minio/vendor/github.com/pierrec/lz4/writer.go
Bala FA b0deea27df Refactor s3select to support parquet. (#7023)
Also handle pretty formatted JSON documents.
2019-01-08 16:53:04 -08:00

268 lines
6.3 KiB
Go

package lz4
import (
"encoding/binary"
"fmt"
"io"
"github.com/pierrec/lz4/internal/xxh32"
)
// Writer implements the LZ4 frame encoder.
type Writer struct {
Header
buf [19]byte // magic number(4) + header(flags(2)+[Size(8)+DictID(4)]+checksum(1)) does not exceed 19 bytes
dst io.Writer // Destination.
checksum xxh32.XXHZero // Frame checksum.
zdata []byte // Compressed data.
data []byte // Data to be compressed.
idx int // Index into data.
hashtable [winSize]int // Hash table used in CompressBlock().
}
// NewWriter returns a new LZ4 frame encoder.
// No access to the underlying io.Writer is performed.
// The supplied Header is checked at the first Write.
// It is ok to change it before the first Write but then not until a Reset() is performed.
func NewWriter(dst io.Writer) *Writer {
return &Writer{dst: dst}
}
// writeHeader builds and writes the header (magic+header) to the underlying io.Writer.
func (z *Writer) writeHeader() error {
// Default to 4Mb if BlockMaxSize is not set.
if z.Header.BlockMaxSize == 0 {
z.Header.BlockMaxSize = bsMapID[7]
}
// The only option that needs to be validated.
bSize := z.Header.BlockMaxSize
bSizeID, ok := bsMapValue[bSize]
if !ok {
return fmt.Errorf("lz4: invalid block max size: %d", bSize)
}
// Allocate the compressed/uncompressed buffers.
// The compressed buffer cannot exceed the uncompressed one.
if n := 2 * bSize; cap(z.zdata) < n {
z.zdata = make([]byte, n, n)
}
z.zdata = z.zdata[:bSize]
z.data = z.zdata[:cap(z.zdata)][bSize:]
z.idx = 0
// Size is optional.
buf := z.buf[:]
// Set the fixed size data: magic number, block max size and flags.
binary.LittleEndian.PutUint32(buf[0:], frameMagic)
flg := byte(Version << 6)
flg |= 1 << 5 // No block dependency.
if z.Header.BlockChecksum {
flg |= 1 << 4
}
if z.Header.Size > 0 {
flg |= 1 << 3
}
if !z.Header.NoChecksum {
flg |= 1 << 2
}
buf[4] = flg
buf[5] = bSizeID << 4
// Current buffer size: magic(4) + flags(1) + block max size (1).
n := 6
// Optional items.
if z.Header.Size > 0 {
binary.LittleEndian.PutUint64(buf[n:], z.Header.Size)
n += 8
}
// The header checksum includes the flags, block max size and optional Size.
buf[n] = byte(xxh32.ChecksumZero(buf[4:n]) >> 8 & 0xFF)
z.checksum.Reset()
// Header ready, write it out.
if _, err := z.dst.Write(buf[0 : n+1]); err != nil {
return err
}
z.Header.done = true
if debugFlag {
debug("wrote header %v", z.Header)
}
return nil
}
// Write compresses data from the supplied buffer into the underlying io.Writer.
// Write does not return until the data has been written.
func (z *Writer) Write(buf []byte) (int, error) {
if !z.Header.done {
if err := z.writeHeader(); err != nil {
return 0, err
}
}
if debugFlag {
debug("input buffer len=%d index=%d", len(buf), z.idx)
}
zn := len(z.data)
var n int
for len(buf) > 0 {
if z.idx == 0 && len(buf) >= zn {
// Avoid a copy as there is enough data for a block.
if err := z.compressBlock(buf[:zn]); err != nil {
return n, err
}
n += zn
buf = buf[zn:]
continue
}
// Accumulate the data to be compressed.
m := copy(z.data[z.idx:], buf)
n += m
z.idx += m
buf = buf[m:]
if debugFlag {
debug("%d bytes copied to buf, current index %d", n, z.idx)
}
if z.idx < len(z.data) {
// Buffer not filled.
if debugFlag {
debug("need more data for compression")
}
return n, nil
}
// Buffer full.
if err := z.compressBlock(z.data); err != nil {
return n, err
}
z.idx = 0
}
return n, nil
}
// compressBlock compresses a block.
func (z *Writer) compressBlock(data []byte) error {
if !z.NoChecksum {
z.checksum.Write(data)
}
// The compressed block size cannot exceed the input's.
var zn int
var err error
if level := z.Header.CompressionLevel; level != 0 {
zn, err = CompressBlockHC(data, z.zdata, level)
} else {
zn, err = CompressBlock(data, z.zdata, z.hashtable[:])
}
var zdata []byte
var bLen uint32
if debugFlag {
debug("block compression %d => %d", len(data), zn)
}
if err == nil && zn > 0 && zn < len(data) {
// Compressible and compressed size smaller than uncompressed: ok!
bLen = uint32(zn)
zdata = z.zdata[:zn]
} else {
// Uncompressed block.
bLen = uint32(len(data)) | compressedBlockFlag
zdata = data
}
if debugFlag {
debug("block compression to be written len=%d data len=%d", bLen, len(zdata))
}
// Write the block.
if err := z.writeUint32(bLen); err != nil {
return err
}
if _, err := z.dst.Write(zdata); err != nil {
return err
}
if z.BlockChecksum {
checksum := xxh32.ChecksumZero(zdata)
if debugFlag {
debug("block checksum %x", checksum)
}
if err := z.writeUint32(checksum); err != nil {
return err
}
}
if debugFlag {
debug("current frame checksum %x", z.checksum.Sum32())
}
return nil
}
// Flush flushes any pending compressed data to the underlying writer.
// Flush does not return until the data has been written.
// If the underlying writer returns an error, Flush returns that error.
func (z *Writer) Flush() error {
if debugFlag {
debug("flush with index %d", z.idx)
}
if z.idx == 0 {
return nil
}
return z.compressBlock(z.data[:z.idx])
}
// Close closes the Writer, flushing any unwritten data to the underlying io.Writer, but does not close the underlying io.Writer.
func (z *Writer) Close() error {
if !z.Header.done {
if err := z.writeHeader(); err != nil {
return err
}
}
if err := z.Flush(); err != nil {
return err
}
if debugFlag {
debug("writing last empty block")
}
if err := z.writeUint32(0); err != nil {
return err
}
if !z.NoChecksum {
checksum := z.checksum.Sum32()
if debugFlag {
debug("stream checksum %x", checksum)
}
if err := z.writeUint32(checksum); err != nil {
return err
}
}
return nil
}
// Reset clears the state of the Writer z such that it is equivalent to its
// initial state from NewWriter, but instead writing to w.
// No access to the underlying io.Writer is performed.
func (z *Writer) Reset(w io.Writer) {
z.Header = Header{}
z.dst = w
z.checksum.Reset()
z.zdata = z.zdata[:0]
z.data = z.data[:0]
z.idx = 0
}
// writeUint32 writes a uint32 to the underlying writer.
func (z *Writer) writeUint32(x uint32) error {
buf := z.buf[:4]
binary.LittleEndian.PutUint32(buf, x)
_, err := z.dst.Write(buf)
return err
}