release() return l.attachPoint.makeQID(&stat), nil } // Walk implements p9.File. func (l *localFile) Walk(names []string) ([]p9.QID, p9.File, error) { qids, file, _, err := l.walk(names) return qids, file, err } // WalkGetAttr implements p9.File. func (l *localFile) WalkGetAttr(names []string) ([]p9.QID, p9.File, p9.AttrMask, p9.Attr, error) { qids, file, stat, err := l.walk(names) if err != nil { return nil, nil, p9.AttrMask{}, p9.Attr{}, err } mask, attr := l.fillAttr(&stat) return qids, file, mask, attr, nil } func (l *localFile) walk(names []string) ([]p9.QID, p9.File, unix.Stat_t, error) { // Duplicate current file if 'names' is empty. if len(names) == 0 { newFile, readable, err := openAnyFile(l.hostPath, func(mode int) (*fd.FD, error) { return reopenProcFd(l.file, openFlags|mode) }) if err != nil { return nil, nil, unix.Stat_t{}, extractErrno(err) } stat, err := fstat(newFile.FD()) if err != nil { _ = newFile.Close() return nil, nil, unix.Stat_t{}, extractErrno(err) } c := &localFile{ attachPoint: l.attachPoint, hostPath: l.hostPath, file: newFile, mode: invalidMode, fileType: l.fileType, qid: l.attachPoint.makeQID(&stat), controlReadable: readable, } return []p9.QID{c.qid}, c, stat, nil } qids := make([]p9.QID, 0, len(names)) var lastStat unix.Stat_t last := l for _, name := range names { f, path, readable, err := openAnyFileFromParent(last, name) if last != l { _ = last.Close() } if err != nil { return nil, nil, unix.Stat_t{}, extractErrno(err) } lastStat, err = fstat(f.FD()) if err != nil { _ = f.Close() return nil, nil, unix.Stat_t{}, extractErrno(err) } c, err := newLocalFile(last.attachPoint, f, path, readable, &lastStat) if err != nil { _ = f.Close() return nil, nil, unix.Stat_t{}, extractErrno(err) } qids = append(qids, c.qid) last = c } return qids, last, lastStat, nil } // StatFS implements p9.File. func (l *localFile) StatFS() (p9.FSStat, error) { var s unix.Statfs_t if err := unix.Fstatfs(l.file.FD(), &s); err != nil { return p9.FSStat{}, extractErrno(err) } // Populate with what's available. return p9.FSStat{ Type: uint32(s.Type), BlockSize: uint32(s.Bsize), Blocks: s.Blocks, BlocksFree: s.Bfree, BlocksAvailable: s.Bavail, Files: s.Files, FilesFree: s.Ffree, NameLength: uint32(s.Namelen), }, nil } // FSync implements p9.File. func (l *localFile) FSync() error { if !l.isOpen() { return unix.EBADF } if err := unix.Fsync(l.file.FD()); err != nil { return extractErrno(err) } return nil } // GetAttr implements p9.File. func (l *localFile) GetAttr(_ p9.AttrMask) (p9.QID, p9.AttrMask, p9.Attr, error) { stat, err := fstat(l.file.FD()) if err != nil { return p9.QID{}, p9.AttrMask{}, p9.Attr{}, extractErrno(err) } mask, attr := l.fillAttr(&stat) return l.qid, mask, attr, nil } func (l *localFile) fillAttr(stat *unix.Stat_t) (p9.AttrMask, p9.Attr) { attr := p9.Attr{ Mode: p9.FileMode(stat.Mode), UID: p9.UID(stat.Uid), GID: p9.GID(stat.Gid), NLink: uint64(stat.Nlink), RDev: stat.Rdev, Size: uint64(stat.Size), BlockSize: uint64(stat.Blksize), Blocks: uint64(stat.Blocks), ATimeSeconds: uint64(stat.Atim.Sec), ATimeNanoSeconds: uint64(stat.Atim.Nsec), MTimeSeconds: uint64(stat.Mtim.Sec), MTimeNanoSeconds: uint64(stat.Mtim.Nsec), CTimeSeconds: uint64(stat.Ctim.Sec), CTimeNanoSeconds: uint64(stat.Ctim.Nsec), } valid := p9.AttrMask{ Mode: true, UID: true, GID: true, NLink: true, RDev: true, Size: true, Blocks: true, ATime: true, MTime: true, CTime: true, } return valid, attr } // SetAttr implements p9.File. Due to mismatch in file API, options // cannot be changed atomically and user may see partial changes when // an error happens. func (l *localFile) SetAttr(valid p9.SetAttrMask, attr p9.SetAttr) error { if err := l.checkROMount(); err != nil { return err } allowed := p9.SetAttrMask{ Permissions: true, UID: true, GID: true, Size: true, ATime: true, MTime: true, ATimeNotSystemTime: true, MTimeNotSystemTime: true, } if valid.Empty() { // Nothing to do. return nil } // Handle all the sanity checks up front so that the client gets a // consistent result that is not attribute dependent. if !valid.IsSubsetOf(allowed) { log.Warningf("SetAttr() failed for %q, mask: %v", l.hostPath, valid) return unix.EPERM } // Check if it's possible to use cached file, or if another one needs to be // opened for write. f := l.file if l.fileType == unix.S_IFREG && l.mode != p9.WriteOnly && l.mode != p9.ReadWrite { var err error f, err = reopenProcFd(l.file, openFlags|os.O_WRONLY) if err != nil { return extractErrno(err) } defer f.Close() } // The semantics are to either return an error if no changes were made, // or no error if *all* changes were made. Well, this can be impossible // if the filesystem rejects at least one of the changes, especially // since some operations are not easy to undo atomically. // // This could be made better if SetAttr actually returned the changes // it did make, so the client can at least know what has changed. So // we at least attempt to make all of the changes and return a generic // error if any of them fails, which at least doesn't bias any change // over another. var err error if valid.Permissions { if cerr := unix.Fchmod(f.FD(), uint32(attr.Permissions)); cerr != nil { log.Debugf("SetAttr fchmod failed %q, err: %v", l.hostPath, cerr) err = extractErrno(cerr) } } if valid.Size { if terr := unix.Ftruncate(f.FD(), int64(attr.Size)); terr != nil { log.Debugf("SetAttr ftruncate failed %q, err: %v", l.hostPath, terr) err = extractErrno(terr) } } if valid.ATime || valid.MTime { utimes := [2]unix.Timespec{ {Sec: 0, Nsec: linux.UTIME_OMIT}, {Sec: 0, Nsec: linux.UTIME_OMIT}, } if valid.ATime { if valid.ATimeNotSystemTime { utimes[0].Sec = int64(attr.ATimeSeconds) utimes[0].Nsec = int64(attr.ATimeNanoSeconds) } else { utimes[0].Nsec = linux.UTIME_NOW } } if valid.MTime { if valid.MTimeNotSystemTime { utimes[1].Sec = int64(attr.MTimeSeconds) utimes[1].Nsec = int64(attr.MTimeNanoSeconds) } else { utimes[1].Nsec = linux.UTIME_NOW } } if l.fileType == unix.S_IFLNK { // utimensat operates different that other syscalls. To operate on a // symlink it *requires* AT_SYMLINK_NOFOLLOW with dirFD and a non-empty // name. parent, oErr := unix.Open(path.Dir(l.hostPath), openFlags|unix.O_PATH, 0) if oErr != nil { return extractErrno(oErr) } defer unix.Close(parent) if tErr := utimensat(parent, path.Base(l.hostPath), utimes, linux.AT_SYMLINK_NOFOLLOW); tErr != nil { log.Debugf("SetAttr utimens failed %q, err: %v", l.hostPath, tErr) err = extractErrno(tErr) } } else { // Directories and regular files can operate directly on the fd // using empty name. if terr := utimensat(f.FD(), "", utimes, 0); terr != nil { log.Debugf("SetAttr utimens failed %q, err: %v", l.hostPath, terr) err = extractErrno(terr) } } } if valid.UID || valid.GID { uid := -1 if valid.UID { uid = int(attr.UID) } gid := -1 if valid.GID { gid = int(attr.GID) } if oErr := unix.Fchownat(f.FD(), "", uid, gid, linux.AT_EMPTY_PATH|linux.AT_SYMLINK_NOFOLLOW); oErr != nil { log.Debugf("SetAttr fchownat failed %q, err: %v", l.hostPath, oErr) err = extractErrno(oErr) } } return err } func (*localFile) GetXattr(string, uint64) (string, error) { return "", unix.EOPNOTSUPP } func (*localFile) SetXattr(string, string, uint32) error { return unix.EOPNOTSUPP } func (*localFile) ListXattr(uint64) (map[string]struct{}, error) { return nil, unix.EOPNOTSUPP } func (*localFile) RemoveXattr(string) error { return unix.EOPNOTSUPP } // Allocate implements p9.File. func (l *localFile) Allocate(mode p9.AllocateMode, offset, length uint64) error { if !l.isOpen() { return unix.EBADF } if err := unix.Fallocate(l.file.FD(), mode.ToLinux(), int64(offset), int64(length)); err != nil { return extractErrno(err) } return nil } // Rename implements p9.File; this should never be called. func (*localFile) Rename(p9.File, string) error { panic("rename called directly") } // RenameAt implements p9.File.RenameAt. func (l *localFile) RenameAt(oldName string, directory p9.File, newName string) error { if err := l.checkROMount(); err != nil { return err } newParent := directory.(*localFile) if err := renameat(l.file.FD(), oldName, newParent.file.FD(), newName); err != nil { return extractErrno(err) } return nil } // ReadAt implements p9.File. func (l *localFile) ReadAt(p []byte, offset uint64) (int, error) { if l.mode != p9.ReadOnly && l.mode != p9.ReadWrite { return 0, unix.EBADF } if !l.isOpen() { return 0, unix.EBADF } r, err := l.file.ReadAt(p, int64(offset)) switch err { case nil, io.EOF: return r, nil default: return r, extractErrno(err) } } // WriteAt implements p9.File. func (l *localFile) WriteAt(p []byte, offset uint64) (int, error) { if l.mode != p9.WriteOnly && l.mode != p9.ReadWrite { return 0, unix.EBADF } if !l.isOpen() { return 0, unix.EBADF } w, err := l.file.WriteAt(p, int64(offset)) if err != nil { return w, extractErrno(err) } return w, nil } // Symlink implements p9.File. func (l *localFile) Symlink(target, newName string, uid p9.UID, gid p9.GID) (p9.QID, error) { if err := l.checkROMount(); err != nil { return p9.QID{}, err } if err := unix.Symlinkat(target, l.file.FD(), newName); err != nil { return p9.QID{}, extractErrno(err) } cu := cleanup.Make(func() { // Best effort attempt to remove the symlink in case of failure. if err := unix.Unlinkat(l.file.FD(), newName, 0); err != nil { log.Warningf("error unlinking file %q after failure: %v", path.Join(l.hostPath, newName), err) } }) defer cu.Clean() // Open symlink to change ownership and stat it. f, err := fd.OpenAt(l.file, newName, unix.O_PATH|openFlags, 0) if err != nil { return p9.QID{}, extractErrno(err) } defer f.Close() if uid != processUID || gid != processGID { if err := fchown(f.FD(), uid, gid); err != nil { return p9.QID{}, extractErrno(err) } } stat, err := fstat(f.FD()) if err != nil { return p9.QID{}, extractErrno(err) } cu.Release() return l.attachPoint.makeQID(&stat), nil } // Link implements p9.File. func (l *localFile) Link(target p9.File, newName string) error { if err := l.checkROMount(); err != nil { return err } targetFile := target.(*localFile) if err := unix.Linkat(targetFile.file.FD(), "", l.file.FD(), newName, linux.AT_EMPTY_PATH); err != nil { return extractErrno(err) } return nil } // Mknod implements p9.File. func (l *localFile) Mknod(name string, mode p9.FileMode, _ uint32, _ uint32, uid p9.UID, gid p9.GID) (p9.QID, error) { if err := l.checkROMount(); err != nil { return p9.QID{}, err } // From mknod(2) man page: // "EPERM: [...] if the filesystem containing pathname does not support // the type of node requested." if mode.FileType() != p9.ModeRegular { return p9.QID{}, unix.EPERM } // Allow Mknod to create regular files. if err := unix.Mknodat(l.file.FD(), name, uint32(mode), 0); err != nil { return p9.QID{}, err } cu := cleanup.Make(func() { // Best effort attempt to remove the file in case of failure. if err := unix.Unlinkat(l.file.FD(), name, 0); err != nil { log.Warningf("error unlinking file %q after failure: %v", path.Join(l.hostPath, name), err) } }) defer cu.Clean() // Open file to change ownership and stat it. child, err := fd.OpenAt(l.file, name, unix.O_PATH|openFlags, 0) if err != nil { return p9.QID{}, extractErrno(err) } defer child.Close() if uid != processUID || gid != processGID { if err := fchown(child.FD(), uid, gid); err != nil { return p9.QID{}, extractErrno(err) } } stat, err := fstat(child.FD()) if err != nil { return p9.QID{}, extractErrno(err) } cu.Release() return l.attachPoint.makeQID(&stat), nil } // UnlinkAt implements p9.File. func (l *localFile) UnlinkAt(name string, flags uint32) error { if err := l.checkROMount(); err != nil { return err } if err := unix.Unlinkat(l.file.FD(), name, int(flags)); err != nil { return extractErrno(err) } return nil } // Readdir implements p9.File. func (l *localFile) Readdir(offset uint64, count uint32) ([]p9.Dirent, error) { if l.mode != p9.ReadOnly && l.mode != p9.ReadWrite { return nil, unix.EBADF } if !l.isOpen() { return nil, unix.EBADF } // Readdirnames is a cursor over directories, so seek back to 0 to ensure it's // reading all directory contents. Take a lock because this operation is // stateful. l.readDirMu.Lock() defer l.readDirMu.Unlock() skip := uint64(0) // Check if the file is at the correct position already. If not, seek to // the beginning and read the entire directory again. We always seek if // offset is 0, since this is side-effectual (equivalent to rewinddir(3), // which causes the directory stream to resynchronize with the directory's // current contents). if l.lastDirentOffset != offset || offset == 0 { if _, err := unix.Seek(l.file.FD(), 0, 0); err != nil { return nil, extractErrno(err) } skip = offset } dirents, err := l.readDirent(l.file.FD(), offset, count, skip) if err == nil { // On success, remember the offset that was returned at the current // position. l.lastDirentOffset = offset + uint64(len(dirents)) } else { // On failure, the state is unknown, force call to seek() next time. l.lastDirentOffset = math.MaxUint64 } return dirents, err } func (l *localFile) readDirent(f int, offset uint64, count uint32, skip uint64) ([]p9.Dirent, error) { var dirents []p9.Dirent // Limit 'count' to cap the slice size that is returned. const maxCount = 100000 if count > maxCount { count = maxCount } // Pre-allocate buffers that will be reused to get partial results. direntsBuf := make([]byte, 8192) names := make([]string, 0, 100) end := offset + uint64(count) for offset < end { dirSize, err := unix.ReadDirent(f, direntsBuf) if err != nil { return dirents, err } if dirSize <= 0 { return dirents, nil } names := names[:0] _, _, names = unix.ParseDirent(direntsBuf[:dirSize], -1, names) // Skip over entries that the caller is not interested in. if skip > 0 { if skip > uint64(len(names)) { skip -= uint64(len(names)) names = names[:0] } else { names = names[skip:] skip = 0 } } for _, name := range names { stat, err := statAt(l.file.FD(), name) if err != nil { log.Warningf("Readdir is skipping file with failed stat %q, err: %v", l.hostPath, err) continue } qid := l.attachPoint.makeQID(&stat) offset++ dirents = append(dirents, p9.Dirent{ QID: qid, Type: qid.Type, Name: name, Offset: offset, }) } } return dirents, nil } // Readlink implements p9.File. func (l *localFile) Readlink() (string, error) { // Shamelessly stolen from os.Readlink (added upper bound limit to buffer). const limit = 1024 * 1024 for len := 128; len < limit; len *= 2 { b := make([]byte, len) n, err := unix.Readlinkat(l.file.FD(), "", b) if err != nil { return "", extractErrno(err) } if n < len { return string(b[:n]), nil } } return "", unix.ENOMEM } // Flush implements p9.File. func (l *localFile) Flush() error { return nil } // Connect implements p9.File. func (l *localFile) Connect(flags p9.ConnectFlags) (*fd.FD, error) { if !l.attachPoint.conf.HostUDS { return nil, unix.ECONNREFUSED } // TODO(gvisor.dev/issue/1003): Due to different app vs replacement // mappings, the app path may have fit in the sockaddr, but we can't // fit f.path in our sockaddr. We'd need to redirect through a shorter // path in order to actually connect to this socket. if len(l.hostPath) > linux.UnixPathMax { return nil, unix.ECONNREFUSED } var stype int switch flags { case p9.StreamSocket: stype = unix.SOCK_STREAM case p9.DgramSocket: stype = unix.SOCK_DGRAM case p9.SeqpacketSocket: stype = unix.SOCK_SEQPACKET default: return nil, unix.ENXIO } f, err := unix.Socket(unix.AF_UNIX, stype, 0) if err != nil { return nil, err } if err := unix.SetNonblock(f, true); err != nil { _ = unix.Close(f) return nil, err } sa := unix.SockaddrUnix{Name: l.hostPath} if err := unix.Connect(f, &sa); err != nil { _ = unix.Close(f) return nil, err } return fd.New(f), nil } // Close implements p9.File. func (l *localFile) Close() error { l.mode = invalidMode err := l.file.Close() l.file = nil return err } func (l *localFile) isOpen() bool { return l.mode != invalidMode } // Renamed implements p9.Renamed. func (l *localFile) Renamed(newDir p9.File, newName string) { l.hostPath = join(newDir.(*localFile).hostPath, newName) } // extractErrno tries to determine the errno. func extractErrno(err error) unix.Errno { if err == nil { // This should never happen. The likely result will be that // some user gets the frustrating "error: SUCCESS" message. log.Warningf("extractErrno called with nil error!") return 0 } switch err { case os.ErrNotExist: return unix.ENOENT case os.ErrExist: return unix.EEXIST case os.ErrPermission: return unix.EACCES case os.ErrInvalid: return unix.EINVAL } // See if it's an errno or a common wrapped error. switch e := err.(type) { case unix.Errno: return e case *os.PathError: return extractErrno(e.Err) case *os.LinkError: return extractErrno(e.Err) case *os.SyscallError: return extractErrno(e.Err) } // Fall back to EIO. log.Debugf("Unknown error: %v, defaulting to EIO", err) return unix.EIO } func (l *localFile) checkROMount() error { if conf := l.attachPoint.conf; conf.ROMount { return unix.EROFS } return nil }