openethereum/ethcore/sync/src/tests/consensus.rs
Anton Gavrilov d86333af6b Private transactions processing error handling (#8431)
* Integration test for private transaction returned

* Do not interrupt verification in case of errors

* Helpers use specified

* Review comments fixed
2018-04-20 15:45:53 +02:00

206 lines
9.2 KiB
Rust

// Copyright 2015-2017 Parity Technologies (UK) Ltd.
// This file is part of Parity.
// Parity is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
// Parity is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
// You should have received a copy of the GNU General Public License
// along with Parity. If not, see <http://www.gnu.org/licenses/>.
use std::sync::Arc;
use hash::keccak;
use ethereum_types::{U256, Address};
use io::{IoHandler, IoChannel};
use ethcore::client::{ChainInfo, ClientIoMessage};
use ethcore::spec::Spec;
use ethcore::miner::MinerService;
use ethcore::account_provider::AccountProvider;
use ethkey::{KeyPair, Secret};
use transaction::{Action, PendingTransaction, Transaction};
use super::helpers::*;
use SyncConfig;
fn new_tx(secret: &Secret, nonce: U256, chain_id: u64) -> PendingTransaction {
let signed = Transaction {
nonce: nonce.into(),
gas_price: 0.into(),
gas: 21000.into(),
action: Action::Call(Address::default()),
value: 0.into(),
data: Vec::new(),
}.sign(secret, Some(chain_id));
PendingTransaction::new(signed, None)
}
#[test]
fn authority_round() {
let s0 = KeyPair::from_secret_slice(&keccak("1")).unwrap();
let s1 = KeyPair::from_secret_slice(&keccak("0")).unwrap();
let ap = Arc::new(AccountProvider::transient_provider());
ap.insert_account(s0.secret().clone(), "").unwrap();
ap.insert_account(s1.secret().clone(), "").unwrap();
let chain_id = Spec::new_test_round().chain_id();
let mut net = TestNet::with_spec_and_accounts(2, SyncConfig::default(), Spec::new_test_round, Some(ap));
let io_handler0: Arc<IoHandler<ClientIoMessage>> = Arc::new(TestIoHandler::new(net.peer(0).chain.clone()));
let io_handler1: Arc<IoHandler<ClientIoMessage>> = Arc::new(TestIoHandler::new(net.peer(1).chain.clone()));
// Push transaction to both clients. Only one of them gets lucky to produce a block.
net.peer(0).miner.set_author(s0.address(), Some("".into())).unwrap();
net.peer(1).miner.set_author(s1.address(), Some("".to_owned())).unwrap();
net.peer(0).chain.engine().register_client(Arc::downgrade(&net.peer(0).chain) as _);
net.peer(1).chain.engine().register_client(Arc::downgrade(&net.peer(1).chain) as _);
net.peer(0).chain.set_io_channel(IoChannel::to_handler(Arc::downgrade(&io_handler1)));
net.peer(1).chain.set_io_channel(IoChannel::to_handler(Arc::downgrade(&io_handler0)));
// exchange statuses
net.sync();
// Trigger block proposal
net.peer(0).miner.import_own_transaction(&*net.peer(0).chain, new_tx(s0.secret(), 0.into(), chain_id)).unwrap();
net.peer(1).miner.import_own_transaction(&*net.peer(1).chain, new_tx(s1.secret(), 0.into(), chain_id)).unwrap();
// Sync a block
net.sync();
assert_eq!(net.peer(0).chain.chain_info().best_block_number, 1);
assert_eq!(net.peer(1).chain.chain_info().best_block_number, 1);
net.peer(0).miner.import_own_transaction(&*net.peer(0).chain, new_tx(s0.secret(), 1.into(), chain_id)).unwrap();
net.peer(1).miner.import_own_transaction(&*net.peer(1).chain, new_tx(s1.secret(), 1.into(), chain_id)).unwrap();
// Move to next proposer step.
net.peer(0).chain.engine().step();
net.peer(1).chain.engine().step();
net.sync();
assert_eq!(net.peer(0).chain.chain_info().best_block_number, 2);
assert_eq!(net.peer(1).chain.chain_info().best_block_number, 2);
// Fork the network with equal height.
net.peer(0).miner.import_own_transaction(&*net.peer(0).chain, new_tx(s0.secret(), 2.into(), chain_id)).unwrap();
net.peer(1).miner.import_own_transaction(&*net.peer(1).chain, new_tx(s1.secret(), 2.into(), chain_id)).unwrap();
// Let both nodes build one block.
net.peer(0).chain.engine().step();
let early_hash = net.peer(0).chain.chain_info().best_block_hash;
net.peer(1).chain.engine().step();
net.peer(0).chain.engine().step();
net.peer(1).chain.engine().step();
let ci0 = net.peer(0).chain.chain_info();
let ci1 = net.peer(1).chain.chain_info();
assert_eq!(ci0.best_block_number, 3);
assert_eq!(ci1.best_block_number, 3);
assert!(ci0.best_block_hash != ci1.best_block_hash);
// Reorg to the chain with earlier view.
net.sync();
let ci0 = net.peer(0).chain.chain_info();
let ci1 = net.peer(1).chain.chain_info();
assert_eq!(ci0.best_block_number, 3);
assert_eq!(ci1.best_block_number, 3);
assert_eq!(ci0.best_block_hash, ci1.best_block_hash);
assert_eq!(ci1.best_block_hash, early_hash);
// Selfish miner
net.peer(0).miner.import_own_transaction(&*net.peer(0).chain, new_tx(s0.secret(), 3.into(), chain_id)).unwrap();
net.peer(1).miner.import_own_transaction(&*net.peer(1).chain, new_tx(s1.secret(), 3.into(), chain_id)).unwrap();
// Node 0 is an earlier primary.
net.peer(0).chain.engine().step();
assert_eq!(net.peer(0).chain.chain_info().best_block_number, 4);
net.peer(0).chain.engine().step();
net.peer(0).chain.engine().step();
net.peer(0).chain.engine().step();
assert_eq!(net.peer(0).chain.chain_info().best_block_number, 4);
// Node 1 makes 2 blocks, but is a later primary on the first one.
net.peer(1).chain.engine().step();
net.peer(1).chain.engine().step();
net.peer(1).miner.import_own_transaction(&*net.peer(1).chain, new_tx(s1.secret(), 4.into(), chain_id)).unwrap();
net.peer(1).chain.engine().step();
net.peer(1).chain.engine().step();
assert_eq!(net.peer(1).chain.chain_info().best_block_number, 5);
// Reorg to the longest chain one not ealier view one.
net.sync();
let ci0 = net.peer(0).chain.chain_info();
let ci1 = net.peer(1).chain.chain_info();
assert_eq!(ci0.best_block_number, 5);
assert_eq!(ci1.best_block_number, 5);
assert_eq!(ci0.best_block_hash, ci1.best_block_hash);
}
#[test]
fn tendermint() {
let s0 = KeyPair::from_secret_slice(&keccak("1")).unwrap();
let s1 = KeyPair::from_secret_slice(&keccak("0")).unwrap();
let ap = Arc::new(AccountProvider::transient_provider());
ap.insert_account(s0.secret().clone(), "").unwrap();
ap.insert_account(s1.secret().clone(), "").unwrap();
let chain_id = Spec::new_test_tendermint().chain_id();
let mut net = TestNet::with_spec_and_accounts(2, SyncConfig::default(), Spec::new_test_tendermint, Some(ap));
let io_handler0: Arc<IoHandler<ClientIoMessage>> = Arc::new(TestIoHandler::new(net.peer(0).chain.clone()));
let io_handler1: Arc<IoHandler<ClientIoMessage>> = Arc::new(TestIoHandler::new(net.peer(1).chain.clone()));
// Push transaction to both clients. Only one of them issues a proposal.
net.peer(0).miner.set_author(s0.address(), Some("".into())).unwrap();
trace!(target: "poa", "Peer 0 is {}.", s0.address());
net.peer(1).miner.set_author(s1.address(), Some("".into())).unwrap();
trace!(target: "poa", "Peer 1 is {}.", s1.address());
net.peer(0).chain.engine().register_client(Arc::downgrade(&net.peer(0).chain) as _);
net.peer(1).chain.engine().register_client(Arc::downgrade(&net.peer(1).chain) as _);
net.peer(0).chain.set_io_channel(IoChannel::to_handler(Arc::downgrade(&io_handler0)));
net.peer(1).chain.set_io_channel(IoChannel::to_handler(Arc::downgrade(&io_handler1)));
// Exhange statuses
net.sync();
// Propose
net.peer(0).miner.import_own_transaction(&*net.peer(0).chain, new_tx(s0.secret(), 0.into(), chain_id)).unwrap();
net.sync();
// Propose timeout, synchronous for now
net.peer(0).chain.engine().step();
net.peer(1).chain.engine().step();
// Prevote, precommit and commit
net.sync();
assert_eq!(net.peer(0).chain.chain_info().best_block_number, 1);
assert_eq!(net.peer(1).chain.chain_info().best_block_number, 1);
net.peer(1).miner.import_own_transaction(&*net.peer(1).chain, new_tx(s1.secret(), 0.into(), chain_id)).unwrap();
// Commit timeout
net.peer(0).chain.engine().step();
net.peer(1).chain.engine().step();
// Propose
net.sync();
// Propose timeout
net.peer(0).chain.engine().step();
net.peer(1).chain.engine().step();
// Prevote, precommit and commit
net.sync();
assert_eq!(net.peer(0).chain.chain_info().best_block_number, 2);
assert_eq!(net.peer(1).chain.chain_info().best_block_number, 2);
net.peer(0).miner.import_own_transaction(&*net.peer(0).chain, new_tx(s0.secret(), 1.into(), chain_id)).unwrap();
net.peer(1).miner.import_own_transaction(&*net.peer(1).chain, new_tx(s1.secret(), 1.into(), chain_id)).unwrap();
// Peers get disconnected.
// Commit
net.peer(0).chain.engine().step();
net.peer(1).chain.engine().step();
// Propose
net.peer(0).chain.engine().step();
net.peer(1).chain.engine().step();
net.peer(0).miner.import_own_transaction(&*net.peer(0).chain, new_tx(s0.secret(), 2.into(), chain_id)).unwrap();
net.peer(1).miner.import_own_transaction(&*net.peer(1).chain, new_tx(s1.secret(), 2.into(), chain_id)).unwrap();
// Send different prevotes
net.sync();
// Prevote timeout
net.peer(0).chain.engine().step();
net.peer(1).chain.engine().step();
// Precommit and commit
net.sync();
// Propose timeout
net.peer(0).chain.engine().step();
net.peer(1).chain.engine().step();
net.sync();
let ci0 = net.peer(0).chain.chain_info();
let ci1 = net.peer(1).chain.chain_info();
assert_eq!(ci0.best_block_number, 3);
assert_eq!(ci1.best_block_number, 3);
assert_eq!(ci0.best_block_hash, ci1.best_block_hash);
}