/* * Minio Cloud Storage, (C) 2016 Minio, Inc. * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ package main import ( "errors" "fmt" "io" slashpath "path" "sync" ) // ReadFile - read file func (xl XL) ReadFile(volume, path string, startOffset int64) (io.ReadCloser, error) { // Input validation. if !isValidVolname(volume) { return nil, errInvalidArgument } if !isValidPath(path) { return nil, errInvalidArgument } // Acquire a read lock. nsMutex.RLock(volume, path) onlineDisks, metadata, heal, err := xl.listOnlineDisks(volume, path) nsMutex.RUnlock(volume, path) if err != nil { return nil, err } if heal { // Heal in background safely, since we already have read // quorum disks. Let the reads continue. go func() { hErr := xl.healFile(volume, path) errorIf(hErr, "Unable to heal file "+volume+"/"+path+".") }() } // Acquire read lock again. nsMutex.RLock(volume, path) readers := make([]io.ReadCloser, len(xl.storageDisks)) for index, disk := range onlineDisks { if disk == nil { continue } erasurePart := slashpath.Join(path, fmt.Sprintf("file.%d", index)) // If disk.ReadFile returns error and we don't have read quorum it will be taken care as // ReedSolomon.Reconstruct() will fail later. var reader io.ReadCloser offset := int64(0) if reader, err = disk.ReadFile(volume, erasurePart, offset); err == nil { readers[index] = reader } } nsMutex.RUnlock(volume, path) // Initialize pipe. pipeReader, pipeWriter := io.Pipe() go func() { var totalLeft = metadata.Stat.Size // Read until the totalLeft. for totalLeft > 0 { // Figure out the right blockSize as it was encoded before. var curBlockSize int64 if metadata.Erasure.BlockSize < totalLeft { curBlockSize = metadata.Erasure.BlockSize } else { curBlockSize = totalLeft } // Calculate the current encoded block size. curEncBlockSize := getEncodedBlockLen(curBlockSize, metadata.Erasure.DataBlocks) enBlocks := make([][]byte, len(xl.storageDisks)) var wg = &sync.WaitGroup{} // Loop through all readers and read. for index, reader := range readers { // Initialize shard slice and fill the data from each parts. enBlocks[index] = make([]byte, curEncBlockSize) if reader == nil { continue } // Parallelize reading. wg.Add(1) go func(index int, reader io.Reader) { defer wg.Done() // Read the necessary blocks. _, rErr := io.ReadFull(reader, enBlocks[index]) if rErr != nil && rErr != io.ErrUnexpectedEOF { readers[index] = nil } }(index, reader) } // Wait for the read routines to finish. wg.Wait() // Check blocks if they are all zero in length. if checkBlockSize(enBlocks) == 0 { pipeWriter.CloseWithError(errDataCorrupt) return } // Verify the blocks. var ok bool ok, err = xl.ReedSolomon.Verify(enBlocks) if err != nil { pipeWriter.CloseWithError(err) return } // Verification failed, blocks require reconstruction. if !ok { for index, reader := range readers { if reader == nil { // Reconstruct expects missing blocks to be nil. enBlocks[index] = nil } } err = xl.ReedSolomon.Reconstruct(enBlocks) if err != nil { pipeWriter.CloseWithError(err) return } // Verify reconstructed blocks again. ok, err = xl.ReedSolomon.Verify(enBlocks) if err != nil { pipeWriter.CloseWithError(err) return } if !ok { // Blocks cannot be reconstructed, corrupted data. err = errors.New("Verification failed after reconstruction, data likely corrupted.") pipeWriter.CloseWithError(err) return } } // Get all the data blocks. dataBlocks := getDataBlocks(enBlocks, metadata.Erasure.DataBlocks, int(curBlockSize)) // Verify if the offset is right for the block, if not move to // the next block. if startOffset > 0 { startOffset = startOffset - int64(len(dataBlocks)) // Start offset is greater than or equal to zero, skip the dataBlocks. if startOffset >= 0 { totalLeft = totalLeft - metadata.Erasure.BlockSize continue } // Now get back the remaining offset if startOffset is negative. startOffset = startOffset + int64(len(dataBlocks)) } // Write safely the necessary blocks. _, err = pipeWriter.Write(dataBlocks[int(startOffset):]) if err != nil { pipeWriter.CloseWithError(err) return } // Reset offset to '0' to read rest of the blocks. startOffset = int64(0) // Save what's left after reading erasureBlockSize. totalLeft = totalLeft - metadata.Erasure.BlockSize } // Cleanly end the pipe after a successful decoding. pipeWriter.Close() // Cleanly close all the underlying data readers. for _, reader := range readers { if reader == nil { continue } reader.Close() } }() // Return the pipe for the top level caller to start reading. return pipeReader, nil }