xs/herradurakex.go

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2018-01-06 15:30:56 +00:00
/* Herradura - a Key exchange scheme in the style of Diffie-Hellman Key Exchange.
Copyright (C) 2017 Omar Alejandro Herrera Reyna
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <https://www.gnu.org/licenses/>.
golang implementation by Russ Magee (rmagee_at_gmail.com) */
package herradurakex
import (
"fmt"
"math/big"
"math/rand"
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"net"
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"time"
)
// This type holds the session state for a key exchange
type HerraduraKEx struct {
intSz, pubSz int
randctx *rand.Rand
a *big.Int
b *big.Int
d, PeerD *big.Int
fa *big.Int
}
//// Returns a new HerraduraKEx struct with default intSz,pubSz
//func New() (h *HerraduraKEx) {
// return New(256, 64)
//}
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// Returns a new HerraduraKEx struct
func New(i int, p int) (h *HerraduraKEx) {
h = new(HerraduraKEx)
if i == 0 {
i = 256
}
if p == 0 {
p = 64
}
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h.intSz = i
h.pubSz = p
h.seed()
h.a = h.rand()
h.b = h.rand()
h.d = h.fscxRevolve(h.a, h.b, h.pubSz)
return h
}
func (h *HerraduraKEx) seed() {
r := rand.New(rand.NewSource(time.Now().UnixNano()))
h.randctx = r
}
func (h *HerraduraKEx) rand() (v *big.Int) {
v = big.NewInt(0)
v.Rand(h.randctx, h.getMax())
return v
}
// Return max value for an n-bit big.Int
func (h *HerraduraKEx) getMax() (v *big.Int) {
v = big.NewInt(0)
var max big.Int
for i := 0; i < h.intSz; i++ {
max.SetBit(v, i, 1)
}
v = &max
return v
}
func (h *HerraduraKEx) bitX(x *big.Int, pos int) (ret int64) {
if pos < 0 {
pos = h.intSz - pos
}
if pos == 0 {
ret = int64(x.Bit(1) ^ x.Bit(0) ^ x.Bit(h.intSz-1))
} else if pos == h.intSz-1 {
ret = int64(x.Bit(0) ^ x.Bit(pos) ^ x.Bit(pos-1))
} else {
ret = int64(x.Bit((pos+1)%h.intSz) ^ x.Bit(pos) ^ x.Bit(pos-1))
}
return ret
}
func (h *HerraduraKEx) bit(up, down *big.Int, posU, posD int) (ret *big.Int) {
return big.NewInt(h.bitX(up, posU) ^ h.bitX(down, posD))
}
func (h *HerraduraKEx) fscx(up, down *big.Int) (result *big.Int) {
result = big.NewInt(0)
for count := 0; count < h.intSz; count++ {
result.Lsh(result, 1)
result.Add(result, h.bit(up, down, count, count))
}
return result
}
// This is the iteration function using the result of the previous iteration as the first
// parameter and the second parameter of the first iteration
func (h *HerraduraKEx) fscxRevolve(x, y *big.Int, passes int) (result *big.Int) {
result = big.NewInt(0)
result = x
for count := 0; count < passes; count++ {
result = h.fscx(result, y)
}
return result
}
func (h *HerraduraKEx) D() *big.Int {
return h.d
}
func (h *HerraduraKEx) FA() {
h.fa = h.fscxRevolve(h.PeerD, h.b, h.intSz-h.pubSz)
h.fa.Xor(h.fa, h.a)
}
func (h *HerraduraKEx) String() string {
return fmt.Sprintf("s:%d p:%d\na:%s\nb:%s\nd:->%s\n<-PeerD:%s\nfa:%s",
h.intSz, h.pubSz,
h.a.Text(16), h.b.Text(16),
h.d.Text(16),
h.PeerD.Text(16),
h.fa.Text(16))
}
/*---------------------------------------------------------------------*/
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type Conn struct {
c net.Conn // which also implements io.Reader, io.Writer, ...
h *HerraduraKEx
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}
// Dial as net.Dial(), but with implicit HKEx PeerD read on connect
func Dial(protocol string, ipport string) (hc *Conn, err error) {
c, err := net.Dial(protocol, ipport)
if err != nil {
return nil, err
}
hc = &Conn{c, New(0, 0)}
// KEx
fmt.Fprintf(c, "0x%s\n", hc.h.d.Text(16))
d := big.NewInt(0)
_, err = fmt.Fscanln(c, d)
if err != nil {
return nil, err
}
hc.h.PeerD = d
fmt.Printf("** D:%s\n", hc.h.d.Text(16))
fmt.Printf("**(c)** peerD:%s\n", hc.h.PeerD.Text(16))
hc.h.FA()
fmt.Printf("**(c)** FA:%s\n", hc.h.fa)
return
}
func (hc *Conn) Close() (err error) {
err = hc.c.Close()
fmt.Println("[Conn Closing]")
return
}
/*---------------------------------------------------------------------*/
type HKExListener struct {
l net.Listener
}
func Listen(protocol string, ipport string) (hl HKExListener, e error) {
l, err := net.Listen(protocol, ipport)
if err != nil {
return HKExListener{nil}, err
}
fmt.Println("[Listening]")
hl.l = l
return
}
func (hl *HKExListener) Close() {
hl.l.Close()
fmt.Println("[Listener Closed]")
}
func (hl *HKExListener) Accept() (hc Conn, err error) {
c, err := hl.l.Accept()
fmt.Println("[Accepted]")
if err != nil {
return Conn{nil, nil}, err
}
hc = Conn{c, New(0, 0)}
d := big.NewInt(0)
_, err = fmt.Fscanln(c, d)
if err != nil {
fmt.Println("[Error]")
return hc, err
}
hc.h.PeerD = d
fmt.Printf("** D:%s\n", hc.h.d.Text(16))
fmt.Printf("**(s)** peerD:%s\n", hc.h.PeerD.Text(16))
hc.h.FA()
fmt.Printf("**(s)** FA:%s\n", hc.h.fa)
// KEx
fmt.Fprintf(c, "0x%s\n", hc.h.d.Text(16))
return
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}
/*---------------------------------------------------------------------*/
func (hc Conn) Read(b []byte) (n int, err error) {
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n, err = hc.c.Read(b)
fmt.Printf("[Decrypting...]\n")
fmt.Printf("[ciphertext:%+v]\n", b[0:n])
for i := 0; i < n; i++ {
//for i, _ := range b {
// FOR TESTING ONLY!! USE REAL CRYPTO HERE
//b[i] ^= byte( hc.h.d.Mod(hc.h.d, big.NewInt(int64(c))).Int64() )
b[i] ^= hc.h.fa.Bytes()[0]
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}
fmt.Printf("[plaintext:%+v]\n", b[0:n])
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return
}
func (hc Conn) Write(b []byte) (n int, err error) {
fmt.Printf("[Encrypting...]\n")
for i, _ := range b {
// FOR TESTING ONLY!! USE REAL CRYPTO HERE
//b[i] ^= byte( hc.h.d.Mod(hc.h.d, big.NewInt(int64(c))).Int64() )
b[i] ^= hc.h.fa.Bytes()[0]
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}
fmt.Printf("[ciphertext:%+v]\n", b)
n, err = hc.c.Write(b)
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return
}
// Return c coerced into a HKEx Conn (which implements interface net.Conn)
// Only useful if one wants to convert an open connection later to HKEx
// (Use Dial() instead to start with HKEx automatically.)
func NewHKExConn(c *net.Conn) (hc *Conn) {
hc = new(Conn)
hc.c = *c
hc.h = New(0, 0)
d := big.NewInt(0)
_, err := fmt.Fscanln(hc.c, d)
if err != nil {
//
}
hc.h.PeerD = d
fmt.Printf("** D:%s\n", hc.h.d.Text(16))
fmt.Printf("** peerD:%s\n", hc.h.PeerD.Text(16))
return
}