rclone/backend/compress/compress.go

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// Package compress provides wrappers for Fs and Object which implement compression.
package compress
import (
"bufio"
"bytes"
"context"
"crypto/md5"
"encoding/base64"
"encoding/binary"
"encoding/hex"
"encoding/json"
"errors"
"fmt"
"io"
"os"
"path"
"regexp"
"strings"
"time"
"github.com/buengese/sgzip"
"github.com/gabriel-vasile/mimetype"
"github.com/rclone/rclone/fs"
"github.com/rclone/rclone/fs/accounting"
"github.com/rclone/rclone/fs/chunkedreader"
"github.com/rclone/rclone/fs/config/configmap"
"github.com/rclone/rclone/fs/config/configstruct"
"github.com/rclone/rclone/fs/fspath"
"github.com/rclone/rclone/fs/hash"
"github.com/rclone/rclone/fs/log"
"github.com/rclone/rclone/fs/object"
"github.com/rclone/rclone/fs/operations"
)
// Globals
const (
initialChunkSize = 262144 // Initial and max sizes of chunks when reading parts of the file. Currently
maxChunkSize = 8388608 // at 256 KiB and 8 MiB.
bufferSize = 8388608
heuristicBytes = 1048576
minCompressionRatio = 1.1
gzFileExt = ".gz"
metaFileExt = ".json"
uncompressedFileExt = ".bin"
)
// Compression modes
const (
Uncompressed = 0
Gzip = 2
)
var nameRegexp = regexp.MustCompile(`^(.+?)\.([A-Za-z0-9-_]{11})$`)
// Register with Fs
func init() {
// Build compression mode options.
compressionModeOptions := []fs.OptionExample{
{ // Default compression mode options {
Value: "gzip",
Help: "Standard gzip compression with fastest parameters.",
},
}
// Register our remote
fs.Register(&fs.RegInfo{
Name: "compress",
Description: "Compress a remote",
NewFs: NewFs,
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MetadataInfo: &fs.MetadataInfo{
Help: `Any metadata supported by the underlying remote is read and written.`,
},
Options: []fs.Option{{
Name: "remote",
Help: "Remote to compress.",
Required: true,
}, {
Name: "mode",
Help: "Compression mode.",
Default: "gzip",
Examples: compressionModeOptions,
}, {
Name: "level",
Help: `GZIP compression level (-2 to 9).
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Generally -1 (default, equivalent to 5) is recommended.
Levels 1 to 9 increase compression at the cost of speed. Going past 6
generally offers very little return.
Level -2 uses Huffman encoding only. Only use if you know what you
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are doing.
Level 0 turns off compression.`,
Default: sgzip.DefaultCompression,
Advanced: true,
}, {
Name: "ram_cache_limit",
Help: `Some remotes don't allow the upload of files with unknown size.
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In this case the compressed file will need to be cached to determine
it's size.
Files smaller than this limit will be cached in RAM, files larger than
this limit will be cached on disk.`,
Default: fs.SizeSuffix(20 * 1024 * 1024),
Advanced: true,
}},
})
}
// Options defines the configuration for this backend
type Options struct {
Remote string `config:"remote"`
CompressionMode string `config:"mode"`
CompressionLevel int `config:"level"`
RAMCacheLimit fs.SizeSuffix `config:"ram_cache_limit"`
}
/*** FILESYSTEM FUNCTIONS ***/
// Fs represents a wrapped fs.Fs
type Fs struct {
fs.Fs
wrapper fs.Fs
name string
root string
opt Options
mode int // compression mode id
features *fs.Features // optional features
}
// NewFs constructs an Fs from the path, container:path
func NewFs(ctx context.Context, name, rpath string, m configmap.Mapper) (fs.Fs, error) {
// Parse config into Options struct
opt := new(Options)
err := configstruct.Set(m, opt)
if err != nil {
return nil, err
}
remote := opt.Remote
if strings.HasPrefix(remote, name+":") {
return nil, errors.New("can't point press remote at itself - check the value of the remote setting")
}
wInfo, wName, wPath, wConfig, err := fs.ConfigFs(remote)
if err != nil {
return nil, fmt.Errorf("failed to parse remote %q to wrap: %w", remote, err)
}
// Strip trailing slashes if they exist in rpath
rpath = strings.TrimRight(rpath, "\\/")
// First, check for a file
// If a metadata file was found, return an error. Otherwise, check for a directory
remotePath := fspath.JoinRootPath(wPath, makeMetadataName(rpath))
wrappedFs, err := wInfo.NewFs(ctx, wName, remotePath, wConfig)
if err != fs.ErrorIsFile {
remotePath = fspath.JoinRootPath(wPath, rpath)
wrappedFs, err = wInfo.NewFs(ctx, wName, remotePath, wConfig)
}
if err != nil && err != fs.ErrorIsFile {
return nil, fmt.Errorf("failed to make remote %s:%q to wrap: %w", wName, remotePath, err)
}
// Create the wrapping fs
f := &Fs{
Fs: wrappedFs,
name: name,
root: rpath,
opt: *opt,
mode: compressionModeFromName(opt.CompressionMode),
}
// Correct root if definitely pointing to a file
if err == fs.ErrorIsFile {
f.root = path.Dir(f.root)
if f.root == "." || f.root == "/" {
f.root = ""
}
}
// the features here are ones we could support, and they are
// ANDed with the ones from wrappedFs
f.features = (&fs.Features{
CaseInsensitive: true,
DuplicateFiles: false,
ReadMimeType: false,
WriteMimeType: false,
GetTier: true,
SetTier: true,
BucketBased: true,
CanHaveEmptyDirectories: true,
ReadMetadata: true,
WriteMetadata: true,
UserMetadata: true,
ReadDirMetadata: true,
WriteDirMetadata: true,
WriteDirSetModTime: true,
UserDirMetadata: true,
DirModTimeUpdatesOnWrite: true,
PartialUploads: true,
}).Fill(ctx, f).Mask(ctx, wrappedFs).WrapsFs(f, wrappedFs)
// We support reading MIME types no matter the wrapped fs
f.features.ReadMimeType = true
// We can only support putstream if we have serverside copy or move
if !operations.CanServerSideMove(wrappedFs) {
f.features.Disable("PutStream")
}
return f, err
}
func compressionModeFromName(name string) int {
switch name {
case "gzip":
return Gzip
default:
return Uncompressed
}
}
// Converts an int64 to base64
func int64ToBase64(number int64) string {
intBytes := make([]byte, 8)
binary.LittleEndian.PutUint64(intBytes, uint64(number))
return base64.RawURLEncoding.EncodeToString(intBytes)
}
// Converts base64 to int64
func base64ToInt64(str string) (int64, error) {
intBytes, err := base64.RawURLEncoding.DecodeString(str)
if err != nil {
return 0, err
}
return int64(binary.LittleEndian.Uint64(intBytes)), nil
}
// Processes a file name for a compressed file. Returns the original file name, the extension, and the size of the original file.
// Returns -2 for the original size if the file is uncompressed.
func processFileName(compressedFileName string) (origFileName string, extension string, origSize int64, err error) {
// Separate the filename and size from the extension
extensionPos := strings.LastIndex(compressedFileName, ".")
if extensionPos == -1 {
return "", "", 0, errors.New("file name has no extension")
}
extension = compressedFileName[extensionPos:]
nameWithSize := compressedFileName[:extensionPos]
if extension == uncompressedFileExt {
return nameWithSize, extension, -2, nil
}
match := nameRegexp.FindStringSubmatch(nameWithSize)
if match == nil || len(match) != 3 {
return "", "", 0, errors.New("invalid filename")
}
size, err := base64ToInt64(match[2])
if err != nil {
return "", "", 0, errors.New("could not decode size")
}
return match[1], gzFileExt, size, nil
}
// Generates the file name for a metadata file
func makeMetadataName(remote string) (newRemote string) {
return remote + metaFileExt
}
// Checks whether a file is a metadata file
func isMetadataFile(filename string) bool {
return strings.HasSuffix(filename, metaFileExt)
}
// Checks whether a file is a metadata file and returns the original
// file name and a flag indicating whether it was a metadata file or
// not.
func unwrapMetadataFile(filename string) (string, bool) {
if !isMetadataFile(filename) {
return "", false
}
return filename[:len(filename)-len(metaFileExt)], true
}
// makeDataName generates the file name for a data file with specified compression mode
func makeDataName(remote string, size int64, mode int) (newRemote string) {
if mode != Uncompressed {
newRemote = remote + "." + int64ToBase64(size) + gzFileExt
} else {
newRemote = remote + uncompressedFileExt
}
return newRemote
}
// dataName generates the file name for data file
func (f *Fs) dataName(remote string, size int64, compressed bool) (name string) {
if !compressed {
return makeDataName(remote, size, Uncompressed)
}
return makeDataName(remote, size, f.mode)
}
// addData parses an object and adds it to the DirEntries
func (f *Fs) addData(entries *fs.DirEntries, o fs.Object) {
origFileName, _, size, err := processFileName(o.Remote())
if err != nil {
fs.Errorf(o, "Error on parsing file name: %v", err)
return
}
if size == -2 { // File is uncompressed
size = o.Size()
}
metaName := makeMetadataName(origFileName)
*entries = append(*entries, f.newObjectSizeAndNameOnly(o, metaName, size))
}
// addDir adds a dir to the dir entries
func (f *Fs) addDir(entries *fs.DirEntries, dir fs.Directory) {
*entries = append(*entries, f.newDir(dir))
}
// newDir returns a dir
func (f *Fs) newDir(dir fs.Directory) fs.Directory {
return dir // We're using the same dir
}
// processEntries parses the file names and adds metadata to the dir entries
func (f *Fs) processEntries(entries fs.DirEntries) (newEntries fs.DirEntries, err error) {
newEntries = entries[:0] // in place filter
for _, entry := range entries {
switch x := entry.(type) {
case fs.Object:
if !isMetadataFile(x.Remote()) {
f.addData(&newEntries, x) // Only care about data files for now; metadata files are redundant.
}
case fs.Directory:
f.addDir(&newEntries, x)
default:
return nil, fmt.Errorf("unknown object type %T", entry)
}
}
return newEntries, nil
}
// List the objects and directories in dir into entries. The
// entries can be returned in any order but should be for a
// complete directory.
//
// dir should be "" to list the root, and should not have
// trailing slashes.
//
// This should return ErrDirNotFound if the directory isn't
// found.
// List entries and process them
func (f *Fs) List(ctx context.Context, dir string) (entries fs.DirEntries, err error) {
entries, err = f.Fs.List(ctx, dir)
if err != nil {
return nil, err
}
return f.processEntries(entries)
}
// ListR lists the objects and directories of the Fs starting
// from dir recursively into out.
//
// dir should be "" to start from the root, and should not
// have trailing slashes.
//
// This should return ErrDirNotFound if the directory isn't
// found.
//
// It should call callback for each tranche of entries read.
// These need not be returned in any particular order. If
// callback returns an error then the listing will stop
// immediately.
//
// Don't implement this unless you have a more efficient way
// of listing recursively that doing a directory traversal.
func (f *Fs) ListR(ctx context.Context, dir string, callback fs.ListRCallback) (err error) {
return f.Fs.Features().ListR(ctx, dir, func(entries fs.DirEntries) error {
newEntries, err := f.processEntries(entries)
if err != nil {
return err
}
return callback(newEntries)
})
}
// NewObject finds the Object at remote.
func (f *Fs) NewObject(ctx context.Context, remote string) (fs.Object, error) {
// Read metadata from metadata object
mo, err := f.Fs.NewObject(ctx, makeMetadataName(remote))
if err != nil {
return nil, err
}
meta, err := readMetadata(ctx, mo)
if err != nil {
return nil, fmt.Errorf("error decoding metadata: %w", err)
}
// Create our Object
o, err := f.Fs.NewObject(ctx, makeDataName(remote, meta.CompressionMetadata.Size, meta.Mode))
if err != nil {
return nil, err
}
return f.newObject(o, mo, meta), nil
}
// checkCompressAndType checks if an object is compressible and determines it's mime type
// returns a multireader with the bytes that were read to determine mime type
func checkCompressAndType(in io.Reader) (newReader io.Reader, compressible bool, mimeType string, err error) {
in, wrap := accounting.UnWrap(in)
buf := make([]byte, heuristicBytes)
n, err := in.Read(buf)
buf = buf[:n]
if err != nil && err != io.EOF {
return nil, false, "", err
}
mime := mimetype.Detect(buf)
compressible, err = isCompressible(bytes.NewReader(buf))
if err != nil {
return nil, false, "", err
}
in = io.MultiReader(bytes.NewReader(buf), in)
return wrap(in), compressible, mime.String(), nil
}
// isCompressible checks the compression ratio of the provided data and returns true if the ratio exceeds
// the configured threshold
func isCompressible(r io.Reader) (bool, error) {
var b bytes.Buffer
w, err := sgzip.NewWriterLevel(&b, sgzip.DefaultCompression)
if err != nil {
return false, err
}
n, err := io.Copy(w, r)
if err != nil {
return false, err
}
err = w.Close()
if err != nil {
return false, err
}
ratio := float64(n) / float64(b.Len())
return ratio > minCompressionRatio, nil
}
// verifyObjectHash verifies the Objects hash
func (f *Fs) verifyObjectHash(ctx context.Context, o fs.Object, hasher *hash.MultiHasher, ht hash.Type) error {
srcHash := hasher.Sums()[ht]
dstHash, err := o.Hash(ctx, ht)
if err != nil {
return fmt.Errorf("failed to read destination hash: %w", err)
}
if srcHash != "" && dstHash != "" && srcHash != dstHash {
// remove object
err = o.Remove(ctx)
if err != nil {
fs.Errorf(o, "Failed to remove corrupted object: %v", err)
}
return fmt.Errorf("corrupted on transfer: %v compressed hashes differ src(%s) %q vs dst(%s) %q", ht, f.Fs, srcHash, o.Fs(), dstHash)
}
return nil
}
type putFn func(ctx context.Context, in io.Reader, src fs.ObjectInfo, options ...fs.OpenOption) (fs.Object, error)
type compressionResult struct {
err error
meta sgzip.GzipMetadata
}
// replicating some of operations.Rcat functionality because we want to support remotes without streaming
// support and of course cannot know the size of a compressed file before compressing it.
func (f *Fs) rcat(ctx context.Context, dstFileName string, in io.ReadCloser, modTime time.Time, options []fs.OpenOption) (o fs.Object, err error) {
// cache small files in memory and do normal upload
buf := make([]byte, f.opt.RAMCacheLimit)
if n, err := io.ReadFull(in, buf); err == io.EOF || err == io.ErrUnexpectedEOF {
src := object.NewStaticObjectInfo(dstFileName, modTime, int64(len(buf[:n])), false, nil, f.Fs)
return f.Fs.Put(ctx, bytes.NewBuffer(buf[:n]), src, options...)
}
// Need to include what we already read
in = &ReadCloserWrapper{
Reader: io.MultiReader(bytes.NewReader(buf), in),
Closer: in,
}
canStream := f.Fs.Features().PutStream != nil
if canStream {
src := object.NewStaticObjectInfo(dstFileName, modTime, -1, false, nil, f.Fs)
return f.Fs.Features().PutStream(ctx, in, src, options...)
}
fs.Debugf(f, "Target remote doesn't support streaming uploads, creating temporary local file")
tempFile, err := os.CreateTemp("", "rclone-press-")
defer func() {
// these errors should be relatively uncritical and the upload should've succeeded so it's okay-ish
// to ignore them
_ = tempFile.Close()
_ = os.Remove(tempFile.Name())
}()
if err != nil {
return nil, fmt.Errorf("failed to create temporary local FS to spool file: %w", err)
}
if _, err = io.Copy(tempFile, in); err != nil {
return nil, fmt.Errorf("failed to write temporary local file: %w", err)
}
if _, err = tempFile.Seek(0, 0); err != nil {
return nil, err
}
finfo, err := tempFile.Stat()
if err != nil {
return nil, err
}
return f.Fs.Put(ctx, tempFile, object.NewStaticObjectInfo(dstFileName, modTime, finfo.Size(), false, nil, f.Fs))
}
// Put a compressed version of a file. Returns a wrappable object and metadata.
func (f *Fs) putCompress(ctx context.Context, in io.Reader, src fs.ObjectInfo, options []fs.OpenOption, mimeType string) (fs.Object, *ObjectMetadata, error) {
// Unwrap reader accounting
in, wrap := accounting.UnWrap(in)
// Add the metadata hasher
metaHasher := md5.New()
in = io.TeeReader(in, metaHasher)
// Compress the file
pipeReader, pipeWriter := io.Pipe()
results := make(chan compressionResult)
go func() {
gz, err := sgzip.NewWriterLevel(pipeWriter, f.opt.CompressionLevel)
if err != nil {
results <- compressionResult{err: err, meta: sgzip.GzipMetadata{}}
return
}
_, err = io.Copy(gz, in)
gzErr := gz.Close()
if gzErr != nil {
fs.Errorf(nil, "Failed to close compress: %v", gzErr)
if err == nil {
err = gzErr
}
}
closeErr := pipeWriter.Close()
if closeErr != nil {
fs.Errorf(nil, "Failed to close pipe: %v", closeErr)
if err == nil {
err = closeErr
}
}
results <- compressionResult{err: err, meta: gz.MetaData()}
}()
wrappedIn := wrap(bufio.NewReaderSize(pipeReader, bufferSize)) // Probably no longer needed as sgzip has it's own buffering
// Find a hash the destination supports to compute a hash of
// the compressed data.
ht := f.Fs.Hashes().GetOne()
var hasher *hash.MultiHasher
var err error
if ht != hash.None {
// unwrap the accounting again
wrappedIn, wrap = accounting.UnWrap(wrappedIn)
hasher, err = hash.NewMultiHasherTypes(hash.NewHashSet(ht))
if err != nil {
return nil, nil, err
}
// add the hasher and re-wrap the accounting
wrappedIn = io.TeeReader(wrappedIn, hasher)
wrappedIn = wrap(wrappedIn)
}
// Transfer the data
o, err := f.rcat(ctx, makeDataName(src.Remote(), src.Size(), f.mode), io.NopCloser(wrappedIn), src.ModTime(ctx), options)
//o, err := operations.Rcat(ctx, f.Fs, makeDataName(src.Remote(), src.Size(), f.mode), io.NopCloser(wrappedIn), src.ModTime(ctx))
if err != nil {
if o != nil {
removeErr := o.Remove(ctx)
if removeErr != nil {
fs.Errorf(o, "Failed to remove partially transferred object: %v", err)
}
}
return nil, nil, err
}
// Check whether we got an error during compression
result := <-results
err = result.err
if err != nil {
if o != nil {
removeErr := o.Remove(ctx)
if removeErr != nil {
fs.Errorf(o, "Failed to remove partially compressed object: %v", err)
}
}
return nil, nil, err
}
// Generate metadata
meta := newMetadata(result.meta.Size, f.mode, result.meta, hex.EncodeToString(metaHasher.Sum(nil)), mimeType)
// Check the hashes of the compressed data if we were comparing them
if ht != hash.None && hasher != nil {
err = f.verifyObjectHash(ctx, o, hasher, ht)
if err != nil {
return nil, nil, err
}
}
return o, meta, nil
}
// Put an uncompressed version of a file. Returns a wrappable object and metadata.
func (f *Fs) putUncompress(ctx context.Context, in io.Reader, src fs.ObjectInfo, put putFn, options []fs.OpenOption, mimeType string) (fs.Object, *ObjectMetadata, error) {
// Unwrap the accounting, add our metadata hasher, then wrap it back on
in, wrap := accounting.UnWrap(in)
hs := hash.NewHashSet(hash.MD5)
ht := f.Fs.Hashes().GetOne()
if !hs.Contains(ht) {
hs.Add(ht)
}
metaHasher, err := hash.NewMultiHasherTypes(hs)
if err != nil {
return nil, nil, err
}
in = io.TeeReader(in, metaHasher)
wrappedIn := wrap(in)
// Put the object
o, err := put(ctx, wrappedIn, f.wrapInfo(src, makeDataName(src.Remote(), src.Size(), Uncompressed), src.Size()), options...)
if err != nil {
if o != nil {
removeErr := o.Remove(ctx)
if removeErr != nil {
fs.Errorf(o, "Failed to remove partially transferred object: %v", err)
}
}
return nil, nil, err
}
// Check the hashes of the compressed data if we were comparing them
if ht != hash.None {
err := f.verifyObjectHash(ctx, o, metaHasher, ht)
if err != nil {
return nil, nil, err
}
}
// Return our object and metadata
sum, err := metaHasher.Sum(hash.MD5)
if err != nil {
return nil, nil, err
}
return o, newMetadata(o.Size(), Uncompressed, sgzip.GzipMetadata{}, hex.EncodeToString(sum), mimeType), nil
}
// This function will write a metadata struct to a metadata Object for an src. Returns a wrappable metadata object.
func (f *Fs) putMetadata(ctx context.Context, meta *ObjectMetadata, src fs.ObjectInfo, options []fs.OpenOption, put putFn) (mo fs.Object, err error) {
// Generate the metadata contents
data, err := json.Marshal(meta)
if err != nil {
return nil, err
}
metaReader := bytes.NewReader(data)
// Put the data
mo, err = put(ctx, metaReader, f.wrapInfo(src, makeMetadataName(src.Remote()), int64(len(data))), options...)
if err != nil {
if mo != nil {
removeErr := mo.Remove(ctx)
if removeErr != nil {
fs.Errorf(mo, "Failed to remove partially transferred object: %v", err)
}
}
return nil, err
}
return mo, nil
}
// This function will put both the data and metadata for an Object.
// putData is the function used for data, while putMeta is the function used for metadata.
// The putData function will only be used when the object is not compressible if the
// data is compressible this parameter will be ignored.
func (f *Fs) putWithCustomFunctions(ctx context.Context, in io.Reader, src fs.ObjectInfo, options []fs.OpenOption,
putData putFn, putMeta putFn, compressible bool, mimeType string) (*Object, error) {
// Put file then metadata
var dataObject fs.Object
var meta *ObjectMetadata
var err error
if compressible {
dataObject, meta, err = f.putCompress(ctx, in, src, options, mimeType)
} else {
dataObject, meta, err = f.putUncompress(ctx, in, src, putData, options, mimeType)
}
if err != nil {
return nil, err
}
mo, err := f.putMetadata(ctx, meta, src, options, putMeta)
// meta data upload may fail. in this case we try to remove the original object
if err != nil {
removeError := dataObject.Remove(ctx)
if removeError != nil {
return nil, removeError
}
return nil, err
}
return f.newObject(dataObject, mo, meta), nil
}
// Put in to the remote path with the modTime given of the given size
//
// May create the object even if it returns an error - if so
// will return the object and the error, otherwise will return
// nil and the error
func (f *Fs) Put(ctx context.Context, in io.Reader, src fs.ObjectInfo, options ...fs.OpenOption) (fs.Object, error) {
// If there's already an existent objects we need to make sure to explicitly update it to make sure we don't leave
// orphaned data. Alternatively we could also deleted (which would simpler) but has the disadvantage that it
// destroys all server-side versioning.
o, err := f.NewObject(ctx, src.Remote())
if err == fs.ErrorObjectNotFound {
// Get our file compressibility
in, compressible, mimeType, err := checkCompressAndType(in)
if err != nil {
return nil, err
}
return f.putWithCustomFunctions(ctx, in, src, options, f.Fs.Put, f.Fs.Put, compressible, mimeType)
}
if err != nil {
return nil, err
}
return o, o.Update(ctx, in, src, options...)
}
// PutStream uploads to the remote path with the modTime given of indeterminate size
func (f *Fs) PutStream(ctx context.Context, in io.Reader, src fs.ObjectInfo, options ...fs.OpenOption) (fs.Object, error) {
oldObj, err := f.NewObject(ctx, src.Remote())
if err != nil && err != fs.ErrorObjectNotFound {
return nil, err
}
found := err == nil
in, compressible, mimeType, err := checkCompressAndType(in)
if err != nil {
return nil, err
}
newObj, err := f.putWithCustomFunctions(ctx, in, src, options, f.Fs.Features().PutStream, f.Fs.Put, compressible, mimeType)
if err != nil {
return nil, err
}
// Our transfer is now complete. We have to make sure to remove the old object because our new object will
// have a different name except when both the old and the new object where uncompressed.
if found && (oldObj.(*Object).meta.Mode != Uncompressed || compressible) {
err = oldObj.(*Object).Object.Remove(ctx)
if err != nil {
return nil, fmt.Errorf("couldn't remove original object: %w", err)
}
}
// If our new object is compressed we have to rename it with the correct size.
// Uncompressed objects don't store the size in the name so we they'll already have the correct name.
if compressible {
wrapObj, err := operations.Move(ctx, f.Fs, nil, f.dataName(src.Remote(), newObj.size, compressible), newObj.Object)
if err != nil {
return nil, fmt.Errorf("couldn't rename streamed object: %w", err)
}
newObj.Object = wrapObj
}
return newObj, nil
}
// Temporarily disabled. There might be a way to implement this correctly but with the current handling metadata duplicate objects
// will break stuff. Right no I can't think of a way to make this work.
// PutUnchecked uploads the object
//
// This will create a duplicate if we upload a new file without
// checking to see if there is one already - use Put() for that.
// Hashes returns the supported hash sets.
func (f *Fs) Hashes() hash.Set {
return hash.Set(hash.MD5)
}
// Mkdir makes the directory (container, bucket)
//
// Shouldn't return an error if it already exists
func (f *Fs) Mkdir(ctx context.Context, dir string) error {
return f.Fs.Mkdir(ctx, dir)
}
// MkdirMetadata makes the root directory of the Fs object
func (f *Fs) MkdirMetadata(ctx context.Context, dir string, metadata fs.Metadata) (fs.Directory, error) {
if do := f.Fs.Features().MkdirMetadata; do != nil {
return do(ctx, dir, metadata)
}
return nil, fs.ErrorNotImplemented
}
// Rmdir removes the directory (container, bucket) if empty
//
// Return an error if it doesn't exist or isn't empty
func (f *Fs) Rmdir(ctx context.Context, dir string) error {
return f.Fs.Rmdir(ctx, dir)
}
// Purge all files in the root and the root directory
//
// Implement this if you have a way of deleting all the files
// quicker than just running Remove() on the result of List()
//
// Return an error if it doesn't exist
func (f *Fs) Purge(ctx context.Context, dir string) error {
do := f.Fs.Features().Purge
if do == nil {
return fs.ErrorCantPurge
}
return do(ctx, dir)
}
// Copy src to this remote using server side copy operations.
//
// This is stored with the remote path given.
//
// It returns the destination Object and a possible error.
//
// Will only be called if src.Fs().Name() == f.Name()
//
// If it isn't possible then return fs.ErrorCantCopy
func (f *Fs) Copy(ctx context.Context, src fs.Object, remote string) (fs.Object, error) {
do := f.Fs.Features().Copy
if do == nil {
return nil, fs.ErrorCantCopy
}
o, ok := src.(*Object)
if !ok {
return nil, fs.ErrorCantCopy
}
// We might be trying to overwrite a file with a newer version but due to size difference the name
// is different. Therefore we have to remove the old file first (if it exists).
dstFile, err := f.NewObject(ctx, remote)
if err != nil && err != fs.ErrorObjectNotFound {
return nil, err
}
if err == nil {
err := dstFile.Remove(ctx)
if err != nil {
return nil, err
}
}
// Copy over metadata
err = o.loadMetadataIfNotLoaded(ctx)
if err != nil {
return nil, err
}
newFilename := makeMetadataName(remote)
moResult, err := do(ctx, o.mo, newFilename)
if err != nil {
return nil, err
}
// Copy over data
newFilename = makeDataName(remote, src.Size(), o.meta.Mode)
oResult, err := do(ctx, o.Object, newFilename)
if err != nil {
return nil, err
}
return f.newObject(oResult, moResult, o.meta), nil
}
// Move src to this remote using server side move operations.
//
// This is stored with the remote path given.
//
// It returns the destination Object and a possible error.
//
// Will only be called if src.Fs().Name() == f.Name()
//
// If it isn't possible then return fs.ErrorCantMove
func (f *Fs) Move(ctx context.Context, src fs.Object, remote string) (fs.Object, error) {
do := f.Fs.Features().Move
if do == nil {
return nil, fs.ErrorCantMove
}
o, ok := src.(*Object)
if !ok {
return nil, fs.ErrorCantMove
}
// We might be trying to overwrite a file with a newer version but due to size difference the name
// is different. Therefore we have to remove the old file first (if it exists).
dstFile, err := f.NewObject(ctx, remote)
if err != nil && err != fs.ErrorObjectNotFound {
return nil, err
}
if err == nil {
err := dstFile.Remove(ctx)
if err != nil {
return nil, err
}
}
// Move metadata
err = o.loadMetadataIfNotLoaded(ctx)
if err != nil {
return nil, err
}
newFilename := makeMetadataName(remote)
moResult, err := do(ctx, o.mo, newFilename)
if err != nil {
return nil, err
}
// Move data
newFilename = makeDataName(remote, src.Size(), o.meta.Mode)
oResult, err := do(ctx, o.Object, newFilename)
if err != nil {
return nil, err
}
return f.newObject(oResult, moResult, o.meta), nil
}
// DirMove moves src, srcRemote to this remote at dstRemote
// using server side move operations.
//
// Will only be called if src.Fs().Name() == f.Name()
//
// If it isn't possible then return fs.ErrorCantDirMove
//
// If destination exists then return fs.ErrorDirExists
func (f *Fs) DirMove(ctx context.Context, src fs.Fs, srcRemote, dstRemote string) error {
do := f.Fs.Features().DirMove
if do == nil {
return fs.ErrorCantDirMove
}
srcFs, ok := src.(*Fs)
if !ok {
fs.Debugf(srcFs, "Can't move directory - not same remote type")
return fs.ErrorCantDirMove
}
return do(ctx, srcFs.Fs, srcRemote, dstRemote)
}
// DirSetModTime sets the directory modtime for dir
func (f *Fs) DirSetModTime(ctx context.Context, dir string, modTime time.Time) error {
if do := f.Fs.Features().DirSetModTime; do != nil {
return do(ctx, dir, modTime)
}
return fs.ErrorNotImplemented
}
// CleanUp the trash in the Fs
//
// Implement this if you have a way of emptying the trash or
// otherwise cleaning up old versions of files.
func (f *Fs) CleanUp(ctx context.Context) error {
do := f.Fs.Features().CleanUp
if do == nil {
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return errors.New("not supported by underlying remote")
}
return do(ctx)
}
// About gets quota information from the Fs
func (f *Fs) About(ctx context.Context) (*fs.Usage, error) {
do := f.Fs.Features().About
if do == nil {
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return nil, errors.New("not supported by underlying remote")
}
return do(ctx)
}
// UnWrap returns the Fs that this Fs is wrapping
func (f *Fs) UnWrap() fs.Fs {
return f.Fs
}
// WrapFs returns the Fs that is wrapping this Fs
func (f *Fs) WrapFs() fs.Fs {
return f.wrapper
}
// SetWrapper sets the Fs that is wrapping this Fs
func (f *Fs) SetWrapper(wrapper fs.Fs) {
f.wrapper = wrapper
}
// MergeDirs merges the contents of all the directories passed
// in into the first one and rmdirs the other directories.
func (f *Fs) MergeDirs(ctx context.Context, dirs []fs.Directory) error {
do := f.Fs.Features().MergeDirs
if do == nil {
return errors.New("MergeDirs not supported")
}
out := make([]fs.Directory, len(dirs))
for i, dir := range dirs {
out[i] = fs.NewDirCopy(ctx, dir).SetRemote(dir.Remote())
}
return do(ctx, out)
}
// DirCacheFlush resets the directory cache - used in testing
// as an optional interface
func (f *Fs) DirCacheFlush() {
do := f.Fs.Features().DirCacheFlush
if do != nil {
do()
}
}
// ChangeNotify calls the passed function with a path
// that has had changes. If the implementation
// uses polling, it should adhere to the given interval.
func (f *Fs) ChangeNotify(ctx context.Context, notifyFunc func(string, fs.EntryType), pollIntervalChan <-chan time.Duration) {
do := f.Fs.Features().ChangeNotify
if do == nil {
return
}
wrappedNotifyFunc := func(path string, entryType fs.EntryType) {
fs.Logf(f, "path %q entryType %d", path, entryType)
var (
wrappedPath string
isMetadataFile bool
)
switch entryType {
case fs.EntryDirectory:
wrappedPath = path
case fs.EntryObject:
// Note: All we really need to do to monitor the object is to check whether the metadata changed,
// as the metadata contains the hash. This will work unless there's a hash collision and the sizes stay the same.
wrappedPath, isMetadataFile = unwrapMetadataFile(path)
if !isMetadataFile {
return
}
default:
fs.Errorf(path, "press ChangeNotify: ignoring unknown EntryType %d", entryType)
return
}
notifyFunc(wrappedPath, entryType)
}
do(ctx, wrappedNotifyFunc, pollIntervalChan)
}
// PublicLink generates a public link to the remote path (usually readable by anyone)
func (f *Fs) PublicLink(ctx context.Context, remote string, duration fs.Duration, unlink bool) (string, error) {
do := f.Fs.Features().PublicLink
if do == nil {
return "", errors.New("can't PublicLink: not supported by underlying remote")
}
o, err := f.NewObject(ctx, remote)
if err != nil {
// assume it is a directory
return do(ctx, remote, duration, unlink)
}
return do(ctx, o.(*Object).Object.Remote(), duration, unlink)
}
/*** OBJECT FUNCTIONS ***/
// ObjectMetadata describes the metadata for an Object.
type ObjectMetadata struct {
Mode int // Compression mode of the file.
Size int64 // Size of the object.
MD5 string // MD5 hash of the file.
MimeType string // Mime type of the file
CompressionMetadata sgzip.GzipMetadata
}
// Object with external metadata
type Object struct {
fs.Object // Wraps around data object for this object
f *Fs // Filesystem object is in
mo fs.Object // Metadata object for this object
moName string // Metadata file name for this object
size int64 // Size of this object
meta *ObjectMetadata // Metadata struct for this object (nil if not loaded)
}
// This function generates a metadata object
func newMetadata(size int64, mode int, cmeta sgzip.GzipMetadata, md5 string, mimeType string) *ObjectMetadata {
meta := new(ObjectMetadata)
meta.Size = size
meta.Mode = mode
meta.CompressionMetadata = cmeta
meta.MD5 = md5
meta.MimeType = mimeType
return meta
}
// This function will read the metadata from a metadata object.
func readMetadata(ctx context.Context, mo fs.Object) (meta *ObjectMetadata, err error) {
// Open our meradata object
rc, err := mo.Open(ctx)
if err != nil {
return nil, err
}
defer fs.CheckClose(rc, &err)
jr := json.NewDecoder(rc)
meta = new(ObjectMetadata)
if err = jr.Decode(meta); err != nil {
return nil, err
}
return meta, nil
}
// Remove removes this object
func (o *Object) Remove(ctx context.Context) error {
err := o.loadMetadataObjectIfNotLoaded(ctx)
if err != nil {
return err
}
err = o.mo.Remove(ctx)
objErr := o.Object.Remove(ctx)
if err != nil {
return err
}
return objErr
}
// ReadCloserWrapper combines a Reader and a Closer to a ReadCloser
type ReadCloserWrapper struct {
io.Reader
io.Closer
}
// Update in to the object with the modTime given of the given size
func (o *Object) Update(ctx context.Context, in io.Reader, src fs.ObjectInfo, options ...fs.OpenOption) (err error) {
err = o.loadMetadataIfNotLoaded(ctx) // Loads metadata object too
if err != nil {
return err
}
// Function that updates metadata object
updateMeta := func(ctx context.Context, in io.Reader, src fs.ObjectInfo, options ...fs.OpenOption) (fs.Object, error) {
return o.mo, o.mo.Update(ctx, in, src, options...)
}
in, compressible, mimeType, err := checkCompressAndType(in)
if err != nil {
return err
}
// Since we are storing the filesize in the name the new object may have different name than the old
// We'll make sure to delete the old object in this case
var newObject *Object
origName := o.Remote()
if o.meta.Mode != Uncompressed || compressible {
newObject, err = o.f.putWithCustomFunctions(ctx, in, o.f.wrapInfo(src, origName, src.Size()), options, o.f.Fs.Put, updateMeta, compressible, mimeType)
if err != nil {
return err
}
if newObject.Object.Remote() != o.Object.Remote() {
if removeErr := o.Object.Remove(ctx); removeErr != nil {
return removeErr
}
}
} else {
// We can only support update when BOTH the old and the new object are uncompressed because only then
// the filesize will be known beforehand and name will stay the same
update := func(ctx context.Context, in io.Reader, src fs.ObjectInfo, options ...fs.OpenOption) (fs.Object, error) {
return o.Object, o.Object.Update(ctx, in, src, options...)
}
// If we are, just update the object and metadata
newObject, err = o.f.putWithCustomFunctions(ctx, in, src, options, update, updateMeta, compressible, mimeType)
if err != nil {
return err
}
}
// Update object metadata and return
o.Object = newObject.Object
o.meta = newObject.meta
o.size = newObject.size
return nil
}
// This will initialize the variables of a new press Object. The metadata object, mo, and metadata struct, meta, must be specified.
func (f *Fs) newObject(o fs.Object, mo fs.Object, meta *ObjectMetadata) *Object {
if o == nil {
log.Trace(nil, "newObject(%#v, %#v, %#v) called with nil o", o, mo, meta)
}
return &Object{
Object: o,
f: f,
mo: mo,
moName: mo.Remote(),
size: meta.Size,
meta: meta,
}
}
// This initializes the variables of a press Object with only the size. The metadata will be loaded later on demand.
func (f *Fs) newObjectSizeAndNameOnly(o fs.Object, moName string, size int64) *Object {
if o == nil {
log.Trace(nil, "newObjectSizeAndNameOnly(%#v, %#v, %#v) called with nil o", o, moName, size)
}
return &Object{
Object: o,
f: f,
mo: nil,
moName: moName,
size: size,
meta: nil,
}
}
// Shutdown the backend, closing any background tasks and any
// cached connections.
func (f *Fs) Shutdown(ctx context.Context) error {
do := f.Fs.Features().Shutdown
if do == nil {
return nil
}
return do(ctx)
}
// This loads the metadata of a press Object if it's not loaded yet
func (o *Object) loadMetadataIfNotLoaded(ctx context.Context) (err error) {
err = o.loadMetadataObjectIfNotLoaded(ctx)
if err != nil {
return err
}
if o.meta == nil {
o.meta, err = readMetadata(ctx, o.mo)
}
return err
}
// This loads the metadata object of a press Object if it's not loaded yet
func (o *Object) loadMetadataObjectIfNotLoaded(ctx context.Context) (err error) {
if o.mo == nil {
o.mo, err = o.f.Fs.NewObject(ctx, o.moName)
}
return err
}
// Fs returns read only access to the Fs that this object is part of
func (o *Object) Fs() fs.Info {
return o.f
}
// Return a string version
func (o *Object) String() string {
if o == nil {
return "<nil>"
}
return o.Remote()
}
// Remote returns the remote path
func (o *Object) Remote() string {
origFileName, _, _, err := processFileName(o.Object.Remote())
if err != nil {
fs.Errorf(o.f, "Could not get remote path for: %s", o.Object.Remote())
return o.Object.Remote()
}
return origFileName
}
// Size returns the size of the file
func (o *Object) Size() int64 {
if o.meta == nil {
return o.size
}
return o.meta.Size
}
// MimeType returns the MIME type of the file
func (o *Object) MimeType(ctx context.Context) string {
err := o.loadMetadataIfNotLoaded(ctx)
if err != nil {
return "error/error"
}
return o.meta.MimeType
}
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// Metadata returns metadata for an object
//
// It should return nil if there is no Metadata
func (o *Object) Metadata(ctx context.Context) (fs.Metadata, error) {
err := o.loadMetadataIfNotLoaded(ctx)
if err != nil {
return nil, err
}
do, ok := o.mo.(fs.Metadataer)
if !ok {
return nil, nil
}
return do.Metadata(ctx)
}
// SetMetadata sets metadata for an Object
//
// It should return fs.ErrorNotImplemented if it can't set metadata
func (o *Object) SetMetadata(ctx context.Context, metadata fs.Metadata) error {
do, ok := o.Object.(fs.SetMetadataer)
if !ok {
return fs.ErrorNotImplemented
}
return do.SetMetadata(ctx, metadata)
}
// Hash returns the selected checksum of the file
// If no checksum is available it returns ""
func (o *Object) Hash(ctx context.Context, ht hash.Type) (string, error) {
if ht != hash.MD5 {
return "", hash.ErrUnsupported
}
err := o.loadMetadataIfNotLoaded(ctx)
if err != nil {
return "", err
}
return o.meta.MD5, nil
}
// SetTier performs changing storage tier of the Object if
// multiple storage classes supported
func (o *Object) SetTier(tier string) error {
do, ok := o.Object.(fs.SetTierer)
mdo, mok := o.mo.(fs.SetTierer)
if !(ok && mok) {
return errors.New("press: underlying remote does not support SetTier")
}
if err := mdo.SetTier(tier); err != nil {
return err
}
return do.SetTier(tier)
}
// GetTier returns storage tier or class of the Object
func (o *Object) GetTier() string {
do, ok := o.mo.(fs.GetTierer)
if !ok {
return ""
}
return do.GetTier()
}
// UnWrap returns the wrapped Object
func (o *Object) UnWrap() fs.Object {
return o.Object
}
// Open opens the file for read. Call Close() on the returned io.ReadCloser. Note that this call requires quite a bit of overhead.
func (o *Object) Open(ctx context.Context, options ...fs.OpenOption) (rc io.ReadCloser, err error) {
err = o.loadMetadataIfNotLoaded(ctx)
if err != nil {
return nil, err
}
// If we're uncompressed, just pass this to the underlying object
if o.meta.Mode == Uncompressed {
return o.Object.Open(ctx, options...)
}
// Get offset and limit from OpenOptions, pass the rest to the underlying remote
var openOptions = []fs.OpenOption{&fs.SeekOption{Offset: 0}}
var offset, limit int64 = 0, -1
for _, option := range options {
switch x := option.(type) {
case *fs.SeekOption:
offset = x.Offset
case *fs.RangeOption:
offset, limit = x.Decode(o.Size())
default:
openOptions = append(openOptions, option)
}
}
// Get a chunkedreader for the wrapped object
chunkedReader := chunkedreader.New(ctx, o.Object, initialChunkSize, maxChunkSize)
// Get file handle
var file io.Reader
if offset != 0 {
file, err = sgzip.NewReaderAt(chunkedReader, &o.meta.CompressionMetadata, offset)
} else {
file, err = sgzip.NewReader(chunkedReader)
}
if err != nil {
return nil, err
}
var fileReader io.Reader
if limit != -1 {
fileReader = io.LimitReader(file, limit)
} else {
fileReader = file
}
// Return a ReadCloser
return ReadCloserWrapper{Reader: fileReader, Closer: chunkedReader}, nil
}
// ObjectInfo describes a wrapped fs.ObjectInfo for being the source
type ObjectInfo struct {
src fs.ObjectInfo
fs *Fs
remote string
size int64
}
func (f *Fs) wrapInfo(src fs.ObjectInfo, newRemote string, size int64) *ObjectInfo {
return &ObjectInfo{
src: src,
fs: f,
remote: newRemote,
size: size,
}
}
// Fs returns read only access to the Fs that this object is part of
func (o *ObjectInfo) Fs() fs.Info {
if o.fs == nil {
panic("stub ObjectInfo")
}
return o.fs
}
// String returns string representation
func (o *ObjectInfo) String() string {
return o.src.String()
}
// Storable returns whether object is storable
func (o *ObjectInfo) Storable() bool {
return o.src.Storable()
}
// Remote returns the remote path
func (o *ObjectInfo) Remote() string {
if o.remote != "" {
return o.remote
}
return o.src.Remote()
}
// Size returns the size of the file
func (o *ObjectInfo) Size() int64 {
return o.size
}
// ModTime returns the modification time
func (o *ObjectInfo) ModTime(ctx context.Context) time.Time {
return o.src.ModTime(ctx)
}
// Hash returns the selected checksum of the file
// If no checksum is available it returns ""
func (o *ObjectInfo) Hash(ctx context.Context, ht hash.Type) (string, error) {
return "", nil // cannot know the checksum
}
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// ID returns the ID of the Object if known, or "" if not
func (o *ObjectInfo) ID() string {
do, ok := o.src.(fs.IDer)
if !ok {
return ""
}
return do.ID()
}
// MimeType returns the content type of the Object if
// known, or "" if not
func (o *ObjectInfo) MimeType(ctx context.Context) string {
do, ok := o.src.(fs.MimeTyper)
if !ok {
return ""
}
return do.MimeType(ctx)
}
// UnWrap returns the Object that this Object is wrapping or
// nil if it isn't wrapping anything
func (o *ObjectInfo) UnWrap() fs.Object {
return fs.UnWrapObjectInfo(o.src)
}
// Metadata returns metadata for an object
//
// It should return nil if there is no Metadata
func (o *ObjectInfo) Metadata(ctx context.Context) (fs.Metadata, error) {
do, ok := o.src.(fs.Metadataer)
if !ok {
return nil, nil
}
return do.Metadata(ctx)
}
// GetTier returns storage tier or class of the Object
func (o *ObjectInfo) GetTier() string {
do, ok := o.src.(fs.GetTierer)
if !ok {
return ""
}
return do.GetTier()
}
// ID returns the ID of the Object if known, or "" if not
func (o *Object) ID() string {
do, ok := o.Object.(fs.IDer)
if !ok {
return ""
}
return do.ID()
}
// Name of the remote (as passed into NewFs)
func (f *Fs) Name() string {
return f.name
}
// Root of the remote (as passed into NewFs)
func (f *Fs) Root() string {
return f.root
}
// Features returns the optional features of this Fs
func (f *Fs) Features() *fs.Features {
return f.features
}
// Return a string version
func (f *Fs) String() string {
return fmt.Sprintf("Compressed: %s:%s", f.name, f.root)
}
// Precision returns the precision of this Fs
func (f *Fs) Precision() time.Duration {
return f.Fs.Precision()
}
// Check the interfaces are satisfied
var (
_ fs.Fs = (*Fs)(nil)
_ fs.Purger = (*Fs)(nil)
_ fs.Copier = (*Fs)(nil)
_ fs.Mover = (*Fs)(nil)
_ fs.DirMover = (*Fs)(nil)
_ fs.DirSetModTimer = (*Fs)(nil)
_ fs.MkdirMetadataer = (*Fs)(nil)
_ fs.PutStreamer = (*Fs)(nil)
_ fs.CleanUpper = (*Fs)(nil)
_ fs.UnWrapper = (*Fs)(nil)
_ fs.ListRer = (*Fs)(nil)
_ fs.Abouter = (*Fs)(nil)
_ fs.Wrapper = (*Fs)(nil)
_ fs.MergeDirser = (*Fs)(nil)
_ fs.DirCacheFlusher = (*Fs)(nil)
_ fs.ChangeNotifier = (*Fs)(nil)
_ fs.PublicLinker = (*Fs)(nil)
_ fs.Shutdowner = (*Fs)(nil)
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_ fs.FullObjectInfo = (*ObjectInfo)(nil)
_ fs.FullObject = (*Object)(nil)
)