rclone/fs/operations/operations.go
Nick Craig-Wood e43b5ce5e5 Remove github.com/pkg/errors and replace with std library version
This is possible now that we no longer support go1.12 and brings
rclone into line with standard practices in the Go world.

This also removes errors.New and errors.Errorf from lib/errors and
prefers the stdlib errors package over lib/errors.
2021-11-07 11:53:30 +00:00

2280 lines
67 KiB
Go

// Package operations does generic operations on filesystems and objects
package operations
import (
"bytes"
"context"
"encoding/base64"
"encoding/csv"
"encoding/hex"
"errors"
"fmt"
"io"
"io/ioutil"
"net/http"
"os"
"path"
"path/filepath"
"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/pacer"
"github.com/rclone/rclone/lib/random"
"github.com/rclone/rclone/lib/readers"
"golang.org/x/sync/errgroup"
)
// 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
}
// 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)
g.Go(func() (err error) {
srcHash, err = src.Hash(ctx, ht)
if err != nil {
err = fs.CountError(err)
fs.Errorf(src, "Failed to calculate src hash: %v", err)
}
return err
})
g.Go(func() (err error) {
dstHash, err = dst.Hash(ctx, ht)
if err != nil {
err = fs.CountError(err)
fs.Errorf(dst, "Failed to calculate dst hash: %v", err)
}
return err
})
err = g.Wait()
if err != nil {
return false, ht, srcHash, dstHash, err
}
if srcHash == "" {
return true, hash.None, srcHash, dstHash, nil
}
if dstHash == "" {
return true, hash.None, srcHash, dstHash, nil
}
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))
}
// 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,
}
}
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.")
})
}
func equal(ctx context.Context, src fs.ObjectInfo, dst fs.Object, opt equalOpt) bool {
ci := fs.GetConfig(ctx)
if sizeDiffers(ctx, src, dst) {
fs.Debugf(src, "Sizes differ (src %d vs dst %d)", src.Size(), dst.Size())
return false
}
if opt.sizeOnly {
fs.Debugf(src, "Sizes identical")
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)
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)
}
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")
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)
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)
return false
}
if ht == hash.None && !ci.RefreshTimes {
// if couldn't check hash, return that they differ
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")
return false
}
// Update the mtime of the dst object here
err := dst.SetModTime(ctx, srcModTime)
if err == fs.ErrorCantSetModTime {
logModTimeUpload(dst)
fs.Infof(dst, "src and dst identical but can't set mod time without re-uploading")
return false
} else if 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)
}
}
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")
}
}
}
return true
}
// Used to remove a failed copy
//
// Returns whether the file was successfully removed or not
func removeFailedCopy(ctx context.Context, dst fs.Object) bool {
if dst == nil {
return false
}
fs.Infof(dst, "Removing failed copy")
removeErr := dst.Remove(ctx)
if removeErr != nil {
fs.Infof(dst, "Failed to remove failed copy: %s", removeErr)
return false
}
return true
}
// OverrideRemote is a wrapper to override the Remote for an
// ObjectInfo
type OverrideRemote struct {
fs.ObjectInfo
remote string
}
// NewOverrideRemote returns an OverrideRemoteObject which will
// return the remote specified
func NewOverrideRemote(oi fs.ObjectInfo, remote string) *OverrideRemote {
return &OverrideRemote{
ObjectInfo: oi,
remote: remote,
}
}
// Remote returns the overridden remote name
func (o *OverrideRemote) Remote() string {
return o.remote
}
// MimeType returns the mime type of the underlying object or "" if it
// can't be worked out
func (o *OverrideRemote) MimeType(ctx context.Context) string {
if do, ok := o.ObjectInfo.(fs.MimeTyper); ok {
return do.MimeType(ctx)
}
return ""
}
// ID returns the ID of the Object if known, or "" if not
func (o *OverrideRemote) ID() string {
if do, ok := o.ObjectInfo.(fs.IDer); ok {
return do.ID()
}
return ""
}
// UnWrap returns the Object that this Object is wrapping or nil if it
// isn't wrapping anything
func (o *OverrideRemote) UnWrap() fs.Object {
if o, ok := o.ObjectInfo.(fs.Object); ok {
return o
}
return nil
}
// GetTier returns storage tier or class of the Object
func (o *OverrideRemote) GetTier() string {
if do, ok := o.ObjectInfo.(fs.GetTierer); ok {
return do.GetTier()
}
return ""
}
// Check all optional interfaces satisfied
var _ fs.FullObjectInfo = (*OverrideRemote)(nil)
// 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}
}
// Copy src object to dst or f if nil. If dst is nil then it uses
// remote as the name of the new object.
//
// It returns the destination object if possible. Note that this may
// be nil.
func Copy(ctx context.Context, f fs.Fs, dst fs.Object, remote string, src fs.Object) (newDst fs.Object, err error) {
ci := fs.GetConfig(ctx)
tr := accounting.Stats(ctx).NewTransfer(src)
defer func() {
tr.Done(ctx, err)
}()
newDst = dst
if SkipDestructive(ctx, src, "copy") {
in := tr.Account(ctx, nil)
in.DryRun(src.Size())
return newDst, nil
}
maxTries := ci.LowLevelRetries
tries := 0
doUpdate := dst != nil
hashType, hashOption := CommonHash(ctx, f, src.Fs())
var actionTaken string
for {
// Try server-side copy first - if has optional interface and
// is same underlying remote
actionTaken = "Copied (server-side copy)"
if ci.MaxTransfer >= 0 {
var bytesSoFar int64
if ci.CutoffMode == fs.CutoffModeCautious {
bytesSoFar = accounting.Stats(ctx).GetBytesWithPending() + src.Size()
} else {
bytesSoFar = accounting.Stats(ctx).GetBytes()
}
if bytesSoFar >= int64(ci.MaxTransfer) {
if ci.CutoffMode == fs.CutoffModeHard {
return nil, accounting.ErrorMaxTransferLimitReachedFatal
}
return nil, accounting.ErrorMaxTransferLimitReachedGraceful
}
}
if doCopy := f.Features().Copy; doCopy != nil && (SameConfig(src.Fs(), f) || (SameRemoteType(src.Fs(), f) && f.Features().ServerSideAcrossConfigs)) {
in := tr.Account(ctx, nil) // account the transfer
in.ServerSideCopyStart()
newDst, err = doCopy(ctx, src, remote)
if err == nil {
dst = newDst
in.ServerSideCopyEnd(dst.Size()) // account the bytes for the server-side transfer
err = in.Close()
} else {
_ = in.Close()
}
if err == fs.ErrorCantCopy {
tr.Reset(ctx) // skip incomplete accounting - will be overwritten by the manual copy below
}
} else {
err = fs.ErrorCantCopy
}
// If can't server-side copy, do it manually
if err == fs.ErrorCantCopy {
if doMultiThreadCopy(ctx, f, src) {
// Number of streams proportional to size
streams := src.Size() / int64(ci.MultiThreadCutoff)
// With maximum
if streams > int64(ci.MultiThreadStreams) {
streams = int64(ci.MultiThreadStreams)
}
if streams < 2 {
streams = 2
}
dst, err = multiThreadCopy(ctx, f, remote, src, int(streams), tr)
if doUpdate {
actionTaken = "Multi-thread Copied (replaced existing)"
} else {
actionTaken = "Multi-thread Copied (new)"
}
} else {
var in0 io.ReadCloser
options := []fs.OpenOption{hashOption}
for _, option := range ci.DownloadHeaders {
options = append(options, option)
}
in0, err = NewReOpen(ctx, src, ci.LowLevelRetries, options...)
if err != nil {
err = fmt.Errorf("failed to open source object: %w", err)
} else {
if src.Size() == -1 {
// -1 indicates unknown size. Use Rcat to handle both remotes supporting and not supporting PutStream.
if doUpdate {
actionTaken = "Copied (Rcat, replaced existing)"
} else {
actionTaken = "Copied (Rcat, new)"
}
// NB Rcat closes in0
dst, err = Rcat(ctx, f, remote, in0, src.ModTime(ctx))
newDst = dst
} else {
in := tr.Account(ctx, in0).WithBuffer() // account and buffer the transfer
var wrappedSrc fs.ObjectInfo = src
// We try to pass the original object if possible
if src.Remote() != remote {
wrappedSrc = NewOverrideRemote(src, remote)
}
options := []fs.OpenOption{hashOption}
for _, option := range ci.UploadHeaders {
options = append(options, option)
}
if doUpdate {
actionTaken = "Copied (replaced existing)"
err = dst.Update(ctx, in, wrappedSrc, options...)
} else {
actionTaken = "Copied (new)"
dst, err = f.Put(ctx, in, wrappedSrc, options...)
}
closeErr := in.Close()
if err == nil {
newDst = dst
err = closeErr
}
}
}
}
}
tries++
if tries >= maxTries {
break
}
// Retry if err returned a retry error
if fserrors.ContextError(ctx, &err) {
break
}
var retry bool
if fserrors.IsRetryError(err) || fserrors.ShouldRetry(err) {
retry = true
} else if t, ok := pacer.IsRetryAfter(err); ok {
fs.Debugf(src, "Sleeping for %v (as indicated by the server) to obey Retry-After error: %v", t, err)
time.Sleep(t)
retry = true
}
if retry {
fs.Debugf(src, "Received error: %v - low level retry %d/%d", err, tries, maxTries)
tr.Reset(ctx) // skip incomplete accounting - will be overwritten by retry
continue
}
// otherwise finish
break
}
if err != nil {
err = fs.CountError(err)
fs.Errorf(src, "Failed to copy: %v", err)
return newDst, err
}
// Verify sizes are the same after transfer
if sizeDiffers(ctx, src, dst) {
err = fmt.Errorf("corrupted on transfer: sizes differ %d vs %d", src.Size(), dst.Size())
fs.Errorf(dst, "%v", err)
err = fs.CountError(err)
removeFailedCopy(ctx, dst)
return newDst, err
}
// Verify hashes are the same after transfer - ignoring blank hashes
if hashType != hash.None {
// checkHashes has logged and counted errors
equal, _, srcSum, dstSum, _ := checkHashes(ctx, src, dst, hashType)
if !equal {
err = fmt.Errorf("corrupted on transfer: %v hash differ %q vs %q", hashType, srcSum, dstSum)
fs.Errorf(dst, "%v", err)
err = fs.CountError(err)
removeFailedCopy(ctx, dst)
return newDst, err
}
}
if newDst != nil && src.String() != newDst.String() {
fs.Infof(src, "%s to: %s", actionTaken, newDst.String())
} else {
fs.Infof(src, actionTaken)
}
return newDst, err
}
// 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 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.
func Move(ctx context.Context, fdst fs.Fs, dst fs.Object, remote string, src fs.Object) (newDst fs.Object, err error) {
tr := accounting.Stats(ctx).NewCheckingTransfer(src)
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)) {
// 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 && !SameObject(src, dst) {
err = DeleteFile(ctx, dst)
if err != nil {
return newDst, err
}
}
// Move dst <- src
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)")
}
return newDst, nil
case fs.ErrorCantMove:
fs.Debugf(src, "Can't move, switching to copy")
default:
err = fs.CountError(err)
fs.Errorf(src, "Couldn't move: %v", err)
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 {
ext := path.Ext(remote)
base := remote[:len(remote)-len(ext)]
return base + ci.Suffix + ext
}
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) {
ci := fs.GetConfig(ctx)
tr := accounting.Stats(ctx).NewCheckingTransfer(dst)
defer func() {
tr.Done(ctx, err)
}()
numDeletes := accounting.Stats(ctx).Deletes(1)
if ci.MaxDelete != -1 && numDeletes > ci.MaxDelete {
return fserrors.FatalError(errors.New("--max-delete threshold reached"))
}
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.Transfers)
var errorCount int32
var fatalErrorCount int32
for i := 0; i < ci.Transfers; i++ {
go func() {
defer wg.Done()
for dst := range toBeDeleted {
err := DeleteFileWithBackupDir(ctx, dst, backupDir)
if err != nil {
atomic.AddInt32(&errorCount, 1)
if fserrors.IsFatalError(err) {
fs.Errorf(nil, "Got fatal error on delete: %s", err)
atomic.AddInt32(&fatalErrorCount, 1)
return
}
}
}
}()
}
fs.Debugf(nil, "Waiting for deletions to finish")
wg.Wait()
if errorCount > 0 {
err := fmt.Errorf("failed to delete %d files", errorCount)
if fatalErrorCount > 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 is
// aware of case insensitive filesystems.
func fixRoot(f fs.Info) string {
s := strings.Trim(filepath.ToSlash(f.Root()), "/")
if s != "" {
s += "/"
}
if f.Features().CaseInsensitive {
s = strings.ToLower(s)
}
return s
}
// Overlapping returns true if fdst and fsrc point to the same
// underlying Fs and they overlap.
func Overlapping(fdst, fsrc fs.Info) bool {
if !SameConfig(fdst, fsrc) {
return false
}
fdstRoot := fixRoot(fdst)
fsrcRoot := fixRoot(fsrc)
return strings.HasPrefix(fdstRoot, fsrcRoot) || strings.HasPrefix(fsrcRoot, fdstRoot)
}
// 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
}
fdstRoot := fixRoot(fdst)
fsrcRoot := fixRoot(fsrc)
return fdstRoot == fsrcRoot
}
// 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
})
}
// mutex for synchronized output
var outMutex sync.Mutex
// SyncPrintf is a global var holding the Printf function used in syncFprintf so that it can be overridden
// Note, despite name, does not provide sync and should not be called directly
// Call syncFprintf, which provides sync
var SyncPrintf = func(format string, a ...interface{}) {
fmt.Printf(format, a...)
}
// Synchronized fmt.Fprintf
//
// Ignores errors from Fprintf
//
// Updated to print to terminal if no writer is defined
// This special behavior is used to allow easier replacement of the print to terminal code by progress
func syncFprintf(w io.Writer, format string, a ...interface{}) {
outMutex.Lock()
defer outMutex.Unlock()
if w == nil || w == os.Stdout {
SyncPrintf(format, a...)
} else {
_, _ = 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)
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, 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)
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)
}
in, err := NewReOpen(ctx, o, fs.GetConfig(ctx).LowLevelRetries, 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 and encode as hex
byteSum, err := hasher.Sum(ht)
if err != nil {
return "ERROR", fmt.Errorf("Hasher returned an error: %w", err)
}
sum = hex.EncodeToString(byteSum)
} else {
tr := accounting.Stats(ctx).NewCheckingTransfer(o)
defer func() {
tr.Done(ctx, err)
}()
sum, err = o.Hash(ctx, ht)
if err == hash.ErrUnsupported {
return "", fmt.Errorf("Hash unsupported: %w", err)
}
if err != nil {
return "", fmt.Errorf("Failed to get hash %v from backend: %v: %w", ht, err, 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)
if outputBase64 {
width = base64.URLEncoding.EncodedLen(width / 2)
}
concurrencyControl := make(chan struct{}, fs.GetConfig(ctx).Transfers)
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, downloadFlag, o)
if err != nil {
fs.Errorf(o, "%v", fs.CountError(err))
return
}
if outputBase64 {
hexBytes, _ := hex.DecodeString(sum)
sum = base64.URLEncoding.EncodeToString(hexBytes)
}
syncFprintf(w, "%*s %s\n", width, sum, o.Remote())
}()
})
wg.Wait()
return err
}
// 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, err error) {
err = ListFn(ctx, f, func(o fs.Object) {
atomic.AddInt64(&objects, 1)
objectSize := o.Size()
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
}
// 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 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.Transfers)
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) 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)
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)
}
in, err := o.Open(ctx, 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)
}
})
}
// 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) (dst fs.Object, err error) {
ci := fs.GetConfig(ctx)
tr := accounting.Stats(ctx).NewTransferRemoteSize(dstFileName, -1)
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)
}
compare := func(dst fs.Object) error {
var sums map[hash.Type]string
if hasher != nil {
sums = hasher.Sums()
}
src := object.NewStaticObjectInfo(dstFileName, modTime, int64(readCounter.BytesRead()), false, sums, fdst)
if !Equal(ctx, src, dst) {
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])
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(ioutil.Discard, in)
return nil, err
}
objInfo := object.NewStaticObjectInfo(dstFileName, modTime, -1, false, nil, nil)
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
return Copy(ctx, 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)
}
// Now delete the empty directories, starting from the longest path
var toDelete []string
for dir, empty := range dirEmpty {
if empty {
toDelete = append(toDelete, dir)
}
}
sort.Strings(toDelete)
for i := len(toDelete) - 1; i >= 0; i-- {
dir := toDelete[i]
// If a filter matches the directory then that
// directory is a candidate for deletion
if !fi.Include(dir+"/", 0, time.Now()) {
continue
}
err = TryRmdir(ctx, f, dir)
if err != nil {
err = fs.CountError(err)
fs.Errorf(dir, "Failed to rmdir: %v", err)
return err
}
}
return nil
}
// 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: %v", 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: %v", 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)
if dst == nil {
fs.Debugf(src, "Need to transfer - File not found at Destination")
return true
}
// If we should ignore existing files, don't transfer
if ci.IgnoreExisting {
fs.Debugf(src, "Destination exists, skipping")
return false
}
// If we should upload unconditionally
if ci.IgnoreTimes {
fs.Debugf(src, "Transferring unconditionally as --ignore-times is in use")
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")
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
if Equal(ctx, 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) (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)
defer func() {
tr.Done(ctx, err)
}()
body := ioutil.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(ioutil.Discard, in)
return nil, err
}
info := object.NewStaticObjectInfo(dstFileName, modTime, size, true, nil, fdst)
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)
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, dstFileNameFromURL 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 dstFileNameFromURL {
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, dstFileNameFromURL bool, noClobber bool) (dst fs.Object, err error) {
err = copyURLFn(ctx, dstFileName, url, dstFileNameFromURL, 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)
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, 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: %v", 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 Overlapping(fdst, backupDir) {
return nil, fserrors.FatalError(errors.New("destination and parameter to --backup-dir mustn't overlap"))
}
if Overlapping(fsrc, backupDir) {
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
}
// 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)
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)
return nil
}
// Choose operations
Op := Move
if cp {
Op = Copy
}
// Find src object
srcObj, err := fsrc.NewObject(ctx, srcFileName)
if err != nil {
return err
}
// Find dst object if it exists
var dstObj fs.Object
if !ci.NoCheckDest {
dstObj, err = fdst.NewObject(ctx, dstFileName)
if err == fs.ErrorObjectNotFound {
dstObj = nil
} else if err != nil {
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 !cp && fdst.Name() == fsrc.Name() && fdst.Features().CaseInsensitive && dstFileName != srcFileName && strings.EqualFold(dstFilePath, srcFilePath) {
// Create random name to temporarily move file to
tmpObjName := dstFileName + "-rclone-move-" + random.String(8)
_, err := fdst.NewObject(ctx, tmpObjName)
if err != fs.ErrorObjectNotFound {
if err == nil {
return errors.New("found an already existing file with a randomly generated name. Try the operation again")
}
return fmt.Errorf("error while attempting to move file to a temporary location: %w", err)
}
tr := accounting.Stats(ctx).NewTransfer(srcObj)
defer func() {
tr.Done(ctx, err)
}()
tmpObj, err := Op(ctx, fdst, nil, tmpObjName, srcObj)
if err != nil {
return fmt.Errorf("error while moving file to temporary location: %w", err)
}
_, err = Op(ctx, fdst, nil, dstFileName, tmpObj)
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
}
}
NoNeedTransfer, err := CompareOrCopyDest(ctx, fdst, dstObj, srcObj, copyDestDir, backupDir)
if err != nil {
return err
}
if !NoNeedTransfer && NeedTransfer(ctx, dstObj, srcObj) {
// 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 {
return fmt.Errorf("moving to --backup-dir failed: %w", err)
}
// If successful zero out the dstObj as it is no longer there
dstObj = nil
}
_, err = Op(ctx, fdst, dstObj, dstFileName, srcObj)
} else {
tr := accounting.Stats(ctx).NewCheckingTransfer(srcObj)
if !cp {
if ci.IgnoreExisting {
fs.Debugf(srcObj, "Not removing source file as destination file exists and --ignore-existing is set")
} else {
err = DeleteFile(ctx, srcObj)
}
}
tr.Done(ctx, err)
}
return err
}
// MoveFile moves a single file possibly to a new name
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)
}
// CopyFile moves a single file possibly to a new name
func CopyFile(ctx context.Context, fdst fs.Fs, fsrc fs.Fs, dstFileName string, srcFileName string) (err error) {
return moveOrCopyFile(ctx, fdst, fsrc, dstFileName, srcFileName, true)
}
// 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)
}
})
}
// TouchDir touches every file in f with time t
func TouchDir(ctx context.Context, f fs.Fs, t time.Time, recursive bool) error {
return walk.ListR(ctx, f, "", 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() {
l.AppendOutput(func(entry *ListJSONItem) string {
return entry.ModTime.When.Local().Format("2006-01-02 15:04:05")
})
}
// 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
})
}
// 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
}
// 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.Transfers)
g, gCtx := errgroup.WithContext(context.Background())
for i := 0; i < ci.Transfers; 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
}
// 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
}
// GetFsInfo gets the information (FsInfo) about a given Fs
func GetFsInfo(f fs.Fs) *FsInfo {
info := &FsInfo{
Name: f.Name(),
Root: f.Root(),
String: f.String(),
Precision: f.Precision(),
Hashes: make([]string, 0, 4),
Features: f.Features().Enabled(),
}
for _, hashType := range f.Hashes().Array() {
info.Hashes = append(info.Hashes, hashType.String())
}
return info
}
var (
interactiveMu sync.Mutex
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) {
fmt.Printf("rclone: %s \"%v\"?\n", action, subject)
switch 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); 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
}