rclone/backend/chunker/chunker.go
2019-12-09 16:56:32 +00:00

2281 lines
68 KiB
Go

// Package chunker provides wrappers for Fs and Object which split large files in chunks
package chunker
import (
"bytes"
"context"
"crypto/md5"
"crypto/sha1"
"encoding/hex"
"encoding/json"
"fmt"
gohash "hash"
"io"
"io/ioutil"
"math/rand"
"path"
"regexp"
"sort"
"strconv"
"strings"
"sync"
"time"
"github.com/pkg/errors"
"github.com/rclone/rclone/fs"
"github.com/rclone/rclone/fs/accounting"
"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/operations"
)
//
// Chunker's composite files have one or more chunks
// and optional metadata object. If it's present,
// meta object is named after the original file.
//
// The only supported metadata format is simplejson atm.
// It supports only per-file meta objects that are rudimentary,
// used mostly for consistency checks (lazily for performance reasons).
// Other formats can be developed that use an external meta store
// free of these limitations, but this needs some support from
// rclone core (eg. metadata store interfaces).
//
// The following types of chunks are supported:
// data and control, active and temporary.
// Chunk type is identified by matching chunk file name
// based on the chunk name format configured by user.
//
// Both data and control chunks can be either temporary (aka hidden)
// or active (non-temporary aka normal aka permanent).
// An operation creates temporary chunks while it runs.
// By completion it removes temporary and leaves active chunks.
//
// Temporary chunks have a special hardcoded suffix in addition
// to the configured name pattern.
// Temporary suffix includes so called transaction identifier
// (abbreviated as `xactID` below), a generic non-negative base-36 "number"
// used by parallel operations to share a composite object.
// Chunker also accepts the longer decimal temporary suffix (obsolete),
// which is transparently converted to the new format. In its maximum
// length of 13 decimals it makes a 7-digit base-36 number.
//
// Chunker can tell data chunks from control chunks by the characters
// located in the "hash placeholder" position of configured format.
// Data chunks have decimal digits there.
// Control chunks have in that position a short lowercase alphanumeric
// string (starting with a letter) prepended by underscore.
//
// Metadata format v1 does not define any control chunk types,
// they are currently ignored aka reserved.
// In future they can be used to implement resumable uploads etc.
//
const (
ctrlTypeRegStr = `[a-z][a-z0-9]{2,6}`
tempSuffixFormat = `_%04s`
tempSuffixRegStr = `_([0-9a-z]{4,9})`
tempSuffixRegOld = `\.\.tmp_([0-9]{10,13})`
)
var (
// regular expressions to validate control type and temporary suffix
ctrlTypeRegexp = regexp.MustCompile(`^` + ctrlTypeRegStr + `$`)
tempSuffixRegexp = regexp.MustCompile(`^` + tempSuffixRegStr + `$`)
)
// Normally metadata is a small piece of JSON (about 100-300 bytes).
// The size of valid metadata must never exceed this limit.
// Current maximum provides a reasonable room for future extensions.
//
// Please refrain from increasing it, this can cause old rclone versions
// to fail, or worse, treat meta object as a normal file (see NewObject).
// If more room is needed please bump metadata version forcing previous
// releases to ask for upgrade, and offload extra info to a control chunk.
//
// And still chunker's primary function is to chunk large files
// rather than serve as a generic metadata container.
const maxMetadataSize = 255
// Current/highest supported metadata format.
const metadataVersion = 1
// optimizeFirstChunk enables the following optimization in the Put:
// If a single chunk is expected, put the first chunk using the
// base target name instead of a temporary name, thus avoiding
// extra rename operation.
// Warning: this optimization is not transaction safe.
const optimizeFirstChunk = false
// revealHidden is a stub until chunker lands the `reveal hidden` option.
const revealHidden = false
// Prevent memory overflow due to specially crafted chunk name
const maxSafeChunkNumber = 10000000
// Number of attempts to find unique transaction identifier
const maxTransactionProbes = 100
// standard chunker errors
var (
ErrChunkOverflow = errors.New("chunk number overflow")
)
// variants of baseMove's parameter delMode
const (
delNever = 0 // don't delete, just move
delAlways = 1 // delete destination before moving
delFailed = 2 // move, then delete and try again if failed
)
// Register with Fs
func init() {
fs.Register(&fs.RegInfo{
Name: "chunker",
Description: "Transparently chunk/split large files",
NewFs: NewFs,
Options: []fs.Option{{
Name: "remote",
Required: true,
Help: `Remote to chunk/unchunk.
Normally should contain a ':' and a path, eg "myremote:path/to/dir",
"myremote:bucket" or maybe "myremote:" (not recommended).`,
}, {
Name: "chunk_size",
Advanced: false,
Default: fs.SizeSuffix(2147483648), // 2GB
Help: `Files larger than chunk size will be split in chunks.`,
}, {
Name: "name_format",
Advanced: true,
Default: `*.rclone_chunk.###`,
Help: `String format of chunk file names.
The two placeholders are: base file name (*) and chunk number (#...).
There must be one and only one asterisk and one or more consecutive hash characters.
If chunk number has less digits than the number of hashes, it is left-padded by zeros.
If there are more digits in the number, they are left as is.
Possible chunk files are ignored if their name does not match given format.`,
}, {
Name: "start_from",
Advanced: true,
Default: 1,
Help: `Minimum valid chunk number. Usually 0 or 1.
By default chunk numbers start from 1.`,
}, {
Name: "meta_format",
Advanced: true,
Default: "simplejson",
Help: `Format of the metadata object or "none". By default "simplejson".
Metadata is a small JSON file named after the composite file.`,
Examples: []fs.OptionExample{{
Value: "none",
Help: `Do not use metadata files at all. Requires hash type "none".`,
}, {
Value: "simplejson",
Help: `Simple JSON supports hash sums and chunk validation.
It has the following fields: ver, size, nchunks, md5, sha1.`,
}},
}, {
Name: "hash_type",
Advanced: false,
Default: "md5",
Help: `Choose how chunker handles hash sums. All modes but "none" require metadata.`,
Examples: []fs.OptionExample{{
Value: "none",
Help: `Pass any hash supported by wrapped remote for non-chunked files, return nothing otherwise`,
}, {
Value: "md5",
Help: `MD5 for composite files`,
}, {
Value: "sha1",
Help: `SHA1 for composite files`,
}, {
Value: "md5all",
Help: `MD5 for all files`,
}, {
Value: "sha1all",
Help: `SHA1 for all files`,
}, {
Value: "md5quick",
Help: `Copying a file to chunker will request MD5 from the source falling back to SHA1 if unsupported`,
}, {
Value: "sha1quick",
Help: `Similar to "md5quick" but prefers SHA1 over MD5`,
}},
}, {
Name: "fail_hard",
Advanced: true,
Default: false,
Help: `Choose how chunker should handle files with missing or invalid chunks.`,
Examples: []fs.OptionExample{
{
Value: "true",
Help: "Report errors and abort current command.",
}, {
Value: "false",
Help: "Warn user, skip incomplete file and proceed.",
},
},
}},
})
}
// NewFs constructs an Fs from the path, container:path
func NewFs(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
}
if opt.StartFrom < 0 {
return nil, errors.New("start_from must be non-negative")
}
remote := opt.Remote
if strings.HasPrefix(remote, name+":") {
return nil, errors.New("can't point remote at itself - check the value of the remote setting")
}
baseInfo, baseName, basePath, baseConfig, err := fs.ConfigFs(remote)
if err != nil {
return nil, errors.Wrapf(err, "failed to parse remote %q to wrap", remote)
}
// Look for a file first
remotePath := fspath.JoinRootPath(basePath, rpath)
baseFs, err := baseInfo.NewFs(baseName, remotePath, baseConfig)
if err != fs.ErrorIsFile && err != nil {
return nil, errors.Wrapf(err, "failed to make remote %s:%q to wrap", baseName, remotePath)
}
if !operations.CanServerSideMove(baseFs) {
return nil, errors.New("can't use chunker on a backend which doesn't support server side move or copy")
}
f := &Fs{
base: baseFs,
name: name,
root: rpath,
opt: *opt,
}
f.dirSort = true // processEntries requires that meta Objects prerun data chunks atm.
if err := f.configure(opt.NameFormat, opt.MetaFormat, opt.HashType); err != nil {
return nil, err
}
// Handle the tricky case detected by FsMkdir/FsPutFiles/FsIsFile
// when `rpath` points to a composite multi-chunk file without metadata,
// i.e. `rpath` does not exist in the wrapped remote, but chunker
// detects a composite file because it finds the first chunk!
// (yet can't satisfy fstest.CheckListing, will ignore)
if err == nil && !f.useMeta && strings.Contains(rpath, "/") {
firstChunkPath := f.makeChunkName(remotePath, 0, "", "")
_, testErr := baseInfo.NewFs(baseName, firstChunkPath, baseConfig)
if testErr == fs.ErrorIsFile {
err = testErr
}
}
// Note 1: the features here are ones we could support, and they are
// ANDed with the ones from wrappedFs.
// Note 2: features.Fill() points features.PutStream to our PutStream,
// but features.Mask() will nullify it if wrappedFs does not have it.
f.features = (&fs.Features{
CaseInsensitive: true,
DuplicateFiles: true,
ReadMimeType: true,
WriteMimeType: true,
BucketBased: true,
CanHaveEmptyDirectories: true,
ServerSideAcrossConfigs: true,
}).Fill(f).Mask(baseFs).WrapsFs(f, baseFs)
return f, err
}
// Options defines the configuration for this backend
type Options struct {
Remote string `config:"remote"`
ChunkSize fs.SizeSuffix `config:"chunk_size"`
NameFormat string `config:"name_format"`
StartFrom int `config:"start_from"`
MetaFormat string `config:"meta_format"`
HashType string `config:"hash_type"`
FailHard bool `config:"fail_hard"`
}
// Fs represents a wrapped fs.Fs
type Fs struct {
name string
root string
base fs.Fs // remote wrapped by chunker overlay
wrapper fs.Fs // wrapper is used by SetWrapper
useMeta bool // false if metadata format is 'none'
useMD5 bool // mutually exclusive with useSHA1
useSHA1 bool // mutually exclusive with useMD5
hashFallback bool // allows fallback from MD5 to SHA1 and vice versa
hashAll bool // hash all files, mutually exclusive with hashFallback
dataNameFmt string // name format of data chunks
ctrlNameFmt string // name format of control chunks
nameRegexp *regexp.Regexp // regular expression to match chunk names
xactIDRand *rand.Rand // generator of random transaction identifiers
xactIDMutex sync.Mutex // mutex for the source of randomness
opt Options // copy of Options
features *fs.Features // optional features
dirSort bool // reserved for future, ignored
}
// configure sets up chunker for given name format, meta format and hash type.
// It also seeds the source of random transaction identifiers.
// configure must be called only from NewFs or by unit tests.
func (f *Fs) configure(nameFormat, metaFormat, hashType string) error {
if err := f.setChunkNameFormat(nameFormat); err != nil {
return errors.Wrapf(err, "invalid name format '%s'", nameFormat)
}
if err := f.setMetaFormat(metaFormat); err != nil {
return err
}
if err := f.setHashType(hashType); err != nil {
return err
}
randomSeed := time.Now().UnixNano()
f.xactIDRand = rand.New(rand.NewSource(randomSeed))
return nil
}
func (f *Fs) setMetaFormat(metaFormat string) error {
switch metaFormat {
case "none":
f.useMeta = false
case "simplejson":
f.useMeta = true
default:
return fmt.Errorf("unsupported meta format '%s'", metaFormat)
}
return nil
}
// setHashType
// must be called *after* setMetaFormat.
//
// In the "All" mode chunker will force metadata on all files
// if the wrapped remote can't provide given hashsum.
func (f *Fs) setHashType(hashType string) error {
f.useMD5 = false
f.useSHA1 = false
f.hashFallback = false
f.hashAll = false
requireMetaHash := true
switch hashType {
case "none":
requireMetaHash = false
case "md5":
f.useMD5 = true
case "sha1":
f.useSHA1 = true
case "md5quick":
f.useMD5 = true
f.hashFallback = true
case "sha1quick":
f.useSHA1 = true
f.hashFallback = true
case "md5all":
f.useMD5 = true
f.hashAll = !f.base.Hashes().Contains(hash.MD5)
case "sha1all":
f.useSHA1 = true
f.hashAll = !f.base.Hashes().Contains(hash.SHA1)
default:
return fmt.Errorf("unsupported hash type '%s'", hashType)
}
if requireMetaHash && !f.useMeta {
return fmt.Errorf("hash type '%s' requires compatible meta format", hashType)
}
return nil
}
// setChunkNameFormat converts pattern based chunk name format
// into Printf format and Regular expressions for data and
// control chunks.
func (f *Fs) setChunkNameFormat(pattern string) error {
// validate pattern
if strings.Count(pattern, "*") != 1 {
return errors.New("pattern must have exactly one asterisk (*)")
}
numDigits := strings.Count(pattern, "#")
if numDigits < 1 {
return errors.New("pattern must have a hash character (#)")
}
if strings.Index(pattern, "*") > strings.Index(pattern, "#") {
return errors.New("asterisk (*) in pattern must come before hashes (#)")
}
if ok, _ := regexp.MatchString("^[^#]*[#]+[^#]*$", pattern); !ok {
return errors.New("hashes (#) in pattern must be consecutive")
}
if dir, _ := path.Split(pattern); dir != "" {
return errors.New("directory separator prohibited")
}
if pattern[0] != '*' {
return errors.New("pattern must start with asterisk") // to be lifted later
}
// craft a unified regular expression for all types of chunks
reHashes := regexp.MustCompile("[#]+")
reDigits := "[0-9]+"
if numDigits > 1 {
reDigits = fmt.Sprintf("[0-9]{%d,}", numDigits)
}
reDataOrCtrl := fmt.Sprintf("(?:(%s)|_(%s))", reDigits, ctrlTypeRegStr)
// this must be non-greedy or else it could eat up temporary suffix
const mainNameRegStr = "(.+?)"
strRegex := regexp.QuoteMeta(pattern)
strRegex = reHashes.ReplaceAllLiteralString(strRegex, reDataOrCtrl)
strRegex = strings.Replace(strRegex, "\\*", mainNameRegStr, -1)
strRegex = fmt.Sprintf("^%s(?:%s|%s)?$", strRegex, tempSuffixRegStr, tempSuffixRegOld)
f.nameRegexp = regexp.MustCompile(strRegex)
// craft printf formats for active data/control chunks
fmtDigits := "%d"
if numDigits > 1 {
fmtDigits = fmt.Sprintf("%%0%dd", numDigits)
}
strFmt := strings.Replace(pattern, "%", "%%", -1)
strFmt = strings.Replace(strFmt, "*", "%s", 1)
f.dataNameFmt = reHashes.ReplaceAllLiteralString(strFmt, fmtDigits)
f.ctrlNameFmt = reHashes.ReplaceAllLiteralString(strFmt, "_%s")
return nil
}
// makeChunkName produces chunk name (or path) for a given file.
//
// filePath can be name, relative or absolute path of main file.
//
// chunkNo must be a zero based index of data chunk.
// Negative chunkNo eg. -1 indicates a control chunk.
// ctrlType is type of control chunk (must be valid).
// ctrlType must be "" for data chunks.
//
// xactID is a transaction identifier. Empty xactID denotes active chunk,
// otherwise temporary chunk name is produced.
//
func (f *Fs) makeChunkName(filePath string, chunkNo int, ctrlType, xactID string) string {
dir, parentName := path.Split(filePath)
var name, tempSuffix string
switch {
case chunkNo >= 0 && ctrlType == "":
name = fmt.Sprintf(f.dataNameFmt, parentName, chunkNo+f.opt.StartFrom)
case chunkNo < 0 && ctrlTypeRegexp.MatchString(ctrlType):
name = fmt.Sprintf(f.ctrlNameFmt, parentName, ctrlType)
default:
panic("makeChunkName: invalid argument") // must not produce something we can't consume
}
if xactID != "" {
tempSuffix = fmt.Sprintf(tempSuffixFormat, xactID)
if !tempSuffixRegexp.MatchString(tempSuffix) {
panic("makeChunkName: invalid argument")
}
}
return dir + name + tempSuffix
}
// parseChunkName checks whether given file path belongs to
// a chunk and extracts chunk name parts.
//
// filePath can be name, relative or absolute path of a file.
//
// Returned parentPath is path of the composite file owning the chunk.
// It's a non-empty string if valid chunk name is detected
// or "" if it's not a chunk.
// Other returned values depend on detected chunk type:
// data or control, active or temporary:
//
// data chunk - the returned chunkNo is non-negative and ctrlType is ""
// control chunk - the chunkNo is -1 and ctrlType is a non-empty string
// active chunk - the returned xactID is ""
// temporary chunk - the xactID is a non-empty string
func (f *Fs) parseChunkName(filePath string) (parentPath string, chunkNo int, ctrlType, xactID string) {
dir, name := path.Split(filePath)
match := f.nameRegexp.FindStringSubmatch(name)
if match == nil || match[1] == "" {
return "", -1, "", ""
}
var err error
chunkNo = -1
if match[2] != "" {
if chunkNo, err = strconv.Atoi(match[2]); err != nil {
chunkNo = -1
}
if chunkNo -= f.opt.StartFrom; chunkNo < 0 {
fs.Infof(f, "invalid data chunk number in file %q", name)
return "", -1, "", ""
}
}
if match[4] != "" {
xactID = match[4]
}
if match[5] != "" {
// old-style temporary suffix
number, err := strconv.ParseInt(match[5], 10, 64)
if err != nil || number < 0 {
fs.Infof(f, "invalid old-style transaction number in file %q", name)
return "", -1, "", ""
}
// convert old-style transaction number to base-36 transaction ID
xactID = fmt.Sprintf(tempSuffixFormat, strconv.FormatInt(number, 36))
xactID = xactID[1:] // strip leading underscore
}
parentPath = dir + match[1]
ctrlType = match[3]
return
}
// forbidChunk prints error message or raises error if file is chunk.
// First argument sets log prefix, use `false` to suppress message.
func (f *Fs) forbidChunk(o interface{}, filePath string) error {
if parentPath, _, _, _ := f.parseChunkName(filePath); parentPath != "" {
if f.opt.FailHard {
return fmt.Errorf("chunk overlap with %q", parentPath)
}
if boolVal, isBool := o.(bool); !isBool || boolVal {
fs.Errorf(o, "chunk overlap with %q", parentPath)
}
}
return nil
}
// newXactID produces a sufficiently random transaction identifier.
//
// The temporary suffix mask allows identifiers consisting of 4-9
// base-36 digits (ie. digits 0-9 or lowercase letters a-z).
// The identifiers must be unique between transactions running on
// the single file in parallel.
//
// Currently the function produces 6-character identifiers.
// Together with underscore this makes a 7-character temporary suffix.
//
// The first 4 characters isolate groups of transactions by time intervals.
// The maximum length of interval is base-36 "zzzz" ie. 1,679,615 seconds.
// The function rather takes a maximum prime closest to this number
// (see https://primes.utm.edu) as the interval length to better safeguard
// against repeating pseudo-random sequences in cases when rclone is
// invoked from a periodic scheduler like unix cron.
// Thus, the interval is slightly more than 19 days 10 hours 33 minutes.
//
// The remaining 2 base-36 digits (in the range from 0 to 1295 inclusive)
// are taken from the local random source.
// This provides about 0.1% collision probability for two parallel
// operations started at the same second and working on the same file.
//
// Non-empty filePath argument enables probing for existing temporary chunk
// to further eliminate collisions.
func (f *Fs) newXactID(ctx context.Context, filePath string) (xactID string, err error) {
const closestPrimeZzzzSeconds = 1679609
const maxTwoBase36Digits = 1295
unixSec := time.Now().Unix()
if unixSec < 0 {
unixSec = -unixSec // unlikely but the number must be positive
}
circleSec := unixSec % closestPrimeZzzzSeconds
first4chars := strconv.FormatInt(circleSec, 36)
for tries := 0; tries < maxTransactionProbes; tries++ {
f.xactIDMutex.Lock()
randomness := f.xactIDRand.Int63n(maxTwoBase36Digits + 1)
f.xactIDMutex.Unlock()
last2chars := strconv.FormatInt(randomness, 36)
xactID = fmt.Sprintf("%04s%02s", first4chars, last2chars)
if filePath == "" {
return
}
probeChunk := f.makeChunkName(filePath, 0, "", xactID)
_, probeErr := f.base.NewObject(ctx, probeChunk)
if probeErr != nil {
return
}
}
return "", fmt.Errorf("can't setup transaction for %s", filePath)
}
// 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.
//
// Commands normally cleanup all temporary chunks in case of a failure.
// However, if rclone dies unexpectedly, it can leave behind a bunch of
// hidden temporary chunks. List and its underlying chunkEntries()
// silently skip all temporary chunks in the directory. It's okay if
// they belong to an unfinished command running in parallel.
//
// However, there is no way to discover dead temporary chunks atm.
// As a workaround users can use `purge` to forcibly remove the whole
// directory together with dead chunks.
// In future a flag named like `--chunker-list-hidden` may be added to
// rclone that will tell List to reveal hidden chunks.
//
func (f *Fs) List(ctx context.Context, dir string) (entries fs.DirEntries, err error) {
entries, err = f.base.List(ctx, dir)
if err != nil {
return nil, err
}
return f.processEntries(ctx, entries, dir)
}
// 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 than doing a directory traversal.
func (f *Fs) ListR(ctx context.Context, dir string, callback fs.ListRCallback) (err error) {
do := f.base.Features().ListR
return do(ctx, dir, func(entries fs.DirEntries) error {
newEntries, err := f.processEntries(ctx, entries, dir)
if err != nil {
return err
}
return callback(newEntries)
})
}
// processEntries assembles chunk entries into composite entries
func (f *Fs) processEntries(ctx context.Context, origEntries fs.DirEntries, dirPath string) (newEntries fs.DirEntries, err error) {
var sortedEntries fs.DirEntries
if f.dirSort {
// sort entries so that meta objects go before their chunks
sortedEntries = make(fs.DirEntries, len(origEntries))
copy(sortedEntries, origEntries)
sort.Sort(sortedEntries)
} else {
sortedEntries = origEntries
}
byRemote := make(map[string]*Object)
badEntry := make(map[string]bool)
isSubdir := make(map[string]bool)
var tempEntries fs.DirEntries
for _, dirOrObject := range sortedEntries {
switch entry := dirOrObject.(type) {
case fs.Object:
remote := entry.Remote()
if mainRemote, chunkNo, ctrlType, xactID := f.parseChunkName(remote); mainRemote != "" {
if xactID != "" {
if revealHidden {
fs.Infof(f, "ignore temporary chunk %q", remote)
}
break
}
if ctrlType != "" {
if revealHidden {
fs.Infof(f, "ignore control chunk %q", remote)
}
break
}
mainObject := byRemote[mainRemote]
if mainObject == nil && f.useMeta {
fs.Debugf(f, "skip chunk %q without meta object", remote)
break
}
if mainObject == nil {
// useMeta is false - create chunked object without metadata
mainObject = f.newObject(mainRemote, nil, nil)
byRemote[mainRemote] = mainObject
if !badEntry[mainRemote] {
tempEntries = append(tempEntries, mainObject)
}
}
if err := mainObject.addChunk(entry, chunkNo); err != nil {
if f.opt.FailHard {
return nil, err
}
badEntry[mainRemote] = true
}
break
}
object := f.newObject("", entry, nil)
byRemote[remote] = object
tempEntries = append(tempEntries, object)
case fs.Directory:
isSubdir[entry.Remote()] = true
wrapDir := fs.NewDirCopy(ctx, entry)
wrapDir.SetRemote(entry.Remote())
tempEntries = append(tempEntries, wrapDir)
default:
if f.opt.FailHard {
return nil, fmt.Errorf("Unknown object type %T", entry)
}
fs.Debugf(f, "unknown object type %T", entry)
}
}
for _, entry := range tempEntries {
if object, ok := entry.(*Object); ok {
remote := object.Remote()
if isSubdir[remote] {
if f.opt.FailHard {
return nil, fmt.Errorf("%q is both meta object and directory", remote)
}
badEntry[remote] = true // fall thru
}
if badEntry[remote] {
fs.Debugf(f, "invalid directory entry %q", remote)
continue
}
if err := object.validate(); err != nil {
if f.opt.FailHard {
return nil, err
}
fs.Debugf(f, "invalid chunks in object %q", remote)
continue
}
}
newEntries = append(newEntries, entry)
}
if f.dirSort {
sort.Sort(newEntries)
}
return newEntries, nil
}
// NewObject finds the Object at remote.
//
// Please note that every NewObject invocation will scan the whole directory.
// Using here something like fs.DirCache might improve performance
// (yet making the logic more complex).
//
// Note that chunker prefers analyzing file names rather than reading
// the content of meta object assuming that directory scans are fast
// but opening even a small file can be slow on some backends.
//
func (f *Fs) NewObject(ctx context.Context, remote string) (fs.Object, error) {
if err := f.forbidChunk(false, remote); err != nil {
return nil, errors.Wrap(err, "can't access")
}
var (
o *Object
baseObj fs.Object
err error
)
if f.useMeta {
baseObj, err = f.base.NewObject(ctx, remote)
if err != nil {
return nil, err
}
remote = baseObj.Remote()
// Chunker's meta object cannot be large and maxMetadataSize acts
// as a hard limit. Anything larger than that is treated as a
// non-chunked file without even checking its contents, so it's
// paramount to prevent metadata from exceeding the maximum size.
o = f.newObject("", baseObj, nil)
if o.size > maxMetadataSize {
return o, nil
}
} else {
// Metadata is disabled, hence this is either a multi-chunk
// composite file without meta object or a non-chunked file.
// Create an empty wrapper here, scan directory to determine
// which case it is and postpone reading if it's the latter one.
o = f.newObject(remote, nil, nil)
}
// If the object is small, it's probably a meta object.
// However, composite file must have data chunks besides it.
// Scan directory for possible data chunks now and decide later on.
dir := path.Dir(strings.TrimRight(remote, "/"))
if dir == "." {
dir = ""
}
entries, err := f.base.List(ctx, dir)
switch err {
case nil:
// OK, fall thru
case fs.ErrorDirNotFound:
entries = nil
default:
return nil, errors.Wrap(err, "can't detect composite file")
}
for _, dirOrObject := range entries {
entry, ok := dirOrObject.(fs.Object)
if !ok {
continue
}
entryRemote := entry.Remote()
if !strings.Contains(entryRemote, remote) {
continue // bypass regexp to save cpu
}
mainRemote, chunkNo, ctrlType, xactID := f.parseChunkName(entryRemote)
if mainRemote == "" || mainRemote != remote || ctrlType != "" || xactID != "" {
continue // skip non-conforming, temporary and control chunks
}
//fs.Debugf(f, "%q belongs to %q as chunk %d", entryRemote, mainRemote, chunkNo)
if err := o.addChunk(entry, chunkNo); err != nil {
return nil, err
}
}
if o.main == nil && (o.chunks == nil || len(o.chunks) == 0) {
// Scanning hasn't found data chunks with conforming names.
if f.useMeta {
// Metadata is required but absent and there are no chunks.
return nil, fs.ErrorObjectNotFound
}
// Data chunks are not found and metadata is disabled.
// Thus, we are in the "latter case" from above.
// Let's try the postponed reading of a non-chunked file and add it
// as a single chunk to the empty composite wrapper created above
// with nil metadata.
baseObj, err = f.base.NewObject(ctx, remote)
if err == nil {
err = o.addChunk(baseObj, 0)
}
if err != nil {
return nil, err
}
}
// This is either a composite object with metadata or a non-chunked
// file without metadata. Validate it and update the total data size.
// As an optimization, skip metadata reading here - we will call
// readMetadata lazily when needed (reading can be expensive).
if err := o.validate(); err != nil {
return nil, err
}
return o, nil
}
func (o *Object) readMetadata(ctx context.Context) error {
if o.isFull {
return nil
}
if !o.isComposite() || !o.f.useMeta {
o.isFull = true
return nil
}
// validate metadata
metaObject := o.main
reader, err := metaObject.Open(ctx)
if err != nil {
return err
}
metadata, err := ioutil.ReadAll(reader)
_ = reader.Close() // ensure file handle is freed on windows
if err != nil {
return err
}
switch o.f.opt.MetaFormat {
case "simplejson":
metaInfo, err := unmarshalSimpleJSON(ctx, metaObject, metadata, true)
if err != nil {
return errors.Wrap(err, "invalid metadata")
}
if o.size != metaInfo.Size() || len(o.chunks) != metaInfo.nChunks {
return errors.New("metadata doesn't match file size")
}
o.md5 = metaInfo.md5
o.sha1 = metaInfo.sha1
}
o.isFull = true
return nil
}
// put implements Put, PutStream, PutUnchecked, Update
func (f *Fs) put(ctx context.Context, in io.Reader, src fs.ObjectInfo, remote string, options []fs.OpenOption, basePut putFn) (obj fs.Object, err error) {
c := f.newChunkingReader(src)
wrapIn := c.wrapStream(ctx, in, src)
var metaObject fs.Object
defer func() {
if err != nil {
c.rollback(ctx, metaObject)
}
}()
baseRemote := remote
xactID, errXact := f.newXactID(ctx, baseRemote)
if errXact != nil {
return nil, errXact
}
// Transfer chunks data
for c.chunkNo = 0; !c.done; c.chunkNo++ {
if c.chunkNo > maxSafeChunkNumber {
return nil, ErrChunkOverflow
}
tempRemote := f.makeChunkName(baseRemote, c.chunkNo, "", xactID)
size := c.sizeLeft
if size > c.chunkSize {
size = c.chunkSize
}
savedReadCount := c.readCount
// If a single chunk is expected, avoid the extra rename operation
chunkRemote := tempRemote
if c.expectSingle && c.chunkNo == 0 && optimizeFirstChunk {
chunkRemote = baseRemote
}
info := f.wrapInfo(src, chunkRemote, size)
// TODO: handle range/limit options
chunk, errChunk := basePut(ctx, wrapIn, info, options...)
if errChunk != nil {
return nil, errChunk
}
if size > 0 && c.readCount == savedReadCount && c.expectSingle {
// basePut returned success but didn't call chunkingReader's Read.
// This is possible if wrapped remote has performed the put by hash
// because chunker bridges Hash from source for non-chunked files.
// Hence, force Read here to update accounting and hashsums.
if err := c.dummyRead(wrapIn, size); err != nil {
return nil, err
}
}
if c.sizeLeft == 0 && !c.done {
// The file has been apparently put by hash, force completion.
c.done = true
}
// Expected a single chunk but more to come, so name it as usual.
if !c.done && chunkRemote != tempRemote {
fs.Infof(chunk, "Expected single chunk, got more")
chunkMoved, errMove := f.baseMove(ctx, chunk, tempRemote, delFailed)
if errMove != nil {
silentlyRemove(ctx, chunk)
return nil, errMove
}
chunk = chunkMoved
}
// Wrapped remote may or may not have seen EOF from chunking reader,
// eg. the box multi-uploader reads exactly the chunk size specified
// and skips the "EOF" read. Hence, switch to next limit here.
if !(c.chunkLimit == 0 || c.chunkLimit == c.chunkSize || c.sizeTotal == -1 || c.done) {
silentlyRemove(ctx, chunk)
return nil, fmt.Errorf("Destination ignored %d data bytes", c.chunkLimit)
}
c.chunkLimit = c.chunkSize
c.chunks = append(c.chunks, chunk)
}
// Validate uploaded size
if c.sizeTotal != -1 && c.readCount != c.sizeTotal {
return nil, fmt.Errorf("Incorrect upload size %d != %d", c.readCount, c.sizeTotal)
}
// Check for input that looks like valid metadata
needMeta := len(c.chunks) > 1
if c.readCount <= maxMetadataSize && len(c.chunks) == 1 {
_, err := unmarshalSimpleJSON(ctx, c.chunks[0], c.smallHead, false)
needMeta = err == nil
}
// Finalize small object as non-chunked.
// This can be bypassed, and single chunk with metadata will be
// created if forced by consistent hashing or due to unsafe input.
if !needMeta && !f.hashAll && f.useMeta {
// If previous object was chunked, remove its chunks
f.removeOldChunks(ctx, baseRemote)
// Rename single data chunk in place
chunk := c.chunks[0]
if chunk.Remote() != baseRemote {
chunkMoved, errMove := f.baseMove(ctx, chunk, baseRemote, delAlways)
if errMove != nil {
silentlyRemove(ctx, chunk)
return nil, errMove
}
chunk = chunkMoved
}
return f.newObject("", chunk, nil), nil
}
// Validate total size of data chunks
var sizeTotal int64
for _, chunk := range c.chunks {
sizeTotal += chunk.Size()
}
if sizeTotal != c.readCount {
return nil, fmt.Errorf("Incorrect chunks size %d != %d", sizeTotal, c.readCount)
}
// If previous object was chunked, remove its chunks
f.removeOldChunks(ctx, baseRemote)
// Rename data chunks from temporary to final names
for chunkNo, chunk := range c.chunks {
chunkRemote := f.makeChunkName(baseRemote, chunkNo, "", "")
chunkMoved, errMove := f.baseMove(ctx, chunk, chunkRemote, delFailed)
if errMove != nil {
return nil, errMove
}
c.chunks[chunkNo] = chunkMoved
}
if !f.useMeta {
// Remove stale metadata, if any
oldMeta, errOldMeta := f.base.NewObject(ctx, baseRemote)
if errOldMeta == nil {
silentlyRemove(ctx, oldMeta)
}
o := f.newObject(baseRemote, nil, c.chunks)
o.size = sizeTotal
return o, nil
}
// Update meta object
var metadata []byte
switch f.opt.MetaFormat {
case "simplejson":
c.updateHashes()
metadata, err = marshalSimpleJSON(ctx, sizeTotal, len(c.chunks), c.md5, c.sha1)
}
if err == nil {
metaInfo := f.wrapInfo(src, baseRemote, int64(len(metadata)))
metaObject, err = basePut(ctx, bytes.NewReader(metadata), metaInfo)
}
if err != nil {
return nil, err
}
o := f.newObject("", metaObject, c.chunks)
o.size = sizeTotal
return o, nil
}
type putFn func(ctx context.Context, in io.Reader, src fs.ObjectInfo, options ...fs.OpenOption) (fs.Object, error)
type chunkingReader struct {
baseReader io.Reader
sizeTotal int64
sizeLeft int64
readCount int64
chunkSize int64
chunkLimit int64
chunkNo int
err error
done bool
chunks []fs.Object
expectSingle bool
smallHead []byte
fs *Fs
hasher gohash.Hash
md5 string
sha1 string
}
func (f *Fs) newChunkingReader(src fs.ObjectInfo) *chunkingReader {
c := &chunkingReader{
fs: f,
chunkSize: int64(f.opt.ChunkSize),
sizeTotal: src.Size(),
}
c.chunkLimit = c.chunkSize
c.sizeLeft = c.sizeTotal
c.expectSingle = c.sizeTotal >= 0 && c.sizeTotal <= c.chunkSize
return c
}
func (c *chunkingReader) wrapStream(ctx context.Context, in io.Reader, src fs.ObjectInfo) io.Reader {
baseIn, wrapBack := accounting.UnWrap(in)
switch {
case c.fs.useMD5:
if c.md5, _ = src.Hash(ctx, hash.MD5); c.md5 == "" {
if c.fs.hashFallback {
c.sha1, _ = src.Hash(ctx, hash.SHA1)
} else {
c.hasher = md5.New()
}
}
case c.fs.useSHA1:
if c.sha1, _ = src.Hash(ctx, hash.SHA1); c.sha1 == "" {
if c.fs.hashFallback {
c.md5, _ = src.Hash(ctx, hash.MD5)
} else {
c.hasher = sha1.New()
}
}
}
if c.hasher != nil {
baseIn = io.TeeReader(baseIn, c.hasher)
}
c.baseReader = baseIn
return wrapBack(c)
}
func (c *chunkingReader) updateHashes() {
if c.hasher == nil {
return
}
switch {
case c.fs.useMD5:
c.md5 = hex.EncodeToString(c.hasher.Sum(nil))
case c.fs.useSHA1:
c.sha1 = hex.EncodeToString(c.hasher.Sum(nil))
}
}
// Note: Read is not called if wrapped remote performs put by hash.
func (c *chunkingReader) Read(buf []byte) (bytesRead int, err error) {
if c.chunkLimit <= 0 {
// Chunk complete - switch to next one.
// We might not get here because some remotes (eg. box multi-uploader)
// read the specified size exactly and skip the concluding EOF Read.
// Then a check in the put loop will kick in.
c.chunkLimit = c.chunkSize
return 0, io.EOF
}
if int64(len(buf)) > c.chunkLimit {
buf = buf[0:c.chunkLimit]
}
bytesRead, err = c.baseReader.Read(buf)
if err != nil && err != io.EOF {
c.err = err
c.done = true
return
}
c.accountBytes(int64(bytesRead))
if c.chunkNo == 0 && c.expectSingle && bytesRead > 0 && c.readCount <= maxMetadataSize {
c.smallHead = append(c.smallHead, buf[:bytesRead]...)
}
if bytesRead == 0 && c.sizeLeft == 0 {
err = io.EOF // Force EOF when no data left.
}
if err == io.EOF {
c.done = true
}
return
}
func (c *chunkingReader) accountBytes(bytesRead int64) {
c.readCount += bytesRead
c.chunkLimit -= bytesRead
if c.sizeLeft != -1 {
c.sizeLeft -= bytesRead
}
}
// dummyRead updates accounting, hashsums etc by simulating reads
func (c *chunkingReader) dummyRead(in io.Reader, size int64) error {
if c.hasher == nil && c.readCount+size > maxMetadataSize {
c.accountBytes(size)
return nil
}
const bufLen = 1048576 // 1MB
buf := make([]byte, bufLen)
for size > 0 {
n := size
if n > bufLen {
n = bufLen
}
if _, err := io.ReadFull(in, buf[0:n]); err != nil {
return err
}
size -= n
}
return nil
}
// rollback removes uploaded temporary chunks
func (c *chunkingReader) rollback(ctx context.Context, metaObject fs.Object) {
if metaObject != nil {
c.chunks = append(c.chunks, metaObject)
}
for _, chunk := range c.chunks {
if err := chunk.Remove(ctx); err != nil {
fs.Errorf(chunk, "Failed to remove temporary chunk: %v", err)
}
}
}
func (f *Fs) removeOldChunks(ctx context.Context, remote string) {
oldFsObject, err := f.NewObject(ctx, remote)
if err == nil {
oldObject := oldFsObject.(*Object)
for _, chunk := range oldObject.chunks {
if err := chunk.Remove(ctx); err != nil {
fs.Errorf(chunk, "Failed to remove old chunk: %v", err)
}
}
}
}
// Put into the remote path with the given modTime and 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 err := f.forbidChunk(src, src.Remote()); err != nil {
return nil, errors.Wrap(err, "refusing to put")
}
return f.put(ctx, in, src, src.Remote(), options, f.base.Put)
}
// 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) {
if err := f.forbidChunk(src, src.Remote()); err != nil {
return nil, errors.Wrap(err, "refusing to upload")
}
return f.put(ctx, in, src, src.Remote(), options, f.base.Features().PutStream)
}
// 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) error {
if err := o.f.forbidChunk(o, o.Remote()); err != nil {
return errors.Wrap(err, "update refused")
}
if err := o.readMetadata(ctx); err != nil {
// refuse to update a file of unsupported format
return errors.Wrap(err, "refusing to update")
}
basePut := o.f.base.Put
if src.Size() < 0 {
basePut = o.f.base.Features().PutStream
if basePut == nil {
return errors.New("wrapped file system does not support streaming uploads")
}
}
oNew, err := o.f.put(ctx, in, src, o.Remote(), options, basePut)
if err == nil {
*o = *oNew.(*Object)
}
return err
}
// 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.
func (f *Fs) PutUnchecked(ctx context.Context, in io.Reader, src fs.ObjectInfo, options ...fs.OpenOption) (fs.Object, error) {
do := f.base.Features().PutUnchecked
if do == nil {
return nil, errors.New("can't PutUnchecked")
}
// TODO: handle range/limit options and really chunk stream here!
o, err := do(ctx, in, f.wrapInfo(src, "", -1))
if err != nil {
return nil, err
}
return f.newObject("", o, nil), nil
}
// Hashes returns the supported hash sets.
// Chunker advertises a hash type if and only if it can be calculated
// for files of any size, non-chunked or composite.
func (f *Fs) Hashes() hash.Set {
// composites AND no fallback AND (chunker OR wrapped Fs will hash all non-chunked's)
if f.useMD5 && !f.hashFallback && (f.hashAll || f.base.Hashes().Contains(hash.MD5)) {
return hash.NewHashSet(hash.MD5)
}
if f.useSHA1 && !f.hashFallback && (f.hashAll || f.base.Hashes().Contains(hash.SHA1)) {
return hash.NewHashSet(hash.SHA1)
}
return hash.NewHashSet() // can't provide strong guarantees
}
// 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 {
if err := f.forbidChunk(dir, dir); err != nil {
return errors.Wrap(err, "can't mkdir")
}
return f.base.Mkdir(ctx, dir)
}
// 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.base.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.
//
// This command will chain to `purge` from wrapped remote.
// As a result it removes not only composite chunker files with their
// active chunks but also all hidden temporary chunks in the directory.
//
func (f *Fs) Purge(ctx context.Context) error {
do := f.base.Features().Purge
if do == nil {
return fs.ErrorCantPurge
}
return do(ctx)
}
// Remove an object (chunks and metadata, if any)
//
// Remove deletes only active chunks of the composite object.
// It does not try to look for temporary chunks because they could belong
// to another command modifying this composite file in parallel.
//
// Commands normally cleanup all temporary chunks in case of a failure.
// However, if rclone dies unexpectedly, it can leave hidden temporary
// chunks, which cannot be discovered using the `list` command.
// Remove does not try to search for such chunks or to delete them.
// Sometimes this can lead to strange results eg. when `list` shows that
// directory is empty but `rmdir` refuses to remove it because on the
// level of wrapped remote it's actually *not* empty.
// As a workaround users can use `purge` to forcibly remove it.
//
// In future, a flag `--chunker-delete-hidden` may be added which tells
// Remove to search directory for hidden chunks and remove them too
// (at the risk of breaking parallel commands).
//
// Remove is the only operation allowed on the composite files with
// invalid or future metadata format.
// We don't let user copy/move/update unsupported composite files.
// Let's at least let her get rid of them, just complain loudly.
//
// This can litter directory with orphan chunks of unsupported types,
// but as long as we remove meta object, even future releases will
// treat the composite file as removed and refuse to act upon it.
//
// Disclaimer: corruption can still happen if unsupported file is removed
// and then recreated with the same name.
// Unsupported control chunks will get re-picked by a more recent
// rclone version with unexpected results. This can be helped by
// the `delete hidden` flag above or at least the user has been warned.
//
func (o *Object) Remove(ctx context.Context) (err error) {
if err := o.f.forbidChunk(o, o.Remote()); err != nil {
// operations.Move can still call Remove if chunker's Move refuses
// to corrupt file in hard mode. Hence, refuse to Remove, too.
return errors.Wrap(err, "refuse to corrupt")
}
if err := o.readMetadata(ctx); err != nil {
// Proceed but warn user that unexpected things can happen.
fs.Errorf(o, "Removing a file with unsupported metadata: %v", err)
}
// Remove non-chunked file or meta object of a composite file.
if o.main != nil {
err = o.main.Remove(ctx)
}
// Remove only active data chunks, ignore any temporary chunks that
// might probably be created in parallel by other transactions.
for _, chunk := range o.chunks {
chunkErr := chunk.Remove(ctx)
if err == nil {
err = chunkErr
}
}
// There are no known control chunks to remove atm.
return err
}
// copyOrMove implements copy or move
func (f *Fs) copyOrMove(ctx context.Context, o *Object, remote string, do copyMoveFn, md5, sha1, opName string) (fs.Object, error) {
if err := f.forbidChunk(o, remote); err != nil {
return nil, errors.Wrapf(err, "can't %s", opName)
}
if !o.isComposite() {
fs.Debugf(o, "%s non-chunked object...", opName)
oResult, err := do(ctx, o.mainChunk(), remote) // chain operation to a single wrapped chunk
if err != nil {
return nil, err
}
return f.newObject("", oResult, nil), nil
}
if err := o.readMetadata(ctx); err != nil {
// Refuse to copy/move composite files with invalid or future
// metadata format which might involve unsupported chunk types.
return nil, errors.Wrapf(err, "can't %s this file", opName)
}
fs.Debugf(o, "%s %d data chunks...", opName, len(o.chunks))
mainRemote := o.remote
var newChunks []fs.Object
var err error
// Copy/move active data chunks.
// Ignore possible temporary chunks being created by parallel operations.
for _, chunk := range o.chunks {
chunkRemote := chunk.Remote()
if !strings.HasPrefix(chunkRemote, mainRemote) {
err = fmt.Errorf("invalid chunk name %q", chunkRemote)
break
}
chunkSuffix := chunkRemote[len(mainRemote):]
chunkResult, err := do(ctx, chunk, remote+chunkSuffix)
if err != nil {
break
}
newChunks = append(newChunks, chunkResult)
}
// Copy or move old metadata.
// There are no known control chunks to move/copy atm.
var metaObject fs.Object
if err == nil && o.main != nil {
metaObject, err = do(ctx, o.main, remote)
}
if err != nil {
for _, chunk := range newChunks {
silentlyRemove(ctx, chunk)
}
return nil, err
}
// Create wrapping object, calculate and validate total size
newObj := f.newObject(remote, metaObject, newChunks)
err = newObj.validate()
if err != nil {
silentlyRemove(ctx, newObj)
return nil, err
}
// Update metadata
var metadata []byte
switch f.opt.MetaFormat {
case "simplejson":
metadata, err = marshalSimpleJSON(ctx, newObj.size, len(newChunks), md5, sha1)
if err == nil {
metaInfo := f.wrapInfo(metaObject, "", int64(len(metadata)))
err = newObj.main.Update(ctx, bytes.NewReader(metadata), metaInfo)
}
case "none":
if newObj.main != nil {
err = newObj.main.Remove(ctx)
}
}
// Return the composite object
if err != nil {
silentlyRemove(ctx, newObj)
return nil, err
}
return newObj, nil
}
type copyMoveFn func(context.Context, fs.Object, string) (fs.Object, error)
func (f *Fs) okForServerSide(ctx context.Context, src fs.Object, opName string) (obj *Object, md5, sha1 string, ok bool) {
var diff string
obj, ok = src.(*Object)
switch {
case !ok:
diff = "remote types"
case !operations.SameConfig(f.base, obj.f.base):
diff = "wrapped remotes"
case f.opt.ChunkSize != obj.f.opt.ChunkSize:
diff = "chunk sizes"
case f.opt.NameFormat != obj.f.opt.NameFormat:
diff = "chunk name formats"
case f.opt.MetaFormat != obj.f.opt.MetaFormat:
diff = "meta formats"
}
if diff != "" {
fs.Debugf(src, "Can't %s - different %s", opName, diff)
ok = false
return
}
requireMetaHash := obj.isComposite() && f.opt.MetaFormat == "simplejson"
if !requireMetaHash && !f.hashAll {
ok = true // hash is not required for metadata
return
}
switch {
case f.useMD5:
md5, _ = obj.Hash(ctx, hash.MD5)
ok = md5 != ""
if !ok && f.hashFallback {
sha1, _ = obj.Hash(ctx, hash.SHA1)
ok = sha1 != ""
}
case f.useSHA1:
sha1, _ = obj.Hash(ctx, hash.SHA1)
ok = sha1 != ""
if !ok && f.hashFallback {
md5, _ = obj.Hash(ctx, hash.MD5)
ok = md5 != ""
}
default:
ok = false
}
if !ok {
fs.Debugf(src, "Can't %s - required hash not found", opName)
}
return
}
// 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) {
baseCopy := f.base.Features().Copy
if baseCopy == nil {
return nil, fs.ErrorCantCopy
}
obj, md5, sha1, ok := f.okForServerSide(ctx, src, "copy")
if !ok {
return nil, fs.ErrorCantCopy
}
return f.copyOrMove(ctx, obj, remote, baseCopy, md5, sha1, "copy")
}
// 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) {
baseMove := func(ctx context.Context, src fs.Object, remote string) (fs.Object, error) {
return f.baseMove(ctx, src, remote, delNever)
}
obj, md5, sha1, ok := f.okForServerSide(ctx, src, "move")
if !ok {
return nil, fs.ErrorCantMove
}
return f.copyOrMove(ctx, obj, remote, baseMove, md5, sha1, "move")
}
// baseMove chains to the wrapped Move or simulates it by Copy+Delete
func (f *Fs) baseMove(ctx context.Context, src fs.Object, remote string, delMode int) (fs.Object, error) {
var (
dest fs.Object
err error
)
switch delMode {
case delAlways:
dest, err = f.base.NewObject(ctx, remote)
case delFailed:
dest, err = operations.Move(ctx, f.base, nil, remote, src)
if err == nil {
return dest, err
}
dest, err = f.base.NewObject(ctx, remote)
case delNever:
// fall thru, the default
}
if err != nil {
dest = nil
}
return operations.Move(ctx, f.base, dest, remote, src)
}
// 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.base.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.base, srcRemote, dstRemote)
}
// 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.base.Features().CleanUp
if do == nil {
return errors.New("can't CleanUp")
}
return do(ctx)
}
// About gets quota information from the Fs
func (f *Fs) About(ctx context.Context) (*fs.Usage, error) {
do := f.base.Features().About
if do == nil {
return nil, errors.New("About not supported")
}
return do(ctx)
}
// UnWrap returns the Fs that this Fs is wrapping
func (f *Fs) UnWrap() fs.Fs {
return f.base
}
// 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
}
// ChangeNotify calls the passed function with a path
// that has had changes. If the implementation
// uses polling, it should adhere to the given interval.
//
// Replace data chunk names by the name of composite file.
// Ignore temporary and control chunks.
func (f *Fs) ChangeNotify(ctx context.Context, notifyFunc func(string, fs.EntryType), pollIntervalChan <-chan time.Duration) {
do := f.base.Features().ChangeNotify
if do == nil {
return
}
wrappedNotifyFunc := func(path string, entryType fs.EntryType) {
//fs.Debugf(f, "ChangeNotify: path %q entryType %d", path, entryType)
if entryType == fs.EntryObject {
mainPath, _, _, xactID := f.parseChunkName(path)
if mainPath != "" && xactID == "" {
path = mainPath
}
}
notifyFunc(path, entryType)
}
do(ctx, wrappedNotifyFunc, pollIntervalChan)
}
// Object represents a composite file wrapping one or more data chunks
type Object struct {
remote string
main fs.Object // meta object if file is composite, or wrapped non-chunked file, nil if meta format is 'none'
chunks []fs.Object // active data chunks if file is composite, or wrapped file as a single chunk if meta format is 'none'
size int64 // cached total size of chunks in a composite file or -1 for non-chunked files
isFull bool // true if metadata has been read
md5 string
sha1 string
f *Fs
}
func (o *Object) addChunk(chunk fs.Object, chunkNo int) error {
if chunkNo < 0 {
return fmt.Errorf("invalid chunk number %d", chunkNo+o.f.opt.StartFrom)
}
if chunkNo == len(o.chunks) {
o.chunks = append(o.chunks, chunk)
return nil
}
if chunkNo > maxSafeChunkNumber {
return ErrChunkOverflow
}
if chunkNo > len(o.chunks) {
newChunks := make([]fs.Object, (chunkNo + 1), (chunkNo+1)*2)
copy(newChunks, o.chunks)
o.chunks = newChunks
}
o.chunks[chunkNo] = chunk
return nil
}
// validate verifies the object internals and updates total size
func (o *Object) validate() error {
if !o.isComposite() {
_ = o.mainChunk() // verify that single wrapped chunk exists
return nil
}
metaObject := o.main // this file is composite - o.main refers to meta object (or nil if meta format is 'none')
if metaObject != nil && metaObject.Size() > maxMetadataSize {
// metadata of a chunked file must be a tiny piece of json
o.size = -1
return fmt.Errorf("%q metadata is too large", o.remote)
}
var totalSize int64
for _, chunk := range o.chunks {
if chunk == nil {
o.size = -1
return fmt.Errorf("%q has missing chunks", o)
}
totalSize += chunk.Size()
}
o.size = totalSize // cache up the total data size
return nil
}
func (f *Fs) newObject(remote string, main fs.Object, chunks []fs.Object) *Object {
var size int64 = -1
if main != nil {
size = main.Size()
if remote == "" {
remote = main.Remote()
}
}
return &Object{
remote: remote,
main: main,
size: size,
f: f,
chunks: chunks,
}
}
// mainChunk returns:
// - a wrapped object for non-chunked files
// - meta object for chunked files with metadata
// - first chunk for chunked files without metadata
// Never returns nil.
func (o *Object) mainChunk() fs.Object {
if o.main != nil {
return o.main // meta object or non-chunked wrapped file
}
if o.chunks != nil {
return o.chunks[0] // first chunk of a chunked composite file
}
panic("invalid chunked object") // very unlikely
}
func (o *Object) isComposite() bool {
return o.chunks != nil
}
// 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 {
return o.remote
}
// Size returns the size of the file
func (o *Object) Size() int64 {
if o.isComposite() {
return o.size // total size of data chunks in a composite file
}
return o.mainChunk().Size() // size of wrapped non-chunked file
}
// Storable returns whether object is storable
func (o *Object) Storable() bool {
return o.mainChunk().Storable()
}
// ModTime returns the modification time of the file
func (o *Object) ModTime(ctx context.Context) time.Time {
return o.mainChunk().ModTime(ctx)
}
// SetModTime sets the modification time of the file
func (o *Object) SetModTime(ctx context.Context, mtime time.Time) error {
if err := o.readMetadata(ctx); err != nil {
return err // refuse to act on unsupported format
}
return o.mainChunk().SetModTime(ctx, mtime)
}
// Hash returns the selected checksum of the file.
// If no checksum is available it returns "".
//
// Hash won't fail with `unsupported` error but return empty
// hash string if a particular hashsum type is not supported
//
// Hash takes hashsum from metadata if available or requests it
// from wrapped remote for non-chunked files.
// Metadata (if meta format is not 'none') is by default kept
// only for composite files. In the "All" hashing mode chunker
// will force metadata on all files if particular hashsum type
// is not supported by wrapped remote.
//
// Note that Hash prefers the wrapped hashsum for non-chunked
// file, then tries to read it from metadata. This in theory
// handles the unusual case when a small file has been tampered
// on the level of wrapped remote but chunker is unaware of that.
//
func (o *Object) Hash(ctx context.Context, hashType hash.Type) (string, error) {
if !o.isComposite() {
// First, chain to the wrapped non-chunked file if possible.
if value, err := o.mainChunk().Hash(ctx, hashType); err == nil && value != "" {
return value, nil
}
}
if err := o.readMetadata(ctx); err != nil {
return "", err // valid metadata is required to get hash, abort
}
// Try hash from metadata if the file is composite or if wrapped remote fails.
switch hashType {
case hash.MD5:
if o.md5 == "" {
return "", nil
}
return o.md5, nil
case hash.SHA1:
if o.sha1 == "" {
return "", nil
}
return o.sha1, nil
default:
return "", hash.ErrUnsupported
}
}
// UnWrap returns the wrapped Object
func (o *Object) UnWrap() fs.Object {
return o.mainChunk()
}
// Open opens the file for read. Call Close() on the returned io.ReadCloser
func (o *Object) Open(ctx context.Context, options ...fs.OpenOption) (rc io.ReadCloser, err error) {
if !o.isComposite() {
return o.mainChunk().Open(ctx, options...) // chain to wrapped non-chunked file
}
if err := o.readMetadata(ctx); err != nil {
// refuse to open unsupported format
return nil, errors.Wrap(err, "can't open")
}
var openOptions []fs.OpenOption
var offset, limit int64 = 0, -1
for _, option := range options {
switch opt := option.(type) {
case *fs.SeekOption:
offset = opt.Offset
case *fs.RangeOption:
offset, limit = opt.Decode(o.size)
default:
// pass Options on to the wrapped open, if appropriate
openOptions = append(openOptions, option)
}
}
if offset < 0 {
return nil, errors.New("invalid offset")
}
if limit < 0 {
limit = o.size - offset
}
return o.newLinearReader(ctx, offset, limit, openOptions)
}
// linearReader opens and reads file chunks sequentially, without read-ahead
type linearReader struct {
ctx context.Context
chunks []fs.Object
options []fs.OpenOption
limit int64
count int64
pos int
reader io.ReadCloser
err error
}
func (o *Object) newLinearReader(ctx context.Context, offset, limit int64, options []fs.OpenOption) (io.ReadCloser, error) {
r := &linearReader{
ctx: ctx,
chunks: o.chunks,
options: options,
limit: limit,
}
// skip to chunk for given offset
err := io.EOF
for offset >= 0 && err != nil {
offset, err = r.nextChunk(offset)
}
if err == nil || err == io.EOF {
r.err = err
return r, nil
}
return nil, err
}
func (r *linearReader) nextChunk(offset int64) (int64, error) {
if r.err != nil {
return -1, r.err
}
if r.pos >= len(r.chunks) || r.limit <= 0 || offset < 0 {
return -1, io.EOF
}
chunk := r.chunks[r.pos]
count := chunk.Size()
r.pos++
if offset >= count {
return offset - count, io.EOF
}
count -= offset
if r.limit < count {
count = r.limit
}
options := append(r.options, &fs.RangeOption{Start: offset, End: offset + count - 1})
if err := r.Close(); err != nil {
return -1, err
}
reader, err := chunk.Open(r.ctx, options...)
if err != nil {
return -1, err
}
r.reader = reader
r.count = count
return offset, nil
}
func (r *linearReader) Read(p []byte) (n int, err error) {
if r.err != nil {
return 0, r.err
}
if r.limit <= 0 {
r.err = io.EOF
return 0, io.EOF
}
for r.count <= 0 {
// current chunk has been read completely or its size is zero
off, err := r.nextChunk(0)
if off < 0 {
r.err = err
return 0, err
}
}
n, err = r.reader.Read(p)
if err == nil || err == io.EOF {
r.count -= int64(n)
r.limit -= int64(n)
if r.limit > 0 {
err = nil // more data to read
}
}
r.err = err
return
}
func (r *linearReader) Close() (err error) {
if r.reader != nil {
err = r.reader.Close()
r.reader = nil
}
return
}
// ObjectInfo describes a wrapped fs.ObjectInfo for being the source
type ObjectInfo struct {
src fs.ObjectInfo
fs *Fs
nChunks int // number of data chunks
size int64 // overrides source size by the total size of data chunks
remote string // overrides remote name
md5 string // overrides MD5 checksum
sha1 string // overrides SHA1 checksum
}
func (f *Fs) wrapInfo(src fs.ObjectInfo, newRemote string, totalSize int64) *ObjectInfo {
return &ObjectInfo{
src: src,
fs: f,
size: totalSize,
remote: newRemote,
}
}
// Fs returns read only access to the Fs that this object is part of
func (oi *ObjectInfo) Fs() fs.Info {
if oi.fs == nil {
panic("stub ObjectInfo")
}
return oi.fs
}
// String returns string representation
func (oi *ObjectInfo) String() string {
return oi.src.String()
}
// Storable returns whether object is storable
func (oi *ObjectInfo) Storable() bool {
return oi.src.Storable()
}
// Remote returns the remote path
func (oi *ObjectInfo) Remote() string {
if oi.remote != "" {
return oi.remote
}
return oi.src.Remote()
}
// Size returns the size of the file
func (oi *ObjectInfo) Size() int64 {
if oi.size != -1 {
return oi.size
}
return oi.src.Size()
}
// ModTime returns the modification time
func (oi *ObjectInfo) ModTime(ctx context.Context) time.Time {
return oi.src.ModTime(ctx)
}
// Hash returns the selected checksum of the wrapped file
// It returns "" if no checksum is available or if this
// info doesn't wrap the complete file.
func (oi *ObjectInfo) Hash(ctx context.Context, hashType hash.Type) (string, error) {
var errUnsupported error
switch hashType {
case hash.MD5:
if oi.md5 != "" {
return oi.md5, nil
}
case hash.SHA1:
if oi.sha1 != "" {
return oi.sha1, nil
}
default:
errUnsupported = hash.ErrUnsupported
}
if oi.Size() != oi.src.Size() {
// fail if this info wraps only a part of the file
return "", errUnsupported
}
// chain to full source if possible
value, err := oi.src.Hash(ctx, hashType)
if err == hash.ErrUnsupported {
return "", errUnsupported
}
return value, err
}
// ID returns the ID of the Object if known, or "" if not
func (o *Object) ID() string {
if doer, ok := o.mainChunk().(fs.IDer); ok {
return doer.ID()
}
return ""
}
// Meta format `simplejson`
type metaSimpleJSON struct {
// required core fields
Version *int `json:"ver"`
Size *int64 `json:"size"` // total size of data chunks
ChunkNum *int `json:"nchunks"` // number of data chunks
// optional extra fields
MD5 string `json:"md5,omitempty"`
SHA1 string `json:"sha1,omitempty"`
}
// marshalSimpleJSON
//
// Current implementation creates metadata in three cases:
// - for files larger than chunk size
// - if file contents can be mistaken as meta object
// - if consistent hashing is On but wrapped remote can't provide given hash
//
func marshalSimpleJSON(ctx context.Context, size int64, nChunks int, md5, sha1 string) ([]byte, error) {
version := metadataVersion
metadata := metaSimpleJSON{
// required core fields
Version: &version,
Size: &size,
ChunkNum: &nChunks,
// optional extra fields
MD5: md5,
SHA1: sha1,
}
data, err := json.Marshal(&metadata)
if err == nil && data != nil && len(data) >= maxMetadataSize {
// be a nitpicker, never produce something you can't consume
return nil, errors.New("metadata can't be this big, please report to rclone developers")
}
return data, err
}
// unmarshalSimpleJSON
//
// Only metadata format version 1 is supported atm.
// Future releases will transparently migrate older metadata objects.
// New format will have a higher version number and cannot be correctly
// handled by current implementation.
// The version check below will then explicitly ask user to upgrade rclone.
//
func unmarshalSimpleJSON(ctx context.Context, metaObject fs.Object, data []byte, strictChecks bool) (info *ObjectInfo, err error) {
// Be strict about JSON format
// to reduce possibility that a random small file resembles metadata.
if data != nil && len(data) > maxMetadataSize {
return nil, errors.New("too big")
}
if data == nil || len(data) < 2 || data[0] != '{' || data[len(data)-1] != '}' {
return nil, errors.New("invalid json")
}
var metadata metaSimpleJSON
err = json.Unmarshal(data, &metadata)
if err != nil {
return nil, err
}
// Basic fields are strictly required
// to reduce possibility that a random small file resembles metadata.
if metadata.Version == nil || metadata.Size == nil || metadata.ChunkNum == nil {
return nil, errors.New("missing required field")
}
// Perform strict checks, avoid corruption of future metadata formats.
if *metadata.Version < 1 {
return nil, errors.New("wrong version")
}
if *metadata.Size < 0 {
return nil, errors.New("negative file size")
}
if *metadata.ChunkNum < 0 {
return nil, errors.New("negative number of chunks")
}
if *metadata.ChunkNum > maxSafeChunkNumber {
return nil, ErrChunkOverflow
}
if metadata.MD5 != "" {
_, err = hex.DecodeString(metadata.MD5)
if len(metadata.MD5) != 32 || err != nil {
return nil, errors.New("wrong md5 hash")
}
}
if metadata.SHA1 != "" {
_, err = hex.DecodeString(metadata.SHA1)
if len(metadata.SHA1) != 40 || err != nil {
return nil, errors.New("wrong sha1 hash")
}
}
// ChunkNum is allowed to be 0 in future versions
if *metadata.ChunkNum < 1 && *metadata.Version <= metadataVersion {
return nil, errors.New("wrong number of chunks")
}
// Non-strict mode also accepts future metadata versions
if *metadata.Version > metadataVersion && strictChecks {
return nil, fmt.Errorf("version %d is not supported, please upgrade rclone", metadata.Version)
}
var nilFs *Fs // nil object triggers appropriate type method
info = nilFs.wrapInfo(metaObject, "", *metadata.Size)
info.nChunks = *metadata.ChunkNum
info.md5 = metadata.MD5
info.sha1 = metadata.SHA1
return info, nil
}
func silentlyRemove(ctx context.Context, o fs.Object) {
_ = o.Remove(ctx) // ignore error
}
// 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
}
// String returns a description of the FS
func (f *Fs) String() string {
return fmt.Sprintf("Chunked '%s:%s'", f.name, f.root)
}
// Precision returns the precision of this Fs
func (f *Fs) Precision() time.Duration {
return f.base.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.PutUncheckeder = (*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.ChangeNotifier = (*Fs)(nil)
_ fs.ObjectInfo = (*ObjectInfo)(nil)
_ fs.Object = (*Object)(nil)
_ fs.ObjectUnWrapper = (*Object)(nil)
_ fs.IDer = (*Object)(nil)
)