mirror of
https://github.com/42wim/matterbridge.git
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242 lines
5.0 KiB
Go
242 lines
5.0 KiB
Go
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// Copyright 2010 The Go Authors. 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 gf256 implements arithmetic over the Galois Field GF(256).
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package gf256 // import "rsc.io/qr/gf256"
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import "strconv"
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// A Field represents an instance of GF(256) defined by a specific polynomial.
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type Field struct {
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log [256]byte // log[0] is unused
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exp [510]byte
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}
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// NewField returns a new field corresponding to the polynomial poly
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// and generator α. The Reed-Solomon encoding in QR codes uses
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// polynomial 0x11d with generator 2.
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//
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// The choice of generator α only affects the Exp and Log operations.
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func NewField(poly, α int) *Field {
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if poly < 0x100 || poly >= 0x200 || reducible(poly) {
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panic("gf256: invalid polynomial: " + strconv.Itoa(poly))
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}
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var f Field
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x := 1
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for i := 0; i < 255; i++ {
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if x == 1 && i != 0 {
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panic("gf256: invalid generator " + strconv.Itoa(α) +
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" for polynomial " + strconv.Itoa(poly))
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}
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f.exp[i] = byte(x)
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f.exp[i+255] = byte(x)
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f.log[x] = byte(i)
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x = mul(x, α, poly)
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}
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f.log[0] = 255
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for i := 0; i < 255; i++ {
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if f.log[f.exp[i]] != byte(i) {
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panic("bad log")
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}
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if f.log[f.exp[i+255]] != byte(i) {
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panic("bad log")
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}
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}
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for i := 1; i < 256; i++ {
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if f.exp[f.log[i]] != byte(i) {
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panic("bad log")
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}
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}
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return &f
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}
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// nbit returns the number of significant in p.
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func nbit(p int) uint {
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n := uint(0)
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for ; p > 0; p >>= 1 {
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n++
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}
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return n
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}
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// polyDiv divides the polynomial p by q and returns the remainder.
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func polyDiv(p, q int) int {
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np := nbit(p)
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nq := nbit(q)
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for ; np >= nq; np-- {
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if p&(1<<(np-1)) != 0 {
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p ^= q << (np - nq)
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}
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}
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return p
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}
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// mul returns the product x*y mod poly, a GF(256) multiplication.
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func mul(x, y, poly int) int {
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z := 0
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for x > 0 {
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if x&1 != 0 {
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z ^= y
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}
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x >>= 1
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y <<= 1
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if y&0x100 != 0 {
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y ^= poly
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}
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}
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return z
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}
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// reducible reports whether p is reducible.
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func reducible(p int) bool {
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// Multiplying n-bit * n-bit produces (2n-1)-bit,
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// so if p is reducible, one of its factors must be
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// of np/2+1 bits or fewer.
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np := nbit(p)
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for q := 2; q < 1<<(np/2+1); q++ {
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if polyDiv(p, q) == 0 {
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return true
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}
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}
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return false
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}
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// Add returns the sum of x and y in the field.
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func (f *Field) Add(x, y byte) byte {
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return x ^ y
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}
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// Exp returns the base-α exponential of e in the field.
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// If e < 0, Exp returns 0.
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func (f *Field) Exp(e int) byte {
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if e < 0 {
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return 0
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}
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return f.exp[e%255]
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}
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// Log returns the base-α logarithm of x in the field.
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// If x == 0, Log returns -1.
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func (f *Field) Log(x byte) int {
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if x == 0 {
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return -1
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}
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return int(f.log[x])
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}
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// Inv returns the multiplicative inverse of x in the field.
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// If x == 0, Inv returns 0.
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func (f *Field) Inv(x byte) byte {
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if x == 0 {
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return 0
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}
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return f.exp[255-f.log[x]]
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}
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// Mul returns the product of x and y in the field.
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func (f *Field) Mul(x, y byte) byte {
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if x == 0 || y == 0 {
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return 0
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}
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return f.exp[int(f.log[x])+int(f.log[y])]
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}
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// An RSEncoder implements Reed-Solomon encoding
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// over a given field using a given number of error correction bytes.
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type RSEncoder struct {
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f *Field
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c int
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gen []byte
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lgen []byte
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p []byte
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}
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func (f *Field) gen(e int) (gen, lgen []byte) {
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// p = 1
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p := make([]byte, e+1)
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p[e] = 1
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for i := 0; i < e; i++ {
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// p *= (x + Exp(i))
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// p[j] = p[j]*Exp(i) + p[j+1].
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c := f.Exp(i)
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for j := 0; j < e; j++ {
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p[j] = f.Mul(p[j], c) ^ p[j+1]
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}
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p[e] = f.Mul(p[e], c)
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}
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// lp = log p.
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lp := make([]byte, e+1)
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for i, c := range p {
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if c == 0 {
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lp[i] = 255
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} else {
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lp[i] = byte(f.Log(c))
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}
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}
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return p, lp
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}
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// NewRSEncoder returns a new Reed-Solomon encoder
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// over the given field and number of error correction bytes.
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func NewRSEncoder(f *Field, c int) *RSEncoder {
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gen, lgen := f.gen(c)
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return &RSEncoder{f: f, c: c, gen: gen, lgen: lgen}
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}
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// ECC writes to check the error correcting code bytes
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// for data using the given Reed-Solomon parameters.
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func (rs *RSEncoder) ECC(data []byte, check []byte) {
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if len(check) < rs.c {
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panic("gf256: invalid check byte length")
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}
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if rs.c == 0 {
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return
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}
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// The check bytes are the remainder after dividing
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// data padded with c zeros by the generator polynomial.
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// p = data padded with c zeros.
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var p []byte
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n := len(data) + rs.c
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if len(rs.p) >= n {
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p = rs.p
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} else {
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p = make([]byte, n)
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}
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copy(p, data)
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for i := len(data); i < len(p); i++ {
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p[i] = 0
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}
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// Divide p by gen, leaving the remainder in p[len(data):].
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// p[0] is the most significant term in p, and
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// gen[0] is the most significant term in the generator,
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// which is always 1.
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// To avoid repeated work, we store various values as
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// lv, not v, where lv = log[v].
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f := rs.f
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lgen := rs.lgen[1:]
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for i := 0; i < len(data); i++ {
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c := p[i]
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if c == 0 {
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continue
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}
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q := p[i+1:]
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exp := f.exp[f.log[c]:]
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for j, lg := range lgen {
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if lg != 255 { // lgen uses 255 for log 0
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q[j] ^= exp[lg]
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}
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}
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}
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copy(check, p[len(data):])
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rs.p = p
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}
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