// Package operations does generic operations on filesystems and objects package operations import ( "bytes" "context" "encoding/base64" "encoding/csv" "encoding/hex" "encoding/json" "errors" "fmt" "io" "mime" "net/http" "os" "path" "path/filepath" "runtime" "sort" "strconv" "strings" "sync" "sync/atomic" "time" "github.com/rclone/rclone/fs" "github.com/rclone/rclone/fs/accounting" "github.com/rclone/rclone/fs/cache" "github.com/rclone/rclone/fs/config" "github.com/rclone/rclone/fs/filter" "github.com/rclone/rclone/fs/fserrors" "github.com/rclone/rclone/fs/fshttp" "github.com/rclone/rclone/fs/hash" "github.com/rclone/rclone/fs/object" "github.com/rclone/rclone/fs/walk" "github.com/rclone/rclone/lib/atexit" "github.com/rclone/rclone/lib/errcount" "github.com/rclone/rclone/lib/random" "github.com/rclone/rclone/lib/readers" "golang.org/x/sync/errgroup" "golang.org/x/text/unicode/norm" ) // CheckHashes checks the two files to see if they have common // known hash types and compares them // // Returns. // // equal - which is equality of the hashes // // hash - the HashType. This is HashNone if either of the hashes were // unset or a compatible hash couldn't be found. // // err - may return an error which will already have been logged // // If an error is returned it will return equal as false func CheckHashes(ctx context.Context, src fs.ObjectInfo, dst fs.Object) (equal bool, ht hash.Type, err error) { common := src.Fs().Hashes().Overlap(dst.Fs().Hashes()) // fs.Debugf(nil, "Shared hashes: %v", common) if common.Count() == 0 { return true, hash.None, nil } equal, ht, _, _, err = checkHashes(ctx, src, dst, common.GetOne()) return equal, ht, err } var errNoHash = errors.New("no hash available") // checkHashes does the work of CheckHashes but takes a hash.Type and // returns the effective hash type used. func checkHashes(ctx context.Context, src fs.ObjectInfo, dst fs.Object, ht hash.Type) (equal bool, htOut hash.Type, srcHash, dstHash string, err error) { // Calculate hashes in parallel g, ctx := errgroup.WithContext(ctx) var srcErr, dstErr error g.Go(func() (err error) { srcHash, srcErr = src.Hash(ctx, ht) if srcErr != nil { return srcErr } if srcHash == "" { fs.Debugf(src, "Src hash empty - aborting Dst hash check") return errNoHash } return nil }) g.Go(func() (err error) { dstHash, dstErr = dst.Hash(ctx, ht) if dstErr != nil { return dstErr } if dstHash == "" { fs.Debugf(dst, "Dst hash empty - aborting Src hash check") return errNoHash } return nil }) err = g.Wait() if err == errNoHash { return true, hash.None, srcHash, dstHash, nil } if srcErr != nil { err = fs.CountError(srcErr) fs.Errorf(src, "Failed to calculate src hash: %v", err) } if dstErr != nil { err = fs.CountError(dstErr) fs.Errorf(dst, "Failed to calculate dst hash: %v", err) } if err != nil { return false, ht, srcHash, dstHash, err } if srcHash != dstHash { fs.Debugf(src, "%v = %s (%v)", ht, srcHash, src.Fs()) fs.Debugf(dst, "%v = %s (%v)", ht, dstHash, dst.Fs()) } else { fs.Debugf(src, "%v = %s OK", ht, srcHash) } return srcHash == dstHash, ht, srcHash, dstHash, nil } // Equal checks to see if the src and dst objects are equal by looking at // size, mtime and hash // // If the src and dst size are different then it is considered to be // not equal. If --size-only is in effect then this is the only check // that is done. If --ignore-size is in effect then this check is // skipped and the files are considered the same size. // // If the size is the same and the mtime is the same then it is // considered to be equal. This check is skipped if using --checksum. // // If the size is the same and mtime is different, unreadable or // --checksum is set and the hash is the same then the file is // considered to be equal. In this case the mtime on the dst is // updated if --checksum is not set. // // Otherwise the file is considered to be not equal including if there // were errors reading info. func Equal(ctx context.Context, src fs.ObjectInfo, dst fs.Object) bool { return equal(ctx, src, dst, defaultEqualOpt(ctx)) } // DirsEqual is like Equal but for dirs instead of objects. // It returns true if two dirs should be considered "equal" for the purposes of syncCopyMove // (in other words, true == "skip updating modtime/metadata for this dir".) // Unlike Equal, it does not consider size or checksum, as these do not apply to directories. func DirsEqual(ctx context.Context, src, dst fs.Directory, opt DirsEqualOpt) (equal bool) { if dst == nil { return false } ci := fs.GetConfig(ctx) if ci.SizeOnly || ci.Immutable || ci.IgnoreExisting || opt.ModifyWindow == fs.ModTimeNotSupported { return true } if ci.IgnoreTimes { return false } if !(opt.SetDirModtime || opt.SetDirMetadata) { return true } srcModTime, dstModTime := src.ModTime(ctx), dst.ModTime(ctx) if srcModTime.IsZero() || dstModTime.IsZero() { return false } dt := dstModTime.Sub(srcModTime) if dt < opt.ModifyWindow && dt > -opt.ModifyWindow { fs.Debugf(dst, "Directory modification time the same (differ by %s, within tolerance %s)", dt, opt.ModifyWindow) return true } if ci.UpdateOlder && dt >= opt.ModifyWindow { fs.Debugf(dst, "Destination directory is newer than source, skipping") return true } return false } // sizeDiffers compare the size of src and dst taking into account the // various ways of ignoring sizes func sizeDiffers(ctx context.Context, src, dst fs.ObjectInfo) bool { ci := fs.GetConfig(ctx) if ci.IgnoreSize || src.Size() < 0 || dst.Size() < 0 { return false } return src.Size() != dst.Size() } var checksumWarning sync.Once // options for equal function() type equalOpt struct { sizeOnly bool // if set only check size checkSum bool // if set check checksum+size instead of modtime+size updateModTime bool // if set update the modtime if hashes identical and checking with modtime+size forceModTimeMatch bool // if set assume modtimes match } // default set of options for equal() func defaultEqualOpt(ctx context.Context) equalOpt { ci := fs.GetConfig(ctx) return equalOpt{ sizeOnly: ci.SizeOnly, checkSum: ci.CheckSum, updateModTime: !ci.NoUpdateModTime, forceModTimeMatch: false, } } // DirsEqualOpt represents options for DirsEqual function() type DirsEqualOpt struct { ModifyWindow time.Duration // Max time diff to be considered the same SetDirModtime bool // whether to consider dir modtime SetDirMetadata bool // whether to consider dir metadata } var modTimeUploadOnce sync.Once // emit a log if we are about to upload a file to set its modification time func logModTimeUpload(dst fs.Object) { modTimeUploadOnce.Do(func() { fs.Logf(dst.Fs(), "Forced to upload files to set modification times on this backend.") }) } // EqualFn allows replacing Equal() with a custom function during NeedTransfer() type EqualFn func(ctx context.Context, src fs.ObjectInfo, dst fs.Object) bool type equalFnContextKey struct{} var equalFnKey = equalFnContextKey{} // WithEqualFn stores equalFn in ctx and returns a copy of ctx in which equalFnKey = equalFn func WithEqualFn(ctx context.Context, equalFn EqualFn) context.Context { return context.WithValue(ctx, equalFnKey, equalFn) } func equal(ctx context.Context, src fs.ObjectInfo, dst fs.Object, opt equalOpt) bool { ci := fs.GetConfig(ctx) logger, _ := GetLogger(ctx) if sizeDiffers(ctx, src, dst) { fs.Debugf(src, "Sizes differ (src %d vs dst %d)", src.Size(), dst.Size()) logger(ctx, Differ, src, dst, nil) return false } if opt.sizeOnly { fs.Debugf(src, "Sizes identical") logger(ctx, Match, src, dst, nil) return true } // Assert: Size is equal or being ignored // If checking checksum and not modtime if opt.checkSum { // Check the hash same, ht, _ := CheckHashes(ctx, src, dst) if !same { fs.Debugf(src, "%v differ", ht) logger(ctx, Differ, src, dst, nil) return false } if ht == hash.None { common := src.Fs().Hashes().Overlap(dst.Fs().Hashes()) if common.Count() == 0 { checksumWarning.Do(func() { fs.Logf(dst.Fs(), "--checksum is in use but the source and destination have no hashes in common; falling back to --size-only") }) } fs.Debugf(src, "Size of src and dst objects identical") } else { fs.Debugf(src, "Size and %v of src and dst objects identical", ht) } logger(ctx, Match, src, dst, nil) return true } srcModTime := src.ModTime(ctx) if !opt.forceModTimeMatch { // Sizes the same so check the mtime modifyWindow := fs.GetModifyWindow(ctx, src.Fs(), dst.Fs()) if modifyWindow == fs.ModTimeNotSupported { fs.Debugf(src, "Sizes identical") logger(ctx, Match, src, dst, nil) return true } dstModTime := dst.ModTime(ctx) dt := dstModTime.Sub(srcModTime) if dt < modifyWindow && dt > -modifyWindow { fs.Debugf(src, "Size and modification time the same (differ by %s, within tolerance %s)", dt, modifyWindow) logger(ctx, Match, src, dst, nil) return true } fs.Debugf(src, "Modification times differ by %s: %v, %v", dt, srcModTime, dstModTime) } // Check if the hashes are the same same, ht, _ := CheckHashes(ctx, src, dst) if !same { fs.Debugf(src, "%v differ", ht) logger(ctx, Differ, src, dst, nil) return false } if ht == hash.None && !ci.RefreshTimes { // if couldn't check hash, return that they differ logger(ctx, Differ, src, dst, nil) return false } // mod time differs but hash is the same to reset mod time if required if opt.updateModTime { if !SkipDestructive(ctx, src, "update modification time") { // Size and hash the same but mtime different // Error if objects are treated as immutable if ci.Immutable { fs.Errorf(dst, "Timestamp mismatch between immutable objects") logger(ctx, Differ, src, dst, nil) return false } // Update the mtime of the dst object here err := dst.SetModTime(ctx, srcModTime) if errors.Is(err, fs.ErrorCantSetModTime) { logModTimeUpload(dst) fs.Infof(dst, "src and dst identical but can't set mod time without re-uploading") logger(ctx, Differ, src, dst, nil) return false } else if errors.Is(err, fs.ErrorCantSetModTimeWithoutDelete) { logModTimeUpload(dst) fs.Infof(dst, "src and dst identical but can't set mod time without deleting and re-uploading") // Remove the file if BackupDir isn't set. If BackupDir is set we would rather have the old file // put in the BackupDir than deleted which is what will happen if we don't delete it. if ci.BackupDir == "" { err = dst.Remove(ctx) if err != nil { fs.Errorf(dst, "failed to delete before re-upload: %v", err) } } logger(ctx, Differ, src, dst, nil) return false } else if err != nil { err = fs.CountError(err) fs.Errorf(dst, "Failed to set modification time: %v", err) } else { fs.Infof(src, "Updated modification time in destination") } } } logger(ctx, Match, src, dst, nil) return true } // CommonHash returns a single hash.Type and a HashOption with that // type which is in common between the two fs.Fs. func CommonHash(ctx context.Context, fa, fb fs.Info) (hash.Type, *fs.HashesOption) { ci := fs.GetConfig(ctx) // work out which hash to use - limit to 1 hash in common var common hash.Set hashType := hash.None if !ci.IgnoreChecksum { common = fb.Hashes().Overlap(fa.Hashes()) if common.Count() > 0 { hashType = common.GetOne() common = hash.Set(hashType) } } return hashType, &fs.HashesOption{Hashes: common} } // SameObject returns true if src and dst could be pointing to the // same object. func SameObject(src, dst fs.Object) bool { srcFs, dstFs := src.Fs(), dst.Fs() if !SameConfig(srcFs, dstFs) { // If same remote type then check ID of objects if available doSrcID, srcIDOK := src.(fs.IDer) doDstID, dstIDOK := dst.(fs.IDer) if srcIDOK && dstIDOK && SameRemoteType(srcFs, dstFs) { srcID, dstID := doSrcID.ID(), doDstID.ID() if srcID != "" && srcID == dstID { return true } } return false } srcPath := path.Join(srcFs.Root(), src.Remote()) dstPath := path.Join(dstFs.Root(), dst.Remote()) if srcFs.Features().IsLocal && dstFs.Features().IsLocal && runtime.GOOS == "darwin" { if norm.NFC.String(srcPath) == norm.NFC.String(dstPath) { return true } } if dst.Fs().Features().CaseInsensitive { srcPath = strings.ToLower(srcPath) dstPath = strings.ToLower(dstPath) } return srcPath == dstPath } // Move src object to dst or fdst if nil. If dst is nil then it uses // remote as the name of the new object. // // Note that you must check the destination does not exist before // calling this and pass it as dst. If you pass dst=nil and the // destination does exist then this may create duplicates or return // errors. // // It returns the destination object if possible. Note that this may // be nil. // // This is accounted as a check. func Move(ctx context.Context, fdst fs.Fs, dst fs.Object, remote string, src fs.Object) (newDst fs.Object, err error) { return move(ctx, fdst, dst, remote, src, false) } // MoveTransfer moves src object to dst or fdst if nil. If dst is nil // then it uses remote as the name of the new object. // // This is identical to Move but is accounted as a transfer. func MoveTransfer(ctx context.Context, fdst fs.Fs, dst fs.Object, remote string, src fs.Object) (newDst fs.Object, err error) { return move(ctx, fdst, dst, remote, src, true) } // move - see Move for help func move(ctx context.Context, fdst fs.Fs, dst fs.Object, remote string, src fs.Object, isTransfer bool) (newDst fs.Object, err error) { ci := fs.GetConfig(ctx) var tr *accounting.Transfer if isTransfer { tr = accounting.Stats(ctx).NewTransfer(src, fdst) } else { tr = accounting.Stats(ctx).NewCheckingTransfer(src, "moving") } defer func() { if err == nil { accounting.Stats(ctx).Renames(1) } tr.Done(ctx, err) }() newDst = dst if SkipDestructive(ctx, src, "move") { in := tr.Account(ctx, nil) in.DryRun(src.Size()) return newDst, nil } // See if we have Move available if doMove := fdst.Features().Move; doMove != nil && (SameConfig(src.Fs(), fdst) || (SameRemoteType(src.Fs(), fdst) && (fdst.Features().ServerSideAcrossConfigs || ci.ServerSideAcrossConfigs))) { // Delete destination if it exists and is not the same file as src (could be same file while seemingly different if the remote is case insensitive) if dst != nil { if !SameObject(src, dst) { err = DeleteFile(ctx, dst) if err != nil { return newDst, err } } else if needsMoveCaseInsensitive(fdst, fdst, remote, src.Remote(), false) { doMove = func(ctx context.Context, src fs.Object, remote string) (fs.Object, error) { return moveCaseInsensitive(ctx, fdst, fdst, remote, src.Remote(), false, src) } } } // Move dst <- src in := tr.Account(ctx, nil) // account the transfer in.ServerSideTransferStart() newDst, err = doMove(ctx, src, remote) switch err { case nil: if newDst != nil && src.String() != newDst.String() { fs.Infof(src, "Moved (server-side) to: %s", newDst.String()) } else { fs.Infof(src, "Moved (server-side)") } in.ServerSideMoveEnd(newDst.Size()) // account the bytes for the server-side transfer _ = in.Close() return newDst, nil case fs.ErrorCantMove: fs.Debugf(src, "Can't move, switching to copy") _ = in.Close() default: err = fs.CountError(err) fs.Errorf(src, "Couldn't move: %v", err) _ = in.Close() return newDst, err } } // Move not found or didn't work so copy dst <- src newDst, err = Copy(ctx, fdst, dst, remote, src) if err != nil { fs.Errorf(src, "Not deleting source as copy failed: %v", err) return newDst, err } // Delete src if no error on copy return newDst, DeleteFile(ctx, src) } // CanServerSideMove returns true if fdst support server-side moves or // server-side copies // // Some remotes simulate rename by server-side copy and delete, so include // remotes that implements either Mover or Copier. func CanServerSideMove(fdst fs.Fs) bool { canMove := fdst.Features().Move != nil canCopy := fdst.Features().Copy != nil return canMove || canCopy } // SuffixName adds the current --suffix to the remote, obeying // --suffix-keep-extension if set func SuffixName(ctx context.Context, remote string) string { ci := fs.GetConfig(ctx) if ci.Suffix == "" { return remote } if ci.SuffixKeepExtension { var ( base = remote exts = "" first = true ext = path.Ext(remote) ) for ext != "" { // Look second and subsequent extensions in mime types. // If they aren't found then don't keep it as an extension. if !first && mime.TypeByExtension(ext) == "" { break } base = base[:len(base)-len(ext)] exts = ext + exts first = false ext = path.Ext(base) } return base + ci.Suffix + exts } return remote + ci.Suffix } // DeleteFileWithBackupDir deletes a single file respecting --dry-run // and accumulating stats and errors. // // If backupDir is set then it moves the file to there instead of // deleting func DeleteFileWithBackupDir(ctx context.Context, dst fs.Object, backupDir fs.Fs) (err error) { tr := accounting.Stats(ctx).NewCheckingTransfer(dst, "deleting") defer func() { tr.Done(ctx, err) }() err = accounting.Stats(ctx).DeleteFile(ctx, dst.Size()) if err != nil { return err } action, actioned := "delete", "Deleted" if backupDir != nil { action, actioned = "move into backup dir", "Moved into backup dir" } skip := SkipDestructive(ctx, dst, action) if skip { // do nothing } else if backupDir != nil { err = MoveBackupDir(ctx, backupDir, dst) } else { err = dst.Remove(ctx) } if err != nil { fs.Errorf(dst, "Couldn't %s: %v", action, err) err = fs.CountError(err) } else if !skip { fs.Infof(dst, actioned) } return err } // DeleteFile deletes a single file respecting --dry-run and accumulating stats and errors. // // If useBackupDir is set and --backup-dir is in effect then it moves // the file to there instead of deleting func DeleteFile(ctx context.Context, dst fs.Object) (err error) { return DeleteFileWithBackupDir(ctx, dst, nil) } // DeleteFilesWithBackupDir removes all the files passed in the // channel // // If backupDir is set the files will be placed into that directory // instead of being deleted. func DeleteFilesWithBackupDir(ctx context.Context, toBeDeleted fs.ObjectsChan, backupDir fs.Fs) error { var wg sync.WaitGroup ci := fs.GetConfig(ctx) wg.Add(ci.Checkers) var errorCount atomic.Int32 var fatalErrorCount atomic.Int32 for i := 0; i < ci.Checkers; i++ { go func() { defer wg.Done() for dst := range toBeDeleted { err := DeleteFileWithBackupDir(ctx, dst, backupDir) if err != nil { errorCount.Add(1) logger, _ := GetLogger(ctx) logger(ctx, TransferError, nil, dst, err) if fserrors.IsFatalError(err) { fs.Errorf(dst, "Got fatal error on delete: %s", err) fatalErrorCount.Add(1) return } } } }() } fs.Debugf(nil, "Waiting for deletions to finish") wg.Wait() if errorCount.Load() > 0 { err := fmt.Errorf("failed to delete %d files", errorCount.Load()) if fatalErrorCount.Load() > 0 { return fserrors.FatalError(err) } return err } return nil } // DeleteFiles removes all the files passed in the channel func DeleteFiles(ctx context.Context, toBeDeleted fs.ObjectsChan) error { return DeleteFilesWithBackupDir(ctx, toBeDeleted, nil) } // SameRemoteType returns true if fdst and fsrc are the same type func SameRemoteType(fdst, fsrc fs.Info) bool { return fmt.Sprintf("%T", fdst) == fmt.Sprintf("%T", fsrc) } // SameConfig returns true if fdst and fsrc are using the same config // file entry func SameConfig(fdst, fsrc fs.Info) bool { return fdst.Name() == fsrc.Name() } // SameConfigArr returns true if any of []fsrcs has same config file entry with fdst func SameConfigArr(fdst fs.Info, fsrcs []fs.Fs) bool { for _, fsrc := range fsrcs { if fdst.Name() == fsrc.Name() { return true } } return false } // Same returns true if fdst and fsrc point to the same underlying Fs func Same(fdst, fsrc fs.Info) bool { return SameConfig(fdst, fsrc) && strings.Trim(fdst.Root(), "/") == strings.Trim(fsrc.Root(), "/") } // fixRoot returns the Root with a trailing / if not empty. // // It returns a case folded version for case insensitive file systems func fixRoot(f fs.Info) (s string, folded string) { s = strings.Trim(filepath.ToSlash(f.Root()), "/") if s != "" { s += "/" } folded = s if f.Features().CaseInsensitive { folded = strings.ToLower(s) } return s, folded } // OverlappingFilterCheck returns true if fdst and fsrc point to the same // underlying Fs and they overlap without fdst being excluded by any filter rule. func OverlappingFilterCheck(ctx context.Context, fdst fs.Fs, fsrc fs.Fs) bool { if !SameConfig(fdst, fsrc) { return false } fdstRoot, fdstRootFolded := fixRoot(fdst) fsrcRoot, fsrcRootFolded := fixRoot(fsrc) if fdstRootFolded == fsrcRootFolded { return true } else if strings.HasPrefix(fdstRootFolded, fsrcRootFolded) { fdstRelative := fdstRoot[len(fsrcRoot):] return filterCheck(ctx, fsrc, fdstRelative) } else if strings.HasPrefix(fsrcRootFolded, fdstRootFolded) { fsrcRelative := fsrcRoot[len(fdstRoot):] return filterCheck(ctx, fdst, fsrcRelative) } return false } // filterCheck checks if dir is included in f func filterCheck(ctx context.Context, f fs.Fs, dir string) bool { fi := filter.GetConfig(ctx) includeDirectory := fi.IncludeDirectory(ctx, f) include, err := includeDirectory(dir) if err != nil { fs.Errorf(f, "Failed to discover whether directory is included: %v", err) return true } return include } // SameDir returns true if fdst and fsrc point to the same // underlying Fs and they are the same directory. func SameDir(fdst, fsrc fs.Info) bool { if !SameConfig(fdst, fsrc) { return false } _, fdstRootFolded := fixRoot(fdst) _, fsrcRootFolded := fixRoot(fsrc) return fdstRootFolded == fsrcRootFolded } // Retry runs fn up to maxTries times if it returns a retriable error func Retry(ctx context.Context, o interface{}, maxTries int, fn func() error) (err error) { for tries := 1; tries <= maxTries; tries++ { // Call the function which might error err = fn() if err == nil { break } // Retry if err returned a retry error if fserrors.ContextError(ctx, &err) { break } if fserrors.IsRetryError(err) || fserrors.ShouldRetry(err) { fs.Debugf(o, "Received error: %v - low level retry %d/%d", err, tries, maxTries) continue } break } return err } // ListFn lists the Fs to the supplied function // // Lists in parallel which may get them out of order func ListFn(ctx context.Context, f fs.Fs, fn func(fs.Object)) error { ci := fs.GetConfig(ctx) return walk.ListR(ctx, f, "", false, ci.MaxDepth, walk.ListObjects, func(entries fs.DirEntries) error { entries.ForObject(fn) return nil }) } // StdoutMutex mutex for synchronized output on stdout var StdoutMutex sync.Mutex // SyncPrintf is a global var holding the Printf function so that it // can be overridden. // // This writes to stdout holding the StdoutMutex. If you are going to // override it and write to os.Stdout then you should hold the // StdoutMutex too. var SyncPrintf = func(format string, a ...interface{}) { StdoutMutex.Lock() defer StdoutMutex.Unlock() fmt.Printf(format, a...) } // SyncFprintf - Synchronized fmt.Fprintf // // Ignores errors from Fprintf. // // Prints to stdout if w is nil func SyncFprintf(w io.Writer, format string, a ...interface{}) { if w == nil || w == os.Stdout { SyncPrintf(format, a...) } else { StdoutMutex.Lock() defer StdoutMutex.Unlock() _, _ = fmt.Fprintf(w, format, a...) } } // SizeString make string representation of size for output // // Optional human-readable format including a binary suffix func SizeString(size int64, humanReadable bool) string { if humanReadable { if size < 0 { return "-" + fs.SizeSuffix(-size).String() } return fs.SizeSuffix(size).String() } return strconv.FormatInt(size, 10) } // SizeStringField make string representation of size for output in fixed width field // // Optional human-readable format including a binary suffix // Argument rawWidth is used to format field with of raw value. When humanReadable // option the width is hard coded to 9, since SizeSuffix strings have precision 3 // and longest value will be "999.999Ei". This way the width can be optimized // depending to the humanReadable option. To always use a longer width the return // value can always be fed into another format string with a specific field with. func SizeStringField(size int64, humanReadable bool, rawWidth int) string { str := SizeString(size, humanReadable) if humanReadable { return fmt.Sprintf("%9s", str) } return fmt.Sprintf("%[2]*[1]s", str, rawWidth) } // CountString make string representation of count for output // // Optional human-readable format including a decimal suffix func CountString(count int64, humanReadable bool) string { if humanReadable { if count < 0 { return "-" + fs.CountSuffix(-count).String() } return fs.CountSuffix(count).String() } return strconv.FormatInt(count, 10) } // CountStringField make string representation of count for output in fixed width field // // Similar to SizeStringField, but human readable with decimal prefix and field width 8 // since there is no 'i' in the decimal prefix symbols (e.g. "999.999E") func CountStringField(count int64, humanReadable bool, rawWidth int) string { str := CountString(count, humanReadable) if humanReadable { return fmt.Sprintf("%8s", str) } return fmt.Sprintf("%[2]*[1]s", str, rawWidth) } // List the Fs to the supplied writer // // Shows size and path - obeys includes and excludes. // // Lists in parallel which may get them out of order func List(ctx context.Context, f fs.Fs, w io.Writer) error { ci := fs.GetConfig(ctx) return ListFn(ctx, f, func(o fs.Object) { SyncFprintf(w, "%s %s\n", SizeStringField(o.Size(), ci.HumanReadable, 9), o.Remote()) }) } // ListLong lists the Fs to the supplied writer // // Shows size, mod time and path - obeys includes and excludes. // // Lists in parallel which may get them out of order func ListLong(ctx context.Context, f fs.Fs, w io.Writer) error { ci := fs.GetConfig(ctx) return ListFn(ctx, f, func(o fs.Object) { tr := accounting.Stats(ctx).NewCheckingTransfer(o, "listing") defer func() { tr.Done(ctx, nil) }() modTime := o.ModTime(ctx) SyncFprintf(w, "%s %s %s\n", SizeStringField(o.Size(), ci.HumanReadable, 9), modTime.Local().Format("2006-01-02 15:04:05.000000000"), o.Remote()) }) } // HashSum returns the human-readable hash for ht passed in. This may // be UNSUPPORTED or ERROR. If it isn't returning a valid hash it will // return an error. func HashSum(ctx context.Context, ht hash.Type, base64Encoded bool, downloadFlag bool, o fs.Object) (string, error) { var sum string var err error // If downloadFlag is true, download and hash the file. // If downloadFlag is false, call o.Hash asking the remote for the hash if downloadFlag { // Setup: Define accounting, open the file with NewReOpen to provide restarts, account for the transfer, and setup a multi-hasher with the appropriate type // Execution: io.Copy file to hasher, get hash and encode in hex tr := accounting.Stats(ctx).NewTransfer(o, nil) defer func() { tr.Done(ctx, err) }() // Open with NewReOpen to provide restarts var options []fs.OpenOption for _, option := range fs.GetConfig(ctx).DownloadHeaders { options = append(options, option) } var in io.ReadCloser in, err = Open(ctx, o, options...) if err != nil { return "ERROR", fmt.Errorf("failed to open file %v: %w", o, err) } // Account and buffer the transfer in = tr.Account(ctx, in).WithBuffer() // Setup hasher hasher, err := hash.NewMultiHasherTypes(hash.NewHashSet(ht)) if err != nil { return "UNSUPPORTED", fmt.Errorf("hash unsupported: %w", err) } // Copy to hasher, downloading the file and passing directly to hash _, err = io.Copy(hasher, in) if err != nil { return "ERROR", fmt.Errorf("failed to copy file to hasher: %w", err) } // Get hash as hex or base64 encoded string sum, err = hasher.SumString(ht, base64Encoded) if err != nil { return "ERROR", fmt.Errorf("hasher returned an error: %w", err) } } else { tr := accounting.Stats(ctx).NewCheckingTransfer(o, "hashing") defer func() { tr.Done(ctx, err) }() sum, err = o.Hash(ctx, ht) if base64Encoded { hexBytes, _ := hex.DecodeString(sum) sum = base64.URLEncoding.EncodeToString(hexBytes) } if err == hash.ErrUnsupported { return "", fmt.Errorf("hash unsupported: %w", err) } if err != nil { return "", fmt.Errorf("failed to get hash %v from backend: %w", ht, err) } } return sum, nil } // HashLister does an md5sum equivalent for the hash type passed in // Updated to handle both standard hex encoding and base64 // Updated to perform multiple hashes concurrently func HashLister(ctx context.Context, ht hash.Type, outputBase64 bool, downloadFlag bool, f fs.Fs, w io.Writer) error { width := hash.Width(ht, outputBase64) // Use --checkers concurrency unless downloading in which case use --transfers concurrency := fs.GetConfig(ctx).Checkers if downloadFlag { concurrency = fs.GetConfig(ctx).Transfers } concurrencyControl := make(chan struct{}, concurrency) var wg sync.WaitGroup err := ListFn(ctx, f, func(o fs.Object) { wg.Add(1) concurrencyControl <- struct{}{} go func() { defer func() { <-concurrencyControl wg.Done() }() sum, err := HashSum(ctx, ht, outputBase64, downloadFlag, o) if err != nil { fs.Errorf(o, "%v", fs.CountError(err)) return } SyncFprintf(w, "%*s %s\n", width, sum, o.Remote()) }() }) wg.Wait() return err } // HashSumStream outputs a line compatible with md5sum to w based on the // input stream in and the hash type ht passed in. If outputBase64 is // set then the hash will be base64 instead of hexadecimal. func HashSumStream(ht hash.Type, outputBase64 bool, in io.ReadCloser, w io.Writer) error { hasher, err := hash.NewMultiHasherTypes(hash.NewHashSet(ht)) if err != nil { return fmt.Errorf("hash unsupported: %w", err) } written, err := io.Copy(hasher, in) fs.Debugf(nil, "Creating %s hash of %d bytes read from input stream", ht, written) if err != nil { return fmt.Errorf("failed to copy input to hasher: %w", err) } sum, err := hasher.SumString(ht, outputBase64) if err != nil { return fmt.Errorf("hasher returned an error: %w", err) } width := hash.Width(ht, outputBase64) SyncFprintf(w, "%*s -\n", width, sum) return nil } // Count counts the objects and their sizes in the Fs // // Obeys includes and excludes func Count(ctx context.Context, f fs.Fs) (objects int64, size int64, sizelessObjects int64, err error) { err = ListFn(ctx, f, func(o fs.Object) { atomic.AddInt64(&objects, 1) objectSize := o.Size() if objectSize < 0 { atomic.AddInt64(&sizelessObjects, 1) } else if objectSize > 0 { atomic.AddInt64(&size, objectSize) } }) return } // ConfigMaxDepth returns the depth to use for a recursive or non recursive listing. func ConfigMaxDepth(ctx context.Context, recursive bool) int { ci := fs.GetConfig(ctx) depth := ci.MaxDepth if !recursive && depth < 0 { depth = 1 } return depth } // ListDir lists the directories/buckets/containers in the Fs to the supplied writer func ListDir(ctx context.Context, f fs.Fs, w io.Writer) error { ci := fs.GetConfig(ctx) return walk.ListR(ctx, f, "", false, ConfigMaxDepth(ctx, false), walk.ListDirs, func(entries fs.DirEntries) error { entries.ForDir(func(dir fs.Directory) { if dir != nil { SyncFprintf(w, "%s %13s %s %s\n", SizeStringField(dir.Size(), ci.HumanReadable, 12), dir.ModTime(ctx).Local().Format("2006-01-02 15:04:05"), CountStringField(dir.Items(), ci.HumanReadable, 9), dir.Remote()) } }) return nil }) } // Mkdir makes a destination directory or container func Mkdir(ctx context.Context, f fs.Fs, dir string) error { if SkipDestructive(ctx, fs.LogDirName(f, dir), "make directory") { return nil } fs.Debugf(fs.LogDirName(f, dir), "Making directory") err := f.Mkdir(ctx, dir) if err != nil { err = fs.CountError(err) return err } return nil } // MkdirMetadata makes a destination directory or container with metadata // // If the destination Fs doesn't support this it will fall back to // Mkdir and in this case newDst will be nil. func MkdirMetadata(ctx context.Context, f fs.Fs, dir string, metadata fs.Metadata) (newDst fs.Directory, err error) { do := f.Features().MkdirMetadata if do == nil { return nil, Mkdir(ctx, f, dir) } logName := fs.LogDirName(f, dir) if SkipDestructive(ctx, logName, "make directory") { return nil, nil } fs.Debugf(fs.LogDirName(f, dir), "Making directory with metadata") newDst, err = do(ctx, dir, metadata) if err != nil { err = fs.CountError(err) return nil, err } if mtime, ok := metadata["mtime"]; ok { fs.Infof(logName, "Made directory with metadata (mtime=%s)", mtime) } else { fs.Infof(logName, "Made directory with metadata") } return newDst, err } // MkdirModTime makes a destination directory or container with modtime // // It will try to make the directory with MkdirMetadata and if that // succeeds it will return a non-nil newDst. In all other cases newDst // will be nil. // // If the directory was created with MkDir then it will attempt to use // Fs.DirSetModTime to update the directory modtime if available. func MkdirModTime(ctx context.Context, f fs.Fs, dir string, modTime time.Time) (newDst fs.Directory, err error) { logName := fs.LogDirName(f, dir) if SkipDestructive(ctx, logName, "make directory") { return nil, nil } metadata := fs.Metadata{ "mtime": modTime.Format(time.RFC3339Nano), } newDst, err = MkdirMetadata(ctx, f, dir, metadata) if err != nil { return nil, err } if newDst != nil { // The directory was created and we have logged already return newDst, nil } // The directory was created with Mkdir then we should try to set the time if do := f.Features().DirSetModTime; do != nil { err = do(ctx, dir, modTime) } fs.Infof(logName, "Made directory with modification time %v", modTime) return newDst, err } // TryRmdir removes a container but not if not empty. It doesn't // count errors but may return one. func TryRmdir(ctx context.Context, f fs.Fs, dir string) error { accounting.Stats(ctx).DeletedDirs(1) if SkipDestructive(ctx, fs.LogDirName(f, dir), "remove directory") { return nil } fs.Infof(fs.LogDirName(f, dir), "Removing directory") return f.Rmdir(ctx, dir) } // Rmdir removes a container but not if not empty func Rmdir(ctx context.Context, f fs.Fs, dir string) error { err := TryRmdir(ctx, f, dir) if err != nil { err = fs.CountError(err) return err } return err } // Purge removes a directory and all of its contents func Purge(ctx context.Context, f fs.Fs, dir string) (err error) { doFallbackPurge := true if doPurge := f.Features().Purge; doPurge != nil { doFallbackPurge = false accounting.Stats(ctx).DeletedDirs(1) if SkipDestructive(ctx, fs.LogDirName(f, dir), "purge directory") { return nil } err = doPurge(ctx, dir) if errors.Is(err, fs.ErrorCantPurge) { doFallbackPurge = true } } if doFallbackPurge { // DeleteFiles and Rmdir observe --dry-run err = DeleteFiles(ctx, listToChan(ctx, f, dir)) if err != nil { return err } err = Rmdirs(ctx, f, dir, false) } if err != nil { err = fs.CountError(err) return err } return nil } // Delete removes all the contents of a container. Unlike Purge, it // obeys includes and excludes. func Delete(ctx context.Context, f fs.Fs) error { ci := fs.GetConfig(ctx) delChan := make(fs.ObjectsChan, ci.Checkers) delErr := make(chan error, 1) go func() { delErr <- DeleteFiles(ctx, delChan) }() err := ListFn(ctx, f, func(o fs.Object) { delChan <- o }) close(delChan) delError := <-delErr if err == nil { err = delError } return err } // listToChan will transfer all objects in the listing to the output // // If an error occurs, the error will be logged, and it will close the // channel. // // If the error was ErrorDirNotFound then it will be ignored func listToChan(ctx context.Context, f fs.Fs, dir string) fs.ObjectsChan { ci := fs.GetConfig(ctx) o := make(fs.ObjectsChan, ci.Checkers) go func() { defer close(o) err := walk.ListR(ctx, f, dir, true, ci.MaxDepth, walk.ListObjects, func(entries fs.DirEntries) error { entries.ForObject(func(obj fs.Object) { o <- obj }) return nil }) if err != nil && err != fs.ErrorDirNotFound { err = fmt.Errorf("failed to list: %w", err) err = fs.CountError(err) fs.Errorf(nil, "%v", err) } }() return o } // CleanUp removes the trash for the Fs func CleanUp(ctx context.Context, f fs.Fs) error { doCleanUp := f.Features().CleanUp if doCleanUp == nil { return fmt.Errorf("%v doesn't support cleanup", f) } if SkipDestructive(ctx, f, "clean up old files") { return nil } return doCleanUp(ctx) } // wrap a Reader and a Closer together into a ReadCloser type readCloser struct { io.Reader io.Closer } // Cat any files to the io.Writer // // if offset == 0 it will be ignored // if offset > 0 then the file will be seeked to that offset // if offset < 0 then the file will be seeked that far from the end // // if count < 0 then it will be ignored // if count >= 0 then only that many characters will be output func Cat(ctx context.Context, f fs.Fs, w io.Writer, offset, count int64, sep []byte) error { var mu sync.Mutex ci := fs.GetConfig(ctx) return ListFn(ctx, f, func(o fs.Object) { var err error tr := accounting.Stats(ctx).NewTransfer(o, nil) defer func() { tr.Done(ctx, err) }() opt := fs.RangeOption{Start: offset, End: -1} size := o.Size() if opt.Start < 0 { opt.Start += size } if count >= 0 { opt.End = opt.Start + count - 1 } var options []fs.OpenOption if opt.Start > 0 || opt.End >= 0 { options = append(options, &opt) } for _, option := range ci.DownloadHeaders { options = append(options, option) } var in io.ReadCloser in, err = Open(ctx, o, options...) if err != nil { err = fs.CountError(err) fs.Errorf(o, "Failed to open: %v", err) return } if count >= 0 { in = &readCloser{Reader: &io.LimitedReader{R: in, N: count}, Closer: in} } in = tr.Account(ctx, in).WithBuffer() // account and buffer the transfer // take the lock just before we output stuff, so at the last possible moment mu.Lock() defer mu.Unlock() _, err = io.Copy(w, in) if err != nil { err = fs.CountError(err) fs.Errorf(o, "Failed to send to output: %v", err) } if len(sep) >= 0 { _, err = w.Write(sep) if err != nil { err = fs.CountError(err) fs.Errorf(o, "Failed to send separator to output: %v", err) } } }) } // Rcat reads data from the Reader until EOF and uploads it to a file on remote func Rcat(ctx context.Context, fdst fs.Fs, dstFileName string, in io.ReadCloser, modTime time.Time, meta fs.Metadata) (dst fs.Object, err error) { ci := fs.GetConfig(ctx) tr := accounting.Stats(ctx).NewTransferRemoteSize(dstFileName, -1, nil, fdst) defer func() { tr.Done(ctx, err) }() in = tr.Account(ctx, in).WithBuffer() readCounter := readers.NewCountingReader(in) var trackingIn io.Reader var hasher *hash.MultiHasher var options []fs.OpenOption if !ci.IgnoreChecksum { hashes := hash.NewHashSet(fdst.Hashes().GetOne()) // just pick one hash hashOption := &fs.HashesOption{Hashes: hashes} options = append(options, hashOption) hasher, err = hash.NewMultiHasherTypes(hashes) if err != nil { return nil, err } trackingIn = io.TeeReader(readCounter, hasher) } else { trackingIn = readCounter } for _, option := range ci.UploadHeaders { options = append(options, option) } if ci.MetadataSet != nil { options = append(options, fs.MetadataOption(ci.MetadataSet)) } compare := func(dst fs.Object) error { var sums map[hash.Type]string opt := defaultEqualOpt(ctx) if hasher != nil { // force --checksum on if we have hashes opt.checkSum = true sums = hasher.Sums() } src := object.NewStaticObjectInfo(dstFileName, modTime, int64(readCounter.BytesRead()), false, sums, fdst).WithMetadata(meta) if !equal(ctx, src, dst, opt) { err = fmt.Errorf("corrupted on transfer") err = fs.CountError(err) fs.Errorf(dst, "%v", err) return err } return nil } // check if file small enough for direct upload buf := make([]byte, ci.StreamingUploadCutoff) if n, err := io.ReadFull(trackingIn, buf); err == io.EOF || err == io.ErrUnexpectedEOF { fs.Debugf(fdst, "File to upload is small (%d bytes), uploading instead of streaming", n) src := object.NewMemoryObject(dstFileName, modTime, buf[:n]).WithMetadata(meta) return Copy(ctx, fdst, nil, dstFileName, src) } // Make a new ReadCloser with the bits we've already read in = &readCloser{ Reader: io.MultiReader(bytes.NewReader(buf), trackingIn), Closer: in, } fStreamTo := fdst canStream := fdst.Features().PutStream != nil if !canStream { fs.Debugf(fdst, "Target remote doesn't support streaming uploads, creating temporary local FS to spool file") tmpLocalFs, err := fs.TemporaryLocalFs(ctx) if err != nil { return nil, fmt.Errorf("failed to create temporary local FS to spool file: %w", err) } defer func() { err := Purge(ctx, tmpLocalFs, "") if err != nil { fs.Infof(tmpLocalFs, "Failed to cleanup temporary FS: %v", err) } }() fStreamTo = tmpLocalFs } if SkipDestructive(ctx, dstFileName, "upload from pipe") { // prevents "broken pipe" errors _, err = io.Copy(io.Discard, in) return nil, err } objInfo := object.NewStaticObjectInfo(dstFileName, modTime, -1, false, nil, nil).WithMetadata(meta) if dst, err = fStreamTo.Features().PutStream(ctx, in, objInfo, options...); err != nil { return dst, err } if err = compare(dst); err != nil { return dst, err } if !canStream { // copy dst (which is the local object we have just streamed to) to the remote newCtx := ctx if ci.Metadata && len(meta) != 0 { // If we have metadata and we are setting it then use // the --metadataset mechanism to supply it to Copy var newCi *fs.ConfigInfo newCtx, newCi = fs.AddConfig(ctx) if len(newCi.MetadataSet) == 0 { newCi.MetadataSet = meta } else { var newMeta fs.Metadata newMeta.Merge(meta) newMeta.Merge(newCi.MetadataSet) // --metadata-set takes priority newCi.MetadataSet = newMeta } } return Copy(newCtx, fdst, nil, dstFileName, dst) } return dst, nil } // PublicLink adds a "readable by anyone with link" permission on the given file or folder. func PublicLink(ctx context.Context, f fs.Fs, remote string, expire fs.Duration, unlink bool) (string, error) { doPublicLink := f.Features().PublicLink if doPublicLink == nil { return "", fmt.Errorf("%v doesn't support public links", f) } return doPublicLink(ctx, remote, expire, unlink) } // Rmdirs removes any empty directories (or directories only // containing empty directories) under f, including f. // // Rmdirs obeys the filters func Rmdirs(ctx context.Context, f fs.Fs, dir string, leaveRoot bool) error { ci := fs.GetConfig(ctx) fi := filter.GetConfig(ctx) dirEmpty := make(map[string]bool) dirEmpty[dir] = !leaveRoot err := walk.Walk(ctx, f, dir, false, ci.MaxDepth, func(dirPath string, entries fs.DirEntries, err error) error { if err != nil { err = fs.CountError(err) fs.Errorf(f, "Failed to list %q: %v", dirPath, err) return nil } for _, entry := range entries { switch x := entry.(type) { case fs.Directory: // add a new directory as empty dir := x.Remote() _, found := dirEmpty[dir] if !found { dirEmpty[dir] = true } case fs.Object: // mark the parents of the file as being non-empty dir := x.Remote() for dir != "" { dir = path.Dir(dir) if dir == "." || dir == "/" { dir = "" } empty, found := dirEmpty[dir] // End if we reach a directory which is non-empty if found && !empty { break } dirEmpty[dir] = false } } } return nil }) if err != nil { return fmt.Errorf("failed to rmdirs: %w", err) } // Group directories to delete by level var toDelete [][]string for dir, empty := range dirEmpty { if empty { // If a filter matches the directory then that // directory is a candidate for deletion if fi.IncludeRemote(dir + "/") { level := strings.Count(dir, "/") + 1 // The root directory "" is at the top level if dir == "" { level = 0 } if len(toDelete) < level+1 { toDelete = append(toDelete, make([][]string, level+1-len(toDelete))...) } toDelete[level] = append(toDelete[level], dir) } } } var ( errCount = errcount.New() ) // Delete all directories at the same level in parallel for level := len(toDelete) - 1; level >= 0; level-- { dirs := toDelete[level] if len(dirs) == 0 { continue } fs.Debugf(nil, "removing %d level %d directories", len(dirs), level) sort.Strings(dirs) g, gCtx := errgroup.WithContext(ctx) g.SetLimit(ci.Checkers) for _, dir := range dirs { // End early if error if gCtx.Err() != nil { break } dir := dir g.Go(func() error { err := TryRmdir(gCtx, f, dir) if err != nil { err = fs.CountError(err) fs.Errorf(dir, "Failed to rmdir: %v", err) errCount.Add(err) } return nil // don't return errors, just count them }) } err := g.Wait() if err != nil { return err } } return errCount.Err("failed to remove directories") } // GetCompareDest sets up --compare-dest func GetCompareDest(ctx context.Context) (CompareDest []fs.Fs, err error) { ci := fs.GetConfig(ctx) CompareDest, err = cache.GetArr(ctx, ci.CompareDest) if err != nil { return nil, fserrors.FatalError(fmt.Errorf("failed to make fs for --compare-dest %q: %w", ci.CompareDest, err)) } return CompareDest, nil } // compareDest checks --compare-dest to see if src needs to // be copied // // Returns True if src is in --compare-dest func compareDest(ctx context.Context, dst, src fs.Object, CompareDest fs.Fs) (NoNeedTransfer bool, err error) { var remote string if dst == nil { remote = src.Remote() } else { remote = dst.Remote() } CompareDestFile, err := CompareDest.NewObject(ctx, remote) switch err { case fs.ErrorObjectNotFound: return false, nil case nil: break default: return false, err } opt := defaultEqualOpt(ctx) opt.updateModTime = false if equal(ctx, src, CompareDestFile, opt) { fs.Debugf(src, "Destination found in --compare-dest, skipping") return true, nil } return false, nil } // GetCopyDest sets up --copy-dest func GetCopyDest(ctx context.Context, fdst fs.Fs) (CopyDest []fs.Fs, err error) { ci := fs.GetConfig(ctx) CopyDest, err = cache.GetArr(ctx, ci.CopyDest) if err != nil { return nil, fserrors.FatalError(fmt.Errorf("failed to make fs for --copy-dest %q: %w", ci.CopyDest, err)) } if !SameConfigArr(fdst, CopyDest) { return nil, fserrors.FatalError(errors.New("parameter to --copy-dest has to be on the same remote as destination")) } for _, cf := range CopyDest { if cf.Features().Copy == nil { return nil, fserrors.FatalError(errors.New("can't use --copy-dest on a remote which doesn't support server side copy")) } } return CopyDest, nil } // copyDest checks --copy-dest to see if src needs to // be copied // // Returns True if src was copied from --copy-dest func copyDest(ctx context.Context, fdst fs.Fs, dst, src fs.Object, CopyDest, backupDir fs.Fs) (NoNeedTransfer bool, err error) { var remote string if dst == nil { remote = src.Remote() } else { remote = dst.Remote() } CopyDestFile, err := CopyDest.NewObject(ctx, remote) switch err { case fs.ErrorObjectNotFound: return false, nil case nil: break default: return false, err } opt := defaultEqualOpt(ctx) opt.updateModTime = false if equal(ctx, src, CopyDestFile, opt) { if dst == nil || !Equal(ctx, src, dst) { if dst != nil && backupDir != nil { err = MoveBackupDir(ctx, backupDir, dst) if err != nil { return false, fmt.Errorf("moving to --backup-dir failed: %w", err) } // If successful zero out the dstObj as it is no longer there dst = nil } _, err := Copy(ctx, fdst, dst, remote, CopyDestFile) if err != nil { fs.Errorf(src, "Destination found in --copy-dest, error copying") return false, nil } fs.Debugf(src, "Destination found in --copy-dest, using server-side copy") return true, nil } fs.Debugf(src, "Unchanged skipping") return true, nil } fs.Debugf(src, "Destination not found in --copy-dest") return false, nil } // CompareOrCopyDest checks --compare-dest and --copy-dest to see if src // does not need to be copied // // Returns True if src does not need to be copied func CompareOrCopyDest(ctx context.Context, fdst fs.Fs, dst, src fs.Object, CompareOrCopyDest []fs.Fs, backupDir fs.Fs) (NoNeedTransfer bool, err error) { ci := fs.GetConfig(ctx) if len(ci.CompareDest) > 0 { for _, compareF := range CompareOrCopyDest { NoNeedTransfer, err := compareDest(ctx, dst, src, compareF) if NoNeedTransfer || err != nil { return NoNeedTransfer, err } } } else if len(ci.CopyDest) > 0 { for _, copyF := range CompareOrCopyDest { NoNeedTransfer, err := copyDest(ctx, fdst, dst, src, copyF, backupDir) if NoNeedTransfer || err != nil { return NoNeedTransfer, err } } } return false, nil } // NeedTransfer checks to see if src needs to be copied to dst using // the current config. // // Returns a flag which indicates whether the file needs to be // transferred or not. func NeedTransfer(ctx context.Context, dst, src fs.Object) bool { ci := fs.GetConfig(ctx) logger, _ := GetLogger(ctx) if dst == nil { fs.Debugf(src, "Need to transfer - File not found at Destination") logger(ctx, MissingOnDst, src, nil, nil) return true } // If we should ignore existing files, don't transfer if ci.IgnoreExisting { fs.Debugf(src, "Destination exists, skipping") logger(ctx, Match, src, dst, nil) return false } // If we should upload unconditionally if ci.IgnoreTimes { fs.Debugf(src, "Transferring unconditionally as --ignore-times is in use") logger(ctx, Differ, src, dst, nil) return true } // If UpdateOlder is in effect, skip if dst is newer than src if ci.UpdateOlder { srcModTime := src.ModTime(ctx) dstModTime := dst.ModTime(ctx) dt := dstModTime.Sub(srcModTime) // If have a mutually agreed precision then use that modifyWindow := fs.GetModifyWindow(ctx, dst.Fs(), src.Fs()) if modifyWindow == fs.ModTimeNotSupported { // Otherwise use 1 second as a safe default as // the resolution of the time a file was // uploaded. modifyWindow = time.Second } switch { case dt >= modifyWindow: fs.Debugf(src, "Destination is newer than source, skipping") logger(ctx, Match, src, dst, nil) return false case dt <= -modifyWindow: // force --checksum on for the check and do update modtimes by default opt := defaultEqualOpt(ctx) opt.forceModTimeMatch = true if equal(ctx, src, dst, opt) { fs.Debugf(src, "Unchanged skipping") return false } default: // Do a size only compare unless --checksum is set opt := defaultEqualOpt(ctx) opt.sizeOnly = !ci.CheckSum if equal(ctx, src, dst, opt) { fs.Debugf(src, "Destination mod time is within %v of source and files identical, skipping", modifyWindow) return false } fs.Debugf(src, "Destination mod time is within %v of source but files differ, transferring", modifyWindow) } } else { // Check to see if changed or not equalFn, ok := ctx.Value(equalFnKey).(EqualFn) if ok { return !equalFn(ctx, src, dst) } if Equal(ctx, src, dst) && !SameObject(src, dst) { fs.Debugf(src, "Unchanged skipping") return false } } return true } // RcatSize reads data from the Reader until EOF and uploads it to a file on remote. // Pass in size >=0 if known, <0 if not known func RcatSize(ctx context.Context, fdst fs.Fs, dstFileName string, in io.ReadCloser, size int64, modTime time.Time, meta fs.Metadata) (dst fs.Object, err error) { var obj fs.Object if size >= 0 { var err error // Size known use Put tr := accounting.Stats(ctx).NewTransferRemoteSize(dstFileName, size, nil, fdst) defer func() { tr.Done(ctx, err) }() body := io.NopCloser(in) // we let the server close the body in := tr.Account(ctx, body) // account the transfer (no buffering) if SkipDestructive(ctx, dstFileName, "upload from pipe") { // prevents "broken pipe" errors _, err = io.Copy(io.Discard, in) return nil, err } info := object.NewStaticObjectInfo(dstFileName, modTime, size, true, nil, fdst).WithMetadata(meta) obj, err = fdst.Put(ctx, in, info) if err != nil { fs.Errorf(dstFileName, "Post request put error: %v", err) return nil, err } } else { // Size unknown use Rcat obj, err = Rcat(ctx, fdst, dstFileName, in, modTime, meta) if err != nil { fs.Errorf(dstFileName, "Post request rcat error: %v", err) return nil, err } } return obj, nil } // copyURLFunc is called from CopyURLFn type copyURLFunc func(ctx context.Context, dstFileName string, in io.ReadCloser, size int64, modTime time.Time) (err error) // copyURLFn copies the data from the url to the function supplied func copyURLFn(ctx context.Context, dstFileName string, url string, autoFilename, dstFileNameFromHeader bool, fn copyURLFunc) (err error) { client := fshttp.NewClient(ctx) resp, err := client.Get(url) if err != nil { return err } defer fs.CheckClose(resp.Body, &err) if resp.StatusCode < 200 || resp.StatusCode >= 300 { return fmt.Errorf("CopyURL failed: %s", resp.Status) } modTime, err := http.ParseTime(resp.Header.Get("Last-Modified")) if err != nil { modTime = time.Now() } if autoFilename { if dstFileNameFromHeader { _, params, err := mime.ParseMediaType(resp.Header.Get("Content-Disposition")) headerFilename := path.Base(strings.Replace(params["filename"], "\\", "/", -1)) if err != nil || headerFilename == "" { return fmt.Errorf("CopyURL failed: filename not found in the Content-Disposition header") } fs.Debugf(headerFilename, "filename found in Content-Disposition header.") return fn(ctx, headerFilename, resp.Body, resp.ContentLength, modTime) } dstFileName = path.Base(resp.Request.URL.Path) if dstFileName == "." || dstFileName == "/" { return fmt.Errorf("CopyURL failed: file name wasn't found in url") } fs.Debugf(dstFileName, "File name found in url") } return fn(ctx, dstFileName, resp.Body, resp.ContentLength, modTime) } // CopyURL copies the data from the url to (fdst, dstFileName) func CopyURL(ctx context.Context, fdst fs.Fs, dstFileName string, url string, autoFilename, dstFileNameFromHeader bool, noClobber bool) (dst fs.Object, err error) { err = copyURLFn(ctx, dstFileName, url, autoFilename, dstFileNameFromHeader, func(ctx context.Context, dstFileName string, in io.ReadCloser, size int64, modTime time.Time) (err error) { if noClobber { _, err = fdst.NewObject(ctx, dstFileName) if err == nil { return errors.New("CopyURL failed: file already exist") } } dst, err = RcatSize(ctx, fdst, dstFileName, in, size, modTime, nil) return err }) return dst, err } // CopyURLToWriter copies the data from the url to the io.Writer supplied func CopyURLToWriter(ctx context.Context, url string, out io.Writer) (err error) { return copyURLFn(ctx, "", url, false, false, func(ctx context.Context, dstFileName string, in io.ReadCloser, size int64, modTime time.Time) (err error) { _, err = io.Copy(out, in) return err }) } // BackupDir returns the correctly configured --backup-dir func BackupDir(ctx context.Context, fdst fs.Fs, fsrc fs.Fs, srcFileName string) (backupDir fs.Fs, err error) { ci := fs.GetConfig(ctx) if ci.BackupDir != "" { backupDir, err = cache.Get(ctx, ci.BackupDir) if err != nil { return nil, fserrors.FatalError(fmt.Errorf("failed to make fs for --backup-dir %q: %w", ci.BackupDir, err)) } if !SameConfig(fdst, backupDir) { return nil, fserrors.FatalError(errors.New("parameter to --backup-dir has to be on the same remote as destination")) } if srcFileName == "" { if OverlappingFilterCheck(ctx, backupDir, fdst) { return nil, fserrors.FatalError(errors.New("destination and parameter to --backup-dir mustn't overlap")) } if OverlappingFilterCheck(ctx, backupDir, fsrc) { return nil, fserrors.FatalError(errors.New("source and parameter to --backup-dir mustn't overlap")) } } else { if ci.Suffix == "" { if SameDir(fdst, backupDir) { return nil, fserrors.FatalError(errors.New("destination and parameter to --backup-dir mustn't be the same")) } if SameDir(fsrc, backupDir) { return nil, fserrors.FatalError(errors.New("source and parameter to --backup-dir mustn't be the same")) } } } } else if ci.Suffix != "" { // --backup-dir is not set but --suffix is - use the destination as the backupDir backupDir = fdst } else { return nil, fserrors.FatalError(errors.New("internal error: BackupDir called when --backup-dir and --suffix both empty")) } if !CanServerSideMove(backupDir) { return nil, fserrors.FatalError(errors.New("can't use --backup-dir on a remote which doesn't support server-side move or copy")) } return backupDir, nil } // MoveBackupDir moves a file to the backup dir func MoveBackupDir(ctx context.Context, backupDir fs.Fs, dst fs.Object) (err error) { remoteWithSuffix := SuffixName(ctx, dst.Remote()) overwritten, _ := backupDir.NewObject(ctx, remoteWithSuffix) _, err = Move(ctx, backupDir, overwritten, remoteWithSuffix, dst) return err } // needsMoveCaseInsensitive returns true if moveCaseInsensitive is needed func needsMoveCaseInsensitive(fdst fs.Fs, fsrc fs.Fs, dstFileName string, srcFileName string, cp bool) bool { dstFilePath := path.Join(fdst.Root(), dstFileName) srcFilePath := path.Join(fsrc.Root(), srcFileName) return !cp && fdst.Name() == fsrc.Name() && fdst.Features().CaseInsensitive && dstFileName != srcFileName && strings.EqualFold(dstFilePath, srcFilePath) } // Special case for changing case of a file on a case insensitive remote // This will move the file to a temporary name then // move it back to the intended destination. This is required // to avoid issues with certain remotes and avoid file deletion. // returns nil, nil if !needsMoveCaseInsensitive. // this does not account a transfer -- the caller should do that if desired. func moveCaseInsensitive(ctx context.Context, fdst fs.Fs, fsrc fs.Fs, dstFileName string, srcFileName string, cp bool, srcObj fs.Object) (newDst fs.Object, err error) { if !needsMoveCaseInsensitive(fdst, fsrc, dstFileName, srcFileName, cp) { return nil, nil } logger, _ := GetLogger(ctx) // Choose operations Op := MoveTransfer if cp { Op = Copy } if SkipDestructive(ctx, srcFileName, "rename to "+dstFileName) { // avoid fatalpanic on --dry-run (trying to access non-existent tmpObj) return nil, nil } // Create random name to temporarily move file to tmpObjName := dstFileName + "-rclone-move-" + random.String(8) tmpObjFail, err := fdst.NewObject(ctx, tmpObjName) if err != fs.ErrorObjectNotFound { if err == nil { logger(ctx, TransferError, nil, tmpObjFail, err) return nil, errors.New("found an already existing file with a randomly generated name. Try the operation again") } logger(ctx, TransferError, nil, tmpObjFail, err) return nil, fmt.Errorf("error while attempting to move file to a temporary location: %w", err) } fs.Debugf(srcObj, "moving to %v", tmpObjName) tmpObj, err := Op(ctx, fdst, nil, tmpObjName, srcObj) if err != nil { logger(ctx, TransferError, srcObj, tmpObj, err) return nil, fmt.Errorf("error while moving file to temporary location: %w", err) } fs.Debugf(srcObj, "moving to %v", dstFileName) newDst, err = Op(ctx, fdst, nil, dstFileName, tmpObj) logger(ctx, MissingOnDst, tmpObj, nil, err) return newDst, err } // moveOrCopyFile moves or copies a single file possibly to a new name func moveOrCopyFile(ctx context.Context, fdst fs.Fs, fsrc fs.Fs, dstFileName string, srcFileName string, cp bool) (err error) { ci := fs.GetConfig(ctx) logger, usingLogger := GetLogger(ctx) dstFilePath := path.Join(fdst.Root(), dstFileName) srcFilePath := path.Join(fsrc.Root(), srcFileName) if fdst.Name() == fsrc.Name() && dstFilePath == srcFilePath { fs.Debugf(fdst, "don't need to copy/move %s, it is already at target location", dstFileName) if usingLogger { srcObj, _ := fsrc.NewObject(ctx, srcFileName) dstObj, _ := fsrc.NewObject(ctx, dstFileName) logger(ctx, Match, srcObj, dstObj, nil) } return nil } // Choose operations Op := MoveTransfer if cp { Op = Copy } // Find src object srcObj, err := fsrc.NewObject(ctx, srcFileName) if err != nil { logger(ctx, TransferError, srcObj, nil, err) return err } // Find dst object if it exists var dstObj fs.Object if !ci.NoCheckDest { dstObj, err = fdst.NewObject(ctx, dstFileName) if errors.Is(err, fs.ErrorObjectNotFound) { dstObj = nil } else if err != nil { logger(ctx, TransferError, nil, dstObj, err) return err } } // Special case for changing case of a file on a case insensitive remote // This will move the file to a temporary name then // move it back to the intended destination. This is required // to avoid issues with certain remotes and avoid file deletion. if needsMoveCaseInsensitive(fdst, fsrc, dstFileName, srcFileName, cp) { tr := accounting.Stats(ctx).NewTransfer(srcObj, fdst) defer func() { tr.Done(ctx, err) }() _, err = moveCaseInsensitive(ctx, fdst, fsrc, dstFileName, srcFileName, cp, srcObj) return err } var backupDir fs.Fs var copyDestDir []fs.Fs if ci.BackupDir != "" || ci.Suffix != "" { backupDir, err = BackupDir(ctx, fdst, fsrc, srcFileName) if err != nil { return fmt.Errorf("creating Fs for --backup-dir failed: %w", err) } } if len(ci.CompareDest) > 0 { copyDestDir, err = GetCompareDest(ctx) if err != nil { return err } } else if len(ci.CopyDest) > 0 { copyDestDir, err = GetCopyDest(ctx, fdst) if err != nil { return err } } needTransfer := NeedTransfer(ctx, dstObj, srcObj) if needTransfer { NoNeedTransfer, err := CompareOrCopyDest(ctx, fdst, dstObj, srcObj, copyDestDir, backupDir) if err != nil { return err } if NoNeedTransfer { needTransfer = false } } if needTransfer { // If destination already exists, then we must move it into --backup-dir if required if dstObj != nil && backupDir != nil { err = MoveBackupDir(ctx, backupDir, dstObj) if err != nil { logger(ctx, TransferError, dstObj, nil, err) return fmt.Errorf("moving to --backup-dir failed: %w", err) } // If successful zero out the dstObj as it is no longer there logger(ctx, MissingOnDst, dstObj, nil, nil) dstObj = nil } _, err = Op(ctx, fdst, dstObj, dstFileName, srcObj) } else { if !cp { if ci.IgnoreExisting { fs.Debugf(srcObj, "Not removing source file as destination file exists and --ignore-existing is set") logger(ctx, Match, srcObj, dstObj, nil) } else if !SameObject(srcObj, dstObj) { err = DeleteFile(ctx, srcObj) logger(ctx, Differ, srcObj, dstObj, nil) } } } return err } // MoveFile moves a single file possibly to a new name // // This is treated as a transfer. func MoveFile(ctx context.Context, fdst fs.Fs, fsrc fs.Fs, dstFileName string, srcFileName string) (err error) { return moveOrCopyFile(ctx, fdst, fsrc, dstFileName, srcFileName, false) } // SetTier changes tier of object in remote func SetTier(ctx context.Context, fsrc fs.Fs, tier string) error { return ListFn(ctx, fsrc, func(o fs.Object) { objImpl, ok := o.(fs.SetTierer) if !ok { fs.Errorf(fsrc, "Remote object does not implement SetTier") return } err := objImpl.SetTier(tier) if err != nil { fs.Errorf(fsrc, "Failed to do SetTier, %v", err) } }) } // SetTierFile changes tier of a single file in remote func SetTierFile(ctx context.Context, o fs.Object, tier string) error { do, ok := o.(fs.SetTierer) if !ok { return errors.New("remote object does not implement SetTier") } err := do.SetTier(tier) if err != nil { fs.Errorf(o, "Failed to do SetTier, %v", err) return err } return nil } // TouchDir touches every file in directory with time t func TouchDir(ctx context.Context, f fs.Fs, remote string, t time.Time, recursive bool) error { return walk.ListR(ctx, f, remote, false, ConfigMaxDepth(ctx, recursive), walk.ListObjects, func(entries fs.DirEntries) error { entries.ForObject(func(o fs.Object) { if !SkipDestructive(ctx, o, "touch") { fs.Debugf(f, "Touching %q", o.Remote()) err := o.SetModTime(ctx, t) if err != nil { err = fmt.Errorf("failed to touch: %w", err) err = fs.CountError(err) fs.Errorf(o, "%v", err) } } }) return nil }) } // ListFormat defines files information print format type ListFormat struct { separator string dirSlash bool absolute bool output []func(entry *ListJSONItem) string csv *csv.Writer buf bytes.Buffer } // SetSeparator changes separator in struct func (l *ListFormat) SetSeparator(separator string) { l.separator = separator } // SetDirSlash defines if slash should be printed func (l *ListFormat) SetDirSlash(dirSlash bool) { l.dirSlash = dirSlash } // SetAbsolute prints a leading slash in front of path names func (l *ListFormat) SetAbsolute(absolute bool) { l.absolute = absolute } // SetCSV defines if the output should be csv // // Note that you should call SetSeparator before this if you want a // custom separator func (l *ListFormat) SetCSV(useCSV bool) { if useCSV { l.csv = csv.NewWriter(&l.buf) if l.separator != "" { l.csv.Comma = []rune(l.separator)[0] } } else { l.csv = nil } } // SetOutput sets functions used to create files information func (l *ListFormat) SetOutput(output []func(entry *ListJSONItem) string) { l.output = output } // AddModTime adds file's Mod Time to output func (l *ListFormat) AddModTime(timeFormat string) { switch timeFormat { case "": timeFormat = "2006-01-02 15:04:05" case "Layout": timeFormat = time.Layout case "ANSIC": timeFormat = time.ANSIC case "UnixDate": timeFormat = time.UnixDate case "RubyDate": timeFormat = time.RubyDate case "RFC822": timeFormat = time.RFC822 case "RFC822Z": timeFormat = time.RFC822Z case "RFC850": timeFormat = time.RFC850 case "RFC1123": timeFormat = time.RFC1123 case "RFC1123Z": timeFormat = time.RFC1123Z case "RFC3339": timeFormat = time.RFC3339 case "RFC3339Nano": timeFormat = time.RFC3339Nano case "Kitchen": timeFormat = time.Kitchen case "Stamp": timeFormat = time.Stamp case "StampMilli": timeFormat = time.StampMilli case "StampMicro": timeFormat = time.StampMicro case "StampNano": timeFormat = time.StampNano case "DateTime": // timeFormat = time.DateTime // missing in go1.19 timeFormat = "2006-01-02 15:04:05" case "DateOnly": // timeFormat = time.DateOnly // missing in go1.19 timeFormat = "2006-01-02" case "TimeOnly": // timeFormat = time.TimeOnly // missing in go1.19 timeFormat = "15:04:05" } l.AppendOutput(func(entry *ListJSONItem) string { return entry.ModTime.When.Local().Format(timeFormat) }) } // AddSize adds file's size to output func (l *ListFormat) AddSize() { l.AppendOutput(func(entry *ListJSONItem) string { return strconv.FormatInt(entry.Size, 10) }) } // normalisePath makes sure the path has the correct slashes for the current mode func (l *ListFormat) normalisePath(entry *ListJSONItem, remote string) string { if l.absolute && !strings.HasPrefix(remote, "/") { remote = "/" + remote } if entry.IsDir && l.dirSlash { remote += "/" } return remote } // AddPath adds path to file to output func (l *ListFormat) AddPath() { l.AppendOutput(func(entry *ListJSONItem) string { return l.normalisePath(entry, entry.Path) }) } // AddEncrypted adds the encrypted path to file to output func (l *ListFormat) AddEncrypted() { l.AppendOutput(func(entry *ListJSONItem) string { return l.normalisePath(entry, entry.Encrypted) }) } // AddHash adds the hash of the type given to the output func (l *ListFormat) AddHash(ht hash.Type) { hashName := ht.String() l.AppendOutput(func(entry *ListJSONItem) string { if entry.IsDir { return "" } return entry.Hashes[hashName] }) } // AddID adds file's ID to the output if known func (l *ListFormat) AddID() { l.AppendOutput(func(entry *ListJSONItem) string { return entry.ID }) } // AddOrigID adds file's Original ID to the output if known func (l *ListFormat) AddOrigID() { l.AppendOutput(func(entry *ListJSONItem) string { return entry.OrigID }) } // AddTier adds file's Tier to the output if known func (l *ListFormat) AddTier() { l.AppendOutput(func(entry *ListJSONItem) string { return entry.Tier }) } // AddMimeType adds file's MimeType to the output if known func (l *ListFormat) AddMimeType() { l.AppendOutput(func(entry *ListJSONItem) string { return entry.MimeType }) } // AddMetadata adds file's Metadata to the output if known func (l *ListFormat) AddMetadata() { l.AppendOutput(func(entry *ListJSONItem) string { metadata := entry.Metadata if metadata == nil { metadata = make(fs.Metadata) } out, err := json.Marshal(metadata) if err != nil { return fmt.Sprintf("Failed to read metadata: %v", err.Error()) } return string(out) }) } // AppendOutput adds string generated by specific function to printed output func (l *ListFormat) AppendOutput(functionToAppend func(item *ListJSONItem) string) { l.output = append(l.output, functionToAppend) } // Format prints information about the DirEntry in the format defined func (l *ListFormat) Format(entry *ListJSONItem) (result string) { var out []string for _, fun := range l.output { out = append(out, fun(entry)) } if l.csv != nil { l.buf.Reset() _ = l.csv.Write(out) // can't fail writing to bytes.Buffer l.csv.Flush() result = strings.TrimRight(l.buf.String(), "\n") } else { result = strings.Join(out, l.separator) } return result } // FormatForLSFPrecision Returns a time format for the given precision func FormatForLSFPrecision(precision time.Duration) string { switch { case precision <= time.Nanosecond: return "2006-01-02 15:04:05.000000000" case precision <= 10*time.Nanosecond: return "2006-01-02 15:04:05.00000000" case precision <= 100*time.Nanosecond: return "2006-01-02 15:04:05.0000000" case precision <= time.Microsecond: return "2006-01-02 15:04:05.000000" case precision <= 10*time.Microsecond: return "2006-01-02 15:04:05.00000" case precision <= 100*time.Microsecond: return "2006-01-02 15:04:05.0000" case precision <= time.Millisecond: return "2006-01-02 15:04:05.000" case precision <= 10*time.Millisecond: return "2006-01-02 15:04:05.00" case precision <= 100*time.Millisecond: return "2006-01-02 15:04:05.0" } return "2006-01-02 15:04:05" } // DirMove renames srcRemote to dstRemote // // It does this by loading the directory tree into memory (using ListR // if available) and doing renames in parallel. func DirMove(ctx context.Context, f fs.Fs, srcRemote, dstRemote string) (err error) { ci := fs.GetConfig(ctx) if SkipDestructive(ctx, srcRemote, "dirMove") { accounting.Stats(ctx).Renames(1) return nil } // Use DirMove if possible if doDirMove := f.Features().DirMove; doDirMove != nil { err = doDirMove(ctx, f, srcRemote, dstRemote) if err == nil { accounting.Stats(ctx).Renames(1) } return err } // Load the directory tree into memory tree, err := walk.NewDirTree(ctx, f, srcRemote, true, -1) if err != nil { return fmt.Errorf("RenameDir tree walk: %w", err) } // Get the directories in sorted order dirs := tree.Dirs() // Make the destination directories - must be done in order not in parallel for _, dir := range dirs { dstPath := dstRemote + dir[len(srcRemote):] err := f.Mkdir(ctx, dstPath) if err != nil { return fmt.Errorf("RenameDir mkdir: %w", err) } } // Rename the files in parallel type rename struct { o fs.Object newPath string } renames := make(chan rename, ci.Checkers) g, gCtx := errgroup.WithContext(context.Background()) for i := 0; i < ci.Checkers; i++ { g.Go(func() error { for job := range renames { dstOverwritten, _ := f.NewObject(gCtx, job.newPath) _, err := Move(gCtx, f, dstOverwritten, job.newPath, job.o) if err != nil { return err } select { case <-gCtx.Done(): return gCtx.Err() default: } } return nil }) } for dir, entries := range tree { dstPath := dstRemote + dir[len(srcRemote):] for _, entry := range entries { if o, ok := entry.(fs.Object); ok { renames <- rename{o, path.Join(dstPath, path.Base(o.Remote()))} } } } close(renames) err = g.Wait() if err != nil { return fmt.Errorf("RenameDir renames: %w", err) } // Remove the source directories in reverse order for i := len(dirs) - 1; i >= 0; i-- { err := f.Rmdir(ctx, dirs[i]) if err != nil { return fmt.Errorf("RenameDir rmdir: %w", err) } } return nil } // DirMoveCaseInsensitive does DirMove in two steps (to temp name, then real name) // which is necessary for some case-insensitive backends func DirMoveCaseInsensitive(ctx context.Context, f fs.Fs, srcRemote, dstRemote string) (err error) { tmpDstRemote := dstRemote + "-rclone-move-" + random.String(8) err = DirMove(ctx, f, srcRemote, tmpDstRemote) if err != nil { return err } return DirMove(ctx, f, tmpDstRemote, dstRemote) } // FsInfo provides information about a remote type FsInfo struct { // Name of the remote (as passed into NewFs) Name string // Root of the remote (as passed into NewFs) Root string // String returns a description of the FS String string // Precision of the ModTimes in this Fs in Nanoseconds Precision time.Duration // Returns the supported hash types of the filesystem Hashes []string // Features returns the optional features of this Fs Features map[string]bool // MetadataInfo returns info about the metadata for this backend MetadataInfo *fs.MetadataInfo } // GetFsInfo gets the information (FsInfo) about a given Fs func GetFsInfo(f fs.Fs) *FsInfo { features := f.Features() info := &FsInfo{ Name: f.Name(), Root: f.Root(), String: f.String(), Precision: f.Precision(), Hashes: make([]string, 0, 4), Features: features.Enabled(), MetadataInfo: nil, } for _, hashType := range f.Hashes().Array() { info.Hashes = append(info.Hashes, hashType.String()) } fsInfo, _, _, _, err := fs.ParseRemote(fs.ConfigString(f)) if err == nil && fsInfo != nil && fsInfo.MetadataInfo != nil { info.MetadataInfo = fsInfo.MetadataInfo } return info } var ( interactiveMu sync.Mutex // protects the following variables skipped = map[string]bool{} ) // skipDestructiveChoose asks the user which action to take // // Call with interactiveMu held func skipDestructiveChoose(ctx context.Context, subject interface{}, action string) (skip bool) { // Lock the StdoutMutex - must not call fs.Log anything // otherwise it will deadlock with --interactive --progress StdoutMutex.Lock() fmt.Printf("\nrclone: %s \"%v\"?\n", action, subject) i := config.CommandDefault([]string{ "yYes, this is OK", "nNo, skip this", fmt.Sprintf("sSkip all %s operations with no more questions", action), fmt.Sprintf("!Do all %s operations with no more questions", action), "qExit rclone now.", }, 0) StdoutMutex.Unlock() switch i { case 'y': skip = false case 'n': skip = true case 's': skip = true skipped[action] = true fs.Logf(nil, "Skipping all %s operations from now on without asking", action) case '!': skip = false skipped[action] = false fs.Logf(nil, "Doing all %s operations from now on without asking", action) case 'q': fs.Logf(nil, "Quitting rclone now") atexit.Run() os.Exit(0) default: skip = true fs.Errorf(nil, "Bad choice %c", i) } return skip } // SkipDestructive should be called whenever rclone is about to do an destructive operation. // // It will check the --dry-run flag and it will ask the user if the --interactive flag is set. // // subject should be the object or directory in use // // action should be a descriptive word or short phrase // // Together they should make sense in this sentence: "Rclone is about // to action subject". func SkipDestructive(ctx context.Context, subject interface{}, action string) (skip bool) { var flag string ci := fs.GetConfig(ctx) switch { case ci.DryRun: flag = "--dry-run" skip = true case ci.Interactive: flag = "--interactive" interactiveMu.Lock() defer interactiveMu.Unlock() var found bool skip, found = skipped[action] if !found { skip = skipDestructiveChoose(ctx, subject, action) } default: return false } if skip { size := int64(-1) if do, ok := subject.(interface{ Size() int64 }); ok { size = do.Size() } if size >= 0 { fs.Logf(subject, "Skipped %s as %s is set (size %v)", fs.LogValue("skipped", action), flag, fs.LogValue("size", fs.SizeSuffix(size))) } else { fs.Logf(subject, "Skipped %s as %s is set", fs.LogValue("skipped", action), flag) } } return skip } // Return the best way of describing the directory for the logs func dirName(f fs.Fs, dst fs.Directory, dir string) any { if dst != nil { if dst.Remote() != "" { return dst } // Root is described as the Fs return f } if dir != "" { return dir } // Root is described as the Fs return f } // CopyDirMetadata copies the src directory to dst or f if nil. If dst is nil then it uses // dir as the name of the new directory. // // It returns the destination directory if possible. Note that this may // be nil. func CopyDirMetadata(ctx context.Context, f fs.Fs, dst fs.Directory, dir string, src fs.Directory) (newDst fs.Directory, err error) { ci := fs.GetConfig(ctx) logName := dirName(f, dst, dir) if SkipDestructive(ctx, logName, "update directory metadata") { return nil, nil } // Options for the directory metadata options := []fs.OpenOption{} if ci.MetadataSet != nil { options = append(options, fs.MetadataOption(ci.MetadataSet)) } // Read metadata from src and add options and use metadata mapper metadata, err := fs.GetMetadataOptions(ctx, f, src, options) if err != nil { return nil, err } // Fall back to ModTime if metadata not available if metadata == nil { metadata = fs.Metadata{} } if metadata["mtime"] == "" { metadata["mtime"] = src.ModTime(ctx).Format(time.RFC3339Nano) } // Now set the metadata if dst == nil { do := f.Features().MkdirMetadata if do == nil { return nil, fmt.Errorf("internal error: expecting %v to have MkdirMetadata method: %w", f, fs.ErrorNotImplemented) } newDst, err = do(ctx, dir, metadata) } else { do, ok := dst.(fs.SetMetadataer) if !ok { return nil, fmt.Errorf("internal error: expecting directory %s (%T) from %v to have SetMetadata method: %w", logName, dst, f, fs.ErrorNotImplemented) } err = do.SetMetadata(ctx, metadata) newDst = dst } if err != nil { return nil, err } fs.Infof(logName, "Updated directory metadata") return newDst, nil } // SetDirModTime sets the modtime on dst or dir // // If dst is nil then it uses dir as the name of the directory. // // It returns the destination directory if possible. Note that this // may be nil. // // It does not create the directory. func SetDirModTime(ctx context.Context, f fs.Fs, dst fs.Directory, dir string, modTime time.Time) (newDst fs.Directory, err error) { logName := dirName(f, dst, dir) if SkipDestructive(ctx, logName, "set directory modification time") { return nil, nil } if dst != nil { dir = dst.Remote() } // Try to set the ModTime with the Directory.SetModTime method first as this is the most efficient if dst != nil { if do, ok := dst.(fs.SetModTimer); ok { err := do.SetModTime(ctx, modTime) if err != nil { return dst, err } fs.Infof(logName, "Set directory modification time (using SetModTime)") return dst, nil } } // Next try to set the ModTime with the Fs.DirSetModTime method as this works for non-metadata backends if do := f.Features().DirSetModTime; do != nil { err := do(ctx, dir, modTime) if err != nil { return dst, err } fs.Infof(logName, "Set directory modification time (using DirSetModTime)") return dst, nil } // Something should have worked so return an error return nil, fmt.Errorf("no method to set directory modtime found for %v (%T): %w", f, dst, fs.ErrorNotImplemented) }