src/pkg/compress/bzip2/move_to_front.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 bzip2

 // moveToFrontDecoder implements a move-to-front list. Such a list is an
 // efficient way to transform a string with repeating elements into one with
 // many small valued numbers, which is suitable for entropy encoding. It works
 // by starting with an initial list of symbols and references symbols by their
 // index into that list. When a symbol is referenced, it's moved to the front
 // of the list. Thus, a repeated symbol ends up being encoded with many zeros,
 // as the symbol will be at the front of the list after the first access.
 type moveToFrontDecoder struct {
 	// Rather than actually keep the list in memory, the symbols are stored
 	// as a circular, double linked list with the symbol indexed by head
 	// at the front of the list.
 	symbols []byte
 	next    []uint8
 	prev    []uint8
 	head    uint8
 }

 // newMTFDecoder creates a move-to-front decoder with an explicit initial list
 // of symbols.
 func newMTFDecoder(symbols []byte) *moveToFrontDecoder {
 	if len(symbols) > 256 {
 		panic("too many symbols")
 	}

 	m := &moveToFrontDecoder{
 		symbols: symbols,
 		next:    make([]uint8, len(symbols)),
 		prev:    make([]uint8, len(symbols)),
 	}

 	m.threadLinkedList()
 	return m
 }

 // newMTFDecoderWithRange creates a move-to-front decoder with an initial
 // symbol list of 0...n-1.
 func newMTFDecoderWithRange(n int) *moveToFrontDecoder {
 	if n > 256 {
 		panic("newMTFDecoderWithRange: cannot have > 256 symbols")
 	}

 	m := &moveToFrontDecoder{
 		symbols: make([]uint8, n),
 		next:    make([]uint8, n),
 		prev:    make([]uint8, n),
 	}

 	for i := 0; i < n; i++ {
 		m.symbols[i] = byte(i)
 	}

 	m.threadLinkedList()
 	return m
 }

 // threadLinkedList creates the initial linked-list pointers.
 func (m *moveToFrontDecoder) threadLinkedList() {
 	if len(m.symbols) == 0 {
 		return
 	}

 	m.prev[0] = uint8(len(m.symbols) - 1)

 	for i := 0; i < len(m.symbols)-1; i++ {
 		m.next[i] = uint8(i + 1)
 		m.prev[i+1] = uint8(i)
 	}

 	m.next[len(m.symbols)-1] = 0
 }

 func (m *moveToFrontDecoder) Decode(n int) (b byte) {
 	// Most of the time, n will be zero so it's worth dealing with this
 	// simple case.
 	if n == 0 {
 		return m.symbols[m.head]
 	}

 	i := m.head
 	for j := 0; j < n; j++ {
 		i = m.next[i]
 	}
 	b = m.symbols[i]

 	m.next[m.prev[i]] = m.next[i]
 	m.prev[m.next[i]] = m.prev[i]
 	m.next[i] = m.head
 	m.prev[i] = m.prev[m.head]
 	m.next[m.prev[m.head]] = i
 	m.prev[m.head] = i
 	m.head = i

 	return
 }

 // First returns the symbol at the front of the list.
 func (m *moveToFrontDecoder) First() byte {
 	return m.symbols[m.head]
 }
	// 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 bzip2

	// moveToFrontDecoder implements a move-to-front list. Such a list is an
	// efficient way to transform a string with repeating elements into one with
	// many small valued numbers, which is suitable for entropy encoding. It works
	// by starting with an initial list of symbols and references symbols by their
	// index into that list. When a symbol is referenced, it's moved to the front
	// of the list. Thus, a repeated symbol ends up being encoded with many zeros,
	// as the symbol will be at the front of the list after the first access.
	type moveToFrontDecoder struct {
	// Rather than actually keep the list in memory, the symbols are stored
	// as a circular, double linked list with the symbol indexed by head
	// at the front of the list.
	symbols []byte
	next []uint8
	prev []uint8
	head uint8
	}

	// newMTFDecoder creates a move-to-front decoder with an explicit initial list
	// of symbols.
	func newMTFDecoder(symbols []byte) *moveToFrontDecoder {
	if len(symbols) > 256 {
	panic("too many symbols")
	}

	m := &moveToFrontDecoder{
	symbols: symbols,
	next: make([]uint8, len(symbols)),
	prev: make([]uint8, len(symbols)),
	}

	m.threadLinkedList()
	return m
	}

	// newMTFDecoderWithRange creates a move-to-front decoder with an initial
	// symbol list of 0...n-1.
	func newMTFDecoderWithRange(n int) *moveToFrontDecoder {
	if n > 256 {
	panic("newMTFDecoderWithRange: cannot have > 256 symbols")
	}

	m := &moveToFrontDecoder{
	symbols: make([]uint8, n),
	next: make([]uint8, n),
	prev: make([]uint8, n),
	}

	for i := 0; i < n; i++ {
	m.symbols[i] = byte(i)
	}

	m.threadLinkedList()
	return m
	}

	// threadLinkedList creates the initial linked-list pointers.
	func (m *moveToFrontDecoder) threadLinkedList() {
	if len(m.symbols) == 0 {
	return
	}

	m.prev[0] = uint8(len(m.symbols) - 1)

	for i := 0; i < len(m.symbols)-1; i++ {
	m.next[i] = uint8(i + 1)
	m.prev[i+1] = uint8(i)
	}

	m.next[len(m.symbols)-1] = 0
	}

	func (m *moveToFrontDecoder) Decode(n int) (b byte) {
	// Most of the time, n will be zero so it's worth dealing with this
	// simple case.
	if n == 0 {
	return m.symbols[m.head]
	}

	i := m.head
	for j := 0; j < n; j++ {
	i = m.next[i]
	}
	b = m.symbols[i]

	m.next[m.prev[i]] = m.next[i]
	m.prev[m.next[i]] = m.prev[i]
	m.next[i] = m.head
	m.prev[i] = m.prev[m.head]
	m.next[m.prev[m.head]] = i
	m.prev[m.head] = i
	m.head = i

	return
	}

	// First returns the symbol at the front of the list.
	func (m *moveToFrontDecoder) First() byte {
	return m.symbols[m.head]
	}