vpncloud/src/crypto.rs

255 lines
9.2 KiB
Rust

// VpnCloud - Peer-to-Peer VPN
// Copyright (C) 2015-2020 Dennis Schwerdel
// This software is licensed under GPL-3 or newer (see LICENSE.md)
use std::{num::NonZeroU32, str::FromStr};
use ring::{aead::*, pbkdf2, rand::*};
use super::types::Error;
const SALT: &[u8; 32] = b"vpncloudVPNCLOUDvpncl0udVpnCloud";
const HEX_PREFIX: &str = "hex:";
const HASH_PREFIX: &str = "hash:";
#[derive(Serialize, Deserialize, Debug, PartialEq, Clone, Copy)]
pub enum CryptoMethod {
#[serde(rename = "chacha20")]
ChaCha20,
#[serde(rename = "aes256")]
AES256,
#[serde(rename = "aes128")]
AES128
}
impl FromStr for CryptoMethod {
type Err = &'static str;
fn from_str(text: &str) -> Result<Self, Self::Err> {
Ok(match &text.to_lowercase() as &str {
"chacha20" | "chacha" => Self::ChaCha20,
"aes256" => Self::AES256,
"aes128" | "aes" => Self::AES128,
_ => return Err("Unknown method")
})
}
}
pub struct CryptoData {
crypto_key: LessSafeKey,
nonce: Vec<u8>,
key: Vec<u8>
}
#[allow(unknown_lints, clippy::large_enum_variant)]
pub enum Crypto {
None,
ChaCha20Poly1305(CryptoData),
AES256GCM(CryptoData),
AES128GCM(CryptoData)
}
fn inc_nonce(nonce: &mut [u8]) {
let l = nonce.len();
for i in (0..l).rev() {
let mut num = nonce[i];
num = num.wrapping_add(1);
nonce[i] = num;
if num > 0 {
return
}
}
warn!("Nonce overflowed");
}
impl Crypto {
#[inline]
pub fn method(&self) -> u8 {
match *self {
Crypto::None => 0,
Crypto::ChaCha20Poly1305 { .. } => 1,
Crypto::AES256GCM { .. } => 2,
Crypto::AES128GCM { .. } => 3
}
}
#[inline]
pub fn nonce_bytes(&self) -> usize {
match *self {
Crypto::None => 0,
Crypto::ChaCha20Poly1305(ref data) | Crypto::AES256GCM(ref data) | Crypto::AES128GCM(ref data) => {
data.crypto_key.algorithm().nonce_len()
}
}
}
#[inline]
pub fn get_key(&self) -> &[u8] {
match *self {
Crypto::None => &[],
Crypto::ChaCha20Poly1305(ref data) | Crypto::AES256GCM(ref data) | Crypto::AES128GCM(ref data) => &data.key
}
}
#[inline]
#[allow(unknown_lints, clippy::match_same_arms)]
pub fn additional_bytes(&self) -> usize {
match *self {
Crypto::None => 0,
Crypto::ChaCha20Poly1305(ref data) | Crypto::AES256GCM(ref data) | Crypto::AES128GCM(ref data) => {
data.crypto_key.algorithm().tag_len()
}
}
}
pub fn from_shared_key(method: CryptoMethod, password: &str) -> Self {
let algo = match method {
CryptoMethod::ChaCha20 => &CHACHA20_POLY1305,
CryptoMethod::AES256 => &AES_256_GCM,
CryptoMethod::AES128 => &AES_128_GCM
};
let mut key: Vec<u8> = Vec::with_capacity(algo.key_len());
for _ in 0..algo.key_len() {
key.push(0);
}
if password.starts_with(HEX_PREFIX) {
let password = &password[HEX_PREFIX.len()..];
if password.len() != 2 * algo.key_len() {
fail!("Raw secret key must be exactly {} bytes long", algo.key_len());
}
for i in 0..algo.key_len() {
key[i] = try_fail!(
u8::from_str_radix(&password[2 * i..=2 * i + 1], 16),
"Failed to parse raw secret key: {}"
);
}
} else {
let password = if password.starts_with(HASH_PREFIX) { &password[HASH_PREFIX.len()..] } else { password };
pbkdf2::derive(
pbkdf2::PBKDF2_HMAC_SHA256,
NonZeroU32::new(4096).unwrap(),
SALT,
password.as_bytes(),
&mut key
);
}
let crypto_key = LessSafeKey::new(UnboundKey::new(algo, &key[..algo.key_len()]).expect("Failed to create key"));
let mut nonce: Vec<u8> = Vec::with_capacity(algo.nonce_len());
for _ in 0..algo.nonce_len() {
nonce.push(0);
}
if SystemRandom::new().fill(&mut nonce).is_err() {
fail!("Randomizing nonce failed");
}
// make sure the nonce will not overflow
if nonce[0] == 0xff {
nonce[0] = 0
}
let data = CryptoData { crypto_key, nonce, key };
match method {
CryptoMethod::ChaCha20 => Crypto::ChaCha20Poly1305(data),
CryptoMethod::AES256 => Crypto::AES256GCM(data),
CryptoMethod::AES128 => Crypto::AES128GCM(data)
}
}
pub fn decrypt(&self, buf: &mut [u8], nonce: &[u8], header: &[u8]) -> Result<usize, Error> {
match *self {
Crypto::None => Ok(buf.len()),
Crypto::ChaCha20Poly1305(ref data) | Crypto::AES256GCM(ref data) | Crypto::AES128GCM(ref data) => {
let nonce = Nonce::try_assume_unique_for_key(nonce).unwrap();
match data.crypto_key.open_in_place(nonce, Aad::from(header), buf) {
Ok(plaintext) => Ok(plaintext.len()),
Err(_) => Err(Error::Crypto("Failed to decrypt"))
}
}
}
}
pub fn encrypt(&mut self, buf: &mut [u8], mlen: usize, nonce_bytes: &mut [u8], header: &[u8]) -> usize {
let tag_len = self.additional_bytes();
match *self {
Crypto::None => mlen,
Crypto::ChaCha20Poly1305(ref mut data)
| Crypto::AES256GCM(ref mut data)
| Crypto::AES128GCM(ref mut data) => {
inc_nonce(&mut data.nonce);
assert!(buf.len() - mlen >= tag_len);
let nonce = Nonce::try_assume_unique_for_key(&data.nonce).unwrap();
let tag = data
.crypto_key
.seal_in_place_separate_tag(nonce, Aad::from(header), &mut buf[..mlen])
.expect("Failed to encrypt");
buf[mlen..mlen + tag_len].copy_from_slice(tag.as_ref());
nonce_bytes.clone_from_slice(&data.nonce);
mlen + tag_len
}
}
}
}
#[test]
fn encrypt_decrypt_chacha20poly1305() {
let mut sender = Crypto::from_shared_key(CryptoMethod::ChaCha20, "test");
let receiver = Crypto::from_shared_key(CryptoMethod::ChaCha20, "test");
let msg = "HelloWorld0123456789";
let msg_bytes = msg.as_bytes();
let mut buffer = [0u8; 1024];
let header = [0u8; 8];
buffer[..msg_bytes.len()].clone_from_slice(&msg_bytes);
let mut nonce1 = [0u8; 12];
let size = sender.encrypt(&mut buffer, msg_bytes.len(), &mut nonce1, &header);
assert_eq!(size, msg_bytes.len() + sender.additional_bytes());
assert!(msg_bytes != &buffer[..msg_bytes.len()] as &[u8]);
receiver.decrypt(&mut buffer[..size], &nonce1, &header).unwrap();
assert_eq!(msg_bytes, &buffer[..msg_bytes.len()] as &[u8]);
let mut nonce2 = [0u8; 12];
let size = sender.encrypt(&mut buffer, msg_bytes.len(), &mut nonce2, &header);
assert!(nonce1 != nonce2);
receiver.decrypt(&mut buffer[..size], &nonce2, &header).unwrap();
assert_eq!(msg_bytes, &buffer[..msg_bytes.len()] as &[u8]);
}
#[test]
fn encrypt_decrypt_aes256() {
let mut sender = Crypto::from_shared_key(CryptoMethod::AES256, "test");
let receiver = Crypto::from_shared_key(CryptoMethod::AES256, "test");
let msg = "HelloWorld0123456789";
let msg_bytes = msg.as_bytes();
let mut buffer = [0u8; 1024];
let header = [0u8; 8];
buffer[..msg_bytes.len()].clone_from_slice(&msg_bytes);
let mut nonce1 = [0u8; 12];
let size = sender.encrypt(&mut buffer, msg_bytes.len(), &mut nonce1, &header);
assert_eq!(size, msg_bytes.len() + sender.additional_bytes());
assert!(msg_bytes != &buffer[..msg_bytes.len()] as &[u8]);
receiver.decrypt(&mut buffer[..size], &nonce1, &header).unwrap();
assert_eq!(msg_bytes, &buffer[..msg_bytes.len()] as &[u8]);
let mut nonce2 = [0u8; 12];
let size = sender.encrypt(&mut buffer, msg_bytes.len(), &mut nonce2, &header);
assert!(nonce1 != nonce2);
receiver.decrypt(&mut buffer[..size], &nonce2, &header).unwrap();
assert_eq!(msg_bytes, &buffer[..msg_bytes.len()] as &[u8]);
}
#[test]
fn encrypt_decrypt_aes128() {
let mut sender = Crypto::from_shared_key(CryptoMethod::AES128, "test");
let receiver = Crypto::from_shared_key(CryptoMethod::AES128, "test");
let msg = "HelloWorld0123456789";
let msg_bytes = msg.as_bytes();
let mut buffer = [0u8; 1024];
let header = [0u8; 8];
buffer[..msg_bytes.len()].clone_from_slice(&msg_bytes);
let mut nonce1 = [0u8; 12];
let size = sender.encrypt(&mut buffer, msg_bytes.len(), &mut nonce1, &header);
assert_eq!(size, msg_bytes.len() + sender.additional_bytes());
assert!(msg_bytes != &buffer[..msg_bytes.len()] as &[u8]);
receiver.decrypt(&mut buffer[..size], &nonce1, &header).unwrap();
assert_eq!(msg_bytes, &buffer[..msg_bytes.len()] as &[u8]);
let mut nonce2 = [0u8; 12];
let size = sender.encrypt(&mut buffer, msg_bytes.len(), &mut nonce2, &header);
assert!(nonce1 != nonce2);
receiver.decrypt(&mut buffer[..size], &nonce2, &header).unwrap();
assert_eq!(msg_bytes, &buffer[..msg_bytes.len()] as &[u8]);
}