Tests work

This commit is contained in:
Dennis Schwerdel 2021-03-26 22:55:40 +00:00
parent da9befe235
commit fb0676ba6b
5 changed files with 140 additions and 142 deletions

View File

@ -1,24 +1,24 @@
use super::{core::test_speed, rotate::RotationState};
pub use super::{
core::{CryptoCore, EXTRA_LEN, TAG_LEN},
init::{is_init_message, InitResult, InitState, INIT_MESSAGE_FIRST_BYTE}
init::{is_init_message, InitMsg, InitResult, InitState, INIT_MESSAGE_FIRST_BYTE, STAGE_PONG},
};
use crate::{
error::Error,
types::NodeId,
util::{from_base62, to_base62, MsgBuffer}
util::{from_base62, to_base62, MsgBuffer},
};
use libc::BPF_FS_MAGIC;
use ring::{
aead::{self, Algorithm, LessSafeKey, UnboundKey},
agreement::{EphemeralPrivateKey, UnparsedPublicKey},
pbkdf2,
rand::{SecureRandom, SystemRandom},
signature::{Ed25519KeyPair, KeyPair, ED25519_PUBLIC_KEY_LEN}
signature::{Ed25519KeyPair, KeyPair, ED25519_PUBLIC_KEY_LEN},
};
use smallvec::{smallvec, SmallVec};
use std::{fmt::Debug, io::Read, num::NonZeroU32, sync::Arc, time::Duration};
const SALT: &[u8; 32] = b"vpncloudVPNCLOUDvpncl0udVpnCloud";
pub const MESSAGE_TYPE_ROTATION: u8 = 0x10;
@ -28,7 +28,6 @@ pub type EcdhPublicKey = UnparsedPublicKey<SmallVec<[u8; 96]>>;
pub type EcdhPrivateKey = EphemeralPrivateKey;
pub type Key = SmallVec<[u8; 32]>;
const DEFAULT_ALGORITHMS: [&str; 3] = ["AES128", "AES256", "CHACHA20"];
#[cfg(test)]
@ -38,17 +37,15 @@ const SPEED_TEST_TIME: f32 = 0.1;
const ROTATE_INTERVAL: usize = 120;
pub trait Payload: Debug + PartialEq + Sized {
fn write_to(&self, buffer: &mut MsgBuffer);
fn read_from<R: Read>(r: R) -> Result<Self, Error>;
}
#[derive(Clone)]
pub struct Algorithms {
pub algorithm_speeds: SmallVec<[(&'static Algorithm, f32); 3]>,
pub allow_unencrypted: bool
pub allow_unencrypted: bool,
}
#[derive(Debug, Default, Deserialize, Serialize, Clone, PartialEq)]
@ -58,14 +55,14 @@ pub struct Config {
pub private_key: Option<String>,
pub public_key: Option<String>,
pub trusted_keys: Vec<String>,
pub algorithms: Vec<String>
pub algorithms: Vec<String>,
}
pub struct Crypto {
node_id: NodeId,
key_pair: Arc<Ed25519KeyPair>,
trusted_keys: Arc<[Ed25519PublicKey]>,
algorithms: Algorithms
algorithms: Algorithms,
}
impl Crypto {
@ -78,12 +75,12 @@ impl Crypto {
let algo = match &name.to_uppercase() as &str {
"UNENCRYPTED" | "NONE" | "PLAIN" => {
unencrypted = true;
continue
continue;
}
"AES128" | "AES128_GCM" | "AES_128" | "AES_128_GCM" => &aead::AES_128_GCM,
"AES256" | "AES256_GCM" | "AES_256" | "AES_256_GCM" => &aead::AES_256_GCM,
"CHACHA" | "CHACHA20" | "CHACHA20_POLY1305" => &aead::CHACHA20_POLY1305,
_ => return Err(Error::InvalidConfig("Unknown crypto method"))
_ => return Err(Error::InvalidConfig("Unknown crypto method")),
};
algos.push(algo)
}
@ -100,7 +97,7 @@ impl Crypto {
} else if let Some(password) = &config.password {
Self::keypair_from_password(password)
} else {
return Err(Error::InvalidConfig("Either private_key or password must be set"))
return Err(Error::InvalidConfig("Either private_key or password must be set"));
};
let mut trusted_keys = vec![];
for tn in &config.trusted_keys {
@ -134,7 +131,7 @@ impl Crypto {
node_id,
key_pair: Arc::new(key_pair),
trusted_keys: trusted_keys.into_boxed_slice().into(),
algorithms: algos
algorithms: algos,
})
}
@ -151,7 +148,7 @@ impl Crypto {
NonZeroU32::new(4096).unwrap(),
SALT,
password.as_bytes(),
&mut bytes
&mut bytes,
);
}
}
@ -193,7 +190,7 @@ impl Crypto {
fn parse_public_key(pubkey: &str) -> Result<Ed25519PublicKey, Error> {
let pubkey = from_base62(pubkey).map_err(|_| Error::InvalidConfig("Failed to parse public key"))?;
if pubkey.len() != ED25519_PUBLIC_KEY_LEN {
return Err(Error::InvalidConfig("Failed to parse public key"))
return Err(Error::InvalidConfig("Failed to parse public key"));
}
let mut result = [0; ED25519_PUBLIC_KEY_LEN];
result.clone_from_slice(&pubkey);
@ -205,53 +202,61 @@ impl Crypto {
}
}
#[derive(Debug, PartialEq)]
pub enum MessageResult {
Message(u8),
Reply,
None
None,
}
pub enum PeerCrypto {
Encrypted {
last_init_message: Vec<u8>,
trusted_keys: Arc<[Ed25519PublicKey]>,
algorithm: &'static Algorithm,
rotation: RotationState,
core: Arc<CryptoCore>,
rotate_counter: usize
rotate_counter: usize,
},
Unencrypted {
last_init_message: Vec<u8>
}
last_init_message: Vec<u8>,
trusted_keys: Arc<[Ed25519PublicKey]>,
},
}
impl PeerCrypto {
pub fn algorithm_name(&self) -> &'static str {
match self {
PeerCrypto::Encrypted { algorithm, .. } => {
match *algorithm {
PeerCrypto::Encrypted { algorithm, .. } => match *algorithm {
x if x == &aead::CHACHA20_POLY1305 => "CHACHA20",
x if x == &aead::AES_128_GCM => "AES128",
x if x == &aead::AES_256_GCM => "AES256",
_ => unreachable!()
}
}
PeerCrypto::Unencrypted { .. } => "PLAIN"
_ => unreachable!(),
},
PeerCrypto::Unencrypted { .. } => "PLAIN",
}
}
pub fn get_core(&self) -> Option<Arc<CryptoCore>> {
match self {
PeerCrypto::Encrypted { core, .. } => Some(core.clone()),
PeerCrypto::Unencrypted { .. } => None
PeerCrypto::Unencrypted { .. } => None,
}
}
fn handle_init_message(&mut self, buffer: &mut MsgBuffer) -> Result<MessageResult, Error> {
// TODO: parse message stage
// TODO: depending on stage resend last message
match self {
PeerCrypto::Encrypted { trusted_keys, last_init_message, .. }
| PeerCrypto::Unencrypted { trusted_keys, last_init_message, .. } => {
let (msg, _) = InitMsg::read_from(buffer.buffer(), &trusted_keys)?;
buffer.clear();
if msg.stage() == STAGE_PONG {
buffer.set_length(last_init_message.len());
buffer.message_mut().copy_from_slice(last_init_message);
}
return Ok(MessageResult::Reply)
}
}
Ok(MessageResult::None)
}
@ -264,7 +269,7 @@ impl PeerCrypto {
}
Ok(())
}
PeerCrypto::Unencrypted { .. } => Err(Error::Crypto("Rotation when unencrypted"))
PeerCrypto::Unencrypted { .. } => Err(Error::Crypto("Rotation when unencrypted")),
}
}
@ -287,7 +292,7 @@ impl PeerCrypto {
pub fn handle_message(&mut self, buffer: &mut MsgBuffer) -> Result<MessageResult, Error> {
// HOT PATH
if buffer.is_empty() {
return Err(Error::InvalidCryptoState("No message in buffer"))
return Err(Error::InvalidCryptoState("No message in buffer"));
}
if is_init_message(buffer.buffer()) {
// COLD PATH
@ -330,7 +335,6 @@ impl PeerCrypto {
}
}
#[cfg(test)]
mod tests {
use super::*;
@ -362,18 +366,18 @@ mod tests {
debug!("Node1 <- Node2");
let res = node1.handle_init(&mut msg).unwrap();
assert_eq!(res, InitResult::Success { peer_payload: vec![], is_initiator: false });
assert_eq!(res, InitResult::Success { peer_payload: vec![], is_initiator: true });
assert!(!msg.is_empty());
debug!("Node1 -> Node2");
let res = node2.handle_init(&mut msg).unwrap();
assert_eq!(res, InitResult::Success { peer_payload: vec![], is_initiator: true });
assert_eq!(res, InitResult::Success { peer_payload: vec![], is_initiator: false });
assert!(msg.is_empty());
let mut node1 = node1.finish(&mut msg);
assert!(msg.is_empty());
let mut node2 = node2.finish(&mut msg);
assert!(msg.is_empty());
assert!(!msg.is_empty());
debug!("Node1 <- Node2");
let res = node1.handle_message(&mut msg).unwrap();

View File

@ -54,12 +54,11 @@
// Once every second, both nodes check whether they have already finished the initialization. If not, they repeat their
// last message. After 5 seconds, the initialization is aborted as failed.
use super::{
common::MESSAGE_TYPE_ROTATION,
core::{CryptoCore, EXTRA_LEN},
rotate::RotationState,
Algorithms, EcdhPrivateKey, EcdhPublicKey, Ed25519PublicKey, Payload, PeerCrypto,
common::MESSAGE_TYPE_ROTATION
};
use crate::{error::Error, types::NodeId, util::MsgBuffer};
use byteorder::{NetworkEndian, ReadBytesExt, WriteBytesExt};
@ -68,14 +67,14 @@ use ring::{
agreement::{agree_ephemeral, X25519},
digest,
rand::{SecureRandom, SystemRandom},
signature::{self, Ed25519KeyPair, KeyPair, ED25519, ED25519_PUBLIC_KEY_LEN}
signature::{self, Ed25519KeyPair, KeyPair, ED25519, ED25519_PUBLIC_KEY_LEN},
};
use smallvec::{smallvec, SmallVec};
use std::{
cmp, f32,
fmt::Debug,
io::{self, Cursor, Read, Write},
sync::Arc
sync::Arc,
};
pub const INIT_MESSAGE_FIRST_BYTE: u8 = 0xff;
@ -91,29 +90,27 @@ pub const MAX_FAILED_RETRIES: usize = 120;
pub const SALTED_NODE_ID_HASH_LEN: usize = 20;
pub type SaltedNodeIdHash = [u8; SALTED_NODE_ID_HASH_LEN];
pub fn is_init_message(msg: &[u8]) -> bool {
!msg.is_empty() && msg[0] == INIT_MESSAGE_FIRST_BYTE
}
#[allow(clippy::large_enum_variant)]
pub enum InitMsg {
Ping {
salted_node_id_hash: SaltedNodeIdHash,
ecdh_public_key: EcdhPublicKey,
algorithms: Algorithms
algorithms: Algorithms,
},
Pong {
salted_node_id_hash: SaltedNodeIdHash,
ecdh_public_key: EcdhPublicKey,
algorithms: Algorithms,
encrypted_payload: MsgBuffer
encrypted_payload: MsgBuffer,
},
Peng {
salted_node_id_hash: SaltedNodeIdHash,
encrypted_payload: MsgBuffer
}
encrypted_payload: MsgBuffer,
},
}
impl InitMsg {
@ -124,11 +121,11 @@ impl InitMsg {
const PART_SALTED_NODE_ID_HASH: u8 = 2;
const PART_STAGE: u8 = 1;
fn stage(&self) -> u8 {
pub fn stage(&self) -> u8 {
match self {
InitMsg::Ping { .. } => STAGE_PING,
InitMsg::Pong { .. } => STAGE_PONG,
InitMsg::Peng { .. } => STAGE_PENG
InitMsg::Peng { .. } => STAGE_PENG,
}
}
@ -136,7 +133,7 @@ impl InitMsg {
match self {
InitMsg::Ping { salted_node_id_hash, .. }
| InitMsg::Pong { salted_node_id_hash, .. }
| InitMsg::Peng { salted_node_id_hash, .. } => salted_node_id_hash
| InitMsg::Peng { salted_node_id_hash, .. } => salted_node_id_hash,
}
}
@ -150,11 +147,11 @@ impl InitMsg {
short_hash
}
fn read_from(buffer: &[u8], trusted_keys: &[Ed25519PublicKey]) -> Result<(Self, Ed25519PublicKey), Error> {
pub fn read_from(buffer: &[u8], trusted_keys: &[Ed25519PublicKey]) -> Result<(Self, Ed25519PublicKey), Error> {
let mut r = Cursor::new(buffer);
if r.read_u8().map_err(|_| Error::Parse("Init message too short"))? != INIT_MESSAGE_FIRST_BYTE {
return Err(Error::Parse("Init message has invalid first byte"))
return Err(Error::Parse("Init message has invalid first byte"));
}
let mut public_key_salt = [0; 4];
r.read_exact(&mut public_key_salt).map_err(|_| Error::Parse("Init message too short"))?;
@ -166,11 +163,11 @@ impl InitMsg {
if Self::calculate_hash(tk, &public_key_salt) == public_key_hash {
public_key_data.clone_from_slice(tk);
found_key = true;
break
break;
}
}
if !found_key {
return Err(Error::Crypto("untrusted peer"))
return Err(Error::Crypto("untrusted peer"));
}
let mut stage = None;
@ -182,19 +179,19 @@ impl InitMsg {
loop {
let field = r.read_u8().map_err(|_| Error::Parse("Init message too short"))?;
if field == Self::PART_END {
break
break;
}
let field_len = r.read_u16::<NetworkEndian>().map_err(|_| Error::Parse("Init message too short"))? as usize;
match field {
Self::PART_STAGE => {
if field_len != 1 {
return Err(Error::CryptoInit("Invalid size for stage field"))
return Err(Error::CryptoInit("Invalid size for stage field"));
}
stage = Some(r.read_u8().map_err(|_| Error::Parse("Init message too short"))?)
}
Self::PART_SALTED_NODE_ID_HASH => {
if field_len != SALTED_NODE_ID_HASH_LEN {
return Err(Error::CryptoInit("Invalid size for salted node id hash field"))
return Err(Error::CryptoInit("Invalid size for salted node id hash field"));
}
let mut id = [0; SALTED_NODE_ID_HASH_LEN];
r.read_exact(&mut id).map_err(|_| Error::Parse("Init message too short"))?;
@ -224,7 +221,7 @@ impl InitMsg {
1 => Some(&AES_128_GCM),
2 => Some(&AES_256_GCM),
3 => Some(&CHACHA20_POLY1305),
_ => None
_ => None,
};
let speed =
r.read_f32::<NetworkEndian>().map_err(|_| Error::Parse("Init message too short"))?;
@ -250,53 +247,53 @@ impl InitMsg {
let signed_data = &r.into_inner()[0..pos];
let public_key = signature::UnparsedPublicKey::new(&ED25519, &public_key_data);
if public_key.verify(&signed_data, &signature).is_err() {
return Err(Error::Crypto("invalid signature"))
return Err(Error::Crypto("invalid signature"));
}
let stage = match stage {
Some(val) => val,
None => return Err(Error::CryptoInit("Init message without stage"))
None => return Err(Error::CryptoInit("Init message without stage")),
};
let salted_node_id_hash = match salted_node_id_hash {
Some(val) => val,
None => return Err(Error::CryptoInit("Init message without node id"))
None => return Err(Error::CryptoInit("Init message without node id")),
};
let msg = match stage {
STAGE_PING => {
let ecdh_public_key = match ecdh_public_key {
Some(val) => val,
None => return Err(Error::CryptoInit("Init message without ecdh public key"))
None => return Err(Error::CryptoInit("Init message without ecdh public key")),
};
let algorithms = match algorithms {
Some(val) => val,
None => return Err(Error::CryptoInit("Init message without algorithms"))
None => return Err(Error::CryptoInit("Init message without algorithms")),
};
Self::Ping { salted_node_id_hash, ecdh_public_key, algorithms }
}
STAGE_PONG => {
let ecdh_public_key = match ecdh_public_key {
Some(val) => val,
None => return Err(Error::CryptoInit("Init message without ecdh public key"))
None => return Err(Error::CryptoInit("Init message without ecdh public key")),
};
let algorithms = match algorithms {
Some(val) => val,
None => return Err(Error::CryptoInit("Init message without algorithms"))
None => return Err(Error::CryptoInit("Init message without algorithms")),
};
let encrypted_payload = match encrypted_payload {
Some(val) => val,
None => return Err(Error::CryptoInit("Init message without payload"))
None => return Err(Error::CryptoInit("Init message without payload")),
};
Self::Pong { salted_node_id_hash, ecdh_public_key, algorithms, encrypted_payload }
}
STAGE_PENG => {
let encrypted_payload = match encrypted_payload {
Some(val) => val,
None => return Err(Error::CryptoInit("Init message without payload"))
None => return Err(Error::CryptoInit("Init message without payload")),
};
Self::Peng { salted_node_id_hash, encrypted_payload }
}
_ => return Err(Error::CryptoInit("Invalid stage"))
_ => return Err(Error::CryptoInit("Invalid stage")),
};
Ok((msg, public_key_data))
@ -336,7 +333,7 @@ impl InitMsg {
w.write_u16::<NetworkEndian>(key_bytes.len() as u16)?;
w.write_all(&key_bytes)?;
}
_ => ()
_ => (),
}
match &self {
@ -364,7 +361,7 @@ impl InitMsg {
w.write_f32::<NetworkEndian>(*speed)?;
}
}
_ => ()
_ => (),
}
match &self {
@ -373,7 +370,7 @@ impl InitMsg {
w.write_u16::<NetworkEndian>(encrypted_payload.len() as u16)?;
w.write_all(encrypted_payload.message())?;
}
_ => ()
_ => (),
}
w.write_u8(Self::PART_END)?;
@ -387,11 +384,10 @@ impl InitMsg {
}
}
#[derive(PartialEq, Debug)]
pub enum InitResult<P: Payload> {
Continue,
Success { peer_payload: P, is_initiator: bool }
Success { peer_payload: P, is_initiator: bool },
}
pub struct InitState<P: Payload> {
@ -409,13 +405,13 @@ pub struct InitState<P: Payload> {
algorithms: Algorithms,
#[allow(dead_code)] // Used in tests
selected_algorithm: Option<&'static Algorithm>,
failed_retries: usize
failed_retries: usize,
}
impl<P: Payload> InitState<P> {
pub fn new(
node_id: NodeId, payload: P, key_pair: Arc<Ed25519KeyPair>, trusted_keys: Arc<[Ed25519PublicKey]>,
algorithms: Algorithms
algorithms: Algorithms,
) -> Self {
let mut hash = [0; SALTED_NODE_ID_HASH_LEN];
let rng = SystemRandom::new();
@ -437,7 +433,7 @@ impl<P: Payload> InitState<P> {
selected_algorithm: None,
algorithms,
failed_retries: 0,
close_time: 60
close_time: 60,
}
}
@ -523,28 +519,22 @@ impl<P: Payload> InitState<P> {
let mut public_key = [0; ED25519_PUBLIC_KEY_LEN];
public_key.clone_from_slice(self.key_pair.as_ref().public_key().as_ref());
let msg = match stage {
STAGE_PING => {
InitMsg::Ping {
salted_node_id_hash: self.salted_node_id_hash,
ecdh_public_key: ecdh_public_key.unwrap(),
algorithms: self.algorithms.clone()
}
}
STAGE_PONG => {
InitMsg::Pong {
STAGE_PING => InitMsg::Ping {
salted_node_id_hash: self.salted_node_id_hash,
ecdh_public_key: ecdh_public_key.unwrap(),
algorithms: self.algorithms.clone(),
encrypted_payload: self.encrypt_payload()
}
}
STAGE_PENG => {
InitMsg::Peng {
},
STAGE_PONG => InitMsg::Pong {
salted_node_id_hash: self.salted_node_id_hash,
encrypted_payload: self.encrypt_payload()
}
}
_ => unreachable!()
ecdh_public_key: ecdh_public_key.unwrap(),
algorithms: self.algorithms.clone(),
encrypted_payload: self.encrypt_payload(),
},
STAGE_PENG => InitMsg::Peng {
salted_node_id_hash: self.salted_node_id_hash,
encrypted_payload: self.encrypt_payload(),
},
_ => unreachable!(),
};
let mut bytes = out.buffer();
let len = msg.write_to(&mut bytes, &self.key_pair).expect("Buffer too small");
@ -563,7 +553,7 @@ impl<P: Payload> InitState<P> {
fn select_algorithm(&self, peer_algos: &Algorithms) -> Result<Option<(&'static Algorithm, f32)>, Error> {
if self.algorithms.allow_unencrypted && peer_algos.allow_unencrypted {
return Ok(None)
return Ok(None);
}
// For each supported algorithm, find the algorithm in the list of the peer (ignore algorithm if not found).
// Take the minimal speed reported by either us or the peer.
@ -597,7 +587,7 @@ impl<P: Payload> InitState<P> {
if self.salted_node_id_hash == salted_node_id_hash
|| self.check_salted_node_id_hash(&salted_node_id_hash, self.node_id)
{
return Err(Error::CryptoInitFatal("Connected to self"))
return Err(Error::CryptoInitFatal("Connected to self"));
}
if stage != self.next_stage {
if self.next_stage == STAGE_PONG && stage == STAGE_PING {
@ -610,15 +600,15 @@ impl<P: Payload> InitState<P> {
self.last_message = None;
self.ecdh_private_key = None;
} else {
return Ok(InitResult::Continue)
return Ok(InitResult::Continue);
}
} else if self.next_stage == CLOSING {
return Ok(InitResult::Continue)
return Ok(InitResult::Continue);
} else if self.last_message.is_some() {
self.repeat_last_message(out);
return Ok(InitResult::Continue)
return Ok(InitResult::Continue);
} else {
return Err(Error::CryptoInitFatal("Received invalid stage as first message"))
return Err(Error::CryptoInitFatal("Received invalid stage as first message"));
}
}
self.failed_retries = 0;
@ -683,23 +673,25 @@ impl<P: Payload> InitState<P> {
let rotation = RotationState::new(!self.is_initiator, buffer);
if !buffer.is_empty() {
buffer.prepend_byte(MESSAGE_TYPE_ROTATION);
crypto.encrypt(buffer);
}
PeerCrypto::Encrypted {
algorithm: crypto.algorithm(),
trusted_keys: self.trusted_keys.clone(),
core: crypto,
rotation,
rotate_counter: 0,
last_init_message: self.last_message.unwrap()
last_init_message: self.last_message.unwrap(),
}
} else {
PeerCrypto::Unencrypted {
last_init_message: self.last_message.unwrap()
last_init_message: self.last_message.unwrap(),
trusted_keys: self.trusted_keys.clone(),
}
}
}
}
#[cfg(test)]
mod tests {
use super::*;
@ -731,7 +723,7 @@ mod tests {
rng.fill(&mut node2).unwrap();
let algorithms = Algorithms {
algorithm_speeds: smallvec![(&AES_128_GCM, 600.0), (&AES_256_GCM, 500.0), (&CHACHA20_POLY1305, 400.0)],
allow_unencrypted: false
allow_unencrypted: false,
};
let sender = InitState::new(node1, vec![1], key_pair.clone(), trusted_nodes.clone(), algorithms.clone());
let receiver = InitState::new(node2, vec![2], key_pair, trusted_nodes, algorithms);
@ -751,12 +743,12 @@ mod tests {
assert_eq!(sender.stage(), WAITING_TO_CLOSE);
let result = match result {
InitResult::Success { .. } => receiver.handle_init(&mut out).unwrap(),
InitResult::Continue => unreachable!()
InitResult::Continue => unreachable!(),
};
assert_eq!(receiver.stage(), CLOSING);
match result {
InitResult::Success { .. } => assert!(out.is_empty()),
InitResult::Continue => unreachable!()
InitResult::Continue => unreachable!(),
}
}
@ -782,14 +774,14 @@ mod tests {
// lost peng, sender recovers
out.clear();
}
InitResult::Continue => unreachable!()
InitResult::Continue => unreachable!(),
};
sender.every_second(&mut out).unwrap();
let result = receiver.handle_init(&mut out).unwrap();
assert_eq!(receiver.stage(), CLOSING);
match result {
InitResult::Success { .. } => assert!(out.is_empty()),
InitResult::Continue => unreachable!()
InitResult::Continue => unreachable!(),
}
}
@ -813,7 +805,7 @@ mod tests {
// lost peng, sender recovers
out.clear();
}
InitResult::Continue => unreachable!()
InitResult::Continue => unreachable!(),
};
receiver.every_second(&mut out).unwrap();
sender.handle_init(&mut out).unwrap();
@ -821,7 +813,7 @@ mod tests {
assert_eq!(receiver.stage(), CLOSING);
match result {
InitResult::Success { .. } => assert!(out.is_empty()),
InitResult::Continue => unreachable!()
InitResult::Continue => unreachable!(),
}
}
@ -870,7 +862,7 @@ mod tests {
}
fn test_algorithm_negotiation(
algos1: Algorithms, algos2: Algorithms, success: bool, selected: Option<&'static Algorithm>
algos1: Algorithms, algos2: Algorithms, success: bool, selected: Option<&'static Algorithm>,
) {
let (mut sender, mut receiver) = create_pair();
sender.algorithms = algos1;
@ -880,7 +872,7 @@ mod tests {
let res = receiver.handle_init(&mut out);
assert_eq!(res.is_ok(), success);
if !success {
return
return;
}
sender.handle_init(&mut out).unwrap();
receiver.handle_init(&mut out).unwrap();
@ -894,70 +886,70 @@ mod tests {
test_algorithm_negotiation(
Algorithms {
algorithm_speeds: smallvec![(&AES_128_GCM, 600.0), (&AES_256_GCM, 500.0), (&CHACHA20_POLY1305, 400.0)],
allow_unencrypted: false
allow_unencrypted: false,
},
Algorithms {
algorithm_speeds: smallvec![(&AES_128_GCM, 600.0), (&AES_256_GCM, 500.0), (&CHACHA20_POLY1305, 400.0)],
allow_unencrypted: false
allow_unencrypted: false,
},
true,
Some(&AES_128_GCM)
Some(&AES_128_GCM),
);
// Overlapping but different
test_algorithm_negotiation(
Algorithms {
algorithm_speeds: smallvec![(&AES_256_GCM, 500.0), (&CHACHA20_POLY1305, 400.0)],
allow_unencrypted: false
allow_unencrypted: false,
},
Algorithms {
algorithm_speeds: smallvec![(&AES_128_GCM, 600.0), (&AES_256_GCM, 500.0)],
allow_unencrypted: false
allow_unencrypted: false,
},
true,
Some(&AES_256_GCM)
Some(&AES_256_GCM),
);
// Select fastest pair
test_algorithm_negotiation(
Algorithms {
algorithm_speeds: smallvec![(&AES_128_GCM, 600.0), (&AES_256_GCM, 500.0), (&CHACHA20_POLY1305, 400.0)],
allow_unencrypted: false
allow_unencrypted: false,
},
Algorithms {
algorithm_speeds: smallvec![(&AES_128_GCM, 40.0), (&AES_256_GCM, 50.0), (&CHACHA20_POLY1305, 60.0)],
allow_unencrypted: false
allow_unencrypted: false,
},
true,
Some(&CHACHA20_POLY1305)
Some(&CHACHA20_POLY1305),
);
// Select unencrypted if supported by both
test_algorithm_negotiation(
Algorithms {
algorithm_speeds: smallvec![(&AES_128_GCM, 600.0), (&AES_256_GCM, 500.0), (&CHACHA20_POLY1305, 400.0)],
allow_unencrypted: true
allow_unencrypted: true,
},
Algorithms {
algorithm_speeds: smallvec![(&AES_128_GCM, 600.0), (&AES_256_GCM, 500.0), (&CHACHA20_POLY1305, 400.0)],
allow_unencrypted: true
allow_unencrypted: true,
},
true,
None
None,
);
// Do not select unencrypted if only supported by one
test_algorithm_negotiation(
Algorithms {
algorithm_speeds: smallvec![(&AES_128_GCM, 600.0), (&AES_256_GCM, 500.0), (&CHACHA20_POLY1305, 400.0)],
allow_unencrypted: true
allow_unencrypted: true,
},
Algorithms {
algorithm_speeds: smallvec![(&AES_128_GCM, 600.0), (&AES_256_GCM, 500.0), (&CHACHA20_POLY1305, 400.0)],
allow_unencrypted: false
allow_unencrypted: false,
},
true,
Some(&AES_128_GCM)
Some(&AES_128_GCM),
);
// Fail if no match
@ -965,10 +957,10 @@ mod tests {
Algorithms { algorithm_speeds: smallvec![(&AES_128_GCM, 600.0)], allow_unencrypted: true },
Algorithms {
algorithm_speeds: smallvec![(&AES_256_GCM, 500.0), (&CHACHA20_POLY1305, 400.0)],
allow_unencrypted: false
allow_unencrypted: false,
},
false,
Some(&AES_128_GCM)
Some(&AES_128_GCM),
);
}
}

View File

@ -75,7 +75,7 @@ impl<D: Device, P: Protocol, S: Socket, TS: TimeSource> GenericCloud<D, P, S, TS
peer_crypto.clone(),
table.clone(),
);
let socket_thread = SocketThread::<S, D, P, TS>::new(
let mut socket_thread = SocketThread::<S, D, P, TS>::new(
config.clone(),
device,
socket,
@ -85,6 +85,7 @@ impl<D: Device, P: Protocol, S: Socket, TS: TimeSource> GenericCloud<D, P, S, TS
port_forwarding,
stats_file,
);
socket_thread.housekeep().await?;
Ok(Self { socket_thread, device_thread })
}

View File

@ -127,7 +127,7 @@ impl<S: Socket, D: Device, P: Protocol, TS: TimeSource> SocketThread<S, D, P, TS
next_beacon: now,
next_peers: now,
next_stats_out: now + STATS_INTERVAL,
next_own_address_reset: now + OWN_ADDRESS_RESET_INTERVAL,
next_own_address_reset: now,
pending_inits: HashMap::default(),
reconnect_peers: SmallVec::new(),
own_addresses: SmallVec::new(),
@ -336,20 +336,20 @@ impl<S: Socket, D: Device, P: Protocol, TS: TimeSource> SocketThread<S, D, P, TS
return Err(err);
}
};
self.update_peer_info(src, Some(info)).await?;
self.buffer.clear();
self.update_peer_info(src, Some(info)).await?;
}
MESSAGE_TYPE_KEEPALIVE => {
self.update_peer_info(src, None).await?;
self.buffer.clear();
self.update_peer_info(src, None).await?;
}
MESSAGE_TYPE_CLOSE => {
self.remove_peer(src);
self.buffer.clear();
self.remove_peer(src);
}
_ => {
self.traffic.count_invalid_protocol(self.buffer.len());
self.buffer.clear();
self.traffic.count_invalid_protocol(self.buffer.len());
return Err(Error::Message("Unknown message type"));
}
},

View File

@ -93,6 +93,7 @@ impl<P: Protocol> Simulator<P> {
DebugLogger::set_node(self.next_port as usize);
self.next_port += 1;
let node = TestNode::new(&config, MockSocket::new(addr), MockDevice::new(), None, None).await.unwrap();
DebugLogger::set_node(0);
self.nodes.insert(addr, node);
addr