mox/vendor/rsc.io/qr/gf256/gf256.go
Mechiel Lukkien 2b97c21f99
make setting up apple mail clients easier by providing .mobileconfig device management profiles
including showing a qr code to easily get the file on iphones.
the profile is currently in the "account" page.

idea by x8x in issue #65
2023-09-23 12:08:35 +02:00

241 lines
5 KiB
Go
Raw Permalink Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

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