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simotlocal.go
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simotlocal.go
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package simot
import (
"crypto/aes"
"crypto/cipher"
"crypto/rand"
"crypto/subtle"
"errors"
"io"
"github.com/cloudflare/circl/group"
"golang.org/x/crypto/sha3"
)
const keyLength = 16
// AES GCM encryption, we don't need to pad because our input is fixed length
// Need to use authenticated encryption to defend against tampering on ciphertext
// Input: key, plaintext message
// Output: ciphertext
func aesEncGCM(key, plaintext []byte) []byte {
block, err := aes.NewCipher(key)
if err != nil {
panic(err)
}
aesgcm, err := cipher.NewGCM(block)
if err != nil {
panic(err.Error())
}
nonce := make([]byte, aesgcm.NonceSize())
if _, err := io.ReadFull(rand.Reader, nonce); err != nil {
panic(err)
}
ciphertext := aesgcm.Seal(nonce, nonce, plaintext, nil)
return ciphertext
}
// AES GCM decryption
// Input: key, ciphertext message
// Output: plaintext
func aesDecGCM(key, ciphertext []byte) ([]byte, error) {
block, err := aes.NewCipher(key)
if err != nil {
panic(err)
}
aesgcm, err := cipher.NewGCM(block)
if err != nil {
panic(err.Error())
}
nonceSize := aesgcm.NonceSize()
if len(ciphertext) < nonceSize {
return nil, errors.New("ciphertext too short")
}
nonce, encryptedMessage := ciphertext[:nonceSize], ciphertext[nonceSize:]
plaintext, err := aesgcm.Open(nil, nonce, encryptedMessage, nil)
return plaintext, err
}
// Initialization
// Input: myGroup, the group we operate in
// Input: m0, m1 the 2 message of the sender
// Input: index, the index of this SimOT
// Output: A = [a]G, a the sender randomness
func (sender *Sender) InitSender(myGroup group.Group, m0, m1 []byte, index int) group.Element {
sender.a = myGroup.RandomNonZeroScalar(rand.Reader)
sender.k0 = make([]byte, keyLength)
sender.k1 = make([]byte, keyLength)
sender.m0 = m0
sender.m1 = m1
sender.index = index
sender.A = myGroup.NewElement()
sender.A.MulGen(sender.a)
sender.myGroup = myGroup
return sender.A.Copy()
}
// Round 1
// ---- sender should send A to receiver ----
// Input: myGroup, the group we operate in
// Input: choice, the receiver choice bit
// Input: index, the index of this SimOT
// Input: A, from sender
// Output: B = [b]G if c == 0, B = A+[b]G if c == 1 (Implementation in constant time). b, the receiver randomness
func (receiver *Receiver) Round1Receiver(myGroup group.Group, choice int, index int, A group.Element) group.Element {
receiver.b = myGroup.RandomNonZeroScalar(rand.Reader)
receiver.c = choice
receiver.kR = make([]byte, keyLength)
receiver.index = index
receiver.A = A
receiver.myGroup = myGroup
bG := myGroup.NewElement()
bG.MulGen(receiver.b)
AorI := myGroup.NewElement()
AorI.CMov(choice, A)
receiver.B = myGroup.NewElement()
receiver.B.Add(bG, AorI)
return receiver.B.Copy()
}
// Round 2
// ---- receiver should send B to sender ----
// Input: B from the receiver
// Output: e0, e1, encryption of m0 and m1 under key k0, k1
func (sender *Sender) Round2Sender(B group.Element) ([]byte, []byte) {
sender.B = B
aB := sender.myGroup.NewElement()
aB.Mul(sender.B, sender.a)
maA := sender.myGroup.NewElement()
maA.Mul(sender.A, sender.a)
maA.Neg(maA)
aBaA := sender.myGroup.NewElement()
aBaA.Add(aB, maA)
// Hash the whole transcript A|B|...
AByte, errByte := sender.A.MarshalBinary()
if errByte != nil {
panic(errByte)
}
BByte, errByte := sender.B.MarshalBinary()
if errByte != nil {
panic(errByte)
}
aBByte, errByte := aB.MarshalBinary()
if errByte != nil {
panic(errByte)
}
hashByte0 := append(AByte, BByte...)
hashByte0 = append(hashByte0, aBByte...)
s := sha3.NewShake128()
_, errWrite := s.Write(hashByte0)
if errWrite != nil {
panic(errWrite)
}
_, errRead := s.Read(sender.k0)
if errRead != nil {
panic(errRead)
}
aBaAByte, errByte := aBaA.MarshalBinary()
if errByte != nil {
panic(errByte)
}
hashByte1 := append(AByte, BByte...)
hashByte1 = append(hashByte1, aBaAByte...)
s = sha3.NewShake128()
_, errWrite = s.Write(hashByte1)
if errWrite != nil {
panic(errWrite)
}
_, errRead = s.Read(sender.k1)
if errRead != nil {
panic(errRead)
}
e0 := aesEncGCM(sender.k0, sender.m0)
sender.e0 = e0
e1 := aesEncGCM(sender.k1, sender.m1)
sender.e1 = e1
return sender.e0, sender.e1
}
// Round 3
// ---- sender should send e0, e1 to receiver ----
// Input: e0, e1: encryption of m0 and m1 from the sender
// Input: choice, choice bit of receiver
// Choose e0 or e1 based on choice bit in constant time
func (receiver *Receiver) Round3Receiver(e0, e1 []byte, choice int) error {
receiver.ec = make([]byte, len(e1))
// If c == 1, copy e1
subtle.ConstantTimeCopy(choice, receiver.ec, e1)
// If c == 0, copy e0
subtle.ConstantTimeCopy(1-choice, receiver.ec, e0)
AByte, errByte := receiver.A.MarshalBinary()
if errByte != nil {
panic(errByte)
}
BByte, errByte := receiver.B.MarshalBinary()
if errByte != nil {
panic(errByte)
}
bA := receiver.myGroup.NewElement()
bA.Mul(receiver.A, receiver.b)
bAByte, errByte := bA.MarshalBinary()
if errByte != nil {
panic(errByte)
}
// Hash the whole transcript so far
hashByte := append(AByte, BByte...)
hashByte = append(hashByte, bAByte...)
s := sha3.NewShake128()
_, errWrite := s.Write(hashByte)
if errWrite != nil {
panic(errWrite)
}
_, errRead := s.Read(receiver.kR) // kR, decryption key of mc
if errRead != nil {
panic(errRead)
}
mc, errDec := aesDecGCM(receiver.kR, receiver.ec)
if errDec != nil {
return errDec
}
receiver.mc = mc
return nil
}
func (receiver *Receiver) Returnmc() []byte {
return receiver.mc
}
func (sender *Sender) Returne0e1() ([]byte, []byte) {
return sender.e0, sender.e1
}
func (sender *Sender) Returnm0m1() ([]byte, []byte) {
return sender.m0, sender.m1
}