// Upload object to QingStor // +build !plan9 package qingstor import ( "bytes" "crypto/md5" "fmt" "hash" "io" "sort" "sync" "github.com/ncw/rclone/fs" "github.com/pkg/errors" qs "github.com/yunify/qingstor-sdk-go/service" ) const ( // maxSinglePartSize = 1024 * 1024 * 1024 * 5 // The maximum allowed size when uploading a single object to QingStor // maxMultiPartSize = 1024 * 1024 * 1024 * 1 // The maximum allowed part size when uploading a part to QingStor minMultiPartSize = 1024 * 1024 * 4 // The minimum allowed part size when uploading a part to QingStor maxMultiParts = 10000 // The maximum allowed number of parts in an multi-part upload ) const ( defaultUploadPartSize = 1024 * 1024 * 64 // The default part size to buffer chunks of a payload into. defaultUploadConcurrency = 4 // the default number of goroutines to spin up when using multiPartUpload. ) func readFillBuf(r io.Reader, b []byte) (offset int, err error) { for offset < len(b) && err == nil { var n int n, err = r.Read(b[offset:]) offset += n } return offset, err } // uploadInput contains all input for upload requests to QingStor. type uploadInput struct { body io.Reader qsSvc *qs.Service mimeType string zone string bucket string key string partSize int64 concurrency int maxUploadParts int } // uploader internal structure to manage an upload to QingStor. type uploader struct { cfg *uploadInput totalSize int64 // set to -1 if the size is not known readerPos int64 // current reader position readerSize int64 // current reader content size } // newUploader creates a new Uploader instance to upload objects to QingStor. func newUploader(in *uploadInput) *uploader { u := &uploader{ cfg: in, } return u } // bucketInit initiate as bucket controller func (u *uploader) bucketInit() (*qs.Bucket, error) { bucketInit, err := u.cfg.qsSvc.Bucket(u.cfg.bucket, u.cfg.zone) return bucketInit, err } // String converts uploader to a string func (u *uploader) String() string { return fmt.Sprintf("QingStor bucket %s key %s", u.cfg.bucket, u.cfg.key) } // nextReader returns a seekable reader representing the next packet of data. // This operation increases the shared u.readerPos counter, but note that it // does not need to be wrapped in a mutex because nextReader is only called // from the main thread. func (u *uploader) nextReader() (io.ReadSeeker, int, error) { type readerAtSeeker interface { io.ReaderAt io.ReadSeeker } switch r := u.cfg.body.(type) { case readerAtSeeker: var err error n := u.cfg.partSize if u.totalSize >= 0 { bytesLeft := u.totalSize - u.readerPos if bytesLeft <= u.cfg.partSize { err = io.EOF n = bytesLeft } } reader := io.NewSectionReader(r, u.readerPos, n) u.readerPos += n u.readerSize = n return reader, int(n), err default: part := make([]byte, u.cfg.partSize) n, err := readFillBuf(r, part) u.readerPos += int64(n) u.readerSize = int64(n) return bytes.NewReader(part[0:n]), n, err } } // init will initialize all default options. func (u *uploader) init() { if u.cfg.concurrency == 0 { u.cfg.concurrency = defaultUploadConcurrency } if u.cfg.partSize == 0 { u.cfg.partSize = defaultUploadPartSize } if u.cfg.maxUploadParts == 0 { u.cfg.maxUploadParts = maxMultiParts } // Try to get the total size for some optimizations u.totalSize = -1 switch r := u.cfg.body.(type) { case io.Seeker: pos, _ := r.Seek(0, io.SeekCurrent) defer func() { _, _ = r.Seek(pos, io.SeekStart) }() n, err := r.Seek(0, io.SeekEnd) if err != nil { return } u.totalSize = n // Try to adjust partSize if it is too small and account for // integer division truncation. if u.totalSize/u.cfg.partSize >= int64(u.cfg.partSize) { // Add one to the part size to account for remainders // during the size calculation. e.g odd number of bytes. u.cfg.partSize = (u.totalSize / int64(u.cfg.maxUploadParts)) + 1 } } } // singlePartUpload upload a single object that contentLength less than "defaultUploadPartSize" func (u *uploader) singlePartUpload(buf io.ReadSeeker) error { bucketInit, _ := u.bucketInit() req := qs.PutObjectInput{ ContentLength: &u.readerPos, ContentType: &u.cfg.mimeType, Body: buf, } _, err := bucketInit.PutObject(u.cfg.key, &req) if err == nil { fs.Debugf(u, "Upload single objcet finished") } return err } // Upload upload a object into QingStor func (u *uploader) upload() error { u.init() if u.cfg.partSize < minMultiPartSize { return errors.Errorf("part size must be at least %d bytes", minMultiPartSize) } // Do one read to determine if we have more than one part reader, _, err := u.nextReader() if err == io.EOF { // single part fs.Debugf(u, "Uploading as single part object to QingStor") return u.singlePartUpload(reader) } else if err != nil { return errors.Errorf("read upload data failed: %s", err) } fs.Debugf(u, "Uploading as multi-part object to QingStor") mu := multiUploader{uploader: u} return mu.multiPartUpload(reader) } // internal structure to manage a specific multipart upload to QingStor. type multiUploader struct { *uploader wg sync.WaitGroup mtx sync.Mutex err error uploadID *string objectParts completedParts hashMd5 hash.Hash } // keeps track of a single chunk of data being sent to QingStor. type chunk struct { buffer io.ReadSeeker partNumber int size int64 } // completedParts is a wrapper to make parts sortable by their part number, // since QingStor required this list to be sent in sorted order. type completedParts []*qs.ObjectPartType func (a completedParts) Len() int { return len(a) } func (a completedParts) Swap(i, j int) { a[i], a[j] = a[j], a[i] } func (a completedParts) Less(i, j int) bool { return *a[i].PartNumber < *a[j].PartNumber } // String converts multiUploader to a string func (mu *multiUploader) String() string { if uploadID := mu.uploadID; uploadID != nil { return fmt.Sprintf("QingStor bucket %s key %s uploadID %s", mu.cfg.bucket, mu.cfg.key, *uploadID) } return fmt.Sprintf("QingStor bucket %s key %s uploadID ", mu.cfg.bucket, mu.cfg.key) } // getErr is a thread-safe getter for the error object func (mu *multiUploader) getErr() error { mu.mtx.Lock() defer mu.mtx.Unlock() return mu.err } // setErr is a thread-safe setter for the error object func (mu *multiUploader) setErr(e error) { mu.mtx.Lock() defer mu.mtx.Unlock() mu.err = e } // readChunk runs in worker goroutines to pull chunks off of the ch channel // and send() them as UploadPart requests. func (mu *multiUploader) readChunk(ch chan chunk) { defer mu.wg.Done() for { c, ok := <-ch if !ok { break } if mu.getErr() == nil { if err := mu.send(c); err != nil { mu.setErr(err) } } } } // initiate init an Multiple Object and obtain UploadID func (mu *multiUploader) initiate() error { bucketInit, _ := mu.bucketInit() req := qs.InitiateMultipartUploadInput{ ContentType: &mu.cfg.mimeType, } fs.Debugf(mu, "Initiating a multi-part upload") rsp, err := bucketInit.InitiateMultipartUpload(mu.cfg.key, &req) if err == nil { mu.uploadID = rsp.UploadID mu.hashMd5 = md5.New() } return err } // send upload a part into QingStor func (mu *multiUploader) send(c chunk) error { bucketInit, _ := mu.bucketInit() req := qs.UploadMultipartInput{ PartNumber: &c.partNumber, UploadID: mu.uploadID, ContentLength: &c.size, Body: c.buffer, } fs.Debugf(mu, "Uploading a part to QingStor with partNumber %d and partSize %d", c.partNumber, c.size) _, err := bucketInit.UploadMultipart(mu.cfg.key, &req) if err != nil { return err } fs.Debugf(mu, "Done uploading part partNumber %d and partSize %d", c.partNumber, c.size) mu.mtx.Lock() defer mu.mtx.Unlock() _, _ = c.buffer.Seek(0, 0) _, _ = io.Copy(mu.hashMd5, c.buffer) parts := qs.ObjectPartType{PartNumber: &c.partNumber, Size: &c.size} mu.objectParts = append(mu.objectParts, &parts) return err } // list list the ObjectParts of an multipart upload func (mu *multiUploader) list() error { bucketInit, _ := mu.bucketInit() req := qs.ListMultipartInput{ UploadID: mu.uploadID, } fs.Debugf(mu, "Reading multi-part details") rsp, err := bucketInit.ListMultipart(mu.cfg.key, &req) if err == nil { mu.objectParts = rsp.ObjectParts } return err } // complete complete an multipart upload func (mu *multiUploader) complete() error { var err error if err = mu.getErr(); err != nil { return err } bucketInit, _ := mu.bucketInit() //if err = mu.list(); err != nil { // return err //} //md5String := fmt.Sprintf("\"%s\"", hex.EncodeToString(mu.hashMd5.Sum(nil))) md5String := fmt.Sprintf("\"%x\"", mu.hashMd5.Sum(nil)) sort.Sort(mu.objectParts) req := qs.CompleteMultipartUploadInput{ UploadID: mu.uploadID, ObjectParts: mu.objectParts, ETag: &md5String, } fs.Debugf(mu, "Completing multi-part object") _, err = bucketInit.CompleteMultipartUpload(mu.cfg.key, &req) if err == nil { fs.Debugf(mu, "Complete multi-part finished") } return err } // abort abort an multipart upload func (mu *multiUploader) abort() error { var err error bucketInit, _ := mu.bucketInit() if uploadID := mu.uploadID; uploadID != nil { req := qs.AbortMultipartUploadInput{ UploadID: uploadID, } fs.Debugf(mu, "Aborting multi-part object %q", *uploadID) _, err = bucketInit.AbortMultipartUpload(mu.cfg.key, &req) } return err } // multiPartUpload upload a multiple object into QingStor func (mu *multiUploader) multiPartUpload(firstBuf io.ReadSeeker) error { var err error //Initiate an multi-part upload if err = mu.initiate(); err != nil { return err } ch := make(chan chunk, mu.cfg.concurrency) for i := 0; i < mu.cfg.concurrency; i++ { mu.wg.Add(1) go mu.readChunk(ch) } var partNumber int ch <- chunk{partNumber: partNumber, buffer: firstBuf, size: mu.readerSize} for mu.getErr() == nil { partNumber++ // This upload exceeded maximum number of supported parts, error now. if partNumber > mu.cfg.maxUploadParts || partNumber > maxMultiParts { var msg string if partNumber > mu.cfg.maxUploadParts { msg = fmt.Sprintf("exceeded total allowed configured maxUploadParts (%d). "+ "Adjust PartSize to fit in this limit", mu.cfg.maxUploadParts) } else { msg = fmt.Sprintf("exceeded total allowed QingStor limit maxUploadParts (%d). "+ "Adjust PartSize to fit in this limit", maxMultiParts) } mu.setErr(errors.New(msg)) break } var reader io.ReadSeeker var nextChunkLen int reader, nextChunkLen, err = mu.nextReader() if err != nil && err != io.EOF { return err } if nextChunkLen == 0 && partNumber > 0 { // No need to upload empty part, if file was empty to start // with empty single part would of been created and never // started multipart upload. break } num := partNumber ch <- chunk{partNumber: num, buffer: reader, size: mu.readerSize} } // Wait for all goroutines finish close(ch) mu.wg.Wait() // Complete Multipart Upload err = mu.complete() if mu.getErr() != nil || err != nil { _ = mu.abort() } return err }