forked from Shiloh/githaven
399 lines
8.1 KiB
Go
Vendored
399 lines
8.1 KiB
Go
Vendored
// Copyright 2014-2021 Ulrich Kunitz. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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package lzma
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import (
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"errors"
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"fmt"
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"io"
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)
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const (
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// maximum size of compressed data in a chunk
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maxCompressed = 1 << 16
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// maximum size of uncompressed data in a chunk
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maxUncompressed = 1 << 21
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)
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// chunkType represents the type of an LZMA2 chunk. Note that this
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// value is an internal representation and no actual encoding of a LZMA2
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// chunk header.
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type chunkType byte
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// Possible values for the chunk type.
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const (
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// end of stream
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cEOS chunkType = iota
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// uncompressed; reset dictionary
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cUD
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// uncompressed; no reset of dictionary
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cU
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// LZMA compressed; no reset
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cL
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// LZMA compressed; reset state
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cLR
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// LZMA compressed; reset state; new property value
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cLRN
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// LZMA compressed; reset state; new property value; reset dictionary
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cLRND
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)
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// chunkTypeStrings provide a string representation for the chunk types.
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var chunkTypeStrings = [...]string{
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cEOS: "EOS",
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cU: "U",
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cUD: "UD",
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cL: "L",
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cLR: "LR",
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cLRN: "LRN",
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cLRND: "LRND",
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}
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// String returns a string representation of the chunk type.
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func (c chunkType) String() string {
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if !(cEOS <= c && c <= cLRND) {
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return "unknown"
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}
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return chunkTypeStrings[c]
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}
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// Actual encodings for the chunk types in the value. Note that the high
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// uncompressed size bits are stored in the header byte additionally.
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const (
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hEOS = 0
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hUD = 1
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hU = 2
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hL = 1 << 7
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hLR = 1<<7 | 1<<5
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hLRN = 1<<7 | 1<<6
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hLRND = 1<<7 | 1<<6 | 1<<5
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)
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// errHeaderByte indicates an unsupported value for the chunk header
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// byte. These bytes starts the variable-length chunk header.
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var errHeaderByte = errors.New("lzma: unsupported chunk header byte")
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// headerChunkType converts the header byte into a chunk type. It
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// ignores the uncompressed size bits in the chunk header byte.
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func headerChunkType(h byte) (c chunkType, err error) {
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if h&hL == 0 {
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// no compression
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switch h {
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case hEOS:
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c = cEOS
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case hUD:
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c = cUD
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case hU:
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c = cU
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default:
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return 0, errHeaderByte
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}
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return
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}
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switch h & hLRND {
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case hL:
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c = cL
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case hLR:
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c = cLR
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case hLRN:
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c = cLRN
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case hLRND:
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c = cLRND
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default:
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return 0, errHeaderByte
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}
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return
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}
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// uncompressedHeaderLen provides the length of an uncompressed header
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const uncompressedHeaderLen = 3
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// headerLen returns the length of the LZMA2 header for a given chunk
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// type.
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func headerLen(c chunkType) int {
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switch c {
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case cEOS:
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return 1
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case cU, cUD:
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return uncompressedHeaderLen
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case cL, cLR:
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return 5
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case cLRN, cLRND:
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return 6
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}
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panic(fmt.Errorf("unsupported chunk type %d", c))
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}
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// chunkHeader represents the contents of a chunk header.
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type chunkHeader struct {
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ctype chunkType
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uncompressed uint32
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compressed uint16
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props Properties
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}
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// String returns a string representation of the chunk header.
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func (h *chunkHeader) String() string {
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return fmt.Sprintf("%s %d %d %s", h.ctype, h.uncompressed,
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h.compressed, &h.props)
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}
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// UnmarshalBinary reads the content of the chunk header from the data
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// slice. The slice must have the correct length.
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func (h *chunkHeader) UnmarshalBinary(data []byte) error {
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if len(data) == 0 {
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return errors.New("no data")
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}
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c, err := headerChunkType(data[0])
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if err != nil {
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return err
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}
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n := headerLen(c)
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if len(data) < n {
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return errors.New("incomplete data")
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}
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if len(data) > n {
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return errors.New("invalid data length")
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}
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*h = chunkHeader{ctype: c}
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if c == cEOS {
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return nil
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}
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h.uncompressed = uint32(uint16BE(data[1:3]))
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if c <= cU {
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return nil
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}
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h.uncompressed |= uint32(data[0]&^hLRND) << 16
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h.compressed = uint16BE(data[3:5])
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if c <= cLR {
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return nil
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}
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h.props, err = PropertiesForCode(data[5])
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return err
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}
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// MarshalBinary encodes the chunk header value. The function checks
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// whether the content of the chunk header is correct.
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func (h *chunkHeader) MarshalBinary() (data []byte, err error) {
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if h.ctype > cLRND {
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return nil, errors.New("invalid chunk type")
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}
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if err = h.props.verify(); err != nil {
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return nil, err
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}
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data = make([]byte, headerLen(h.ctype))
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switch h.ctype {
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case cEOS:
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return data, nil
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case cUD:
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data[0] = hUD
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case cU:
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data[0] = hU
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case cL:
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data[0] = hL
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case cLR:
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data[0] = hLR
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case cLRN:
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data[0] = hLRN
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case cLRND:
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data[0] = hLRND
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}
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putUint16BE(data[1:3], uint16(h.uncompressed))
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if h.ctype <= cU {
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return data, nil
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}
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data[0] |= byte(h.uncompressed>>16) &^ hLRND
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putUint16BE(data[3:5], h.compressed)
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if h.ctype <= cLR {
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return data, nil
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}
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data[5] = h.props.Code()
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return data, nil
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}
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// readChunkHeader reads the chunk header from the IO reader.
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func readChunkHeader(r io.Reader) (h *chunkHeader, err error) {
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p := make([]byte, 1, 6)
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if _, err = io.ReadFull(r, p); err != nil {
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return
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}
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c, err := headerChunkType(p[0])
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if err != nil {
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return
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}
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p = p[:headerLen(c)]
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if _, err = io.ReadFull(r, p[1:]); err != nil {
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return
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}
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h = new(chunkHeader)
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if err = h.UnmarshalBinary(p); err != nil {
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return nil, err
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}
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return h, nil
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}
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// uint16BE converts a big-endian uint16 representation to an uint16
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// value.
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func uint16BE(p []byte) uint16 {
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return uint16(p[0])<<8 | uint16(p[1])
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}
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// putUint16BE puts the big-endian uint16 presentation into the given
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// slice.
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func putUint16BE(p []byte, x uint16) {
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p[0] = byte(x >> 8)
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p[1] = byte(x)
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}
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// chunkState is used to manage the state of the chunks
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type chunkState byte
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// start and stop define the initial and terminating state of the chunk
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// state
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const (
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start chunkState = 'S'
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stop chunkState = 'T'
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)
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// errors for the chunk state handling
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var (
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errChunkType = errors.New("lzma: unexpected chunk type")
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errState = errors.New("lzma: wrong chunk state")
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)
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// next transitions state based on chunk type input
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func (c *chunkState) next(ctype chunkType) error {
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switch *c {
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// start state
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case 'S':
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switch ctype {
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case cEOS:
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*c = 'T'
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case cUD:
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*c = 'R'
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case cLRND:
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*c = 'L'
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default:
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return errChunkType
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}
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// normal LZMA mode
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case 'L':
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switch ctype {
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case cEOS:
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*c = 'T'
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case cUD:
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*c = 'R'
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case cU:
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*c = 'U'
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case cL, cLR, cLRN, cLRND:
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break
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default:
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return errChunkType
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}
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// reset required
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case 'R':
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switch ctype {
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case cEOS:
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*c = 'T'
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case cUD, cU:
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break
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case cLRN, cLRND:
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*c = 'L'
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default:
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return errChunkType
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}
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// uncompressed
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case 'U':
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switch ctype {
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case cEOS:
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*c = 'T'
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case cUD:
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*c = 'R'
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case cU:
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break
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case cL, cLR, cLRN, cLRND:
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*c = 'L'
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default:
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return errChunkType
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}
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// terminal state
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case 'T':
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return errChunkType
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default:
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return errState
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}
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return nil
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}
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// defaultChunkType returns the default chunk type for each chunk state.
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func (c chunkState) defaultChunkType() chunkType {
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switch c {
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case 'S':
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return cLRND
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case 'L', 'U':
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return cL
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case 'R':
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return cLRN
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default:
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// no error
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return cEOS
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}
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}
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// maxDictCap defines the maximum dictionary capacity supported by the
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// LZMA2 dictionary capacity encoding.
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const maxDictCap = 1<<32 - 1
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// maxDictCapCode defines the maximum dictionary capacity code.
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const maxDictCapCode = 40
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// The function decodes the dictionary capacity byte, but doesn't change
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// for the correct range of the given byte.
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func decodeDictCap(c byte) int64 {
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return (2 | int64(c)&1) << (11 + (c>>1)&0x1f)
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}
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// DecodeDictCap decodes the encoded dictionary capacity. The function
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// returns an error if the code is out of range.
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func DecodeDictCap(c byte) (n int64, err error) {
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if c >= maxDictCapCode {
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if c == maxDictCapCode {
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return maxDictCap, nil
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}
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return 0, errors.New("lzma: invalid dictionary size code")
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}
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return decodeDictCap(c), nil
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}
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// EncodeDictCap encodes a dictionary capacity. The function returns the
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// code for the capacity that is greater or equal n. If n exceeds the
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// maximum support dictionary capacity, the maximum value is returned.
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func EncodeDictCap(n int64) byte {
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a, b := byte(0), byte(40)
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for a < b {
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c := a + (b-a)>>1
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m := decodeDictCap(c)
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if n <= m {
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if n == m {
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return c
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}
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b = c
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} else {
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a = c + 1
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}
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}
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return a
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}
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