src/compress/lzw/reader.go - go - Git at Google

 // Copyright 2011 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 // Package lzw implements the Lempel-Ziv-Welch compressed data format,
 // described in T. A. Welch, ``A Technique for High-Performance Data
 // Compression'', Computer, 17(6) (June 1984), pp 8-19.
 //
 // In particular, it implements LZW as used by the GIF and PDF file
 // formats, which means variable-width codes up to 12 bits and the first
 // two non-literal codes are a clear code and an EOF code.
 //
 // The TIFF file format uses a similar but incompatible version of the LZW
 // algorithm. See the golang.org/x/image/tiff/lzw package for an
 // implementation.
 package lzw

 // TODO(nigeltao): check that PDF uses LZW in the same way as GIF,
 // modulo LSB/MSB packing order.

 import (
 	"bufio"
 	"errors"
 	"fmt"
 	"io"
 )

 // Order specifies the bit ordering in an LZW data stream.
 type Order int

 const (
 	// LSB means Least Significant Bits first, as used in the GIF file format.
 	LSB Order = iota
 	// MSB means Most Significant Bits first, as used in the TIFF and PDF
 	// file formats.
 	MSB
 )

 const (
 	maxWidth           = 12
 	decoderInvalidCode = 0xffff
 	flushBuffer        = 1 << maxWidth
 )

 // Reader is an io.Reader which can be used to read compressed data in the
 // LZW format.
 type Reader struct {
 	r        io.ByteReader
 	bits     uint32
 	nBits    uint
 	width    uint
 	read     func(*Reader) (uint16, error) // readLSB or readMSB
 	litWidth int                           // width in bits of literal codes
 	err      error

 	// The first 1<<litWidth codes are literal codes.
 	// The next two codes mean clear and EOF.
 	// Other valid codes are in the range [lo, hi] where lo := clear + 2,
 	// with the upper bound incrementing on each code seen.
 	//
 	// overflow is the code at which hi overflows the code width. It always
 	// equals 1 << width.
 	//
 	// last is the most recently seen code, or decoderInvalidCode.
 	//
 	// An invariant is that hi < overflow.
 	clear, eof, hi, overflow, last uint16

 	// Each code c in [lo, hi] expands to two or more bytes. For c != hi:
 	//   suffix[c] is the last of these bytes.
 	//   prefix[c] is the code for all but the last byte.
 	//   This code can either be a literal code or another code in [lo, c).
 	// The c == hi case is a special case.
 	suffix [1 << maxWidth]uint8
 	prefix [1 << maxWidth]uint16

 	// output is the temporary output buffer.
 	// Literal codes are accumulated from the start of the buffer.
 	// Non-literal codes decode to a sequence of suffixes that are first
 	// written right-to-left from the end of the buffer before being copied
 	// to the start of the buffer.
 	// It is flushed when it contains >= 1<<maxWidth bytes,
 	// so that there is always room to decode an entire code.
 	output [2 * 1 << maxWidth]byte
 	o      int    // write index into output
 	toRead []byte // bytes to return from Read
 }

 // readLSB returns the next code for "Least Significant Bits first" data.
 func (r *Reader) readLSB() (uint16, error) {
 	for r.nBits < r.width {
 		x, err := r.r.ReadByte()
 		if err != nil {
 			return 0, err
 		}
 		r.bits |= uint32(x) << r.nBits
 		r.nBits += 8
 	}
 	code := uint16(r.bits & (1<<r.width - 1))
 	r.bits >>= r.width
 	r.nBits -= r.width
 	return code, nil
 }

 // readMSB returns the next code for "Most Significant Bits first" data.
 func (r *Reader) readMSB() (uint16, error) {
 	for r.nBits < r.width {
 		x, err := r.r.ReadByte()
 		if err != nil {
 			return 0, err
 		}
 		r.bits |= uint32(x) << (24 - r.nBits)
 		r.nBits += 8
 	}
 	code := uint16(r.bits >> (32 - r.width))
 	r.bits <<= r.width
 	r.nBits -= r.width
 	return code, nil
 }

 // Read implements io.Reader, reading uncompressed bytes from its underlying Reader.
 func (r *Reader) Read(b []byte) (int, error) {
 	for {
 		if len(r.toRead) > 0 {
 			n := copy(b, r.toRead)
 			r.toRead = r.toRead[n:]
 			return n, nil
 		}
 		if r.err != nil {
 			return 0, r.err
 		}
 		r.decode()
 	}
 }

 // decode decompresses bytes from r and leaves them in d.toRead.
 // read specifies how to decode bytes into codes.
 // litWidth is the width in bits of literal codes.
 func (r *Reader) decode() {
 	// Loop over the code stream, converting codes into decompressed bytes.
 loop:
 	for {
 		code, err := r.read(r)
 		if err != nil {
 			if err == io.EOF {
 				err = io.ErrUnexpectedEOF
 			}
 			r.err = err
 			break
 		}
 		switch {
 		case code < r.clear:
 			// We have a literal code.
 			r.output[r.o] = uint8(code)
 			r.o++
 			if r.last != decoderInvalidCode {
 				// Save what the hi code expands to.
 				r.suffix[r.hi] = uint8(code)
 				r.prefix[r.hi] = r.last
 			}
 		case code == r.clear:
 			r.width = 1 + uint(r.litWidth)
 			r.hi = r.eof
 			r.overflow = 1 << r.width
 			r.last = decoderInvalidCode
 			continue
 		case code == r.eof:
 			r.err = io.EOF
 			break loop
 		case code <= r.hi:
 			c, i := code, len(r.output)-1
 			if code == r.hi && r.last != decoderInvalidCode {
 				// code == hi is a special case which expands to the last expansion
 				// followed by the head of the last expansion. To find the head, we walk
 				// the prefix chain until we find a literal code.
 				c = r.last
 				for c >= r.clear {
 					c = r.prefix[c]
 				}
 				r.output[i] = uint8(c)
 				i--
 				c = r.last
 			}
 			// Copy the suffix chain into output and then write that to w.
 			for c >= r.clear {
 				r.output[i] = r.suffix[c]
 				i--
 				c = r.prefix[c]
 			}
 			r.output[i] = uint8(c)
 			r.o += copy(r.output[r.o:], r.output[i:])
 			if r.last != decoderInvalidCode {
 				// Save what the hi code expands to.
 				r.suffix[r.hi] = uint8(c)
 				r.prefix[r.hi] = r.last
 			}
 		default:
 			r.err = errors.New("lzw: invalid code")
 			break loop
 		}
 		r.last, r.hi = code, r.hi+1
 		if r.hi >= r.overflow {
 			if r.hi > r.overflow {
 				panic("unreachable")
 			}
 			if r.width == maxWidth {
 				r.last = decoderInvalidCode
 				// Undo the d.hi++ a few lines above, so that (1) we maintain
 				// the invariant that d.hi < d.overflow, and (2) d.hi does not
 				// eventually overflow a uint16.
 				r.hi--
 			} else {
 				r.width++
 				r.overflow = 1 << r.width
 			}
 		}
 		if r.o >= flushBuffer {
 			break
 		}
 	}
 	// Flush pending output.
 	r.toRead = r.output[:r.o]
 	r.o = 0
 }

 var errClosed = errors.New("lzw: reader/writer is closed")

 // Close closes the Reader and returns an error for any future read operation.
 // It does not close the underlying io.Reader.
 func (r *Reader) Close() error {
 	r.err = errClosed // in case any Reads come along
 	return nil
 }

 // Reset clears the Reader's state and allows it to be reused again
 // as a new Reader.
 func (r *Reader) Reset(src io.Reader, order Order, litWidth int) {
 	*r = Reader{}
 	r.init(src, order, litWidth)
 }

 // NewReader creates a new io.ReadCloser.
 // Reads from the returned io.ReadCloser read and decompress data from r.
 // If r does not also implement io.ByteReader,
 // the decompressor may read more data than necessary from r.
 // It is the caller's responsibility to call Close on the ReadCloser when
 // finished reading.
 // The number of bits to use for literal codes, litWidth, must be in the
 // range [2,8] and is typically 8. It must equal the litWidth
 // used during compression.
 //
 // It is guaranteed that the underlying type of the returned io.ReadCloser
 // is a *Reader.
 func NewReader(r io.Reader, order Order, litWidth int) io.ReadCloser {
 	return newReader(r, order, litWidth)
 }

 func newReader(src io.Reader, order Order, litWidth int) *Reader {
 	r := new(Reader)
 	r.init(src, order, litWidth)
 	return r
 }

 func (r *Reader) init(src io.Reader, order Order, litWidth int) {
 	switch order {
 	case LSB:
 		r.read = (*Reader).readLSB
 	case MSB:
 		r.read = (*Reader).readMSB
 	default:
 		r.err = errors.New("lzw: unknown order")
 		return
 	}
 	if litWidth < 2 || 8 < litWidth {
 		r.err = fmt.Errorf("lzw: litWidth %d out of range", litWidth)
 		return
 	}

 	br, ok := src.(io.ByteReader)
 	if !ok && src != nil {
 		br = bufio.NewReader(src)
 	}
 	r.r = br
 	r.litWidth = litWidth
 	r.width = 1 + uint(litWidth)
 	r.clear = uint16(1) << uint(litWidth)
 	r.eof, r.hi = r.clear+1, r.clear+1
 	r.overflow = uint16(1) << r.width
 	r.last = decoderInvalidCode
 }
	// Copyright 2011 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	// Package lzw implements the Lempel-Ziv-Welch compressed data format,
	// described in T. A. Welch, ``A Technique for High-Performance Data
	// Compression'', Computer, 17(6) (June 1984), pp 8-19.
	//
	// In particular, it implements LZW as used by the GIF and PDF file
	// formats, which means variable-width codes up to 12 bits and the first
	// two non-literal codes are a clear code and an EOF code.
	//
	// The TIFF file format uses a similar but incompatible version of the LZW
	// algorithm. See the golang.org/x/image/tiff/lzw package for an
	// implementation.
	package lzw

	// TODO(nigeltao): check that PDF uses LZW in the same way as GIF,
	// modulo LSB/MSB packing order.

	import (
	"bufio"
	"errors"
	"fmt"
	"io"
	)

	// Order specifies the bit ordering in an LZW data stream.
	type Order int

	const (
	// LSB means Least Significant Bits first, as used in the GIF file format.
	LSB Order = iota
	// MSB means Most Significant Bits first, as used in the TIFF and PDF
	// file formats.
	MSB
	)

	const (
	maxWidth = 12
	decoderInvalidCode = 0xffff
	flushBuffer = 1 << maxWidth
	)

	// Reader is an io.Reader which can be used to read compressed data in the
	// LZW format.
	type Reader struct {
	r io.ByteReader
	bits uint32
	nBits uint
	width uint
	read func(*Reader) (uint16, error) // readLSB or readMSB
	litWidth int // width in bits of literal codes
	err error

	// The first 1<<litWidth codes are literal codes.
	// The next two codes mean clear and EOF.
	// Other valid codes are in the range [lo, hi] where lo := clear + 2,
	// with the upper bound incrementing on each code seen.
	//
	// overflow is the code at which hi overflows the code width. It always
	// equals 1 << width.
	//
	// last is the most recently seen code, or decoderInvalidCode.
	//
	// An invariant is that hi < overflow.
	clear, eof, hi, overflow, last uint16

	// Each code c in [lo, hi] expands to two or more bytes. For c != hi:
	// suffix[c] is the last of these bytes.
	// prefix[c] is the code for all but the last byte.
	// This code can either be a literal code or another code in [lo, c).
	// The c == hi case is a special case.
	suffix [1 << maxWidth]uint8
	prefix [1 << maxWidth]uint16

	// output is the temporary output buffer.
	// Literal codes are accumulated from the start of the buffer.
	// Non-literal codes decode to a sequence of suffixes that are first
	// written right-to-left from the end of the buffer before being copied
	// to the start of the buffer.
	// It is flushed when it contains >= 1<<maxWidth bytes,
	// so that there is always room to decode an entire code.
	output [2 * 1 << maxWidth]byte
	o int // write index into output
	toRead []byte // bytes to return from Read
	}

	// readLSB returns the next code for "Least Significant Bits first" data.
	func (r *Reader) readLSB() (uint16, error) {
	for r.nBits < r.width {
	x, err := r.r.ReadByte()
	if err != nil {
	return 0, err
	}
	r.bits \|= uint32(x) << r.nBits
	r.nBits += 8
	}
	code := uint16(r.bits & (1<<r.width - 1))
	r.bits >>= r.width
	r.nBits -= r.width
	return code, nil
	}

	// readMSB returns the next code for "Most Significant Bits first" data.
	func (r *Reader) readMSB() (uint16, error) {
	for r.nBits < r.width {
	x, err := r.r.ReadByte()
	if err != nil {
	return 0, err
	}
	r.bits \|= uint32(x) << (24 - r.nBits)
	r.nBits += 8
	}
	code := uint16(r.bits >> (32 - r.width))
	r.bits <<= r.width
	r.nBits -= r.width
	return code, nil
	}

	// Read implements io.Reader, reading uncompressed bytes from its underlying Reader.
	func (r *Reader) Read(b []byte) (int, error) {
	for {
	if len(r.toRead) > 0 {
	n := copy(b, r.toRead)
	r.toRead = r.toRead[n:]
	return n, nil
	}
	if r.err != nil {
	return 0, r.err
	}
	r.decode()
	}
	}

	// decode decompresses bytes from r and leaves them in d.toRead.
	// read specifies how to decode bytes into codes.
	// litWidth is the width in bits of literal codes.
	func (r *Reader) decode() {
	// Loop over the code stream, converting codes into decompressed bytes.
	loop:
	for {
	code, err := r.read(r)
	if err != nil {
	if err == io.EOF {
	err = io.ErrUnexpectedEOF
	}
	r.err = err
	break
	}
	switch {
	case code < r.clear:
	// We have a literal code.
	r.output[r.o] = uint8(code)
	r.o++
	if r.last != decoderInvalidCode {
	// Save what the hi code expands to.
	r.suffix[r.hi] = uint8(code)
	r.prefix[r.hi] = r.last
	}
	case code == r.clear:
	r.width = 1 + uint(r.litWidth)
	r.hi = r.eof
	r.overflow = 1 << r.width
	r.last = decoderInvalidCode
	continue
	case code == r.eof:
	r.err = io.EOF
	break loop
	case code <= r.hi:
	c, i := code, len(r.output)-1
	if code == r.hi && r.last != decoderInvalidCode {
	// code == hi is a special case which expands to the last expansion
	// followed by the head of the last expansion. To find the head, we walk
	// the prefix chain until we find a literal code.
	c = r.last
	for c >= r.clear {
	c = r.prefix[c]
	}
	r.output[i] = uint8(c)
	i--
	c = r.last
	}
	// Copy the suffix chain into output and then write that to w.
	for c >= r.clear {
	r.output[i] = r.suffix[c]
	i--
	c = r.prefix[c]
	}
	r.output[i] = uint8(c)
	r.o += copy(r.output[r.o:], r.output[i:])
	if r.last != decoderInvalidCode {
	// Save what the hi code expands to.
	r.suffix[r.hi] = uint8(c)
	r.prefix[r.hi] = r.last
	}
	default:
	r.err = errors.New("lzw: invalid code")
	break loop
	}
	r.last, r.hi = code, r.hi+1
	if r.hi >= r.overflow {
	if r.hi > r.overflow {
	panic("unreachable")
	}
	if r.width == maxWidth {
	r.last = decoderInvalidCode
	// Undo the d.hi++ a few lines above, so that (1) we maintain
	// the invariant that d.hi < d.overflow, and (2) d.hi does not
	// eventually overflow a uint16.
	r.hi--
	} else {
	r.width++
	r.overflow = 1 << r.width
	}
	}
	if r.o >= flushBuffer {
	break
	}
	}
	// Flush pending output.
	r.toRead = r.output[:r.o]
	r.o = 0
	}

	var errClosed = errors.New("lzw: reader/writer is closed")

	// Close closes the Reader and returns an error for any future read operation.
	// It does not close the underlying io.Reader.
	func (r *Reader) Close() error {
	r.err = errClosed // in case any Reads come along
	return nil
	}

	// Reset clears the Reader's state and allows it to be reused again
	// as a new Reader.
	func (r *Reader) Reset(src io.Reader, order Order, litWidth int) {
	*r = Reader{}
	r.init(src, order, litWidth)
	}

	// NewReader creates a new io.ReadCloser.
	// Reads from the returned io.ReadCloser read and decompress data from r.
	// If r does not also implement io.ByteReader,
	// the decompressor may read more data than necessary from r.
	// It is the caller's responsibility to call Close on the ReadCloser when
	// finished reading.
	// The number of bits to use for literal codes, litWidth, must be in the
	// range [2,8] and is typically 8. It must equal the litWidth
	// used during compression.
	//
	// It is guaranteed that the underlying type of the returned io.ReadCloser
	// is a *Reader.
	func NewReader(r io.Reader, order Order, litWidth int) io.ReadCloser {
	return newReader(r, order, litWidth)
	}

	func newReader(src io.Reader, order Order, litWidth int) *Reader {
	r := new(Reader)
	r.init(src, order, litWidth)
	return r
	}

	func (r *Reader) init(src io.Reader, order Order, litWidth int) {
	switch order {
	case LSB:
	r.read = (*Reader).readLSB
	case MSB:
	r.read = (*Reader).readMSB
	default:
	r.err = errors.New("lzw: unknown order")
	return
	}
	if litWidth < 2 \|\| 8 < litWidth {
	r.err = fmt.Errorf("lzw: litWidth %d out of range", litWidth)
	return
	}

	br, ok := src.(io.ByteReader)
	if !ok && src != nil {
	br = bufio.NewReader(src)
	}
	r.r = br
	r.litWidth = litWidth
	r.width = 1 + uint(litWidth)
	r.clear = uint16(1) << uint(litWidth)
	r.eof, r.hi = r.clear+1, r.clear+1
	r.overflow = uint16(1) << r.width
	r.last = decoderInvalidCode
	}