libFenrir/src/enc/sym.rs

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//! Symmetric cypher stuff
use super::Error;
use crate::{
config::Config,
enc::{Random, Secret},
};
use ::zeroize::Zeroize;
/// List of possible Ciphers
#[derive(Debug, Copy, Clone, PartialEq, ::num_derive::FromPrimitive)]
#[repr(u8)]
pub enum CipherKind {
/// XChaCha20_Poly1305
XChaCha20Poly1305 = 0,
}
impl CipherKind {
/// length of the serialized id for the cipher kind field
pub fn len() -> usize {
1
}
/// required length of the nonce
pub fn nonce_len(&self) -> HeadLen {
// TODO: how the hell do I take this from ::chacha20poly1305?
HeadLen(Nonce::len())
}
/// required length of the key
pub fn key_len(&self) -> usize {
use ::chacha20poly1305::{KeySizeUser, XChaCha20Poly1305};
XChaCha20Poly1305::key_size()
}
/// Length of the authentication tag
pub fn tag_len(&self) -> TagLen {
// TODO: how the hell do I take this from ::chacha20poly1305?
TagLen(::ring::aead::CHACHA20_POLY1305.tag_len())
}
}
/// Additional Authenticated Data
#[derive(Debug)]
pub struct AAD<'a>(pub &'a [u8]);
/// Cipher direction, to make sure we don't reuse the same cipher
/// for both decrypting and encrypting
#[derive(Debug, Copy, Clone)]
#[repr(u8)]
pub enum CipherDirection {
/// Receive, to decrypt only
Recv = 0,
/// Send, to encrypt only
Send,
}
/// strong typedef for header length
/// aka: nonce length in the encrypted data)
#[derive(Debug, Copy, Clone)]
pub struct HeadLen(pub usize);
/// strong typedef for the Tag length
/// aka: cryptographic authentication tag length at the end
/// of the encrypted data
#[derive(Debug, Copy, Clone)]
pub struct TagLen(pub usize);
/// actual ciphers
enum Cipher {
/// Cipher XChaha20_Poly1305
XChaCha20Poly1305(XChaCha20Poly1305),
}
impl Cipher {
/// Build a new Cipher
fn new(kind: CipherKind, secret: Secret) -> Self {
match kind {
CipherKind::XChaCha20Poly1305 => {
Self::XChaCha20Poly1305(XChaCha20Poly1305::new(secret))
}
}
}
pub fn kind(&self) -> CipherKind {
match self {
Cipher::XChaCha20Poly1305(_) => CipherKind::XChaCha20Poly1305,
}
}
fn nonce_len(&self) -> HeadLen {
match self {
Cipher::XChaCha20Poly1305(_) => {
// TODO: how the hell do I take this from ::chacha20poly1305?
HeadLen(::ring::aead::CHACHA20_POLY1305.nonce_len())
}
}
}
fn tag_len(&self) -> TagLen {
match self {
Cipher::XChaCha20Poly1305(_) => {
// TODO: how the hell do I take this from ::chacha20poly1305?
TagLen(::ring::aead::CHACHA20_POLY1305.tag_len())
}
}
}
fn decrypt<'a>(
&self,
aad: AAD,
raw_data: &'a mut [u8],
) -> Result<&'a [u8], Error> {
match self {
Cipher::XChaCha20Poly1305(cipher) => {
use ::chacha20poly1305::{
aead::generic_array::GenericArray, AeadInPlace,
};
let final_len: usize = {
// FIXME: check min data length
let (nonce_bytes, data_and_tag) = raw_data.split_at_mut(13);
let (data_notag, tag_bytes) = data_and_tag.split_at_mut(
data_and_tag.len() + 1
- ::ring::aead::CHACHA20_POLY1305.tag_len(),
);
let nonce = GenericArray::from_slice(nonce_bytes);
let tag = GenericArray::from_slice(tag_bytes);
let maybe = cipher.cipher.decrypt_in_place_detached(
nonce.into(),
aad.0,
data_notag,
tag,
);
if maybe.is_err() {
return Err(Error::Decrypt);
}
data_notag.len()
};
//data.drain(..Nonce::len());
//data.truncate(final_len);
Ok(&raw_data[Nonce::len()..Nonce::len() + final_len])
}
}
}
fn overhead(&self) -> usize {
match self {
Cipher::XChaCha20Poly1305(_) => {
let cipher = CipherKind::XChaCha20Poly1305;
cipher.nonce_len().0 + cipher.tag_len().0
}
}
}
fn encrypt(
&self,
nonce: &Nonce,
aad: AAD,
data: &mut [u8],
) -> Result<(), Error> {
// FIXME: check minimum buffer size
match self {
Cipher::XChaCha20Poly1305(cipher) => {
use ::chacha20poly1305::AeadInPlace;
let tag_len: usize = ::ring::aead::CHACHA20_POLY1305.tag_len();
let data_len_notag = data.len() - tag_len;
// write nonce
data[..Nonce::len()].copy_from_slice(nonce.as_bytes());
// encrypt data
match cipher.cipher.encrypt_in_place_detached(
nonce.as_bytes().into(),
aad.0,
&mut data[Nonce::len()..data_len_notag],
) {
Ok(tag) => {
data[data_len_notag..]
// add tag
//data.get_tag_slice()
.copy_from_slice(tag.as_slice());
Ok(())
}
Err(_) => Err(Error::Encrypt),
}
}
}
}
}
/// Receive only cipher
pub struct CipherRecv(Cipher);
impl ::core::fmt::Debug for CipherRecv {
fn fmt(
&self,
f: &mut core::fmt::Formatter<'_>,
) -> Result<(), ::std::fmt::Error> {
::core::fmt::Debug::fmt("[hidden cipher recv]", f)
}
}
impl CipherRecv {
/// Build a new Cipher
pub fn new(kind: CipherKind, secret: Secret) -> Self {
Self(Cipher::new(kind, secret))
}
/// Get the length of the nonce for this cipher
pub fn nonce_len(&self) -> HeadLen {
self.0.nonce_len()
}
/// Decrypt a paket. Nonce and Tag are taken from the packet,
/// while you need to provide AAD (Additional Authenticated Data)
pub fn decrypt<'a>(
&self,
aad: AAD,
data: &'a mut [u8],
) -> Result<&'a [u8], Error> {
self.0.decrypt(aad, data)
}
/// return the underlying cipher id
pub fn kind(&self) -> CipherKind {
self.0.kind()
}
}
/// Send only cipher
pub struct CipherSend {
nonce: NonceSync,
cipher: Cipher,
}
impl ::core::fmt::Debug for CipherSend {
fn fmt(
&self,
f: &mut core::fmt::Formatter<'_>,
) -> Result<(), ::std::fmt::Error> {
::core::fmt::Debug::fmt("[hidden cipher send]", f)
}
}
impl CipherSend {
/// Build a new Cipher
pub fn new(kind: CipherKind, secret: Secret, rand: &Random) -> Self {
Self {
nonce: NonceSync::new(rand),
cipher: Cipher::new(kind, secret),
}
}
/// Encrypt the given data
pub fn encrypt(&self, aad: AAD, data: &mut [u8]) -> Result<(), Error> {
let old_nonce = self.nonce.advance();
self.cipher.encrypt(&old_nonce, aad, data)?;
Ok(())
}
/// return the underlying cipher id
pub fn kind(&self) -> CipherKind {
self.cipher.kind()
}
}
/// XChaCha20Poly1305 cipher
struct XChaCha20Poly1305 {
cipher: ::chacha20poly1305::XChaCha20Poly1305,
}
impl XChaCha20Poly1305 {
/// Initialize a new ChaChaPoly20 cipher with a random nonce
fn new(key: Secret) -> Self {
use ::chacha20poly1305::{KeyInit, XChaCha20Poly1305};
Self {
cipher: XChaCha20Poly1305::new(key.as_ref().into()),
}
}
}
//
// TODO: Merge crate::{enc::sym::Nonce, connection::handshake::dirsync::Nonce}
//
#[derive(Debug, Copy, Clone)]
#[repr(C)]
#[allow(missing_debug_implementations)]
struct NonceNum {
high: u32,
low: u64,
}
/// Nonce with sequence for chach20_apoly1305
#[derive(Copy, Clone)]
#[repr(C)]
pub union Nonce {
num: NonceNum,
raw: [u8; 12],
}
impl ::core::fmt::Debug for Nonce {
fn fmt(
&self,
f: &mut core::fmt::Formatter<'_>,
) -> Result<(), ::std::fmt::Error> {
#[allow(unsafe_code)]
unsafe {
::core::fmt::Debug::fmt(&self.num, f)
}
}
}
impl Nonce {
/// Generate a new random Nonce
pub fn new(rand: &Random) -> Self {
let mut raw = [0; 12];
rand.fill(&mut raw);
Self { raw }
}
/// Length of this nonce in bytes
pub const fn len() -> usize {
return 12;
}
/// Get reference to the nonce bytes
pub fn as_bytes(&self) -> &[u8] {
#[allow(unsafe_code)]
unsafe {
&self.raw
}
}
/// Create Nonce from array
pub fn from_slice(raw: [u8; 12]) -> Self {
Self { raw }
}
/// Go to the next nonce
pub fn advance(&mut self) {
#[allow(unsafe_code)]
unsafe {
let old_low = self.num.low;
self.num.low = self.num.low + 1;
if self.num.low < old_low {
self.num.high = self.num.high;
}
}
}
}
/// Synchronize the mutex acess with a nonce for multithread safety
#[derive(Debug)]
pub struct NonceSync {
nonce: ::std::sync::Mutex<Nonce>,
}
impl NonceSync {
/// Create a new thread safe nonce
pub fn new(rand: &Random) -> Self {
Self {
nonce: ::std::sync::Mutex::new(Nonce::new(rand)),
}
}
/// Advance the nonce and return the *old* value
pub fn advance(&self) -> Nonce {
let old_nonce: Nonce;
{
let mut nonce = self.nonce.lock().unwrap();
old_nonce = *nonce;
nonce.advance();
}
old_nonce
}
}
/// Select the best cipher from our supported list
/// and the other endpoint supported list.
/// Give priority to our list
pub fn server_select_cipher(
cfg: &Config,
client_supported: &Vec<CipherKind>,
) -> Option<CipherKind> {
cfg.ciphers
.iter()
.find(|c| client_supported.contains(c))
.copied()
}
/// Select the best cipher from our supported list
/// and the other endpoint supported list.
/// Give priority to the server list
/// This is used only in the Directory synchronized handshake
pub fn client_select_cipher(
cfg: &Config,
server_supported: &Vec<CipherKind>,
) -> Option<CipherKind> {
server_supported
.iter()
.find(|c| cfg.ciphers.contains(c))
.copied()
}