use std::{ sync::Arc, time::{UNIX_EPOCH, SystemTime, Duration}, }; use async_trait::async_trait; use parity_scale_codec::{Encode, Decode}; use futures::SinkExt; use tokio::{sync::RwLock, time::sleep}; use tendermint_machine::{ ext::*, SignedMessageFor, StepSender, MessageSender, TendermintMachine, TendermintHandle, }; type TestValidatorId = u16; type TestBlockId = [u8; 4]; struct TestSigner(u16); #[async_trait] impl Signer for TestSigner { type ValidatorId = TestValidatorId; type Signature = [u8; 32]; async fn validator_id(&self) -> Option { Some(self.0) } async fn sign(&self, msg: &[u8]) -> [u8; 32] { let mut sig = [0; 32]; sig[.. 2].copy_from_slice(&self.0.to_le_bytes()); sig[2 .. (2 + 30.min(msg.len()))].copy_from_slice(&msg[.. 30.min(msg.len())]); sig } } struct TestSignatureScheme; impl SignatureScheme for TestSignatureScheme { type ValidatorId = TestValidatorId; type Signature = [u8; 32]; type AggregateSignature = Vec<[u8; 32]>; type Signer = TestSigner; #[must_use] fn verify(&self, validator: u16, msg: &[u8], sig: &[u8; 32]) -> bool { (sig[.. 2] == validator.to_le_bytes()) && (sig[2 ..] == [msg, &[0; 30]].concat()[.. 30]) } fn aggregate(sigs: &[[u8; 32]]) -> Vec<[u8; 32]> { sigs.to_vec() } #[must_use] fn verify_aggregate( &self, signers: &[TestValidatorId], msg: &[u8], sigs: &Vec<[u8; 32]>, ) -> bool { assert_eq!(signers.len(), sigs.len()); for sig in signers.iter().zip(sigs.iter()) { assert!(self.verify(*sig.0, msg, sig.1)); } true } } struct TestWeights; impl Weights for TestWeights { type ValidatorId = TestValidatorId; fn total_weight(&self) -> u64 { 4 } fn weight(&self, id: TestValidatorId) -> u64 { [1; 4][usize::try_from(id).unwrap()] } fn proposer(&self, number: BlockNumber, round: RoundNumber) -> TestValidatorId { TestValidatorId::try_from((number.0 + u64::from(round.0)) % 4).unwrap() } } #[derive(Clone, PartialEq, Debug, Encode, Decode)] struct TestBlock { id: TestBlockId, valid: Result<(), BlockError>, } impl Block for TestBlock { type Id = TestBlockId; fn id(&self) -> TestBlockId { self.id } } #[allow(clippy::type_complexity)] struct TestNetwork(u16, Arc, StepSender)>>>); #[async_trait] impl Network for TestNetwork { type ValidatorId = TestValidatorId; type SignatureScheme = TestSignatureScheme; type Weights = TestWeights; type Block = TestBlock; const BLOCK_PROCESSING_TIME: u32 = 2; const LATENCY_TIME: u32 = 1; fn signer(&self) -> TestSigner { TestSigner(self.0) } fn signature_scheme(&self) -> TestSignatureScheme { TestSignatureScheme } fn weights(&self) -> TestWeights { TestWeights } async fn broadcast(&mut self, msg: SignedMessageFor) { for (messages, _) in self.1.write().await.iter_mut() { messages.send(msg.clone()).await.unwrap(); } } async fn slash(&mut self, _: TestValidatorId) { dbg!("Slash"); todo!() } async fn validate(&mut self, block: &TestBlock) -> Result<(), BlockError> { block.valid } async fn add_block( &mut self, block: TestBlock, commit: Commit, ) -> Option { dbg!("Adding ", &block); assert!(block.valid.is_ok()); assert!(self.verify_commit(block.id(), &commit)); Some(TestBlock { id: (u32::from_le_bytes(block.id) + 1).to_le_bytes(), valid: Ok(()) }) } } impl TestNetwork { async fn new(validators: usize) -> Arc, StepSender)>>> { let arc = Arc::new(RwLock::new(vec![])); { let mut write = arc.write().await; for i in 0 .. validators { let i = u16::try_from(i).unwrap(); let TendermintHandle { messages, machine, step } = TendermintMachine::new( TestNetwork(i, arc.clone()), BlockNumber(1), SystemTime::now().duration_since(UNIX_EPOCH).unwrap().as_secs(), TestBlock { id: 1u32.to_le_bytes(), valid: Ok(()) }, ) .await; tokio::task::spawn(machine.run()); write.push((messages, step)); } } arc } } #[tokio::test] async fn test() { TestNetwork::new(4).await; sleep(Duration::from_secs(30)).await; }