/** * Reed-Solomon Coding over 8-bit values. * * Copyright 2015, Klaus Post * Copyright 2015, Backblaze, Inc. */ package reedsolomon import ( "bytes" "errors" "fmt" "io" "sync" ) // StreamEncoder is an interface to encode Reed-Salomon parity sets for your data. // It provides a fully streaming interface, and processes data in blocks of up to 4MB. // // For small shard sizes, 10MB and below, it is recommended to use the in-memory interface, // since the streaming interface has a start up overhead. // // For all operations, no readers and writers should not assume any order/size of // individual reads/writes. // // For usage examples, see "stream-encoder.go" and "streamdecoder.go" in the examples // folder. type StreamEncoder interface { // Encode parity shards for a set of data shards. // // Input is 'shards' containing readers for data shards followed by parity shards // io.Writer. // // The number of shards must match the number given to NewStream(). // // Each reader must supply the same number of bytes. // // The parity shards will be written to the writer. // The number of bytes written will match the input size. // // If a data stream returns an error, a StreamReadError type error // will be returned. If a parity writer returns an error, a // StreamWriteError will be returned. Encode(data []io.Reader, parity []io.Writer) error // Verify returns true if the parity shards contain correct data. // // The number of shards must match the number total data+parity shards // given to NewStream(). // // Each reader must supply the same number of bytes. // If a shard stream returns an error, a StreamReadError type error // will be returned. Verify(shards []io.Reader) (bool, error) // Reconstruct will recreate the missing shards if possible. // // Given a list of valid shards (to read) and invalid shards (to write) // // You indicate that a shard is missing by setting it to nil in the 'valid' // slice and at the same time setting a non-nil writer in "fill". // An index cannot contain both non-nil 'valid' and 'fill' entry. // If both are provided 'ErrReconstructMismatch' is returned. // // If there are too few shards to reconstruct the missing // ones, ErrTooFewShards will be returned. // // The reconstructed shard set is complete, but integrity is not verified. // Use the Verify function to check if data set is ok. Reconstruct(valid []io.Reader, fill []io.Writer) error // Split a an input stream into the number of shards given to the encoder. // // The data will be split into equally sized shards. // If the data size isn't dividable by the number of shards, // the last shard will contain extra zeros. // // You must supply the total size of your input. // 'ErrShortData' will be returned if it is unable to retrieve the // number of bytes indicated. Split(data io.Reader, dst []io.Writer, size int64) (err error) // Join the shards and write the data segment to dst. // // Only the data shards are considered. // // You must supply the exact output size you want. // If there are to few shards given, ErrTooFewShards will be returned. // If the total data size is less than outSize, ErrShortData will be returned. Join(dst io.Writer, shards []io.Reader, outSize int64) error } // StreamReadError is returned when a read error is encountered // that relates to a supplied stream. // This will allow you to find out which reader has failed. type StreamReadError struct { Err error // The error Stream int // The stream number on which the error occurred } // Error returns the error as a string func (s StreamReadError) Error() string { return fmt.Sprintf("error reading stream %d: %s", s.Stream, s.Err) } // String returns the error as a string func (s StreamReadError) String() string { return s.Error() } // StreamWriteError is returned when a write error is encountered // that relates to a supplied stream. This will allow you to // find out which reader has failed. type StreamWriteError struct { Err error // The error Stream int // The stream number on which the error occurred } // Error returns the error as a string func (s StreamWriteError) Error() string { return fmt.Sprintf("error writing stream %d: %s", s.Stream, s.Err) } // String returns the error as a string func (s StreamWriteError) String() string { return s.Error() } // rsStream contains a matrix for a specific // distribution of datashards and parity shards. // Construct if using NewStream() type rsStream struct { r *reedSolomon bs int // Block size // Shard reader readShards func(dst [][]byte, in []io.Reader) error // Shard writer writeShards func(out []io.Writer, in [][]byte) error } // NewStream creates a new encoder and initializes it to // the number of data shards and parity shards that // you want to use. You can reuse this encoder. // Note that the maximum number of data shards is 256. func NewStream(dataShards, parityShards int, o ...Option) (StreamEncoder, error) { enc, err := New(dataShards, parityShards, o...) if err != nil { return nil, err } rs := enc.(*reedSolomon) r := rsStream{r: rs, bs: 4 << 20} r.readShards = readShards r.writeShards = writeShards return &r, err } // NewStreamC creates a new encoder and initializes it to // the number of data shards and parity shards given. // // This functions as 'NewStream', but allows you to enable CONCURRENT reads and writes. func NewStreamC(dataShards, parityShards int, conReads, conWrites bool, o ...Option) (StreamEncoder, error) { enc, err := New(dataShards, parityShards, o...) if err != nil { return nil, err } rs := enc.(*reedSolomon) r := rsStream{r: rs, bs: 4 << 20} r.readShards = readShards r.writeShards = writeShards if conReads { r.readShards = cReadShards } if conWrites { r.writeShards = cWriteShards } return &r, err } func createSlice(n, length int) [][]byte { out := make([][]byte, n) for i := range out { out[i] = make([]byte, length) } return out } // Encodes parity shards for a set of data shards. // // Input is 'shards' containing readers for data shards followed by parity shards // io.Writer. // // The number of shards must match the number given to NewStream(). // // Each reader must supply the same number of bytes. // // The parity shards will be written to the writer. // The number of bytes written will match the input size. // // If a data stream returns an error, a StreamReadError type error // will be returned. If a parity writer returns an error, a // StreamWriteError will be returned. func (r rsStream) Encode(data []io.Reader, parity []io.Writer) error { if len(data) != r.r.DataShards { return ErrTooFewShards } if len(parity) != r.r.ParityShards { return ErrTooFewShards } all := createSlice(r.r.Shards, r.bs) in := all[:r.r.DataShards] out := all[r.r.DataShards:] read := 0 for { err := r.readShards(in, data) switch err { case nil: case io.EOF: if read == 0 { return ErrShardNoData } return nil default: return err } out = trimShards(out, shardSize(in)) read += shardSize(in) err = r.r.Encode(all) if err != nil { return err } err = r.writeShards(parity, out) if err != nil { return err } } } // Trim the shards so they are all the same size func trimShards(in [][]byte, size int) [][]byte { for i := range in { if in[i] != nil { in[i] = in[i][0:size] } if len(in[i]) < size { in[i] = nil } } return in } func readShards(dst [][]byte, in []io.Reader) error { if len(in) != len(dst) { panic("internal error: in and dst size do not match") } size := -1 for i := range in { if in[i] == nil { dst[i] = nil continue } n, err := io.ReadFull(in[i], dst[i]) // The error is EOF only if no bytes were read. // If an EOF happens after reading some but not all the bytes, // ReadFull returns ErrUnexpectedEOF. switch err { case io.ErrUnexpectedEOF, io.EOF: if size < 0 { size = n } else if n != size { // Shard sizes must match. return ErrShardSize } dst[i] = dst[i][0:n] case nil: continue default: return StreamReadError{Err: err, Stream: i} } } if size == 0 { return io.EOF } return nil } func writeShards(out []io.Writer, in [][]byte) error { if len(out) != len(in) { panic("internal error: in and out size do not match") } for i := range in { if out[i] == nil { continue } n, err := out[i].Write(in[i]) if err != nil { return StreamWriteError{Err: err, Stream: i} } // if n != len(in[i]) { return StreamWriteError{Err: io.ErrShortWrite, Stream: i} } } return nil } type readResult struct { n int size int err error } // cReadShards reads shards concurrently func cReadShards(dst [][]byte, in []io.Reader) error { if len(in) != len(dst) { panic("internal error: in and dst size do not match") } var wg sync.WaitGroup wg.Add(len(in)) res := make(chan readResult, len(in)) for i := range in { if in[i] == nil { dst[i] = nil wg.Done() continue } go func(i int) { defer wg.Done() n, err := io.ReadFull(in[i], dst[i]) // The error is EOF only if no bytes were read. // If an EOF happens after reading some but not all the bytes, // ReadFull returns ErrUnexpectedEOF. res <- readResult{size: n, err: err, n: i} }(i) } wg.Wait() close(res) size := -1 for r := range res { switch r.err { case io.ErrUnexpectedEOF, io.EOF: if size < 0 { size = r.size } else if r.size != size { // Shard sizes must match. return ErrShardSize } dst[r.n] = dst[r.n][0:r.size] case nil: default: return StreamReadError{Err: r.err, Stream: r.n} } } if size == 0 { return io.EOF } return nil } // cWriteShards writes shards concurrently func cWriteShards(out []io.Writer, in [][]byte) error { if len(out) != len(in) { panic("internal error: in and out size do not match") } var errs = make(chan error, len(out)) var wg sync.WaitGroup wg.Add(len(out)) for i := range in { go func(i int) { defer wg.Done() if out[i] == nil { errs <- nil return } n, err := out[i].Write(in[i]) if err != nil { errs <- StreamWriteError{Err: err, Stream: i} return } if n != len(in[i]) { errs <- StreamWriteError{Err: io.ErrShortWrite, Stream: i} } }(i) } wg.Wait() close(errs) for err := range errs { if err != nil { return err } } return nil } // Verify returns true if the parity shards contain correct data. // // The number of shards must match the number total data+parity shards // given to NewStream(). // // Each reader must supply the same number of bytes. // If a shard stream returns an error, a StreamReadError type error // will be returned. func (r rsStream) Verify(shards []io.Reader) (bool, error) { if len(shards) != r.r.Shards { return false, ErrTooFewShards } read := 0 all := createSlice(r.r.Shards, r.bs) for { err := r.readShards(all, shards) if err == io.EOF { if read == 0 { return false, ErrShardNoData } return true, nil } if err != nil { return false, err } read += shardSize(all) ok, err := r.r.Verify(all) if !ok || err != nil { return ok, err } } } // ErrReconstructMismatch is returned by the StreamEncoder, if you supply // "valid" and "fill" streams on the same index. // Therefore it is impossible to see if you consider the shard valid // or would like to have it reconstructed. var ErrReconstructMismatch = errors.New("valid shards and fill shards are mutually exclusive") // Reconstruct will recreate the missing shards if possible. // // Given a list of valid shards (to read) and invalid shards (to write) // // You indicate that a shard is missing by setting it to nil in the 'valid' // slice and at the same time setting a non-nil writer in "fill". // An index cannot contain both non-nil 'valid' and 'fill' entry. // // If there are too few shards to reconstruct the missing // ones, ErrTooFewShards will be returned. // // The reconstructed shard set is complete when explicitly asked for all missing shards. // However its integrity is not automatically verified. // Use the Verify function to check in case the data set is complete. func (r rsStream) Reconstruct(valid []io.Reader, fill []io.Writer) error { if len(valid) != r.r.Shards { return ErrTooFewShards } if len(fill) != r.r.Shards { return ErrTooFewShards } all := createSlice(r.r.Shards, r.bs) reconDataOnly := true for i := range valid { if valid[i] != nil && fill[i] != nil { return ErrReconstructMismatch } if i >= r.r.DataShards && fill[i] != nil { reconDataOnly = false } } read := 0 for { err := r.readShards(all, valid) if err == io.EOF { if read == 0 { return ErrShardNoData } return nil } if err != nil { return err } read += shardSize(all) all = trimShards(all, shardSize(all)) if reconDataOnly { err = r.r.ReconstructData(all) // just reconstruct missing data shards } else { err = r.r.Reconstruct(all) // reconstruct all missing shards } if err != nil { return err } err = r.writeShards(fill, all) if err != nil { return err } } } // Join the shards and write the data segment to dst. // // Only the data shards are considered. // // You must supply the exact output size you want. // If there are to few shards given, ErrTooFewShards will be returned. // If the total data size is less than outSize, ErrShortData will be returned. func (r rsStream) Join(dst io.Writer, shards []io.Reader, outSize int64) error { // Do we have enough shards? if len(shards) < r.r.DataShards { return ErrTooFewShards } // Trim off parity shards if any shards = shards[:r.r.DataShards] for i := range shards { if shards[i] == nil { return StreamReadError{Err: ErrShardNoData, Stream: i} } } // Join all shards src := io.MultiReader(shards...) // Copy data to dst n, err := io.CopyN(dst, src, outSize) if err == io.EOF { return ErrShortData } if err != nil { return err } if n != outSize { return ErrShortData } return nil } // Split a an input stream into the number of shards given to the encoder. // // The data will be split into equally sized shards. // If the data size isn't dividable by the number of shards, // the last shard will contain extra zeros. // // You must supply the total size of your input. // 'ErrShortData' will be returned if it is unable to retrieve the // number of bytes indicated. func (r rsStream) Split(data io.Reader, dst []io.Writer, size int64) error { if size == 0 { return ErrShortData } if len(dst) != r.r.DataShards { return ErrInvShardNum } for i := range dst { if dst[i] == nil { return StreamWriteError{Err: ErrShardNoData, Stream: i} } } // Calculate number of bytes per shard. perShard := (size + int64(r.r.DataShards) - 1) / int64(r.r.DataShards) // Pad data to r.Shards*perShard. padding := make([]byte, (int64(r.r.Shards)*perShard)-size) data = io.MultiReader(data, bytes.NewBuffer(padding)) // Split into equal-length shards and copy. for i := range dst { n, err := io.CopyN(dst[i], data, perShard) if err != io.EOF && err != nil { return err } if n != perShard { return ErrShortData } } return nil }