rclone/backend/mega/mega.go
Nick Craig-Wood 1f255a8567 Add a mega.nz remote #163
Not supported yet:
  * Hash
  * ModTime
  * Server Side Copy

Otherwise fully functional and passing all the tests.
2018-04-18 21:09:54 +01:00

1129 lines
29 KiB
Go

// Package mega provides an interface to the Mega
// object storage system.
package mega
/*
Open questions
* Does mega support a content hash - what exactly are the mega hashes?
* Can mega support setting modification times?
Improvements:
* Uploads could be done in parallel
* Downloads would be more efficient done in one go
* Uploads would be more efficient with bigger chunks
* Looks like mega can support server side copy, but it isn't implemented in go-mega
* Upload can set modtime... - set as int64_t - can set ctime and mtime?
*/
import (
"fmt"
"io"
"path"
"regexp"
"strings"
"sync"
"time"
"github.com/ncw/rclone/fs"
"github.com/ncw/rclone/fs/config/flags"
"github.com/ncw/rclone/fs/config/obscure"
"github.com/ncw/rclone/fs/fshttp"
"github.com/ncw/rclone/fs/hash"
"github.com/ncw/rclone/lib/pacer"
"github.com/ncw/rclone/lib/readers"
"github.com/pkg/errors"
mega "github.com/t3rm1n4l/go-mega"
)
const (
minSleep = 10 * time.Millisecond
maxSleep = 2 * time.Second
decayConstant = 2 // bigger for slower decay, exponential
useTrash = true // FIXME make configurable - rclone global
)
var (
megaDebug = flags.BoolP("mega-debug", "", false, "If set then output more debug from mega.")
megaCacheMu sync.Mutex // mutex for the below
megaCache = map[string]*mega.Mega{} // cache logged in Mega's by user
)
// Register with Fs
func init() {
fs.Register(&fs.RegInfo{
Name: "mega",
Description: "Mega",
NewFs: NewFs,
Options: []fs.Option{{
Name: "user",
Help: "User name",
Optional: true,
}, {
Name: "pass",
Help: "Password.",
Optional: true,
IsPassword: true,
}},
})
}
// Fs represents a remote mega
type Fs struct {
name string // name of this remote
root string // the path we are working on
features *fs.Features // optional features
srv *mega.Mega // the connection to the server
pacer *pacer.Pacer // pacer for API calls
rootNodeMu sync.Mutex // mutex for _rootNode
_rootNode *mega.Node // root node - call findRoot to use this
mkdirMu sync.Mutex // used to serialize calls to mkdir / rmdir
}
// Object describes a mega object
//
// Will definitely have info but maybe not meta
//
// Normally rclone would just store an ID here but go-mega and mega.nz
// expect you to build an entire tree of all the objects in memory.
// In this case we just store a pointer to the object.
type Object struct {
fs *Fs // what this object is part of
remote string // The remote path
info *mega.Node // pointer to the mega node
}
// ------------------------------------------------------------
// 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
}
// String converts this Fs to a string
func (f *Fs) String() string {
return fmt.Sprintf("mega root '%s'", f.root)
}
// Features returns the optional features of this Fs
func (f *Fs) Features() *fs.Features {
return f.features
}
// Pattern to match a mega path
var matcher = regexp.MustCompile(`^([^/]*)(.*)$`)
// parsePath parses an mega 'url'
func parsePath(path string) (root string) {
root = strings.Trim(path, "/")
return
}
// shouldRetry returns a boolean as to whether this err deserves to be
// retried. It returns the err as a convenience
func shouldRetry(err error) (bool, error) {
// Let the mega library handle the low level retries
return false, err
/*
switch errors.Cause(err) {
case mega.EAGAIN, mega.ERATELIMIT, mega.ETEMPUNAVAIL:
return true, err
}
return fserrors.ShouldRetry(err), err
*/
}
// readMetaDataForPath reads the metadata from the path
func (f *Fs) readMetaDataForPath(remote string) (info *mega.Node, err error) {
rootNode, err := f.findRoot(false)
if err != nil {
return nil, err
}
return f.findObject(rootNode, remote)
}
// NewFs constructs an Fs from the path, container:path
func NewFs(name, root string) (fs.Fs, error) {
user := fs.ConfigFileGet(name, "user")
pass := fs.ConfigFileGet(name, "pass")
if pass != "" {
var err error
pass, err = obscure.Reveal(pass)
if err != nil {
return nil, errors.Wrap(err, "couldn't decrypt password")
}
}
// cache *mega.Mega on username so we can re-use and share
// them between remotes. They are expensive to make as they
// contain all the objects and sharing the objects makes the
// move code easier as we don't have to worry about mixing
// them up between different remotes.
megaCacheMu.Lock()
defer megaCacheMu.Unlock()
srv := megaCache[user]
if srv == nil {
srv = mega.New().SetClient(fshttp.NewClient(fs.Config))
srv.SetRetries(fs.Config.LowLevelRetries) // let mega do the low level retries
srv.SetLogger(func(format string, v ...interface{}) {
fs.Infof("*go-mega*", format, v...)
})
if *megaDebug {
srv.SetDebugger(func(format string, v ...interface{}) {
fs.Debugf("*go-mega*", format, v...)
})
}
err := srv.Login(user, pass)
if err != nil {
return nil, errors.Wrap(err, "couldn't login")
}
megaCache[user] = srv
}
root = parsePath(root)
f := &Fs{
name: name,
root: root,
srv: srv,
pacer: pacer.New().SetMinSleep(minSleep).SetMaxSleep(maxSleep).SetDecayConstant(decayConstant),
}
f.features = (&fs.Features{
DuplicateFiles: true,
CanHaveEmptyDirectories: true,
}).Fill(f)
// Find the root node and check if it is a file or not
_, err := f.findRoot(false)
switch err {
case nil:
// root node found and is a directory
case fs.ErrorDirNotFound:
// root node not found, so can't be a file
case fs.ErrorIsFile:
// root node is a file so point to parent directory
root = path.Dir(root)
if root == "." {
root = ""
}
f.root = root
return f, err
}
return f, nil
}
// splitNodePath splits nodePath into / separated parts, returning nil if it
// should refer to the root
func splitNodePath(nodePath string) (parts []string) {
nodePath = path.Clean(nodePath)
parts = strings.Split(nodePath, "/")
if len(parts) == 1 && (parts[0] == "." || parts[0] == "/") {
return nil
}
return parts
}
// findNode looks up the node for the path of the name given from the root given
//
// It returns mega.ENOENT if it wasn't found
func (f *Fs) findNode(rootNode *mega.Node, nodePath string) (*mega.Node, error) {
parts := splitNodePath(nodePath)
if parts == nil {
return rootNode, nil
}
nodes, err := f.srv.FS.PathLookup(rootNode, parts)
if err != nil {
return nil, err
}
return nodes[len(nodes)-1], nil
}
// findDir finds the directory rooted from the node passed in
func (f *Fs) findDir(rootNode *mega.Node, dir string) (node *mega.Node, err error) {
node, err = f.findNode(rootNode, dir)
if err == mega.ENOENT {
return nil, fs.ErrorDirNotFound
} else if err == nil && node.GetType() == mega.FILE {
return nil, fs.ErrorIsFile
}
return node, err
}
// findObject looks up the node for the object of the name given
func (f *Fs) findObject(rootNode *mega.Node, file string) (node *mega.Node, err error) {
node, err = f.findNode(rootNode, file)
if err == mega.ENOENT {
return nil, fs.ErrorObjectNotFound
} else if err == nil && node.GetType() != mega.FILE {
return nil, fs.ErrorNotAFile
}
return node, err
}
// lookupDir looks up the node for the directory of the name given
//
// if create is true it tries to create the root directory if not found
func (f *Fs) lookupDir(dir string) (*mega.Node, error) {
rootNode, err := f.findRoot(false)
if err != nil {
return nil, err
}
return f.findDir(rootNode, dir)
}
// lookupParentDir finds the parent node for the remote passed in
func (f *Fs) lookupParentDir(remote string) (dirNode *mega.Node, leaf string, err error) {
parent, leaf := path.Split(remote)
dirNode, err = f.lookupDir(parent)
return dirNode, leaf, err
}
// mkdir makes the directory and any parent directories for the
// directory of the name given
func (f *Fs) mkdir(rootNode *mega.Node, dir string) (node *mega.Node, err error) {
f.mkdirMu.Lock()
defer f.mkdirMu.Unlock()
parts := splitNodePath(dir)
if parts == nil {
return rootNode, nil
}
var i int
// look up until we find a directory which exists
for i = 0; i <= len(parts); i++ {
var nodes []*mega.Node
nodes, err = f.srv.FS.PathLookup(rootNode, parts[:len(parts)-i])
if err == nil {
if len(nodes) == 0 {
node = rootNode
} else {
node = nodes[len(nodes)-1]
}
break
}
if err != mega.ENOENT {
return nil, errors.Wrap(err, "mkdir lookup failed")
}
}
if err != nil {
return nil, errors.Wrap(err, "internal error: mkdir called with non existent root node")
}
// i is number of directories to create (may be 0)
// node is directory to create them from
for _, name := range parts[len(parts)-i:] {
// create directory called name in node
err = f.pacer.Call(func() (bool, error) {
node, err = f.srv.CreateDir(name, node)
return shouldRetry(err)
})
if err != nil {
return nil, errors.Wrap(err, "mkdir create node failed")
}
}
return node, nil
}
// mkdirParent creates the parent directory of remote
func (f *Fs) mkdirParent(remote string) (dirNode *mega.Node, leaf string, err error) {
rootNode, err := f.findRoot(true)
if err != nil {
return nil, "", err
}
parent, leaf := path.Split(remote)
dirNode, err = f.mkdir(rootNode, parent)
return dirNode, leaf, err
}
// findRoot looks up the root directory node and returns it.
//
// if create is true it tries to create the root directory if not found
func (f *Fs) findRoot(create bool) (*mega.Node, error) {
f.rootNodeMu.Lock()
defer f.rootNodeMu.Unlock()
// Check if we haven't found it already
if f._rootNode != nil {
return f._rootNode, nil
}
// Check for pre-existing root
absRoot := f.srv.FS.GetRoot()
node, err := f.findDir(absRoot, f.root)
//log.Printf("findRoot findDir %p %v", node, err)
if err == nil {
f._rootNode = node
return node, nil
}
if !create || err != fs.ErrorDirNotFound {
return nil, err
}
//..not found so create the root directory
f._rootNode, err = f.mkdir(absRoot, f.root)
return f._rootNode, err
}
// clearRoot unsets the root directory
func (f *Fs) clearRoot() {
f.rootNodeMu.Lock()
f._rootNode = nil
f.rootNodeMu.Unlock()
//log.Printf("cleared root directory")
}
// Return an Object from a path
//
// If it can't be found it returns the error fs.ErrorObjectNotFound.
func (f *Fs) newObjectWithInfo(remote string, info *mega.Node) (fs.Object, error) {
o := &Object{
fs: f,
remote: remote,
}
var err error
if info != nil {
// Set info
err = o.setMetaData(info)
} else {
err = o.readMetaData() // reads info and meta, returning an error
}
if err != nil {
return nil, err
}
return o, nil
}
// NewObject finds the Object at remote. If it can't be found
// it returns the error fs.ErrorObjectNotFound.
func (f *Fs) NewObject(remote string) (fs.Object, error) {
return f.newObjectWithInfo(remote, nil)
}
// list the objects into the function supplied
//
// If directories is set it only sends directories
// User function to process a File item from listAll
//
// Should return true to finish processing
type listFn func(*mega.Node) bool
// Lists the directory required calling the user function on each item found
//
// If the user fn ever returns true then it early exits with found = true
func (f *Fs) list(dir *mega.Node, fn listFn) (found bool, err error) {
nodes, err := f.srv.FS.GetChildren(dir)
if err != nil {
return false, errors.Wrapf(err, "list failed")
}
for _, item := range nodes {
if fn(item) {
found = true
break
}
}
return
}
// 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.
func (f *Fs) List(dir string) (entries fs.DirEntries, err error) {
dirNode, err := f.lookupDir(dir)
if err != nil {
return nil, err
}
var iErr error
_, err = f.list(dirNode, func(info *mega.Node) bool {
remote := path.Join(dir, info.GetName())
switch info.GetType() {
case mega.FOLDER, mega.ROOT, mega.INBOX, mega.TRASH:
d := fs.NewDir(remote, info.GetTimeStamp()).SetID(info.GetHash())
entries = append(entries, d)
case mega.FILE:
o, err := f.newObjectWithInfo(remote, info)
if err != nil {
iErr = err
return true
}
entries = append(entries, o)
}
return false
})
if err != nil {
return nil, err
}
if iErr != nil {
return nil, iErr
}
return entries, nil
}
// Creates from the parameters passed in a half finished Object which
// must have setMetaData called on it
//
// Returns the dirNode, obect, leaf and error
//
// Used to create new objects
func (f *Fs) createObject(remote string, modTime time.Time, size int64) (o *Object, dirNode *mega.Node, leaf string, err error) {
dirNode, leaf, err = f.mkdirParent(remote)
if err != nil {
return nil, nil, leaf, err
}
// Temporary Object under construction
o = &Object{
fs: f,
remote: remote,
}
return o, dirNode, leaf, nil
}
// Put the object
//
// Copy the reader in to the new object which is returned
//
// The new object may have been created if an error is returned
// 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) Put(in io.Reader, src fs.ObjectInfo, options ...fs.OpenOption) (fs.Object, error) {
exisitingObj, err := f.newObjectWithInfo(src.Remote(), nil)
switch err {
case nil:
return exisitingObj, exisitingObj.Update(in, src, options...)
case fs.ErrorObjectNotFound:
// Not found so create it
return f.PutUnchecked(in, src)
default:
return nil, err
}
}
// PutUnchecked the object
//
// Copy the reader in to the new object which is returned
//
// The new object may have been created if an error is returned
// 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(in io.Reader, src fs.ObjectInfo, options ...fs.OpenOption) (fs.Object, error) {
remote := src.Remote()
size := src.Size()
modTime := src.ModTime()
o, _, _, err := f.createObject(remote, modTime, size)
if err != nil {
return nil, err
}
return o, o.Update(in, src, options...)
}
// Mkdir creates the directory if it doesn't exist
func (f *Fs) Mkdir(dir string) error {
rootNode, err := f.findRoot(true)
if err != nil {
return err
}
_, err = f.mkdir(rootNode, dir)
return errors.Wrap(err, "Mkdir failed")
}
// deleteNode removes a file or directory, observing useTrash
func (f *Fs) deleteNode(node *mega.Node) (err error) {
err = f.pacer.Call(func() (bool, error) {
err = f.srv.Delete(node, !useTrash)
return shouldRetry(err)
})
return err
}
// purgeCheck removes the directory dir, if check is set then it
// refuses to do so if it has anything in
func (f *Fs) purgeCheck(dir string, check bool) error {
f.mkdirMu.Lock()
defer f.mkdirMu.Unlock()
rootNode, err := f.findRoot(false)
if err != nil {
return err
}
dirNode, err := f.findDir(rootNode, dir)
if err != nil {
return err
}
if check {
children, err := f.srv.FS.GetChildren(dirNode)
if err != nil {
return errors.Wrap(err, "purgeCheck GetChildren failed")
}
if len(children) > 0 {
return fs.ErrorDirectoryNotEmpty
}
}
err = f.deleteNode(dirNode)
if err != nil {
return errors.Wrap(err, "delete directory node failed")
}
// Remove the root node if we just deleted it
if dirNode == rootNode {
f.clearRoot()
}
time.Sleep(100 * time.Millisecond) // FIXME give the callback a chance
return nil
}
// Rmdir deletes the root folder
//
// Returns an error if it isn't empty
func (f *Fs) Rmdir(dir string) error {
return f.purgeCheck(dir, true)
}
// Precision return the precision of this Fs
func (f *Fs) Precision() time.Duration {
return fs.ModTimeNotSupported
}
// Purge deletes all the files and the container
//
// Optional interface: Only implement this if you have a way of
// deleting all the files quicker than just running Remove() on the
// result of List()
func (f *Fs) Purge() error {
return f.purgeCheck("", false)
}
// move a file or folder (srcFs, srcRemote, info) to (f, dstRemote)
//
// info will be updates
func (f *Fs) move(dstRemote string, srcFs *Fs, srcRemote string, info *mega.Node) (err error) {
var (
dstFs = f
srcDirNode, dstDirNode *mega.Node
srcParent, dstParent string
srcLeaf, dstLeaf string
)
if dstRemote != "" {
// lookup or create the destination parent directory
dstDirNode, dstLeaf, err = dstFs.mkdirParent(dstRemote)
} else {
// find or create the parent of the root directory
absRoot := dstFs.srv.FS.GetRoot()
dstParent, dstLeaf = path.Split(dstFs.root)
dstDirNode, err = dstFs.mkdir(absRoot, dstParent)
}
if err != nil {
return errors.Wrap(err, "server side move failed to make dst parent dir")
}
if srcRemote != "" {
// lookup the existing parent directory
srcDirNode, srcLeaf, err = srcFs.lookupParentDir(srcRemote)
} else {
// lookup the existing root parent
absRoot := srcFs.srv.FS.GetRoot()
srcParent, srcLeaf = path.Split(srcFs.root)
srcDirNode, err = f.findDir(absRoot, srcParent)
}
if err != nil {
return errors.Wrap(err, "server side move failed to lookup src parent dir")
}
// move the object into its new directory if required
if srcDirNode != dstDirNode && srcDirNode.GetHash() != dstDirNode.GetHash() {
//log.Printf("move src %p %q dst %p %q", srcDirNode, srcDirNode.GetName(), dstDirNode, dstDirNode.GetName())
err = f.pacer.Call(func() (bool, error) {
err = f.srv.Move(info, dstDirNode)
return shouldRetry(err)
})
if err != nil {
return errors.Wrap(err, "server side move failed")
}
}
// rename the object if required
if srcLeaf != dstLeaf {
//log.Printf("rename %q to %q", srcLeaf, dstLeaf)
err = f.pacer.Call(func() (bool, error) {
err = f.srv.Rename(info, dstLeaf)
return shouldRetry(err)
})
if err != nil {
return errors.Wrap(err, "server side rename failed")
}
}
time.Sleep(100 * time.Millisecond) // FIXME give events a chance...
return 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(src fs.Object, remote string) (fs.Object, error) {
dstFs := f
//log.Printf("Move %q -> %q", src.Remote(), remote)
srcObj, ok := src.(*Object)
if !ok {
fs.Debugf(src, "Can't move - not same remote type")
return nil, fs.ErrorCantMove
}
// Do the move
err := f.move(remote, srcObj.fs, srcObj.remote, srcObj.info)
if err != nil {
return nil, err
}
// Create a destination object
dstObj := &Object{
fs: dstFs,
remote: remote,
info: srcObj.info,
}
return dstObj, 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(src fs.Fs, srcRemote, dstRemote string) error {
dstFs := f
srcFs, ok := src.(*Fs)
if !ok {
fs.Debugf(srcFs, "Can't move directory - not same remote type")
return fs.ErrorCantDirMove
}
// find the source
info, err := srcFs.lookupDir(srcRemote)
if err != nil {
return err
}
// check the destination doesn't exist
_, err = dstFs.lookupDir(dstRemote)
if err == nil {
return fs.ErrorDirExists
} else if err != fs.ErrorDirNotFound {
return errors.Wrap(err, "DirMove error while checking dest directory")
}
// Do the move
err = f.move(dstRemote, srcFs, srcRemote, info)
if err != nil {
return err
}
// Clear src if it was the root
if srcRemote == "" {
srcFs.clearRoot()
}
return nil
}
// DirCacheFlush an optional interface to flush internal directory cache
func (f *Fs) DirCacheFlush() {
// f.dirCache.ResetRoot()
// FIXME Flush the mega somehow?
}
// Hashes returns the supported hash sets.
func (f *Fs) Hashes() hash.Set {
return hash.Set(hash.None)
}
// PublicLink generates a public link to the remote path (usually readable by anyone)
func (f *Fs) PublicLink(remote string) (link string, err error) {
root, err := f.findRoot(false)
if err != nil {
return "", errors.Wrap(err, "PublicLink failed to find root node")
}
node, err := f.findNode(root, remote)
if err != nil {
return "", errors.Wrap(err, "PublicLink failed to find path")
}
link, err = f.srv.Link(node, true)
if err != nil {
return "", errors.Wrap(err, "PublicLink failed to create link")
}
return link, nil
}
// MergeDirs merges the contents of all the directories passed
// in into the first one and rmdirs the other directories.
func (f *Fs) MergeDirs(dirs []fs.Directory) error {
if len(dirs) < 2 {
return nil
}
// find dst directory
dstDir := dirs[0]
dstDirNode := f.srv.FS.HashLookup(dstDir.ID())
if dstDirNode == nil {
return errors.Errorf("MergeDirs failed to find node for: %v", dstDir)
}
for _, srcDir := range dirs[1:] {
// find src directory
srcDirNode := f.srv.FS.HashLookup(srcDir.ID())
if srcDirNode == nil {
return errors.Errorf("MergeDirs failed to find node for: %v", srcDir)
}
// list the the objects
infos := []*mega.Node{}
_, err := f.list(srcDirNode, func(info *mega.Node) bool {
infos = append(infos, info)
return false
})
if err != nil {
return errors.Wrapf(err, "MergeDirs list failed on %v", srcDir)
}
// move them into place
for _, info := range infos {
fs.Infof(srcDir, "merging %q", info.GetName())
err = f.pacer.Call(func() (bool, error) {
err = f.srv.Move(info, dstDirNode)
return shouldRetry(err)
})
if err != nil {
return errors.Wrapf(err, "MergDirs move failed on %q in %v", info.GetName(), srcDir)
}
}
// rmdir (into trash) the now empty source directory
fs.Infof(srcDir, "removing empty directory")
err = f.deleteNode(srcDirNode)
if err != nil {
return errors.Wrapf(err, "MergDirs move failed to rmdir %q", srcDir)
}
}
return nil
}
// About gets quota information
func (f *Fs) About() (*fs.Usage, error) {
var q mega.QuotaResp
var err error
err = f.pacer.Call(func() (bool, error) {
q, err = f.srv.GetQuota()
return shouldRetry(err)
})
if err != nil {
return nil, errors.Wrap(err, "failed to get Mega Quota")
}
usage := &fs.Usage{
Total: fs.NewUsageValue(int64(q.Mstrg)), // quota of bytes that can be used
Used: fs.NewUsageValue(int64(q.Cstrg)), // bytes in use
Free: fs.NewUsageValue(int64(q.Mstrg - q.Cstrg)), // bytes which can be uploaded before reaching the quota
}
return usage, nil
}
// ------------------------------------------------------------
// Fs returns the parent Fs
func (o *Object) Fs() fs.Info {
return o.fs
}
// 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
}
// Hash returns the hashes of an object
func (o *Object) Hash(t hash.Type) (string, error) {
return "", hash.ErrUnsupported
}
// Size returns the size of an object in bytes
func (o *Object) Size() int64 {
return o.info.GetSize()
}
// setMetaData sets the metadata from info
func (o *Object) setMetaData(info *mega.Node) (err error) {
if info.GetType() != mega.FILE {
return fs.ErrorNotAFile
}
o.info = info
return nil
}
// readMetaData gets the metadata if it hasn't already been fetched
//
// it also sets the info
func (o *Object) readMetaData() (err error) {
if o.info != nil {
return nil
}
info, err := o.fs.readMetaDataForPath(o.remote)
if err != nil {
if err == fs.ErrorDirNotFound {
err = fs.ErrorObjectNotFound
}
return err
}
return o.setMetaData(info)
}
// ModTime returns the modification time of the object
//
//
// It attempts to read the objects mtime and if that isn't present the
// LastModified returned in the http headers
func (o *Object) ModTime() time.Time {
return o.info.GetTimeStamp()
}
// SetModTime sets the modification time of the local fs object
func (o *Object) SetModTime(modTime time.Time) error {
return fs.ErrorCantSetModTime
}
// Storable returns a boolean showing whether this object storable
func (o *Object) Storable() bool {
return true
}
// openObject represents a download in progress
type openObject struct {
mu sync.Mutex
o *Object
d *mega.Download
id int
skip int64
chunk []byte
closed bool
}
// get the next chunk
func (oo *openObject) getChunk() (err error) {
if oo.id >= oo.d.Chunks() {
return io.EOF
}
var chunk []byte
err = oo.o.fs.pacer.Call(func() (bool, error) {
chunk, err = oo.d.DownloadChunk(oo.id)
return shouldRetry(err)
})
if err != nil {
return err
}
oo.id++
oo.chunk = chunk
return nil
}
// Read reads up to len(p) bytes into p.
func (oo *openObject) Read(p []byte) (n int, err error) {
oo.mu.Lock()
defer oo.mu.Unlock()
if oo.closed {
return 0, errors.New("read on closed file")
}
// Skip data at the start if requested
for oo.skip > 0 {
_, size, err := oo.d.ChunkLocation(oo.id)
if err != nil {
return 0, err
}
if oo.skip < int64(size) {
break
}
oo.id++
oo.skip -= int64(size)
}
if len(oo.chunk) == 0 {
err = oo.getChunk()
if err != nil {
return 0, err
}
if oo.skip > 0 {
oo.chunk = oo.chunk[oo.skip:]
oo.skip = 0
}
}
n = copy(p, oo.chunk)
oo.chunk = oo.chunk[n:]
return n, nil
}
// Close closed the file - MAC errors are reported here
func (oo *openObject) Close() (err error) {
oo.mu.Lock()
defer oo.mu.Unlock()
if oo.closed {
return nil
}
err = oo.o.fs.pacer.Call(func() (bool, error) {
err = oo.d.Finish()
return shouldRetry(err)
})
if err != nil {
return errors.Wrap(err, "failed to finish download")
}
oo.closed = true
return nil
}
// Open an object for read
func (o *Object) Open(options ...fs.OpenOption) (in io.ReadCloser, err error) {
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:
if option.Mandatory() {
fs.Logf(o, "Unsupported mandatory option: %v", option)
}
}
}
var d *mega.Download
err = o.fs.pacer.Call(func() (bool, error) {
d, err = o.fs.srv.NewDownload(o.info)
return shouldRetry(err)
})
if err != nil {
return nil, errors.Wrap(err, "open download file failed")
}
oo := &openObject{
o: o,
d: d,
skip: offset,
}
return readers.NewLimitedReadCloser(oo, limit), nil
}
// Update the object with the contents of the io.Reader, modTime and size
//
// If existing is set then it updates the object rather than creating a new one
//
// The new object may have been created if an error is returned
func (o *Object) Update(in io.Reader, src fs.ObjectInfo, options ...fs.OpenOption) (err error) {
size := src.Size()
//modTime := src.ModTime()
remote := o.Remote()
// Create the parent directory
dirNode, leaf, err := o.fs.mkdirParent(remote)
if err != nil {
return errors.Wrap(err, "update make parent dir failed")
}
var u *mega.Upload
err = o.fs.pacer.Call(func() (bool, error) {
u, err = o.fs.srv.NewUpload(dirNode, leaf, size)
return shouldRetry(err)
})
if err != nil {
return errors.Wrap(err, "upload file failed to create session")
}
// Upload the chunks
// FIXME do this in parallel
for id := 0; id < u.Chunks(); id++ {
_, chunkSize, err := u.ChunkLocation(id)
if err != nil {
return errors.Wrap(err, "upload failed to read chunk location")
}
chunk := make([]byte, chunkSize)
_, err = io.ReadFull(in, chunk)
if err != nil {
return errors.Wrap(err, "upload failed to read data")
}
err = o.fs.pacer.Call(func() (bool, error) {
err = u.UploadChunk(id, chunk)
return shouldRetry(err)
})
if err != nil {
return errors.Wrap(err, "upload file failed to upload chunk")
}
}
// Finish the upload
var info *mega.Node
err = o.fs.pacer.Call(func() (bool, error) {
info, err = u.Finish()
return shouldRetry(err)
})
if err != nil {
return errors.Wrap(err, "failed to finish upload")
}
// If the upload succeded and the original object existed, then delete it
if o.info != nil {
err = o.fs.deleteNode(o.info)
if err != nil {
return errors.Wrap(err, "upload failed to remove old version")
}
o.info = nil
}
return o.setMetaData(info)
}
// Remove an object
func (o *Object) Remove() error {
err := o.fs.deleteNode(o.info)
if err != nil {
return errors.Wrap(err, "Remove object failed")
}
return nil
}
// Check the interfaces are satisfied
var (
_ fs.Fs = (*Fs)(nil)
_ fs.Purger = (*Fs)(nil)
_ fs.Mover = (*Fs)(nil)
_ fs.PutUncheckeder = (*Fs)(nil)
_ fs.DirMover = (*Fs)(nil)
_ fs.DirCacheFlusher = (*Fs)(nil)
_ fs.PublicLinker = (*Fs)(nil)
_ fs.MergeDirser = (*Fs)(nil)
_ fs.Abouter = (*Fs)(nil)
_ fs.Object = (*Object)(nil)
)