use {
crate::{
encryption::{
discrete_log::DiscreteLog,
pedersen::{
Pedersen, PedersenCommitment, PedersenOpening, G, H, PEDERSEN_COMMITMENT_LEN,
},
},
RISTRETTO_POINT_LEN, SCALAR_LEN,
},
base64::{prelude::BASE64_STANDARD, Engine},
core::ops::{Add, Mul, Sub},
curve25519_dalek::{
ristretto::{CompressedRistretto, RistrettoPoint},
scalar::Scalar,
traits::Identity,
},
serde::{Deserialize, Serialize},
solana_sdk::{
derivation_path::DerivationPath,
signature::Signature,
signer::{
keypair::generate_seed_from_seed_phrase_and_passphrase, EncodableKey, EncodableKeypair,
SeedDerivable, Signer, SignerError,
},
},
std::convert::TryInto,
subtle::{Choice, ConstantTimeEq},
thiserror::Error,
zeroize::Zeroize,
};
#[cfg(not(target_os = "solana"))]
use {
rand::rngs::OsRng,
sha3::{Digest, Sha3_512},
std::{
error, fmt,
io::{Read, Write},
path::Path,
},
};
const DECRYPT_HANDLE_LEN: usize = RISTRETTO_POINT_LEN;
const ELGAMAL_CIPHERTEXT_LEN: usize = PEDERSEN_COMMITMENT_LEN + DECRYPT_HANDLE_LEN;
const ELGAMAL_PUBKEY_LEN: usize = RISTRETTO_POINT_LEN;
const ELGAMAL_SECRET_KEY_LEN: usize = SCALAR_LEN;
const ELGAMAL_KEYPAIR_LEN: usize = ELGAMAL_PUBKEY_LEN + ELGAMAL_SECRET_KEY_LEN;
#[derive(Error, Clone, Debug, Eq, PartialEq)]
pub enum ElGamalError {
#[error("key derivation method not supported")]
DerivationMethodNotSupported,
#[error("seed length too short for derivation")]
SeedLengthTooShort,
#[error("seed length too long for derivation")]
SeedLengthTooLong,
#[error("failed to deserialize ciphertext")]
CiphertextDeserialization,
#[error("failed to deserialize public key")]
PubkeyDeserialization,
}
pub struct ElGamal;
impl ElGamal {
#[cfg(not(target_os = "solana"))]
#[allow(non_snake_case)]
fn keygen() -> ElGamalKeypair {
let mut s = Scalar::random(&mut OsRng);
let keypair = Self::keygen_with_scalar(&s);
s.zeroize();
keypair
}
#[cfg(not(target_os = "solana"))]
#[allow(non_snake_case)]
fn keygen_with_scalar(s: &Scalar) -> ElGamalKeypair {
let secret = ElGamalSecretKey(*s);
let public = ElGamalPubkey::new(&secret);
ElGamalKeypair { public, secret }
}
#[cfg(not(target_os = "solana"))]
fn encrypt<T: Into<Scalar>>(public: &ElGamalPubkey, amount: T) -> ElGamalCiphertext {
let (commitment, opening) = Pedersen::new(amount);
let handle = public.decrypt_handle(&opening);
ElGamalCiphertext { commitment, handle }
}
#[cfg(not(target_os = "solana"))]
fn encrypt_with<T: Into<Scalar>>(
amount: T,
public: &ElGamalPubkey,
opening: &PedersenOpening,
) -> ElGamalCiphertext {
let commitment = Pedersen::with(amount, opening);
let handle = public.decrypt_handle(opening);
ElGamalCiphertext { commitment, handle }
}
#[cfg(not(target_os = "solana"))]
pub fn encode<T: Into<Scalar>>(amount: T) -> ElGamalCiphertext {
let commitment = Pedersen::encode(amount);
let handle = DecryptHandle(RistrettoPoint::identity());
ElGamalCiphertext { commitment, handle }
}
#[cfg(not(target_os = "solana"))]
fn decrypt(secret: &ElGamalSecretKey, ciphertext: &ElGamalCiphertext) -> DiscreteLog {
DiscreteLog::new(
*G,
ciphertext.commitment.get_point() - &(&secret.0 * &ciphertext.handle.0),
)
}
#[cfg(not(target_os = "solana"))]
fn decrypt_u32(secret: &ElGamalSecretKey, ciphertext: &ElGamalCiphertext) -> Option<u64> {
let discrete_log_instance = Self::decrypt(secret, ciphertext);
discrete_log_instance.decode_u32()
}
}
#[derive(Clone, Debug, Deserialize, PartialEq, Eq, Serialize, Zeroize)]
pub struct ElGamalKeypair {
public: ElGamalPubkey,
secret: ElGamalSecretKey,
}
impl ElGamalKeypair {
pub fn new_for_tests(public: ElGamalPubkey, secret: ElGamalSecretKey) -> Self {
Self { public, secret }
}
#[cfg(not(target_os = "solana"))]
#[allow(non_snake_case)]
pub fn new_from_signer(
signer: &dyn Signer,
public_seed: &[u8],
) -> Result<Self, Box<dyn error::Error>> {
let secret = ElGamalSecretKey::new_from_signer(signer, public_seed)?;
let public = ElGamalPubkey::new(&secret);
Ok(ElGamalKeypair { public, secret })
}
#[cfg(not(target_os = "solana"))]
pub fn new_rand() -> Self {
ElGamal::keygen()
}
pub fn pubkey(&self) -> &ElGamalPubkey {
&self.public
}
pub fn secret(&self) -> &ElGamalSecretKey {
&self.secret
}
pub fn to_bytes(&self) -> [u8; ELGAMAL_KEYPAIR_LEN] {
let mut bytes = [0u8; ELGAMAL_KEYPAIR_LEN];
bytes[..ELGAMAL_PUBKEY_LEN].copy_from_slice(&self.public.to_bytes());
bytes[ELGAMAL_PUBKEY_LEN..].copy_from_slice(self.secret.as_bytes());
bytes
}
pub fn from_bytes(bytes: &[u8]) -> Option<Self> {
if bytes.len() != ELGAMAL_KEYPAIR_LEN {
return None;
}
Some(Self {
public: ElGamalPubkey::from_bytes(&bytes[..ELGAMAL_PUBKEY_LEN])?,
secret: ElGamalSecretKey::from_bytes(bytes[ELGAMAL_PUBKEY_LEN..].try_into().ok()?)?,
})
}
pub fn read_json<R: Read>(reader: &mut R) -> Result<Self, Box<dyn error::Error>> {
let bytes: Vec<u8> = serde_json::from_reader(reader)?;
Self::from_bytes(&bytes).ok_or_else(|| {
std::io::Error::new(std::io::ErrorKind::Other, "Invalid ElGamalKeypair").into()
})
}
pub fn read_json_file<F: AsRef<Path>>(path: F) -> Result<Self, Box<dyn error::Error>> {
Self::read_from_file(path)
}
pub fn write_json<W: Write>(&self, writer: &mut W) -> Result<String, Box<dyn error::Error>> {
let bytes = self.to_bytes();
let json = serde_json::to_string(&bytes.to_vec())?;
writer.write_all(&json.clone().into_bytes())?;
Ok(json)
}
pub fn write_json_file<F: AsRef<Path>>(
&self,
outfile: F,
) -> Result<String, Box<dyn std::error::Error>> {
self.write_to_file(outfile)
}
}
impl EncodableKey for ElGamalKeypair {
fn read<R: Read>(reader: &mut R) -> Result<Self, Box<dyn error::Error>> {
Self::read_json(reader)
}
fn write<W: Write>(&self, writer: &mut W) -> Result<String, Box<dyn error::Error>> {
self.write_json(writer)
}
}
impl SeedDerivable for ElGamalKeypair {
fn from_seed(seed: &[u8]) -> Result<Self, Box<dyn error::Error>> {
let secret = ElGamalSecretKey::from_seed(seed)?;
let public = ElGamalPubkey::new(&secret);
Ok(ElGamalKeypair { public, secret })
}
fn from_seed_and_derivation_path(
_seed: &[u8],
_derivation_path: Option<DerivationPath>,
) -> Result<Self, Box<dyn error::Error>> {
Err(ElGamalError::DerivationMethodNotSupported.into())
}
fn from_seed_phrase_and_passphrase(
seed_phrase: &str,
passphrase: &str,
) -> Result<Self, Box<dyn error::Error>> {
Self::from_seed(&generate_seed_from_seed_phrase_and_passphrase(
seed_phrase,
passphrase,
))
}
}
impl EncodableKeypair for ElGamalKeypair {
type Pubkey = ElGamalPubkey;
fn encodable_pubkey(&self) -> Self::Pubkey {
self.public
}
}
#[derive(Clone, Copy, Debug, Default, Deserialize, Eq, PartialEq, Serialize, Zeroize)]
pub struct ElGamalPubkey(RistrettoPoint);
impl ElGamalPubkey {
#[allow(non_snake_case)]
pub fn new(secret: &ElGamalSecretKey) -> Self {
let s = &secret.0;
assert!(s != &Scalar::zero());
ElGamalPubkey(s.invert() * &(*H))
}
pub fn get_point(&self) -> &RistrettoPoint {
&self.0
}
pub fn to_bytes(&self) -> [u8; ELGAMAL_PUBKEY_LEN] {
self.0.compress().to_bytes()
}
pub fn from_bytes(bytes: &[u8]) -> Option<ElGamalPubkey> {
if bytes.len() != ELGAMAL_PUBKEY_LEN {
return None;
}
Some(ElGamalPubkey(
CompressedRistretto::from_slice(bytes).decompress()?,
))
}
#[cfg(not(target_os = "solana"))]
pub fn encrypt<T: Into<Scalar>>(&self, amount: T) -> ElGamalCiphertext {
ElGamal::encrypt(self, amount)
}
pub fn encrypt_with<T: Into<Scalar>>(
&self,
amount: T,
opening: &PedersenOpening,
) -> ElGamalCiphertext {
ElGamal::encrypt_with(amount, self, opening)
}
pub fn decrypt_handle(self, opening: &PedersenOpening) -> DecryptHandle {
DecryptHandle::new(&self, opening)
}
}
impl EncodableKey for ElGamalPubkey {
fn read<R: Read>(reader: &mut R) -> Result<Self, Box<dyn error::Error>> {
let bytes: Vec<u8> = serde_json::from_reader(reader)?;
Self::from_bytes(&bytes).ok_or_else(|| {
std::io::Error::new(std::io::ErrorKind::Other, "Invalid ElGamalPubkey").into()
})
}
fn write<W: Write>(&self, writer: &mut W) -> Result<String, Box<dyn error::Error>> {
let bytes = self.to_bytes();
let json = serde_json::to_string(&bytes.to_vec())?;
writer.write_all(&json.clone().into_bytes())?;
Ok(json)
}
}
impl fmt::Display for ElGamalPubkey {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(f, "{}", BASE64_STANDARD.encode(self.to_bytes()))
}
}
#[derive(Clone, Debug, Deserialize, Serialize, Zeroize)]
#[zeroize(drop)]
pub struct ElGamalSecretKey(Scalar);
impl ElGamalSecretKey {
pub fn new_from_signer(
signer: &dyn Signer,
public_seed: &[u8],
) -> Result<Self, Box<dyn error::Error>> {
let seed = Self::seed_from_signer(signer, public_seed)?;
let key = Self::from_seed(&seed)?;
Ok(key)
}
pub fn seed_from_signer(
signer: &dyn Signer,
public_seed: &[u8],
) -> Result<Vec<u8>, SignerError> {
let message = [b"ElGamalSecretKey", public_seed].concat();
let signature = signer.try_sign_message(&message)?;
if bool::from(signature.as_ref().ct_eq(Signature::default().as_ref())) {
return Err(SignerError::Custom("Rejecting default signatures".into()));
}
let mut hasher = Sha3_512::new();
hasher.update(signature.as_ref());
let result = hasher.finalize();
Ok(result.to_vec())
}
pub fn new_rand() -> Self {
ElGamalSecretKey(Scalar::random(&mut OsRng))
}
pub fn from_seed(seed: &[u8]) -> Result<Self, ElGamalError> {
const MINIMUM_SEED_LEN: usize = ELGAMAL_SECRET_KEY_LEN;
const MAXIMUM_SEED_LEN: usize = 65535;
if seed.len() < MINIMUM_SEED_LEN {
return Err(ElGamalError::SeedLengthTooShort);
}
if seed.len() > MAXIMUM_SEED_LEN {
return Err(ElGamalError::SeedLengthTooLong);
}
Ok(ElGamalSecretKey(Scalar::hash_from_bytes::<Sha3_512>(seed)))
}
pub fn get_scalar(&self) -> &Scalar {
&self.0
}
pub fn decrypt(&self, ciphertext: &ElGamalCiphertext) -> DiscreteLog {
ElGamal::decrypt(self, ciphertext)
}
pub fn decrypt_u32(&self, ciphertext: &ElGamalCiphertext) -> Option<u64> {
ElGamal::decrypt_u32(self, ciphertext)
}
pub fn as_bytes(&self) -> &[u8; ELGAMAL_SECRET_KEY_LEN] {
self.0.as_bytes()
}
pub fn to_bytes(&self) -> [u8; ELGAMAL_SECRET_KEY_LEN] {
self.0.to_bytes()
}
pub fn from_bytes(bytes: &[u8]) -> Option<ElGamalSecretKey> {
match bytes.try_into() {
Ok(bytes) => Scalar::from_canonical_bytes(bytes).map(ElGamalSecretKey),
_ => None,
}
}
}
impl EncodableKey for ElGamalSecretKey {
fn read<R: Read>(reader: &mut R) -> Result<Self, Box<dyn error::Error>> {
let bytes: Vec<u8> = serde_json::from_reader(reader)?;
Self::from_bytes(&bytes).ok_or_else(|| {
std::io::Error::new(std::io::ErrorKind::Other, "Invalid ElGamalSecretKey").into()
})
}
fn write<W: Write>(&self, writer: &mut W) -> Result<String, Box<dyn error::Error>> {
let bytes = self.to_bytes();
let json = serde_json::to_string(&bytes.to_vec())?;
writer.write_all(&json.clone().into_bytes())?;
Ok(json)
}
}
impl SeedDerivable for ElGamalSecretKey {
fn from_seed(seed: &[u8]) -> Result<Self, Box<dyn error::Error>> {
let key = Self::from_seed(seed)?;
Ok(key)
}
fn from_seed_and_derivation_path(
_seed: &[u8],
_derivation_path: Option<DerivationPath>,
) -> Result<Self, Box<dyn error::Error>> {
Err(ElGamalError::DerivationMethodNotSupported.into())
}
fn from_seed_phrase_and_passphrase(
seed_phrase: &str,
passphrase: &str,
) -> Result<Self, Box<dyn error::Error>> {
let key = Self::from_seed(&generate_seed_from_seed_phrase_and_passphrase(
seed_phrase,
passphrase,
))?;
Ok(key)
}
}
impl From<Scalar> for ElGamalSecretKey {
fn from(scalar: Scalar) -> ElGamalSecretKey {
ElGamalSecretKey(scalar)
}
}
impl Eq for ElGamalSecretKey {}
impl PartialEq for ElGamalSecretKey {
fn eq(&self, other: &Self) -> bool {
self.ct_eq(other).unwrap_u8() == 1u8
}
}
impl ConstantTimeEq for ElGamalSecretKey {
fn ct_eq(&self, other: &Self) -> Choice {
self.0.ct_eq(&other.0)
}
}
#[allow(non_snake_case)]
#[derive(Clone, Copy, Debug, Default, Deserialize, Eq, PartialEq, Serialize)]
pub struct ElGamalCiphertext {
pub commitment: PedersenCommitment,
pub handle: DecryptHandle,
}
impl ElGamalCiphertext {
pub fn add_amount<T: Into<Scalar>>(&self, amount: T) -> Self {
let point = amount.into() * &(*G);
let commitment_to_add = PedersenCommitment::new(point);
ElGamalCiphertext {
commitment: &self.commitment + &commitment_to_add,
handle: self.handle,
}
}
pub fn subtract_amount<T: Into<Scalar>>(&self, amount: T) -> Self {
let point = amount.into() * &(*G);
let commitment_to_subtract = PedersenCommitment::new(point);
ElGamalCiphertext {
commitment: &self.commitment - &commitment_to_subtract,
handle: self.handle,
}
}
pub fn to_bytes(&self) -> [u8; ELGAMAL_CIPHERTEXT_LEN] {
let mut bytes = [0u8; ELGAMAL_CIPHERTEXT_LEN];
bytes[..PEDERSEN_COMMITMENT_LEN].copy_from_slice(&self.commitment.to_bytes());
bytes[PEDERSEN_COMMITMENT_LEN..].copy_from_slice(&self.handle.to_bytes());
bytes
}
pub fn from_bytes(bytes: &[u8]) -> Option<ElGamalCiphertext> {
if bytes.len() != ELGAMAL_CIPHERTEXT_LEN {
return None;
}
Some(ElGamalCiphertext {
commitment: PedersenCommitment::from_bytes(&bytes[..PEDERSEN_COMMITMENT_LEN])?,
handle: DecryptHandle::from_bytes(&bytes[PEDERSEN_COMMITMENT_LEN..])?,
})
}
pub fn decrypt(&self, secret: &ElGamalSecretKey) -> DiscreteLog {
ElGamal::decrypt(secret, self)
}
pub fn decrypt_u32(&self, secret: &ElGamalSecretKey) -> Option<u64> {
ElGamal::decrypt_u32(secret, self)
}
}
impl fmt::Display for ElGamalCiphertext {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(f, "{}", BASE64_STANDARD.encode(self.to_bytes()))
}
}
impl<'a, 'b> Add<&'b ElGamalCiphertext> for &'a ElGamalCiphertext {
type Output = ElGamalCiphertext;
fn add(self, ciphertext: &'b ElGamalCiphertext) -> ElGamalCiphertext {
ElGamalCiphertext {
commitment: &self.commitment + &ciphertext.commitment,
handle: &self.handle + &ciphertext.handle,
}
}
}
define_add_variants!(
LHS = ElGamalCiphertext,
RHS = ElGamalCiphertext,
Output = ElGamalCiphertext
);
impl<'a, 'b> Sub<&'b ElGamalCiphertext> for &'a ElGamalCiphertext {
type Output = ElGamalCiphertext;
fn sub(self, ciphertext: &'b ElGamalCiphertext) -> ElGamalCiphertext {
ElGamalCiphertext {
commitment: &self.commitment - &ciphertext.commitment,
handle: &self.handle - &ciphertext.handle,
}
}
}
define_sub_variants!(
LHS = ElGamalCiphertext,
RHS = ElGamalCiphertext,
Output = ElGamalCiphertext
);
impl<'a, 'b> Mul<&'b Scalar> for &'a ElGamalCiphertext {
type Output = ElGamalCiphertext;
fn mul(self, scalar: &'b Scalar) -> ElGamalCiphertext {
ElGamalCiphertext {
commitment: &self.commitment * scalar,
handle: &self.handle * scalar,
}
}
}
define_mul_variants!(
LHS = ElGamalCiphertext,
RHS = Scalar,
Output = ElGamalCiphertext
);
impl<'a, 'b> Mul<&'b ElGamalCiphertext> for &'a Scalar {
type Output = ElGamalCiphertext;
fn mul(self, ciphertext: &'b ElGamalCiphertext) -> ElGamalCiphertext {
ElGamalCiphertext {
commitment: self * &ciphertext.commitment,
handle: self * &ciphertext.handle,
}
}
}
define_mul_variants!(
LHS = Scalar,
RHS = ElGamalCiphertext,
Output = ElGamalCiphertext
);
#[derive(Clone, Copy, Debug, Default, Deserialize, Eq, PartialEq, Serialize)]
pub struct DecryptHandle(RistrettoPoint);
impl DecryptHandle {
pub fn new(public: &ElGamalPubkey, opening: &PedersenOpening) -> Self {
Self(&public.0 * opening.get_scalar())
}
pub fn get_point(&self) -> &RistrettoPoint {
&self.0
}
pub fn to_bytes(&self) -> [u8; DECRYPT_HANDLE_LEN] {
self.0.compress().to_bytes()
}
pub fn from_bytes(bytes: &[u8]) -> Option<DecryptHandle> {
if bytes.len() != DECRYPT_HANDLE_LEN {
return None;
}
Some(DecryptHandle(
CompressedRistretto::from_slice(bytes).decompress()?,
))
}
}
impl<'a, 'b> Add<&'b DecryptHandle> for &'a DecryptHandle {
type Output = DecryptHandle;
fn add(self, handle: &'b DecryptHandle) -> DecryptHandle {
DecryptHandle(&self.0 + &handle.0)
}
}
define_add_variants!(
LHS = DecryptHandle,
RHS = DecryptHandle,
Output = DecryptHandle
);
impl<'a, 'b> Sub<&'b DecryptHandle> for &'a DecryptHandle {
type Output = DecryptHandle;
fn sub(self, handle: &'b DecryptHandle) -> DecryptHandle {
DecryptHandle(&self.0 - &handle.0)
}
}
define_sub_variants!(
LHS = DecryptHandle,
RHS = DecryptHandle,
Output = DecryptHandle
);
impl<'a, 'b> Mul<&'b Scalar> for &'a DecryptHandle {
type Output = DecryptHandle;
fn mul(self, scalar: &'b Scalar) -> DecryptHandle {
DecryptHandle(&self.0 * scalar)
}
}
define_mul_variants!(LHS = DecryptHandle, RHS = Scalar, Output = DecryptHandle);
impl<'a, 'b> Mul<&'b DecryptHandle> for &'a Scalar {
type Output = DecryptHandle;
fn mul(self, handle: &'b DecryptHandle) -> DecryptHandle {
DecryptHandle(self * &handle.0)
}
}
define_mul_variants!(LHS = Scalar, RHS = DecryptHandle, Output = DecryptHandle);
#[cfg(test)]
mod tests {
use {
super::*,
crate::encryption::pedersen::Pedersen,
bip39::{Language, Mnemonic, MnemonicType, Seed},
solana_sdk::{pubkey::Pubkey, signature::Keypair, signer::null_signer::NullSigner},
std::fs::{self, File},
};
#[test]
fn test_encrypt_decrypt_correctness() {
let ElGamalKeypair { public, secret } = ElGamalKeypair::new_rand();
let amount: u32 = 57;
let ciphertext = ElGamal::encrypt(&public, amount);
let expected_instance = DiscreteLog::new(*G, Scalar::from(amount) * &(*G));
assert_eq!(expected_instance, ElGamal::decrypt(&secret, &ciphertext));
assert_eq!(57_u64, secret.decrypt_u32(&ciphertext).unwrap());
}
#[test]
fn test_encrypt_decrypt_correctness_multithreaded() {
let ElGamalKeypair { public, secret } = ElGamalKeypair::new_rand();
let amount: u32 = 57;
let ciphertext = ElGamal::encrypt(&public, amount);
let mut instance = ElGamal::decrypt(&secret, &ciphertext);
instance.num_threads(4).unwrap();
assert_eq!(57_u64, instance.decode_u32().unwrap());
}
#[test]
fn test_decrypt_handle() {
let ElGamalKeypair {
public: public_0,
secret: secret_0,
} = ElGamalKeypair::new_rand();
let ElGamalKeypair {
public: public_1,
secret: secret_1,
} = ElGamalKeypair::new_rand();
let amount: u32 = 77;
let (commitment, opening) = Pedersen::new(amount);
let handle_0 = public_0.decrypt_handle(&opening);
let handle_1 = public_1.decrypt_handle(&opening);
let ciphertext_0 = ElGamalCiphertext {
commitment,
handle: handle_0,
};
let ciphertext_1 = ElGamalCiphertext {
commitment,
handle: handle_1,
};
let expected_instance = DiscreteLog::new(*G, Scalar::from(amount) * &(*G));
assert_eq!(expected_instance, secret_0.decrypt(&ciphertext_0));
assert_eq!(expected_instance, secret_1.decrypt(&ciphertext_1));
}
#[test]
fn test_homomorphic_addition() {
let ElGamalKeypair { public, secret: _ } = ElGamalKeypair::new_rand();
let amount_0: u64 = 57;
let amount_1: u64 = 77;
let opening_0 = PedersenOpening::new_rand();
let opening_1 = PedersenOpening::new_rand();
let ciphertext_0 = ElGamal::encrypt_with(amount_0, &public, &opening_0);
let ciphertext_1 = ElGamal::encrypt_with(amount_1, &public, &opening_1);
let ciphertext_sum =
ElGamal::encrypt_with(amount_0 + amount_1, &public, &(&opening_0 + &opening_1));
assert_eq!(ciphertext_sum, ciphertext_0 + ciphertext_1);
let opening = PedersenOpening::new_rand();
let ciphertext = ElGamal::encrypt_with(amount_0, &public, &opening);
let ciphertext_sum = ElGamal::encrypt_with(amount_0 + amount_1, &public, &opening);
assert_eq!(ciphertext_sum, ciphertext.add_amount(amount_1));
}
#[test]
fn test_homomorphic_subtraction() {
let ElGamalKeypair { public, secret: _ } = ElGamalKeypair::new_rand();
let amount_0: u64 = 77;
let amount_1: u64 = 55;
let opening_0 = PedersenOpening::new_rand();
let opening_1 = PedersenOpening::new_rand();
let ciphertext_0 = ElGamal::encrypt_with(amount_0, &public, &opening_0);
let ciphertext_1 = ElGamal::encrypt_with(amount_1, &public, &opening_1);
let ciphertext_sub =
ElGamal::encrypt_with(amount_0 - amount_1, &public, &(&opening_0 - &opening_1));
assert_eq!(ciphertext_sub, ciphertext_0 - ciphertext_1);
let opening = PedersenOpening::new_rand();
let ciphertext = ElGamal::encrypt_with(amount_0, &public, &opening);
let ciphertext_sub = ElGamal::encrypt_with(amount_0 - amount_1, &public, &opening);
assert_eq!(ciphertext_sub, ciphertext.subtract_amount(amount_1));
}
#[test]
fn test_homomorphic_multiplication() {
let ElGamalKeypair { public, secret: _ } = ElGamalKeypair::new_rand();
let amount_0: u64 = 57;
let amount_1: u64 = 77;
let opening = PedersenOpening::new_rand();
let ciphertext = ElGamal::encrypt_with(amount_0, &public, &opening);
let scalar = Scalar::from(amount_1);
let ciphertext_prod =
ElGamal::encrypt_with(amount_0 * amount_1, &public, &(&opening * scalar));
assert_eq!(ciphertext_prod, ciphertext * scalar);
assert_eq!(ciphertext_prod, scalar * ciphertext);
}
#[test]
fn test_serde_ciphertext() {
let ElGamalKeypair { public, secret: _ } = ElGamalKeypair::new_rand();
let amount: u64 = 77;
let ciphertext = public.encrypt(amount);
let encoded = bincode::serialize(&ciphertext).unwrap();
let decoded: ElGamalCiphertext = bincode::deserialize(&encoded).unwrap();
assert_eq!(ciphertext, decoded);
}
#[test]
fn test_serde_pubkey() {
let ElGamalKeypair { public, secret: _ } = ElGamalKeypair::new_rand();
let encoded = bincode::serialize(&public).unwrap();
let decoded: ElGamalPubkey = bincode::deserialize(&encoded).unwrap();
assert_eq!(public, decoded);
}
#[test]
fn test_serde_secretkey() {
let ElGamalKeypair { public: _, secret } = ElGamalKeypair::new_rand();
let encoded = bincode::serialize(&secret).unwrap();
let decoded: ElGamalSecretKey = bincode::deserialize(&encoded).unwrap();
assert_eq!(secret, decoded);
}
fn tmp_file_path(name: &str) -> String {
use std::env;
let out_dir = env::var("FARF_DIR").unwrap_or_else(|_| "farf".to_string());
let keypair = ElGamalKeypair::new_rand();
format!("{}/tmp/{}-{}", out_dir, name, keypair.public)
}
#[test]
fn test_write_keypair_file() {
let outfile = tmp_file_path("test_write_keypair_file.json");
let serialized_keypair = ElGamalKeypair::new_rand()
.write_json_file(&outfile)
.unwrap();
let keypair_vec: Vec<u8> = serde_json::from_str(&serialized_keypair).unwrap();
assert!(Path::new(&outfile).exists());
assert_eq!(
keypair_vec,
ElGamalKeypair::read_json_file(&outfile)
.unwrap()
.to_bytes()
.to_vec()
);
#[cfg(unix)]
{
use std::os::unix::fs::PermissionsExt;
assert_eq!(
File::open(&outfile)
.expect("open")
.metadata()
.expect("metadata")
.permissions()
.mode()
& 0o777,
0o600
);
}
fs::remove_file(&outfile).unwrap();
}
#[test]
fn test_write_keypair_file_overwrite_ok() {
let outfile = tmp_file_path("test_write_keypair_file_overwrite_ok.json");
ElGamalKeypair::new_rand()
.write_json_file(&outfile)
.unwrap();
ElGamalKeypair::new_rand()
.write_json_file(&outfile)
.unwrap();
}
#[test]
fn test_write_keypair_file_truncate() {
let outfile = tmp_file_path("test_write_keypair_file_truncate.json");
ElGamalKeypair::new_rand()
.write_json_file(&outfile)
.unwrap();
ElGamalKeypair::read_json_file(&outfile).unwrap();
{
let mut f = File::create(&outfile).unwrap();
f.write_all(String::from_utf8([b'a'; 2048].to_vec()).unwrap().as_bytes())
.unwrap();
}
ElGamalKeypair::new_rand()
.write_json_file(&outfile)
.unwrap();
ElGamalKeypair::read_json_file(&outfile).unwrap();
}
#[test]
fn test_secret_key_new_from_signer() {
let keypair1 = Keypair::new();
let keypair2 = Keypair::new();
assert_ne!(
ElGamalSecretKey::new_from_signer(&keypair1, Pubkey::default().as_ref())
.unwrap()
.0,
ElGamalSecretKey::new_from_signer(&keypair2, Pubkey::default().as_ref())
.unwrap()
.0,
);
let null_signer = NullSigner::new(&Pubkey::default());
assert!(
ElGamalSecretKey::new_from_signer(&null_signer, Pubkey::default().as_ref()).is_err()
);
}
#[test]
fn test_keypair_from_seed() {
let good_seed = vec![0; 32];
assert!(ElGamalKeypair::from_seed(&good_seed).is_ok());
let too_short_seed = vec![0; 31];
assert!(ElGamalKeypair::from_seed(&too_short_seed).is_err());
let too_long_seed = vec![0; 65536];
assert!(ElGamalKeypair::from_seed(&too_long_seed).is_err());
}
#[test]
fn test_keypair_from_seed_phrase_and_passphrase() {
let mnemonic = Mnemonic::new(MnemonicType::Words12, Language::English);
let passphrase = "42";
let seed = Seed::new(&mnemonic, passphrase);
let expected_keypair = ElGamalKeypair::from_seed(seed.as_bytes()).unwrap();
let keypair =
ElGamalKeypair::from_seed_phrase_and_passphrase(mnemonic.phrase(), passphrase).unwrap();
assert_eq!(keypair.public, expected_keypair.public);
}
#[test]
fn test_decrypt_handle_bytes() {
let handle = DecryptHandle(RistrettoPoint::default());
let encoded = handle.to_bytes();
let decoded = DecryptHandle::from_bytes(&encoded).unwrap();
assert_eq!(handle, decoded);
}
#[test]
fn test_serde_decrypt_handle() {
let handle = DecryptHandle(RistrettoPoint::default());
let encoded = bincode::serialize(&handle).unwrap();
let decoded: DecryptHandle = bincode::deserialize(&encoded).unwrap();
assert_eq!(handle, decoded);
}
}