package lsm2 import ( "encoding/binary" "errors" "fmt" "hash/fnv" "io" "iter" ) // [Sour.is|size] [size|hash][data][hash|flag|size]... [prev|count|flag|size] // Commit1: [magic>| end = seek to end of file // <---|-------------+ size = seek to magic header // <---|-------------+10 size + 10 = seek to start of file // <-----------------------------T+10----------------> 10 + size + trailer = full file size // Commit2: [magic>| // +--------|-------------------------------------------------------------------------> // <-------------------------------------|----------------+ // prev = seek to last commit <---|-+ // prev + trailer = size of commit <----T+---------------------------------> // Block: [hash>| end = seek to end of block // <---|-+ size = seek to end of header // <-------------------|-+10 size + 10 = seek to start of block // <---------------------T+10---------------> size + 10 + trailer = full block size const ( TypeUnknown uint64 = iota TypeSegment TypeCommit TypePrevCommit headerSize = 10 maxCommitSize = 4 * binary.MaxVarintLen64 minCommitSize = 3 maxBlockSize = 2 * binary.MaxVarintLen64 minBlockSize = 2 ) var ( Magic = [10]byte([]byte("Sour.is\x00\x00\x00")) Version = uint8(1) hash = fnv.New64a ErrDecode = errors.New("decode") ) type header struct { end uint64 extra []byte } // UnmarshalBinary implements encoding.BinaryUnmarshaler. // It decodes the input binary data into the header struct. // The function expects the input data to be of a specific size (headerSize), // otherwise it returns an error indicating bad data. // It reads the 'end' field from the binary data, updates the 'extra' field, // and reverses the byte order of 'extra' in place. func (h *header) UnmarshalBinary(data []byte) error { if len(data) != headerSize { return fmt.Errorf("%w: bad data", ErrDecode) } h.extra = make([]byte, headerSize) copy(h.extra, data) var bytesRead int h.end, bytesRead = binary.Uvarint(h.extra) reverse(h.extra) h.extra = h.extra[:headerSize-bytesRead] return nil } type Commit struct { flag uint64 // flag values size uint64 // size of the trailer count uint64 // number of entries prev uint64 // previous commit tsize int } // Append marshals the trailer into binary form and appends it to data. // It returns the new slice. func (h *Commit) AppendTrailer(data []byte) []byte { h.flag |= TypeCommit // if h.prev > 0 { // h.flag |= TypePrevCommit // } size := len(data) data = binary.AppendUvarint(data, h.size) data = binary.AppendUvarint(data, h.flag) data = binary.AppendUvarint(data, h.count) // if h.prev > 0 { // data = binary.AppendUvarint(data, h.prev) // } reverse(data[size:]) return data } // UnmarshalBinary implements encoding.BinaryUnmarshaler. // It reads a trailer from binary data, and sets the fields // of the receiver to the values found in the header. func (h *Commit) UnmarshalBinary(data []byte) error { if len(data) < minCommitSize { return fmt.Errorf("%w: bad data", ErrDecode) } var n int h.size, n = binary.Uvarint(data) data = data[n:] h.tsize += n h.flag, n = binary.Uvarint(data) data = data[n:] h.tsize += n h.count, n = binary.Uvarint(data) data = data[n:] h.tsize += n // h.prev = h.size if h.flag&TypePrevCommit == TypePrevCommit { h.prev, n = binary.Uvarint(data) h.tsize += n } return nil } type Block struct { header size uint64 flag uint64 tsize int } func (h *Block) AppendHeader(data []byte) []byte { size := len(data) data = append(data, make([]byte, 10)...) copy(data, h.extra) if h.size == 0 { return data } hdata := binary.AppendUvarint(make([]byte, 0, 10), h.end) reverse(hdata) copy(data[size+10-len(hdata):], hdata) return data } // AppendTrailer marshals the footer into binary form and appends it to data. // It returns the new slice. func (h *Block) AppendTrailer(data []byte) []byte { size := len(data) h.flag |= TypeSegment data = binary.AppendUvarint(data, h.size) data = binary.AppendUvarint(data, h.flag) reverse(data[size:]) return data } // UnmarshalBinary implements encoding.BinaryUnmarshaler. // It reads a footer from binary data, and sets the fields // of the receiver to the values found in the footer. func (h *Block) UnmarshalBinary(data []byte) error { if len(data) < minBlockSize { return fmt.Errorf("%w: bad data", ErrDecode) } var n int h.size, n = binary.Uvarint(data) data = data[n:] h.tsize += n h.flag, n = binary.Uvarint(data) data = data[n:] h.tsize += n copy(h.extra, data[:8]) return nil } type logFile struct { header Commit } func (h *logFile) AppendMagic(data []byte) []byte { size := len(data) data = append(data, Magic[:]...) if h.end == 0 { return data } hdata := binary.AppendUvarint(make([]byte, 0, 10), h.end) reverse(hdata) copy(data[size+10-len(hdata):], hdata) return data } // WriteLogFile writes a log file to w, given a list of segments. // The caller is responsible for calling WriteAt on the correct offset. // The function will return an error if any of the segments fail to write. // The offset is the initial offset of the first segment, and will be // incremented by the length of the segment on each write. // // The log file is written with the following format: // - A header with the magic, version, and flag (Dirty) // - A series of segments, each with: // - A footer with the length and hash of the segment // - The contents of the segment // - A header with the magic, version, flag (Clean), and end offset func WriteLogFile(w io.WriterAt, segments iter.Seq[io.Reader]) error { _, err := w.WriteAt(Magic[:], 0) if err != nil { return err } lf := &LogWriter{ WriterAt: w, } return lf.writeIter(segments) } type rw interface { io.ReaderAt io.WriterAt } func AppendLogFile(rw rw, segments iter.Seq[io.Reader]) error { logFile, err := ReadLogFile(rw) if err != nil { return err } lf := &LogWriter{ WriterAt: rw, logFile: logFile.logFile, } return lf.writeIter( segments) } func (lf *LogWriter) writeIter(segments iter.Seq[io.Reader]) error { lf.size = 0 for s := range segments { n, err := lf.writeBlock(s) if err != nil { return err } lf.end += n lf.size += n lf.count++ } // Write the footer to the log file. // The footer is written at the current end of file position. n, err := lf.WriteAt(lf.AppendTrailer(make([]byte, 0, maxCommitSize)), int64(lf.end)+10) if err != nil { // If there is an error, return it. return err } lf.end += uint64(n) _, err = lf.WriteAt(lf.AppendMagic(make([]byte, 0, 10)), 0) return err } type LogWriter struct { logFile io.WriterAt } // writeBlock writes a segment to the log file at the current end of file position. // The segment is written in chunks of 1024 bytes, and the hash of the segment func (lf *LogWriter) writeBlock(segment io.Reader) (uint64, error) { h := hash() block := Block{} start := int64(lf.end) + 10 end := start bytesWritten := 0 // Write the header to the log file. // The footer is written at the current end of file position. n, err := lf.WriteAt(make([]byte, headerSize), start) bytesWritten += n end += int64(n) if err != nil { // If there is an error, return it. return uint64(bytesWritten), err } // Write the segment to the log file. // The segment is written in chunks of 1024 bytes. for { // Read a chunk of the segment. buf := make([]byte, 1024) n, err := segment.Read(buf) if err != nil { // If the segment is empty, break the loop. if err == io.EOF { break } // If there is an error, return it. return uint64(bytesWritten), err } // Compute the hash of the chunk. h.Write(buf[:n]) // Write the chunk to the log file. // The chunk is written at the current end of file position. n, err = lf.WriteAt(buf[:n], end) bytesWritten += n if err != nil { // If there is an error, return it. return uint64(bytesWritten), err } // Update the length of the segment. end += int64(n) block.size += uint64(n) } block.extra = h.Sum(nil) block.end += block.size // Write the footer to the log file. // The footer is written at the current end of file position. n, err = lf.WriteAt(block.AppendTrailer(make([]byte, 0, maxBlockSize)), end) bytesWritten += n if err != nil { // If there is an error, return it. return uint64(bytesWritten), err } end += int64(n) block.end += uint64(n) // Update header to the log file. // The footer is written at the current end of file position. _, err = lf.WriteAt(block.AppendHeader(make([]byte, 0, headerSize)), start) if err != nil { // If there is an error, return it. return uint64(bytesWritten), err } return uint64(bytesWritten), nil } // reverse reverses a slice in-place. func reverse[T any](b []T) { l := len(b) for i := 0; i < l/2; i++ { b[i], b[l-i-1] = b[l-i-1], b[i] } } type LogReader struct { logFile io.ReaderAt Err error } // ReadLogFile reads a log file from the given io.ReaderAt. It returns a pointer to a LogFile, or an error if the file // could not be read. func ReadLogFile(reader io.ReaderAt) (*LogReader, error) { header := make([]byte, headerSize) n, err := rsr(reader, 0, 10).ReadAt(header, 0) if err != nil { return nil, err } header = header[:n] logFile := &LogReader{ReaderAt: reader} err = logFile.header.UnmarshalBinary(header) if err != nil { return nil, err } if logFile.end == 0 { return logFile, nil } commit := make([]byte, maxCommitSize) n, err = rsr(reader, 10, int64(logFile.end)).ReadAt(commit, 0) if n == 0 && err != nil { return nil, err } commit = commit[:n] err = logFile.Commit.UnmarshalBinary(commit) return logFile, err } // Iterate reads the log file and calls the given function for each segment. // It passes an io.Reader that reads from the current segment. It will stop // calling the function if the function returns false. func (lf *LogReader) Iter() iter.Seq2[uint64, io.Reader] { var commits []*Commit for commit := range lf.iterCommits() { commits = append(commits, &commit) } if lf.Err != nil { return func(yield func(uint64, io.Reader) bool) {} } reverse(commits) return func(yield func(uint64, io.Reader) bool) { start := int64(10) var adj uint64 for _, commit := range commits { size := int64(commit.size) it := iterBlocks(io.NewSectionReader(lf, start, size), size) for i, block := range it { if !yield(adj+i, block) { return } } start += size + int64(commit.tsize) adj = commit.count } } } func iterBlocks(r io.ReaderAt, end int64) iter.Seq2[uint64, io.Reader] { var start int64 var i uint64 return func(yield func(uint64, io.Reader) bool) { buf := make([]byte, maxBlockSize) for start < end { block := &Block{} buf = buf[:10] n, err := rsr(r, int64(start), 10).ReadAt(buf, 0) if n == 0 && err != nil { return } start += int64(n) if err := block.header.UnmarshalBinary(buf); err != nil { return } buf = buf[:maxBlockSize] n, err = rsr(r, int64(start), int64(block.end)).ReadAt(buf, 0) if n == 0 && err != nil { return } buf = buf[:n] err = block.UnmarshalBinary(buf) if err != nil { return } if !yield(i, io.NewSectionReader(r, int64(start), int64(block.size))) { return } i++ start += int64(block.end) } } } func (lf *LogReader) iterCommits() iter.Seq[Commit] { if lf.end == 0 { return func(yield func(Commit) bool) {} } offset := lf.end - lf.size - uint64(lf.tsize) return func(yield func(Commit) bool) { if !yield(lf.Commit) { return } for offset > 10 { commit := Commit{} buf := make([]byte, maxCommitSize) n, err := rsr(lf, 10, int64(offset)).ReadAt(buf, 0) if n == 0 && err != nil { lf.Err = err return } buf = buf[:n] err = commit.UnmarshalBinary(buf) if err != nil { lf.Err = err return } if !yield(commit) { return } offset -= commit.size + uint64(commit.tsize) } } } func (lf *LogReader) Rev() iter.Seq2[uint64, io.Reader] { end := lf.end + 10 i := lf.count return func(yield func(uint64, io.Reader) bool) { for commit := range lf.iterCommits() { end -= uint64(commit.tsize) start := end - commit.size for start < end { block := &Block{} buf := make([]byte, maxBlockSize) n, err := rsr(lf, int64(start), int64(commit.size)).ReadAt(buf, 0) if n == 0 && err != nil { lf.Err = err return } buf = buf[:n] err = block.UnmarshalBinary(buf) if err != nil { lf.Err = err return } if !yield(i-1, io.NewSectionReader(lf, int64(end-block.size)-int64(block.tsize), int64(block.size))) { return } end -= block.size + 10 + uint64(block.tsize) i-- } } } } func rsr(r io.ReaderAt, offset, size int64) *revSegmentReader { r = io.NewSectionReader(r, offset, size) return &revSegmentReader{r, size} } type revSegmentReader struct { io.ReaderAt size int64 } func (r *revSegmentReader) ReadAt(data []byte, offset int64) (int, error) { if offset < 0 { return 0, errors.New("negative offset") } if offset > int64(r.size) { return 0, io.EOF } o := r.size - int64(len(data)) - offset d := int64(len(data)) if o < 0 { d = max(0, d+o) } i, err := r.ReaderAt.ReadAt(data[:d], max(0, o)) reverse(data[:i]) return i, err }