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// Copyright 2014-2019 Ulrich Kunitz. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package lzma
import (
"errors"
"fmt"
"io"
)
// matcher is an interface that supports the identification of the next
// operation.
type matcher interface {
io.Writer
SetDict(d *encoderDict)
NextOp(rep [4]uint32) operation
}
// encoderDict provides the dictionary of the encoder. It includes an
// additional buffer atop of the actual dictionary.
type encoderDict struct {
buf buffer
m matcher
head int64
capacity int
// preallocated array
data [maxMatchLen]byte
}
// newEncoderDict creates the encoder dictionary. The argument bufSize
// defines the size of the additional buffer.
func newEncoderDict(dictCap, bufSize int, m matcher) (d *encoderDict, err error) {
if !(1 <= dictCap && int64(dictCap) <= MaxDictCap) {
return nil, errors.New(
"lzma: dictionary capacity out of range")
}
if bufSize < 1 {
return nil, errors.New(
"lzma: buffer size must be larger than zero")
}
d = &encoderDict{
buf: *newBuffer(dictCap + bufSize),
capacity: dictCap,
m: m,
}
m.SetDict(d)
return d, nil
}
// Discard discards n bytes. Note that n must not be larger than
// MaxMatchLen.
func (d *encoderDict) Discard(n int) {
p := d.data[:n]
k, _ := d.buf.Read(p)
if k < n {
panic(fmt.Errorf("lzma: can't discard %d bytes", n))
}
d.head += int64(n)
d.m.Write(p)
}
// Len returns the data available in the encoder dictionary.
func (d *encoderDict) Len() int {
n := d.buf.Available()
if int64(n) > d.head {
return int(d.head)
}
return n
}
// DictLen returns the actual length of data in the dictionary.
func (d *encoderDict) DictLen() int {
if d.head < int64(d.capacity) {
return int(d.head)
}
return d.capacity
}
// Available returns the number of bytes that can be written by a
// following Write call.
func (d *encoderDict) Available() int {
return d.buf.Available() - d.DictLen()
}
// Write writes data into the dictionary buffer. Note that the position
// of the dictionary head will not be moved. If there is not enough
// space in the buffer ErrNoSpace will be returned.
func (d *encoderDict) Write(p []byte) (n int, err error) {
m := d.Available()
if len(p) > m {
p = p[:m]
err = ErrNoSpace
}
var e error
if n, e = d.buf.Write(p); e != nil {
err = e
}
return n, err
}
// Pos returns the position of the head.
func (d *encoderDict) Pos() int64 { return d.head }
// ByteAt returns the byte at the given distance.
func (d *encoderDict) ByteAt(distance int) byte {
if !(0 < distance && distance <= d.Len()) {
return 0
}
i := d.buf.rear - distance
if i < 0 {
i += len(d.buf.data)
}
return d.buf.data[i]
}
// CopyN copies the last n bytes from the dictionary into the provided
// writer. This is used for copying uncompressed data into an
// uncompressed segment.
func (d *encoderDict) CopyN(w io.Writer, n int) (written int, err error) {
if n <= 0 {
return 0, nil
}
m := d.Len()
if n > m {
n = m
err = ErrNoSpace
}
i := d.buf.rear - n
var e error
if i < 0 {
i += len(d.buf.data)
if written, e = w.Write(d.buf.data[i:]); e != nil {
return written, e
}
i = 0
}
var k int
k, e = w.Write(d.buf.data[i:d.buf.rear])
written += k
if e != nil {
err = e
}
return written, err
}
// Buffered returns the number of bytes in the buffer.
func (d *encoderDict) Buffered() int { return d.buf.Buffered() }
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