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zssp/reference/examples/extensive_test.rs
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Monica Moniot edcf5ebd16 finished update
2023-09-26 08:34:45 -04:00

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/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at https://mozilla.org/MPL/2.0/.
*
* (c) ZeroTier, Inc.
* https://www.zerotier.com/
*/
use std::collections::HashMap;
use std::iter::ExactSizeIterator;
use std::str::FromStr;
use std::sync::atomic::{AtomicBool, Ordering};
use std::sync::{mpsc, Arc};
use std::thread;
use std::time::{Duration, Instant};
use rand_core::OsRng;
use rand_core::RngCore;
use zssp_proto::application::{
AcceptAction, ApplicationLayer, CryptoLayer, RatchetState, RatchetStates, RatchetUpdate, Settings, RATCHET_SIZE,
};
use zssp_proto::crypto::P384KeyPair;
use zssp_proto::crypto_impl::{
Aes256Crate, AesGcmCrate, Kyber1024CratePrivateKey, P384CrateKeyPair, P384CratePublicKey, Sha512Crate,
};
use zssp_proto::Session;
const TEST_MTU: usize = 1500;
struct TestApplication {
time: Instant,
name: &'static str,
ratchets: Ratchets,
}
struct Ratchets {
rf_map: HashMap<[u8; RATCHET_SIZE], RatchetState>,
peer_map: HashMap<u128, RatchetStates>,
}
impl Ratchets {
fn new() -> Self {
Self { rf_map: HashMap::new(), peer_map: HashMap::new() }
}
}
impl CryptoLayer for TestApplication {
const SETTINGS: Settings = Settings {
initial_offer_timeout: Settings::INITIAL_OFFER_TIMEOUT_MS,
rekey_timeout: 60 * 1000,
rekey_after_time: 3000,
rekey_time_max_jitter: 1000,
rekey_after_key_uses: Settings::REKEY_AFTER_KEY_USES,
resend_time: 250,
fragment_assembly_timeout: Settings::FRAGMENT_ASSEMBLY_TIMEOUT_MS,
};
type Rng = OsRng;
type Prp = Aes256Crate;
type Aead = AesGcmCrate;
type Hash = Sha512Crate;
type PublicKey = P384CratePublicKey;
type KeyPair = P384CrateKeyPair;
type Kem = Kyber1024CratePrivateKey;
type SessionData = u128;
}
#[allow(unused)]
impl ApplicationLayer for &mut TestApplication {
type Crypto = TestApplication;
fn hello_requires_recognized_ratchet(&mut self) -> bool {
false
}
fn initiator_disallows_downgrade(&mut self, session: &Arc<Session<TestApplication>>) -> bool {
true
}
fn check_accept_session(
&mut self,
remote_static_key: &P384CratePublicKey,
identity: &[u8],
) -> AcceptAction<TestApplication> {
AcceptAction {
session_data: Some(1),
responder_disallows_downgrade: true,
responder_silently_rejects: false,
}
}
fn restore_by_fingerprint(
&mut self,
ratchet_fingerprint: &[u8; RATCHET_SIZE],
) -> Result<Option<RatchetState>, std::io::Error> {
Ok(self.ratchets.rf_map.get(ratchet_fingerprint).cloned())
}
fn restore_by_identity(
&mut self,
remote_static_key: &P384CratePublicKey,
session_data: &u128,
) -> Result<Option<RatchetStates>, std::io::Error> {
Ok(self.ratchets.peer_map.get(session_data).cloned())
}
fn save_ratchet_state(
&mut self,
remote_static_key: &P384CratePublicKey,
session_data: &u128,
update_data: RatchetUpdate<'_>,
) -> Result<(), std::io::Error> {
self.ratchets.peer_map.insert(*session_data, update_data.to_states());
if let Some(rf) = update_data.added_fingerprint() {
self.ratchets.rf_map.insert(*rf, update_data.state1.clone());
println!("[{}] new ratchet #{}", self.name, update_data.state1.chain_len());
}
if let Some(rf) = update_data.deleted_fingerprint1() {
self.ratchets.rf_map.remove(rf);
}
if let Some(rf) = update_data.deleted_fingerprint2() {
self.ratchets.rf_map.remove(rf);
}
Ok(())
}
fn time(&mut self) -> i64 {
self.time.elapsed().as_millis() as i64
}
fn event_log(&mut self, event: zssp_proto::LogEvent<TestApplication>) {
println!(">[{}] {:?}", self.name, event);
}
}
fn alice_main(
run: &AtomicBool,
packet_success_rate: u32,
mut alice_app: TestApplication,
alice_out: mpsc::SyncSender<Vec<u8>>,
alice_in: mpsc::Receiver<Vec<u8>>,
recursive_out: mpsc::SyncSender<Vec<u8>>,
alice_keypair: P384CrateKeyPair,
bob_pubkey: P384CratePublicKey,
) {
let startup_time = std::time::Instant::now();
let mut context = zssp_proto::Context::<TestApplication>::new(alice_keypair, OsRng);
let mut next_service = startup_time.elapsed().as_millis() as i64 + 500;
let test_data = [1u8; TEST_MTU * 10];
let mut up = false;
let mut alice_session = None;
while run.load(Ordering::Relaxed) {
if alice_session.is_none() {
up = false;
alice_session = Some(
context
.open(
&mut alice_app,
|b| alice_out.send(b).is_ok(),
TEST_MTU,
bob_pubkey.clone(),
0,
Vec::new(),
)
.unwrap(),
);
println!("[alice] opening session");
}
let current_time = startup_time.elapsed().as_millis() as i64;
loop {
let pkt = alice_in.try_recv();
if let Ok(pkt) = pkt {
if OsRng.next_u32() <= packet_success_rate {
use zssp_proto::result::ReceiveError::*;
use zssp_proto::result::ReceiveOk::*;
use zssp_proto::result::SessionEvent::*;
match context.receive(
&mut alice_app,
|b| alice_out.send(b).is_ok(),
TEST_MTU,
|_| Some((|b| alice_out.send(b).is_ok(), TEST_MTU)),
&0,
pkt,
) {
Ok(Unassociated) => {
//println!("[alice] ok");
}
Ok(Session(_, event)) => match event {
Established => {
up = true;
}
Data(data) => {
assert!(!data.is_empty());
//println!("[alice] received {}", data.len());
}
Control => (),
_ => panic!(),
},
Err(e) => {
println!("[alice] ERROR {:?}", e);
if let ByzantineFault(e) = e {
assert!(!e.unnatural())
}
}
}
} else if OsRng.next_u32() | 1 > 0 {
let _ = recursive_out.send(pkt);
}
} else {
break;
}
}
if up {
context
.send(
alice_session.as_ref().unwrap(),
|b| alice_out.send(b).is_ok(),
TEST_MTU,
test_data[..1400 + ((OsRng.next_u64() as usize) % (test_data.len() - 1400))].to_vec(),
)
.unwrap();
} else {
thread::sleep(Duration::from_millis(10));
}
// TODO: we need to more comprehensively test if re-opening the session works
if OsRng.next_u32() <= ((u32::MAX as f64) * 0.000005) as u32 {
alice_session = None;
}
if current_time >= next_service {
next_service =
current_time + context.service(&mut alice_app, |_| Some((|b| alice_out.send(b).is_ok(), TEST_MTU)));
}
}
}
fn bob_main(
run: &AtomicBool,
packet_success_rate: u32,
mut bob_app: TestApplication,
bob_out: mpsc::SyncSender<Vec<u8>>,
bob_in: mpsc::Receiver<Vec<u8>>,
recursive_out: mpsc::SyncSender<Vec<u8>>,
bob_keypair: P384CrateKeyPair,
) {
let startup_time = std::time::Instant::now();
let mut context = zssp_proto::Context::<TestApplication>::new(bob_keypair, OsRng);
let mut last_speed_metric = startup_time.elapsed().as_millis() as i64;
let mut next_service = last_speed_metric + 500;
let mut transferred = 0u64;
let mut bob_session = None;
while run.load(Ordering::Relaxed) {
let pkt = bob_in.recv_timeout(Duration::from_millis(100));
let current_time = startup_time.elapsed().as_millis() as i64;
if let Ok(pkt) = pkt {
if OsRng.next_u32() <= packet_success_rate {
use zssp_proto::result::ReceiveError::*;
use zssp_proto::result::ReceiveOk::*;
use zssp_proto::result::SessionEvent::*;
match context.receive(
&mut bob_app,
|b| bob_out.send(b).is_ok(),
TEST_MTU,
|_| Some((|b| bob_out.send(b).is_ok(), TEST_MTU)),
&0,
pkt,
) {
Ok(Unassociated) => {}
Ok(Session(s, event)) => match event {
NewSession | NewDowngradedSession => {
println!("[bob] new session, took {}s", current_time as f32 / 1000.0);
let _ = bob_session.replace(s);
}
Data(data) => {
assert!(!data.is_empty());
//println!("[bob] received {}", data.len());
transferred += data.len() as u64 * 2; // *2 because we are also sending this many bytes back
context.send(&s, |b| bob_out.send(b).is_ok(), TEST_MTU, data).unwrap();
}
Control => (),
_ => panic!(),
},
Err(e) => {
println!("[bob] ERROR {:?}", e);
if let ByzantineFault(e) = e {
assert!(!e.unnatural())
}
}
}
} else if OsRng.next_u32() | 1 > 0 {
let _ = recursive_out.try_send(pkt);
}
}
let speed_metric_elapsed = current_time - last_speed_metric;
if speed_metric_elapsed >= 10000 {
last_speed_metric = current_time;
println!(
"[bob] throughput: {} MiB/sec (combined input and output)",
((transferred as f64) / 1048576.0) / ((speed_metric_elapsed as f64) / 1000.0)
);
transferred = 0;
}
if current_time >= next_service {
next_service =
current_time + context.service(&mut bob_app, |_| Some((|b| bob_out.send(b).is_ok(), TEST_MTU)));
}
}
}
fn core(time: u64, packet_success_rate: u32) {
let run = &AtomicBool::new(true);
let alice_keypair = P384CrateKeyPair::generate(&mut OsRng);
let alice_app = TestApplication {
time: Instant::now(),
name: "alice",
ratchets: Ratchets::new(),
};
let bob_keypair = P384CrateKeyPair::generate(&mut OsRng);
let bob_pubkey = bob_keypair.public_key();
let bob_app = TestApplication { time: Instant::now(), name: "bob", ratchets: Ratchets::new() };
let (alice_out, bob_in) = mpsc::sync_channel::<Vec<u8>>(256);
let (bob_out, alice_in) = mpsc::sync_channel::<Vec<u8>>(256);
thread::scope(|ts| {
{
let alice_out = alice_out.clone();
let bob_out = bob_out.clone();
ts.spawn(move || {
alice_main(
run,
packet_success_rate,
alice_app,
alice_out,
alice_in,
bob_out,
alice_keypair,
bob_pubkey,
)
});
}
ts.spawn(move || {
bob_main(
run,
packet_success_rate,
bob_app,
bob_out,
bob_in,
alice_out,
bob_keypair,
)
});
thread::sleep(Duration::from_secs(time));
run.store(false, Ordering::SeqCst);
println!("finished");
});
}
fn main() {
let args = std::env::args();
let packet_success_rate = if args.len() <= 1 {
let default_success_rate = 1.0;
((u32::MAX as f64) * default_success_rate) as u32
} else {
((u32::MAX as f64) * f64::from_str(args.last().unwrap().as_str()).unwrap()) as u32
};
core(60 * 60, packet_success_rate)
}
#[test]
fn test_main() {
core(2, u32::MAX / 2)
}
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