forked from klauspost/compress
/
xerial.go
262 lines (240 loc) · 7.22 KB
/
xerial.go
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package xerial
import (
"bytes"
"encoding/binary"
"errors"
"github.com/Memexurer/compress/s2"
)
var (
xerialHeader = []byte{130, 83, 78, 65, 80, 80, 89, 0}
// This is xerial version 1 and minimally compatible with version 1
xerialVersionInfo = []byte{0, 0, 0, 1, 0, 0, 0, 1}
// ErrMalformed is returned by the decoder when the xerial framing
// is malformed
ErrMalformed = errors.New("malformed xerial framing")
)
// Encode *appends* to the specified 'dst' the compressed
// 'src' in xerial framing format. If 'dst' does not have enough
// capacity, then a new slice will be allocated. If 'dst' has
// non-zero length, then if *must* have been built using this function.
func Encode(dst, src []byte) []byte {
if len(dst) == 0 {
dst = append(dst, xerialHeader...)
dst = append(dst, xerialVersionInfo...)
}
// Snappy encode in blocks of maximum 32KB
var (
max = len(src)
blockSize = 32 * 1024
pos = 0
chunk []byte
)
for pos < max {
newPos := min(pos+blockSize, max)
// Find maximum length we need
needLen := s2.MaxEncodedLen(newPos-pos) + 4
if cap(dst)-len(dst) >= needLen {
// Encode directly into dst
dstStart := len(dst) + 4 // Start offset in dst
dstSizePos := dst[len(dst):dstStart] // Reserve space for compressed size
dstEnd := len(dst) + needLen // End offset in dst
// Compress into dst and get actual size.
actual := s2.EncodeSnappy(dst[dstStart:dstEnd], src[pos:newPos])
// Update dst size
dst = dst[:dstStart+len(actual)]
// Store compressed size
binary.BigEndian.PutUint32(dstSizePos, uint32(len(actual)))
} else {
chunk = s2.EncodeSnappy(chunk[:cap(chunk)], src[pos:newPos])
origLen := len(dst)
// First encode the compressed size (big-endian)
// Put* panics if the buffer is too small, so pad 4 bytes first
dst = append(dst, dst[0:4]...)
binary.BigEndian.PutUint32(dst[origLen:], uint32(len(chunk)))
// And now the compressed data
dst = append(dst, chunk...)
}
pos = newPos
}
return dst
}
// EncodeBetter *appends* to the specified 'dst' the compressed
// 'src' in xerial framing format. If 'dst' does not have enough
// capacity, then a new slice will be allocated. If 'dst' has
// non-zero length, then if *must* have been built using this function.
func EncodeBetter(dst, src []byte) []byte {
if len(dst) == 0 {
dst = append(dst, xerialHeader...)
dst = append(dst, xerialVersionInfo...)
}
// Snappy encode in blocks of maximum 32KB
var (
max = len(src)
blockSize = 32 * 1024
pos = 0
chunk []byte
)
for pos < max {
newPos := min(pos+blockSize, max)
// Find maximum length we need
needLen := s2.MaxEncodedLen(newPos-pos) + 4
if cap(dst)-len(dst) >= needLen {
// Encode directly into dst
dstStart := len(dst) + 4 // Start offset in dst
dstSizePos := dst[len(dst):dstStart] // Reserve space for compressed size
dstEnd := len(dst) + needLen // End offset in dst
// Compress into dst and get actual size.
actual := s2.EncodeSnappyBetter(dst[dstStart:dstEnd], src[pos:newPos])
// Update dst size
dst = dst[:dstStart+len(actual)]
// Store compressed size
binary.BigEndian.PutUint32(dstSizePos, uint32(len(actual)))
} else {
chunk = s2.EncodeSnappyBetter(chunk[:cap(chunk)], src[pos:newPos])
origLen := len(dst)
// First encode the compressed size (big-endian)
// Put* panics if the buffer is too small, so pad 4 bytes first
dst = append(dst, dst[0:4]...)
binary.BigEndian.PutUint32(dst[origLen:], uint32(len(chunk)))
// And now the compressed data
dst = append(dst, chunk...)
}
pos = newPos
}
return dst
}
func min(x, y int) int {
if x < y {
return x
}
return y
}
const (
sizeOffset = 16
sizeBytes = 4
)
// Decode decodes snappy data whether it is traditional unframed
// or includes the xerial framing format.
func Decode(src []byte) ([]byte, error) {
return DecodeInto(nil, src)
}
// DecodeInto decodes snappy data whether it is traditional unframed
// or includes the xerial framing format into the specified `dst`.
// It is assumed that the entirety of `dst` including all capacity is available
// for use by this function. If `dst` is nil *or* insufficiently large to hold
// the decoded `src`, new space will be allocated.
// To never allocate bigger destination, use DecodeCapped.
func DecodeInto(dst, src []byte) ([]byte, error) {
var max = len(src)
if max < len(xerialHeader) || !bytes.Equal(src[:8], xerialHeader) {
dst, err := s2.Decode(dst[:cap(dst)], src)
if err != nil {
return dst, ErrMalformed
}
return dst, nil
}
if max == sizeOffset {
return []byte{}, nil
}
if max < sizeOffset+sizeBytes {
return nil, ErrMalformed
}
if len(dst) > 0 {
dst = dst[:0]
}
var (
pos = sizeOffset
chunk []byte
)
for pos+sizeBytes <= max {
size := int(binary.BigEndian.Uint32(src[pos : pos+sizeBytes]))
pos += sizeBytes
nextPos := pos + size
// On architectures where int is 32-bytes wide size + pos could
// overflow so we need to check the low bound as well as the
// high
if nextPos < pos || nextPos > max {
return nil, ErrMalformed
}
nextLen, err := s2.DecodedLen(src[pos:nextPos])
if err != nil {
return nil, err
}
if cap(dst)-len(dst) >= nextLen {
// Decode directly into dst
dstStart := len(dst)
dstEnd := dstStart + nextLen
_, err = s2.Decode(dst[dstStart:dstEnd], src[pos:nextPos])
if err != nil {
return nil, err
}
dst = dst[:dstEnd]
} else {
chunk, err = s2.Decode(chunk[:cap(chunk)], src[pos:nextPos])
if err != nil {
return nil, err
}
dst = append(dst, chunk...)
}
pos = nextPos
}
return dst, nil
}
var ErrDstTooSmall = errors.New("destination buffer too small")
// DecodeCapped decodes snappy data whether it is traditional unframed
// or includes the xerial framing format into the specified `dst`.
// It is assumed that the entirety of `dst` including all capacity is available
// for use by this function. If `dst` is nil *or* insufficiently large to hold
// the decoded `src`, ErrDstTooSmall is returned.
func DecodeCapped(dst, src []byte) ([]byte, error) {
var max = len(src)
if dst == nil {
return nil, ErrDstTooSmall
}
if max < len(xerialHeader) || !bytes.Equal(src[:8], xerialHeader) {
l, err := s2.DecodedLen(src)
if err != nil {
return nil, ErrMalformed
}
if l > cap(dst) {
return nil, ErrDstTooSmall
}
return s2.Decode(dst[:cap(dst)], src)
}
dst = dst[:0]
if max == sizeOffset {
return dst, nil
}
if max < sizeOffset+sizeBytes {
return nil, ErrMalformed
}
pos := sizeOffset
for pos+sizeBytes <= max {
size := int(binary.BigEndian.Uint32(src[pos : pos+sizeBytes]))
pos += sizeBytes
nextPos := pos + size
// On architectures where int is 32-bytes wide size + pos could
// overflow so we need to check the low bound as well as the
// high
if nextPos < pos || nextPos > max {
return nil, ErrMalformed
}
nextLen, err := s2.DecodedLen(src[pos:nextPos])
if err != nil {
return nil, err
}
if cap(dst)-len(dst) < nextLen {
return nil, ErrDstTooSmall
}
// Decode directly into dst
dstStart := len(dst)
dstEnd := dstStart + nextLen
_, err = s2.Decode(dst[dstStart:dstEnd], src[pos:nextPos])
if err != nil {
return nil, err
}
dst = dst[:dstEnd]
pos = nextPos
}
return dst, nil
}