package main import ( "C" "crypto/cipher" "crypto/aes" "syscall" "strings" "bytes" "unsafe" "os" "io" "fmt" "path/filepath" "golang.org/x/sys/unix" "./gocryptfs_internal/cryptocore" "./gocryptfs_internal/stupidgcm" "./gocryptfs_internal/eme" "./gocryptfs_internal/nametransform" "./rewrites/syscallcompat" "./rewrites/configfile" "./rewrites/contentenc" ) const ( file_mode = uint32(0660) folder_mode = uint32(0770) ) type Directory struct { fd int iv []byte } type File struct { fd *os.File path string } type SessionVars struct { root_cipher_dir string nameTransform *nametransform.NameTransform cryptoCore *cryptocore.CryptoCore contentEnc *contentenc.ContentEnc dirCache map[string]Directory file_handles map[int]File fileIDs map[int][]byte } var sessions map[int]SessionVars func err_to_bool(e error) bool { if e == nil { return true } return false } func wipe(d []byte){ for i := range d { d[i] = 0 } d = nil } func clear_dirCache(sessionID int) { for k, _ := range sessions[sessionID].dirCache { delete(sessions[sessionID].dirCache, k) } } func openBackingDir(sessionID int, relPath string) (dirfd int, cName string, err error) { dirRelPath := nametransform.Dir(relPath) dir, ok := sessions[sessionID].dirCache[dirRelPath] if ok { // If relPath is empty, cName is ".". if relPath == "" { cache_dirfd, err := syscall.Dup(dir.fd) if err != nil { return -1, "", err } return cache_dirfd, ".", nil } name := filepath.Base(relPath) cName, err = sessions[sessionID].nameTransform.EncryptAndHashName(name, dir.iv) if err != nil { syscall.Close(dir.fd) return -1, "", err } cache_dirfd, err := syscall.Dup(dir.fd) if err != nil { return -1, "", err } return cache_dirfd, cName, nil } // Open cipherdir (following symlinks) dirfd, err = syscall.Open(sessions[sessionID].root_cipher_dir, syscall.O_DIRECTORY|syscallcompat.O_PATH, 0) if err != nil { return -1, "", err } // If relPath is empty, cName is ".". if relPath == "" { return dirfd, ".", nil } // Walk the directory tree parts := strings.Split(relPath, "/") for i, name := range parts { iv, err := nametransform.ReadDirIVAt(dirfd) if err != nil { syscall.Close(dirfd) return -1, "", err } cName, err = sessions[sessionID].nameTransform.EncryptAndHashName(name, iv) if err != nil { syscall.Close(dirfd) return -1, "", err } // Last part? We are done. if i == len(parts)-1 { cache_dirfd, err := syscall.Dup(dirfd) if err == nil { var dirRelPathCopy strings.Builder dirRelPathCopy.WriteString(dirRelPath) sessions[sessionID].dirCache[dirRelPathCopy.String()] = Directory{cache_dirfd, iv} } break } // Not the last part? Descend into next directory. dirfd2, err := syscallcompat.Openat(dirfd, cName, syscall.O_NOFOLLOW|syscall.O_DIRECTORY|syscallcompat.O_PATH, 0) syscall.Close(dirfd) if err != nil { return -1, "", err } dirfd = dirfd2 } return dirfd, cName, nil } func mkdirWithIv(dirfd int, cName string, mode uint32) error { err := syscallcompat.Mkdirat(dirfd, cName, mode) if err != nil { return err } dirfd2, err := syscallcompat.Openat(dirfd, cName, syscall.O_DIRECTORY|syscall.O_NOFOLLOW|syscallcompat.O_PATH, 0) if err == nil { // Create gocryptfs.diriv err = nametransform.WriteDirIVAt(dirfd2) syscall.Close(dirfd2) } if err != nil { // Delete inconsistent directory (missing gocryptfs.diriv!) err2 := syscallcompat.Unlinkat(dirfd, cName, unix.AT_REMOVEDIR) if err2 != nil { return err2 } } return err } func mangleOpenFlags(flags uint32) (newFlags int) { newFlags = int(flags) // Convert WRONLY to RDWR. We always need read access to do read-modify-write cycles. if (newFlags & syscall.O_ACCMODE) == syscall.O_WRONLY { newFlags = newFlags ^ os.O_WRONLY | os.O_RDWR } // We also cannot open the file in append mode, we need to seek back for RMW newFlags = newFlags &^ os.O_APPEND // O_DIRECT accesses must be aligned in both offset and length. Due to our // crypto header, alignment will be off, even if userspace makes aligned // accesses. Running xfstests generic/013 on ext4 used to trigger lots of // EINVAL errors due to missing alignment. Just fall back to buffered IO. newFlags = newFlags &^ syscallcompat.O_DIRECT // Create and Open are two separate FUSE operations, so O_CREAT should not // be part of the open flags. newFlags = newFlags &^ syscall.O_CREAT // We always want O_NOFOLLOW to be safe against symlink races newFlags |= syscall.O_NOFOLLOW return newFlags } func register_file_handle(sessionID int, file File) int { handleID := -1 c := 0 for handleID == -1 { _, ok := sessions[sessionID].file_handles[c] if !ok { handleID = c } c++ } sessions[sessionID].file_handles[handleID] = file return handleID } func readFileID(fd *os.File) ([]byte, error) { // We read +1 byte to determine if the file has actual content // and not only the header. A header-only file will be considered empty. // This makes File ID poisoning more difficult. readLen := contentenc.HeaderLen + 1 buf := make([]byte, readLen) _, err := fd.ReadAt(buf, 0) if err != nil { return nil, err } buf = buf[:contentenc.HeaderLen] h, err := contentenc.ParseHeader(buf) if err != nil { return nil, err } return h.ID, nil } func createHeader(fd *os.File) (fileID []byte, err error) { h := contentenc.RandomHeader() buf := h.Pack() // Prevent partially written (=corrupt) header by preallocating the space beforehand //NoPrealloc err = syscallcompat.EnospcPrealloc(int(fd.Fd()), 0, contentenc.HeaderLen) if err != nil { return nil, err } // Actually write header _, err = fd.WriteAt(buf, 0) if err != nil { return nil, err } return h.ID, err } func doRead(sessionID, handleID int, dst_buff []byte, offset uint64, length uint64) ([]byte, bool) { f, ok := sessions[sessionID].file_handles[handleID] if !ok { return nil, false } fd := f.fd var fileID []byte test_fileID, ok := sessions[sessionID].fileIDs[handleID] if ok { fileID = test_fileID } else { var err error fileID, err = readFileID(fd) if err != nil || fileID == nil { return nil, false } sessions[sessionID].fileIDs[handleID] = fileID } // Read the backing ciphertext in one go blocks := sessions[sessionID].contentEnc.ExplodePlainRange(offset, length) alignedOffset, alignedLength := blocks[0].JointCiphertextRange(blocks) skip := blocks[0].Skip ciphertext := sessions[sessionID].contentEnc.CReqPool.Get() ciphertext = ciphertext[:int(alignedLength)] n, err := fd.ReadAt(ciphertext, int64(alignedOffset)) if err != nil && err != io.EOF { return nil, false } // The ReadAt came back empty. We can skip all the decryption and return early. if n == 0 { sessions[sessionID].contentEnc.CReqPool.Put(ciphertext) return dst_buff, true } // Truncate ciphertext buffer down to actually read bytes ciphertext = ciphertext[0:n] firstBlockNo := blocks[0].BlockNo // Decrypt it plaintext, err := sessions[sessionID].contentEnc.DecryptBlocks(ciphertext, firstBlockNo, fileID) sessions[sessionID].contentEnc.CReqPool.Put(ciphertext) if err != nil { return nil, false } // 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 out = append(dst_buff, out...) sessions[sessionID].contentEnc.PReqPool.Put(plaintext) return out, true } func doWrite(sessionID, handleID int, data []byte, offset uint64) (uint32, bool){ fileWasEmpty := false f, ok := sessions[sessionID].file_handles[handleID] if !ok { return 0, false } fd := f.fd var err error var fileID []byte test_fileID, ok := sessions[sessionID].fileIDs[handleID] if ok { fileID = test_fileID } else { fileID, err = readFileID(fd) // Write a new file header if the file is empty if err == io.EOF { fileID, err = createHeader(fd) fileWasEmpty = true } if err != nil { return 0, false } sessions[sessionID].fileIDs[handleID] = fileID } // Handle payload data dataBuf := bytes.NewBuffer(data) blocks := sessions[sessionID].contentEnc.ExplodePlainRange(offset, uint64(len(data))) toEncrypt := make([][]byte, len(blocks)) for i, b := range blocks { blockData := dataBuf.Next(int(b.Length)) // Incomplete block -> Read-Modify-Write if b.IsPartial() { // Read oldData, success := doRead(sessionID, handleID, nil, b.BlockPlainOff(), sessions[sessionID].contentEnc.PlainBS()) if !success { return 0, false } // Modify blockData = sessions[sessionID].contentEnc.MergeBlocks(oldData, blockData, int(b.Skip)) } // Write into the to-encrypt list toEncrypt[i] = blockData } // Encrypt all blocks ciphertext := sessions[sessionID].contentEnc.EncryptBlocks(toEncrypt, blocks[0].BlockNo, fileID) // Preallocate so we cannot run out of space in the middle of the write. // This prevents partially written (=corrupt) blocks. cOff := int64(blocks[0].BlockCipherOff()) //NoPrealloc err = syscallcompat.EnospcPrealloc(int(fd.Fd()), cOff, int64(len(ciphertext))) if err != nil { if fileWasEmpty { syscall.Ftruncate(int(fd.Fd()), 0) // Kill the file header again gcf_close_file(sessionID, handleID) //f.fileTableEntry.ID = nil } return 0, false } // Write _, err = fd.WriteAt(ciphertext, cOff) // Return memory to CReqPool sessions[sessionID].contentEnc.CReqPool.Put(ciphertext) if err != nil { return 0, false } return uint32(len(data)), true } // Zero-pad the file of size plainSize to the next block boundary. This is a no-op // if the file is already block-aligned. func zeroPad(sessionID, handleID int, plainSize uint64) bool { lastBlockLen := plainSize % sessions[sessionID].contentEnc.PlainBS() if lastBlockLen == 0 { // Already block-aligned return true } missing := sessions[sessionID].contentEnc.PlainBS() - lastBlockLen pad := make([]byte, missing) _, success := doWrite(sessionID, handleID, pad, plainSize) return success } // truncateGrowFile extends a file using seeking or ftruncate performing RMW on // the first and last block as necessary. New blocks in the middle become // file holes unless they have been fallocate()'d beforehand. func truncateGrowFile(sessionID, handleID int, oldPlainSz uint64, newPlainSz uint64) bool { if newPlainSz <= oldPlainSz { return false } newEOFOffset := newPlainSz - 1 if oldPlainSz > 0 { n1 := sessions[sessionID].contentEnc.PlainOffToBlockNo(oldPlainSz - 1) n2 := sessions[sessionID].contentEnc.PlainOffToBlockNo(newEOFOffset) // The file is grown within one block, no need to pad anything. // Write a single zero to the last byte and let doWrite figure out the RMW. if n1 == n2 { buf := make([]byte, 1) _, success := doWrite(sessionID, handleID, buf, newEOFOffset) return success } } // The truncate creates at least one new block. // // Make sure the old last block is padded to the block boundary. This call // is a no-op if it is already block-aligned. success := zeroPad(sessionID, handleID, oldPlainSz) if !success { return false } // The new size is block-aligned. In this case we can do everything ourselves // and avoid the call to doWrite. if newPlainSz%sessions[sessionID].contentEnc.PlainBS() == 0 { // The file was empty, so it did not have a header. Create one. if oldPlainSz == 0 { id, err := createHeader(sessions[sessionID].file_handles[handleID].fd) if err != nil { return false } sessions[sessionID].fileIDs[handleID] = id } cSz := int64(sessions[sessionID].contentEnc.PlainSizeToCipherSize(newPlainSz)) return err_to_bool(syscall.Ftruncate(int(sessions[sessionID].file_handles[handleID].fd.Fd()), cSz)) } // The new size is NOT aligned, so we need to write a partial block. // Write a single zero to the last byte and let doWrite figure it out. buf := make([]byte, 1) _, success = doWrite(sessionID, handleID, buf, newEOFOffset) return success } func truncate(sessionID, handleID int, newSize uint64) bool { fileFD := int(sessions[sessionID].file_handles[handleID].fd.Fd()) /*// Common case first: Truncate to zero if newSize == 0 { err = syscall.Ftruncate(fileFD, 0) if err != nil { return false } // Truncate to zero kills the file header f.fileTableEntry.ID = nil return true }*/ // We need the old file size to determine if we are growing or shrinking // the file oldSize, _, success := gcf_get_attrs(sessionID, sessions[sessionID].file_handles[handleID].path) if !success { return false } // File size stays the same - nothing to do if newSize == oldSize { return true } // File grows if newSize > oldSize { return truncateGrowFile(sessionID, handleID, oldSize, newSize) } // File shrinks blockNo := sessions[sessionID].contentEnc.PlainOffToBlockNo(newSize) cipherOff := sessions[sessionID].contentEnc.BlockNoToCipherOff(blockNo) plainOff := sessions[sessionID].contentEnc.BlockNoToPlainOff(blockNo) lastBlockLen := newSize - plainOff var data []byte if lastBlockLen > 0 { data, success = doRead(sessionID, handleID, nil, plainOff, lastBlockLen) if !success { return false } } // Truncate down to the last complete block err := syscall.Ftruncate(fileFD, int64(cipherOff)) if err != nil { return false } // Append partial block if lastBlockLen > 0 { _, success := doWrite(sessionID, handleID, data, plainOff) return success } return true } func init_new_session(root_cipher_dir string, masterkey []byte) int { // Initialize EME for filename encryption. var emeCipher *eme.EMECipher var err error var emeBlockCipher cipher.Block emeKey := cryptocore.HkdfDerive(masterkey, cryptocore.HkdfInfoEMENames, cryptocore.KeyLen) emeBlockCipher, err = aes.NewCipher(emeKey) for i := range emeKey { emeKey[i] = 0 } if err == nil { var new_session SessionVars emeCipher = eme.New(emeBlockCipher) new_session.nameTransform = nametransform.New(emeCipher, true, true) // Initialize contentEnc cryptoBackend := cryptocore.BackendGoGCM if stupidgcm.PreferOpenSSL() { cryptoBackend = cryptocore.BackendOpenSSL } forcedecode := false new_session.cryptoCore = cryptocore.New(masterkey, cryptoBackend, contentenc.DefaultIVBits, true, forcedecode) new_session.contentEnc = contentenc.New(new_session.cryptoCore, contentenc.DefaultBS, forcedecode) //copying root_cipher_dir var grcd strings.Builder grcd.WriteString(root_cipher_dir) new_session.root_cipher_dir = grcd.String() // New empty caches new_session.dirCache = make(map[string]Directory) new_session.file_handles = make(map[int]File) new_session.fileIDs = make(map[int][]byte) //find unused sessionID sessionID := -1 c := 0 for sessionID == -1 { _, ok := sessions[c] if !ok { sessionID = c } c++ } if sessions == nil { sessions = make(map[int]SessionVars) } sessions[sessionID] = new_session; return sessionID } return -1 } //export gcf_init func gcf_init(root_cipher_dir string, password, givenScryptHash, returnedScryptHashBuff []byte) int { sessionID := -1 cf, err := configfile.Load(filepath.Join(root_cipher_dir, configfile.ConfDefaultName)) if err == nil { masterkey := cf.GetMasterkey(password, givenScryptHash, returnedScryptHashBuff) if masterkey != nil { sessionID = init_new_session(root_cipher_dir, masterkey) wipe(masterkey) } } return sessionID } //export gcf_close func gcf_close(sessionID int){ sessions[sessionID].cryptoCore.Wipe() for handleID, _ := range sessions[sessionID].file_handles { gcf_close_file(sessionID, handleID) } clear_dirCache(sessionID) delete(sessions, sessionID) } //export gcf_create_volume func gcf_create_volume(root_cipher_dir string, password []byte, logN int, creator string) bool { err := configfile.Create(filepath.Join(root_cipher_dir, configfile.ConfDefaultName), password, false, logN, creator, false, false) if err == nil { dirfd, err := syscall.Open(root_cipher_dir, syscall.O_DIRECTORY|syscallcompat.O_PATH, 0) if err == nil { err = nametransform.WriteDirIVAt(dirfd) syscall.Close(dirfd) return err_to_bool(err) } } return false } //export gcf_change_password func gcf_change_password(root_cipher_dir string, old_password, givenScryptHash, new_password, returnedScryptHashBuff []byte) bool { success := false cf, err := configfile.Load(filepath.Join(root_cipher_dir, configfile.ConfDefaultName)) if err == nil { masterkey := cf.GetMasterkey(old_password, givenScryptHash, nil) if masterkey != nil { logN := cf.ScryptObject.LogN() scryptHash := cf.EncryptKey(masterkey, new_password, logN, len(returnedScryptHashBuff)>0) wipe(masterkey) for i := range scryptHash { returnedScryptHashBuff[i] = scryptHash[i] scryptHash[i] = 0 } success = err_to_bool(cf.WriteFile()) } } return success } //export gcf_list_dir func gcf_list_dir(sessionID int, dirName string) (*C.char, *C.int, C.int) { parentDirFd, cDirName, err := openBackingDir(sessionID, dirName) if err != nil { return nil, nil, 0 } defer syscall.Close(parentDirFd) // Read ciphertext directory var cipherEntries []syscallcompat.DirEntry fd, err := syscallcompat.Openat(parentDirFd, cDirName, syscall.O_RDONLY|syscall.O_DIRECTORY|syscall.O_NOFOLLOW, 0) if err != nil { return nil, nil, 0 } defer syscall.Close(fd) cipherEntries, err = syscallcompat.Getdents(fd) if err != nil { return nil, nil, 0 } // Get DirIV (stays nil if PlaintextNames is used) var cachedIV []byte // Read the DirIV from disk cachedIV, err = nametransform.ReadDirIVAt(fd) if err != nil { return nil, nil, 0 } // Decrypted directory entries var plain strings.Builder var modes []uint32 // Filter and decrypt filenames for i := range cipherEntries { cName := cipherEntries[i].Name if dirName == "" && cName == configfile.ConfDefaultName { // silently ignore "gocryptfs.conf" in the top level dir continue } if cName == nametransform.DirIVFilename { // silently ignore "gocryptfs.diriv" everywhere if dirIV is enabled continue } // Handle long file name isLong := nametransform.NameType(cName) if isLong == nametransform.LongNameContent { cNameLong, err := nametransform.ReadLongNameAt(fd, cName) if err != nil { continue } cName = cNameLong } else if isLong == nametransform.LongNameFilename { // ignore "gocryptfs.longname.*.name" continue } name, err := sessions[sessionID].nameTransform.DecryptName(cName, cachedIV) if err != nil { continue } // Override the ciphertext name with the plaintext name but reuse the rest // of the structure cipherEntries[i].Name = name plain.WriteString(cipherEntries[i].Name+"\x00") modes = append(modes, cipherEntries[i].Mode) } p := C.malloc(C.ulong(C.sizeof_int*len(modes))) for i := 0; i < len(modes); i++ { offset := C.sizeof_int*uintptr(i) *(*C.int)(unsafe.Pointer(uintptr(p)+offset)) = (C.int)(modes[i]) } return C.CString(plain.String()), (*C.int)(p), (C.int)(len(modes)) } //export gcf_mkdir func gcf_mkdir(sessionID int, newPath string) bool { dirfd, cName, err := openBackingDir(sessionID, newPath) if err != nil { return false } defer syscall.Close(dirfd) // We need write and execute permissions to create gocryptfs.diriv. // Also, we need read permissions to open the directory (to avoid // race-conditions between getting and setting the mode). origMode := folder_mode mode := folder_mode | 0700 // Handle long file name if nametransform.IsLongContent(cName) { // Create ".name" err = sessions[sessionID].nameTransform.WriteLongNameAt(dirfd, cName, newPath) if err != nil { return false } // Create directory err = mkdirWithIv(dirfd, cName, mode) if err != nil { nametransform.DeleteLongNameAt(dirfd, cName) return false } } else { err = mkdirWithIv(dirfd, cName, mode) if err != nil { return false } } // Set mode if origMode != mode { dirfd2, err := syscallcompat.Openat(dirfd, cName, syscall.O_RDONLY|syscall.O_DIRECTORY|syscall.O_NOFOLLOW, 0) if err != nil { return false } defer syscall.Close(dirfd2) var st syscall.Stat_t err = syscall.Fstat(dirfd2, &st) if err != nil { return false } // Preserve SGID bit if it was set due to inheritance. origMode = uint32(st.Mode&^0777) | origMode err = syscall.Fchmod(dirfd2, origMode) if err != nil { return false } } return true } //export gcf_rmdir func gcf_rmdir(sessionID int, relPath string) bool { defer clear_dirCache(sessionID) parentDirFd, cName, err := openBackingDir(sessionID, relPath) if err != nil { return false } defer syscall.Close(parentDirFd) dirfd, err := syscallcompat.Openat(parentDirFd, cName, syscall.O_RDONLY|syscall.O_DIRECTORY|syscall.O_NOFOLLOW, 0) if err != nil { return false } defer syscall.Close(dirfd) // Check directory contents children, err := syscallcompat.Getdents(dirfd) if err == io.EOF { // The directory is empty err = unix.Unlinkat(parentDirFd, cName, unix.AT_REMOVEDIR) return err_to_bool(err) } if err != nil { return false } // If the directory is not empty besides gocryptfs.diriv, do not even // attempt the dance around gocryptfs.diriv. if len(children) > 1 { return false } // Move "gocryptfs.diriv" to the parent dir as "gocryptfs.diriv.rmdir.XYZ" tmpName := fmt.Sprintf("%s.rmdir.%d", nametransform.DirIVFilename, cryptocore.RandUint64()) err = syscallcompat.Renameat(dirfd, nametransform.DirIVFilename, parentDirFd, tmpName) if err != nil { return false } // Actual Rmdir err = syscallcompat.Unlinkat(parentDirFd, cName, unix.AT_REMOVEDIR) if err != nil { // This can happen if another file in the directory was created in the // meantime, undo the rename err2 := syscallcompat.Renameat(parentDirFd, tmpName, dirfd, nametransform.DirIVFilename) return err_to_bool(err2) } // Delete "gocryptfs.diriv.rmdir.XYZ" err = syscallcompat.Unlinkat(parentDirFd, tmpName, 0) // Delete .name file if nametransform.IsLongContent(cName) { nametransform.DeleteLongNameAt(parentDirFd, cName) } return true } //export gcf_open_read_mode func gcf_open_read_mode(sessionID int, path string) int { newFlags := mangleOpenFlags(0) dirfd, cName, err := openBackingDir(sessionID, path) if err != nil { return -1 } defer syscall.Close(dirfd) fd, err := syscallcompat.Openat(dirfd, cName, newFlags, 0) if err != nil { return -1 } return register_file_handle(sessionID, File{os.NewFile(uintptr(fd), cName), path}) } //export gcf_open_write_mode func gcf_open_write_mode(sessionID int, path string) int { newFlags := mangleOpenFlags(syscall.O_RDWR) dirfd, cName, err := openBackingDir(sessionID, path) if err != nil { return -1 } defer syscall.Close(dirfd) fd := -1 // Handle long file name if nametransform.IsLongContent(cName) { // Create ".name" err = sessions[sessionID].nameTransform.WriteLongNameAt(dirfd, cName, path) if err != nil { return -1 } // Create content fd, err = syscallcompat.Openat(dirfd, cName, newFlags|syscall.O_CREAT, file_mode) if err != nil { nametransform.DeleteLongNameAt(dirfd, cName) } } else { // Create content, normal (short) file name fd, err = syscallcompat.Openat(dirfd, cName, newFlags|syscall.O_CREAT, file_mode) } if err != nil { // xfstests generic/488 triggers this if err == syscall.EMFILE { var lim syscall.Rlimit syscall.Getrlimit(syscall.RLIMIT_NOFILE, &lim) } return -1 } return register_file_handle(sessionID, File{os.NewFile(uintptr(fd), cName), path}) } //export gcf_truncate func gcf_truncate(sessionID int, path string, offset uint64) bool { handleID := gcf_open_write_mode(sessionID, path) if handleID != -1 { success := truncate(sessionID, handleID, offset) gcf_close_file(sessionID, handleID) return success } return false } //export gcf_close_file func gcf_close_file(sessionID, handleID int){ f, ok := sessions[sessionID].file_handles[handleID] if ok { f.fd.Close() delete(sessions[sessionID].file_handles, handleID) _, ok := sessions[sessionID].fileIDs[handleID] if ok { delete(sessions[sessionID].fileIDs, handleID) } } } //export gcf_read_file func gcf_read_file(sessionID, handleID int, offset uint64, dst_buff []byte) uint32 { length := uint64(len(dst_buff)) if length > contentenc.MAX_KERNEL_WRITE { return 0; } out, _ := doRead(sessionID, handleID, dst_buff[:0], offset, length) return uint32(len(out)) } //export gcf_write_file func gcf_write_file(sessionID, handleID int, offset uint64, data []byte) uint32 { length := uint64(len(data)) if length > contentenc.MAX_KERNEL_WRITE { return 0; } written, _ := doWrite(sessionID, handleID, data, offset) return written } //export gcf_get_attrs func gcf_get_attrs(sessionID int, relPath string) (uint64, int64, bool) { dirfd, cName, err := openBackingDir(sessionID, relPath) if err != nil { return 0, 0, false } var st unix.Stat_t err = syscallcompat.Fstatat(dirfd, cName, &st, unix.AT_SYMLINK_NOFOLLOW) syscall.Close(dirfd) if err != nil { return 0, 0, false } return sessions[sessionID].contentEnc.CipherSizeToPlainSize(uint64(st.Size)), st.Mtim.Sec, true } //export gcf_rename func gcf_rename(sessionID int, oldPath string, newPath string) bool { defer clear_dirCache(sessionID) oldDirfd, oldCName, err := openBackingDir(sessionID, oldPath) if err != nil { return false } defer syscall.Close(oldDirfd) newDirfd, newCName, err := openBackingDir(sessionID, newPath) if err != nil { return false } defer syscall.Close(newDirfd) // Long destination file name: create .name file nameFileAlreadyThere := false if nametransform.IsLongContent(newCName) { err = sessions[sessionID].nameTransform.WriteLongNameAt(newDirfd, newCName, newPath) // Failure to write the .name file is expected when the target path already // exists. Since hashes are pretty unique, there is no need to modify the // .name file in this case, and we ignore the error. if err == syscall.EEXIST { nameFileAlreadyThere = true } else if err != nil { return false } } // Actual rename err = syscallcompat.Renameat(oldDirfd, oldCName, newDirfd, newCName) if err == syscall.ENOTEMPTY || err == syscall.EEXIST { // If an empty directory is overwritten we will always get an error as // the "empty" directory will still contain gocryptfs.diriv. // Interestingly, ext4 returns ENOTEMPTY while xfs returns EEXIST. // We handle that by trying to fs.Rmdir() the target directory and trying // again. if gcf_rmdir(sessionID, newPath) { err = syscallcompat.Renameat(oldDirfd, oldCName, newDirfd, newCName) } } if err != nil { if nametransform.IsLongContent(newCName) && nameFileAlreadyThere == false { // Roll back .name creation unless the .name file was already there nametransform.DeleteLongNameAt(newDirfd, newCName) } return false } if nametransform.IsLongContent(oldCName) { nametransform.DeleteLongNameAt(oldDirfd, oldCName) } return true } //export gcf_remove_file func gcf_remove_file(sessionID int, path string) bool { dirfd, cName, err := openBackingDir(sessionID, path) if err != nil { return false } defer syscall.Close(dirfd) // Delete content err = syscallcompat.Unlinkat(dirfd, cName, 0) if err != nil { return false } // Delete ".name" file if nametransform.IsLongContent(cName) { err = nametransform.DeleteLongNameAt(dirfd, cName) } return err_to_bool(err) } func main(){}