package fusefrontend // FUSE operations on file handles import ( "bytes" "fmt" "io" "log" "os" "sync" "sync/atomic" "syscall" "time" "github.com/hanwen/go-fuse/fuse" "github.com/hanwen/go-fuse/fuse/nodefs" "github.com/rfjakob/gocryptfs/internal/contentenc" "github.com/rfjakob/gocryptfs/internal/syscallcompat" "github.com/rfjakob/gocryptfs/internal/tlog" ) // File - based on loopbackFile in go-fuse/fuse/nodefs/files.go type file struct { fd *os.File // Has Release() already been called on this file? This also means that the // wlock entry has been freed, so let's not crash trying to access it. // Due to concurrency, Release can overtake other operations. These will // return EBADF in that case. released bool // fdLock prevents the fd to be closed while we are in the middle of // an operation. // Every FUSE entrypoint should RLock(). The only user of Lock() is // Release(), which closes the fd and sets "released" to true. fdLock sync.RWMutex // Was the file opened O_WRONLY? writeOnly bool // Content encryption helper contentEnc *contentenc.ContentEnc // Inode number ino uint64 // File header header *contentenc.FileHeader // go-fuse nodefs.loopbackFile loopbackFile nodefs.File // Store what the last byte was written lastWrittenOffset int64 // The opCount is used to judge whether "lastWrittenOffset" is still // guaranteed to be correct. lastOpCount uint64 } // NewFile returns a new go-fuse File instance. func NewFile(fd *os.File, writeOnly bool, contentEnc *contentenc.ContentEnc) (nodefs.File, fuse.Status) { var st syscall.Stat_t err := syscall.Fstat(int(fd.Fd()), &st) if err != nil { tlog.Warn.Printf("NewFile: Fstat on fd %d failed: %v\n", fd.Fd(), err) return nil, fuse.ToStatus(err) } wlock.register(st.Ino) return &file{ fd: fd, writeOnly: writeOnly, contentEnc: contentEnc, ino: st.Ino, loopbackFile: nodefs.NewLoopbackFile(fd), }, fuse.OK } // intFd - return the backing file descriptor as an integer. Used for debug // messages. func (f *file) intFd() int { return int(f.fd.Fd()) } func (f *file) InnerFile() nodefs.File { return nil } func (f *file) SetInode(n *nodefs.Inode) { } // readHeader - load the file header from disk // // Returns io.EOF if the file is empty func (f *file) readHeader() error { buf := make([]byte, contentenc.HeaderLen) _, err := f.fd.ReadAt(buf, 0) if err != nil { return err } h, err := contentenc.ParseHeader(buf) if err != nil { return err } f.header = h return nil } // createHeader - create a new random header and write it to disk func (f *file) createHeader() error { h := contentenc.RandomHeader() buf := h.Pack() // Prevent partially written (=corrupt) header by preallocating the space beforehand err := syscallcompat.EnospcPrealloc(int(f.fd.Fd()), 0, contentenc.HeaderLen) if err != nil { tlog.Warn.Printf("ino%d: createHeader: prealloc failed: %s\n", f.ino, err.Error()) return err } // Actually write header _, err = f.fd.WriteAt(buf, 0) if err != nil { return err } f.header = h return nil } func (f *file) String() string { return fmt.Sprintf("cryptFile(%s)", f.fd.Name()) } // doRead - returns "length" plaintext bytes from plaintext offset "off". // Arguments "length" and "off" do not have to be block-aligned. // // doRead reads the corresponding ciphertext blocks from disk, decrypts them and // returns the requested part of the plaintext. // // Called by Read() for normal reading, // by Write() and Truncate() for Read-Modify-Write func (f *file) doRead(off uint64, length uint64) ([]byte, fuse.Status) { // Read file header if f.header == nil { err := f.readHeader() if err == io.EOF { return nil, fuse.OK } if err != nil { return nil, fuse.ToStatus(err) } } // Read the backing ciphertext in one go blocks := f.contentEnc.ExplodePlainRange(off, length) alignedOffset, alignedLength := blocks[0].JointCiphertextRange(blocks) skip := blocks[0].Skip tlog.Debug.Printf("JointCiphertextRange(%d, %d) -> %d, %d, %d", off, length, alignedOffset, alignedLength, skip) ciphertext := make([]byte, int(alignedLength)) n, err := f.fd.ReadAt(ciphertext, int64(alignedOffset)) if err != nil && err != io.EOF { tlog.Warn.Printf("read: ReadAt: %s", err.Error()) return nil, fuse.ToStatus(err) } // Truncate ciphertext buffer down to actually read bytes ciphertext = ciphertext[0:n] firstBlockNo := blocks[0].BlockNo tlog.Debug.Printf("ReadAt offset=%d bytes (%d blocks), want=%d, got=%d", alignedOffset, firstBlockNo, alignedLength, n) // Decrypt it plaintext, err := f.contentEnc.DecryptBlocks(ciphertext, firstBlockNo, f.header.ID) if err != nil { curruptBlockNo := firstBlockNo + f.contentEnc.PlainOffToBlockNo(uint64(len(plaintext))) cipherOff := f.contentEnc.BlockNoToCipherOff(curruptBlockNo) plainOff := f.contentEnc.BlockNoToPlainOff(curruptBlockNo) tlog.Warn.Printf("ino%d: doRead: corrupt block #%d (plainOff=%d, cipherOff=%d)", f.ino, curruptBlockNo, plainOff, cipherOff) return nil, fuse.EIO } // Crop down to the relevant part var out []byte lenHave := len(plaintext) lenWant := int(skip + length) if lenHave > lenWant { out = plaintext[skip:lenWant] } else if lenHave > int(skip) { out = plaintext[skip:lenHave] } // else: out stays empty, file was smaller than the requested offset return out, fuse.OK } // Read - FUSE call func (f *file) Read(buf []byte, off int64) (resultData fuse.ReadResult, code fuse.Status) { f.fdLock.RLock() defer f.fdLock.RUnlock() tlog.Debug.Printf("ino%d: FUSE Read: offset=%d length=%d", f.ino, len(buf), off) if f.writeOnly { tlog.Warn.Printf("ino%d: Tried to read from write-only file", f.ino) return nil, fuse.EBADF } out, status := f.doRead(uint64(off), uint64(len(buf))) if status == fuse.EIO { tlog.Warn.Printf("ino%d: Read failed with EIO, offset=%d, length=%d", f.ino, len(buf), off) } if status != fuse.OK { return nil, status } tlog.Debug.Printf("ino%d: Read: status %v, returning %d bytes", f.ino, status, len(out)) return fuse.ReadResultData(out), status } // doWrite - encrypt "data" and write it to plaintext offset "off" // // Arguments do not have to be block-aligned, read-modify-write is // performed internally as necessary // // Called by Write() for normal writing, // and by Truncate() to rewrite the last file block. // // Empty writes do nothing and are allowed. func (f *file) doWrite(data []byte, off int64) (uint32, fuse.Status) { // Read header from disk, create a new one if the file is empty if f.header == nil { err := f.readHeader() if err == io.EOF { err = f.createHeader() } if err != nil { return 0, fuse.ToStatus(err) } } var written uint32 status := fuse.OK dataBuf := bytes.NewBuffer(data) blocks := f.contentEnc.ExplodePlainRange(uint64(off), uint64(len(data))) for _, b := range blocks { blockData := dataBuf.Next(int(b.Length)) // Incomplete block -> Read-Modify-Write if b.IsPartial() { // Read o := b.BlockPlainOff() var oldData []byte oldData, status = f.doRead(o, f.contentEnc.PlainBS()) if status != fuse.OK { tlog.Warn.Printf("ino%d fh%d: RMW read failed: %s", f.ino, f.intFd(), status.String()) return written, status } // Modify blockData = f.contentEnc.MergeBlocks(oldData, blockData, int(b.Skip)) tlog.Debug.Printf("len(oldData)=%d len(blockData)=%d", len(oldData), len(blockData)) } // Encrypt blockOffset := b.BlockCipherOff() blockData = f.contentEnc.EncryptBlock(blockData, b.BlockNo, f.header.ID) tlog.Debug.Printf("ino%d: Writing %d bytes to block #%d", f.ino, uint64(len(blockData))-f.contentEnc.BlockOverhead(), b.BlockNo) // Prevent partially written (=corrupt) blocks by preallocating the space beforehand err := syscallcompat.EnospcPrealloc(int(f.fd.Fd()), int64(blockOffset), int64(len(blockData))) if err != nil { tlog.Warn.Printf("ino%d fh%d: doWrite: prealloc failed: %s", f.ino, f.intFd(), err.Error()) status = fuse.ToStatus(err) break } // Write _, err = f.fd.WriteAt(blockData, int64(blockOffset)) if err != nil { tlog.Warn.Printf("doWrite: Write failed: %s", err.Error()) status = fuse.ToStatus(err) break } written += uint32(b.Length) } return written, status } // isConsecutiveWrite returns true if the current write // directly (in time and space) follows the last write. // This is an optimisation for streaming writes on NFS where a // Stat() call is very expensive. // The caller must "wlock.lock(f.ino)" otherwise this check would be racy. func (f *file) isConsecutiveWrite(off int64) bool { opCount := atomic.LoadUint64(&wlock.opCount) return opCount == f.lastOpCount+1 && off == f.lastWrittenOffset+1 } // Write - FUSE call // // If the write creates a hole, pads the file to the next block boundary. func (f *file) Write(data []byte, off int64) (uint32, fuse.Status) { f.fdLock.RLock() defer f.fdLock.RUnlock() if f.released { // The file descriptor has been closed concurrently, which also means // the wlock has been freed. Exit here so we don't crash trying to access // it. tlog.Warn.Printf("ino%d fh%d: Write on released file", f.ino, f.intFd()) return 0, fuse.EBADF } wlock.lock(f.ino) defer wlock.unlock(f.ino) tlog.Debug.Printf("ino%d: FUSE Write: offset=%d length=%d", f.ino, off, len(data)) // If the write creates a file hole, we have to zero-pad the last block. // But if the write directly follows an earlier write, it cannot create a // hole, and we can save one Stat() call. if !f.isConsecutiveWrite(off) { status := f.writePadHole(off) if !status.Ok() { return 0, status } } n, status := f.doWrite(data, off) if status.Ok() { f.lastOpCount = atomic.LoadUint64(&wlock.opCount) f.lastWrittenOffset = off + int64(len(data)) - 1 } return n, status } // Release - FUSE call, close file func (f *file) Release() { f.fdLock.Lock() if f.released { log.Panicf("ino%d fh%d: double release", f.ino, f.intFd()) } f.fd.Close() f.released = true f.fdLock.Unlock() wlock.unregister(f.ino) } // Flush - FUSE call func (f *file) Flush() fuse.Status { f.fdLock.RLock() defer f.fdLock.RUnlock() // Since Flush() may be called for each dup'd fd, we don't // want to really close the file, we just want to flush. This // is achieved by closing a dup'd fd. newFd, err := syscall.Dup(int(f.fd.Fd())) if err != nil { return fuse.ToStatus(err) } err = syscall.Close(newFd) return fuse.ToStatus(err) } func (f *file) Fsync(flags int) (code fuse.Status) { f.fdLock.RLock() defer f.fdLock.RUnlock() return fuse.ToStatus(syscall.Fsync(int(f.fd.Fd()))) } func (f *file) Chmod(mode uint32) fuse.Status { f.fdLock.RLock() defer f.fdLock.RUnlock() // os.File.Chmod goes through the "syscallMode" translation function that messes // up the suid and sgid bits. So use syscall.Fchmod directly. err := syscall.Fchmod(f.intFd(), mode) return fuse.ToStatus(err) } func (f *file) Chown(uid uint32, gid uint32) fuse.Status { f.fdLock.RLock() defer f.fdLock.RUnlock() return fuse.ToStatus(f.fd.Chown(int(uid), int(gid))) } func (f *file) GetAttr(a *fuse.Attr) fuse.Status { f.fdLock.RLock() defer f.fdLock.RUnlock() tlog.Debug.Printf("file.GetAttr()") st := syscall.Stat_t{} err := syscall.Fstat(int(f.fd.Fd()), &st) if err != nil { return fuse.ToStatus(err) } a.FromStat(&st) a.Size = f.contentEnc.CipherSizeToPlainSize(a.Size) return fuse.OK } // BrokenAtime means that atime support is broken. // TODO drop this once https://github.com/hanwen/go-fuse/pull/131 is // merged const BrokenAtime = true func (f *file) Utimens(a *time.Time, m *time.Time) fuse.Status { if BrokenAtime { if m == nil { tlog.Warn.Printf("refusing to set the atime to prevent a crash in go-fuse") return fuse.EINVAL } // Due to a bug in loopbackFile.Utimens, the "a" value will be used // to set both mtime and atime. Because mtime is more important, we // override "a". a = m } f.fdLock.RLock() defer f.fdLock.RUnlock() return f.loopbackFile.Utimens(a, m) }