// 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 . //! Block and transaction verification functions //! //! Block verification is done in 3 steps //! 1. Quick verification upon adding to the block queue //! 2. Signatures verification done in the queue. //! 3. Final verification against the blockchain done before enactment. use std::collections::HashSet; use blockchain::*; use client::BlockChainClient; use engines::EthEngine; use error::{BlockError, Error}; use header::{BlockNumber, Header}; use transaction::SignedTransaction; use views::BlockView; use ethereum_types::{H256, U256}; use bytes::Bytes; use hash::keccak; use heapsize::HeapSizeOf; use rlp::UntrustedRlp; use time::get_time; use triehash::ordered_trie_root; use unexpected::{Mismatch, OutOfBounds}; /// Preprocessed block data gathered in `verify_block_unordered` call pub struct PreverifiedBlock { /// Populated block header pub header: Header, /// Populated block transactions pub transactions: Vec, /// Block bytes pub bytes: Bytes, } impl HeapSizeOf for PreverifiedBlock { fn heap_size_of_children(&self) -> usize { self.header.heap_size_of_children() + self.transactions.heap_size_of_children() + self.bytes.heap_size_of_children() } } /// Phase 1 quick block verification. Only does checks that are cheap. Operates on a single block pub fn verify_block_basic(header: &Header, bytes: &[u8], engine: &EthEngine) -> Result<(), Error> { verify_header_params(&header, engine, true)?; verify_block_integrity(bytes, &header.transactions_root(), &header.uncles_hash())?; engine.verify_block_basic(&header)?; for u in UntrustedRlp::new(bytes).at(2)?.iter().map(|rlp| rlp.as_val::
()) { let u = u?; verify_header_params(&u, engine, false)?; engine.verify_block_basic(&u)?; } // Verify transactions. // TODO: either use transaction views or cache the decoded transactions. let v = BlockView::new(bytes); for t in v.transactions() { engine.verify_transaction_basic(&t, &header)?; } Ok(()) } /// Phase 2 verification. Perform costly checks such as transaction signatures and block nonce for ethash. /// Still operates on a individual block /// Returns a `PreverifiedBlock` structure populated with transactions pub fn verify_block_unordered(header: Header, bytes: Bytes, engine: &EthEngine, check_seal: bool) -> Result { if check_seal { engine.verify_block_unordered(&header)?; for u in UntrustedRlp::new(&bytes).at(2)?.iter().map(|rlp| rlp.as_val::
()) { engine.verify_block_unordered(&u?)?; } } // Verify transactions. let mut transactions = Vec::new(); let nonce_cap = if header.number() >= engine.params().dust_protection_transition { Some((engine.params().nonce_cap_increment * header.number()).into()) } else { None }; { let v = BlockView::new(&bytes); for t in v.transactions() { let t = engine.verify_transaction_unordered(t, &header)?; if let Some(max_nonce) = nonce_cap { if t.nonce >= max_nonce { return Err(BlockError::TooManyTransactions(t.sender()).into()); } } transactions.push(t); } } Ok(PreverifiedBlock { header: header, transactions: transactions, bytes: bytes, }) } /// Parameters for full verification of block family: block bytes, transactions, blockchain, and state access. pub type FullFamilyParams<'a> = (&'a [u8], &'a [SignedTransaction], &'a BlockProvider, &'a BlockChainClient); /// Phase 3 verification. Check block information against parent and uncles. pub fn verify_block_family(header: &Header, parent: &Header, engine: &EthEngine, do_full: Option) -> Result<(), Error> { // TODO: verify timestamp verify_parent(&header, &parent, engine.params().gas_limit_bound_divisor)?; engine.verify_block_family(&header, &parent)?; let (bytes, txs, bc, client) = match do_full { Some(x) => x, None => return Ok(()), }; verify_uncles(header, bytes, bc, engine)?; for transaction in txs { engine.machine().verify_transaction(transaction, header, client)?; } Ok(()) } fn verify_uncles(header: &Header, bytes: &[u8], bc: &BlockProvider, engine: &EthEngine) -> Result<(), Error> { let num_uncles = UntrustedRlp::new(bytes).at(2)?.item_count()?; let max_uncles = engine.maximum_uncle_count(header.number()); if num_uncles != 0 { if num_uncles > max_uncles { return Err(From::from(BlockError::TooManyUncles(OutOfBounds { min: None, max: Some(max_uncles), found: num_uncles, }))); } let mut excluded = HashSet::new(); excluded.insert(header.hash()); let mut hash = header.parent_hash().clone(); excluded.insert(hash.clone()); for _ in 0..engine.maximum_uncle_age() { match bc.block_details(&hash) { Some(details) => { excluded.insert(details.parent.clone()); let b = bc.block(&hash) .expect("parent already known to be stored; qed"); excluded.extend(b.uncle_hashes()); hash = details.parent; } None => break } } let mut verified = HashSet::new(); for uncle in UntrustedRlp::new(bytes).at(2)?.iter().map(|rlp| rlp.as_val::
()) { let uncle = uncle?; if excluded.contains(&uncle.hash()) { return Err(From::from(BlockError::UncleInChain(uncle.hash()))) } if verified.contains(&uncle.hash()) { return Err(From::from(BlockError::DuplicateUncle(uncle.hash()))) } // m_currentBlock.number() - uncle.number() m_cB.n - uP.n() // 1 2 // 2 // 3 // 4 // 5 // 6 7 // (8 Invalid) let depth = if header.number() > uncle.number() { header.number() - uncle.number() } else { 0 }; if depth > engine.maximum_uncle_age() as u64 { return Err(From::from(BlockError::UncleTooOld(OutOfBounds { min: Some(header.number() - depth), max: Some(header.number() - 1), found: uncle.number() }))); } else if depth < 1 { return Err(From::from(BlockError::UncleIsBrother(OutOfBounds { min: Some(header.number() - depth), max: Some(header.number() - 1), found: uncle.number() }))); } // cB // cB.p^1 1 depth, valid uncle // cB.p^2 ---/ 2 // cB.p^3 -----/ 3 // cB.p^4 -------/ 4 // cB.p^5 ---------/ 5 // cB.p^6 -----------/ 6 // cB.p^7 -------------/ // cB.p^8 let mut expected_uncle_parent = header.parent_hash().clone(); let uncle_parent = bc.block_header(&uncle.parent_hash()).ok_or_else(|| Error::from(BlockError::UnknownUncleParent(uncle.parent_hash().clone())))?; for _ in 0..depth { match bc.block_details(&expected_uncle_parent) { Some(details) => { expected_uncle_parent = details.parent; }, None => break } } if expected_uncle_parent != uncle_parent.hash() { return Err(From::from(BlockError::UncleParentNotInChain(uncle_parent.hash()))); } verify_parent(&uncle, &uncle_parent, engine.params().gas_limit_bound_divisor)?; engine.verify_block_family(&uncle, &uncle_parent)?; verified.insert(uncle.hash()); } } Ok(()) } /// Phase 4 verification. Check block information against transaction enactment results, pub fn verify_block_final(expected: &Header, got: &Header) -> Result<(), Error> { if expected.gas_used() != got.gas_used() { return Err(From::from(BlockError::InvalidGasUsed(Mismatch { expected: expected.gas_used().clone(), found: got.gas_used().clone() }))) } if expected.log_bloom() != got.log_bloom() { return Err(From::from(BlockError::InvalidLogBloom(Mismatch { expected: expected.log_bloom().clone(), found: got.log_bloom().clone() }))) } if expected.state_root() != got.state_root() { return Err(From::from(BlockError::InvalidStateRoot(Mismatch { expected: expected.state_root().clone(), found: got.state_root().clone() }))) } if expected.receipts_root() != got.receipts_root() { return Err(From::from(BlockError::InvalidReceiptsRoot(Mismatch { expected: expected.receipts_root().clone(), found: got.receipts_root().clone() }))) } Ok(()) } /// Check basic header parameters. pub fn verify_header_params(header: &Header, engine: &EthEngine, is_full: bool) -> Result<(), Error> { if header.seal().len() != engine.seal_fields() { return Err(From::from(BlockError::InvalidSealArity( Mismatch { expected: engine.seal_fields(), found: header.seal().len() } ))); } if header.number() >= From::from(BlockNumber::max_value()) { return Err(From::from(BlockError::RidiculousNumber(OutOfBounds { max: Some(From::from(BlockNumber::max_value())), min: None, found: header.number() }))) } if header.gas_used() > header.gas_limit() { return Err(From::from(BlockError::TooMuchGasUsed(OutOfBounds { max: Some(header.gas_limit().clone()), min: None, found: header.gas_used().clone() }))); } let min_gas_limit = engine.params().min_gas_limit; if header.gas_limit() < &min_gas_limit { return Err(From::from(BlockError::InvalidGasLimit(OutOfBounds { min: Some(min_gas_limit), max: None, found: header.gas_limit().clone() }))); } let maximum_extra_data_size = engine.maximum_extra_data_size(); if header.number() != 0 && header.extra_data().len() > maximum_extra_data_size { return Err(From::from(BlockError::ExtraDataOutOfBounds(OutOfBounds { min: None, max: Some(maximum_extra_data_size), found: header.extra_data().len() }))); } if let Some(ref ext) = engine.machine().ethash_extensions() { if header.number() >= ext.dao_hardfork_transition && header.number() <= ext.dao_hardfork_transition + 9 && header.extra_data()[..] != b"dao-hard-fork"[..] { return Err(From::from(BlockError::ExtraDataOutOfBounds(OutOfBounds { min: None, max: None, found: 0 }))); } } if is_full { const ACCEPTABLE_DRIFT_SECS: u64 = 15; let max_time = get_time().sec as u64 + ACCEPTABLE_DRIFT_SECS; let invalid_threshold = max_time + ACCEPTABLE_DRIFT_SECS * 9; let timestamp = header.timestamp(); if timestamp > invalid_threshold { return Err(From::from(BlockError::InvalidTimestamp(OutOfBounds { max: Some(max_time), min: None, found: timestamp }))) } if timestamp > max_time { return Err(From::from(BlockError::TemporarilyInvalid(OutOfBounds { max: Some(max_time), min: None, found: timestamp }))) } } Ok(()) } /// Check header parameters agains parent header. fn verify_parent(header: &Header, parent: &Header, gas_limit_divisor: U256) -> Result<(), Error> { if !header.parent_hash().is_zero() && &parent.hash() != header.parent_hash() { return Err(From::from(BlockError::InvalidParentHash(Mismatch { expected: parent.hash(), found: header.parent_hash().clone() }))) } if header.timestamp() <= parent.timestamp() { return Err(From::from(BlockError::InvalidTimestamp(OutOfBounds { max: None, min: Some(parent.timestamp() + 1), found: header.timestamp() }))) } if header.number() != parent.number() + 1 { return Err(From::from(BlockError::InvalidNumber(Mismatch { expected: parent.number() + 1, found: header.number() }))); } if header.number() == 0 { return Err(BlockError::RidiculousNumber(OutOfBounds { min: Some(1), max: None, found: header.number() }).into()); } let parent_gas_limit = *parent.gas_limit(); let min_gas = parent_gas_limit - parent_gas_limit / gas_limit_divisor; let max_gas = parent_gas_limit + parent_gas_limit / gas_limit_divisor; if header.gas_limit() <= &min_gas || header.gas_limit() >= &max_gas { return Err(From::from(BlockError::InvalidGasLimit(OutOfBounds { min: Some(min_gas), max: Some(max_gas), found: header.gas_limit().clone() }))); } Ok(()) } /// Verify block data against header: transactions root and uncles hash. fn verify_block_integrity(block: &[u8], transactions_root: &H256, uncles_hash: &H256) -> Result<(), Error> { let block = UntrustedRlp::new(block); let tx = block.at(1)?; let expected_root = &ordered_trie_root(tx.iter().map(|r| r.as_raw().to_vec())); //TODO: get rid of vectors here if expected_root != transactions_root { return Err(From::from(BlockError::InvalidTransactionsRoot(Mismatch { expected: expected_root.clone(), found: transactions_root.clone() }))) } let expected_uncles = &keccak(block.at(2)?.as_raw()); if expected_uncles != uncles_hash { return Err(From::from(BlockError::InvalidUnclesHash(Mismatch { expected: expected_uncles.clone(), found: uncles_hash.clone() }))) } Ok(()) } #[cfg(test)] mod tests { use super::*; use std::collections::{BTreeMap, HashMap}; use ethereum_types::{H256, H2048, U256}; use blockchain::extras::{BlockDetails, TransactionAddress, BlockReceipts}; use encoded; use hash::keccak; use engines::EthEngine; use error::BlockError::*; use ethkey::{Random, Generator}; use spec::{CommonParams, Spec}; use tests::helpers::{create_test_block_with_data, create_test_block}; use time::get_time; use transaction::{SignedTransaction, Transaction, UnverifiedTransaction, Action}; use types::log_entry::{LogEntry, LocalizedLogEntry}; fn check_ok(result: Result<(), Error>) { result.unwrap_or_else(|e| panic!("Block verification failed: {:?}", e)); } fn check_fail(result: Result<(), Error>, e: BlockError) { match result { Err(Error::Block(ref error)) if *error == e => (), Err(other) => panic!("Block verification failed.\nExpected: {:?}\nGot: {:?}", e, other), Ok(_) => panic!("Block verification failed.\nExpected: {:?}\nGot: Ok", e), } } fn check_fail_timestamp(result: Result<(), Error>, temp: bool) { let name = if temp { "TemporarilyInvalid" } else { "InvalidTimestamp" }; match result { Err(Error::Block(BlockError::InvalidTimestamp(_))) if !temp => (), Err(Error::Block(BlockError::TemporarilyInvalid(_))) if temp => (), Err(other) => panic!("Block verification failed.\nExpected: {}\nGot: {:?}", name, other), Ok(_) => panic!("Block verification failed.\nExpected: {}\nGot: Ok", name), } } struct TestBlockChain { blocks: HashMap, numbers: HashMap, } impl Default for TestBlockChain { fn default() -> Self { TestBlockChain::new() } } impl TestBlockChain { pub fn new() -> Self { TestBlockChain { blocks: HashMap::new(), numbers: HashMap::new(), } } pub fn insert(&mut self, bytes: Bytes) { let number = BlockView::new(&bytes).header_view().number(); let hash = BlockView::new(&bytes).header_view().hash(); self.blocks.insert(hash.clone(), bytes); self.numbers.insert(number, hash.clone()); } } impl BlockProvider for TestBlockChain { fn is_known(&self, hash: &H256) -> bool { self.blocks.contains_key(hash) } fn first_block(&self) -> Option { unimplemented!() } /// Get raw block data fn block(&self, hash: &H256) -> Option { self.blocks.get(hash).cloned().map(encoded::Block::new) } fn block_header_data(&self, hash: &H256) -> Option { self.block(hash) .map(|b| b.header_view().rlp().as_raw().to_vec()) .map(encoded::Header::new) } fn block_body(&self, hash: &H256) -> Option { self.block(hash) .map(|b| BlockChain::block_to_body(&b.into_inner())) .map(encoded::Body::new) } fn best_ancient_block(&self) -> Option { None } /// Get the familial details concerning a block. fn block_details(&self, hash: &H256) -> Option { self.blocks.get(hash).map(|bytes| { let header = BlockView::new(bytes).header(); BlockDetails { number: header.number(), total_difficulty: header.difficulty().clone(), parent: header.parent_hash().clone(), children: Vec::new(), } }) } fn transaction_address(&self, _hash: &H256) -> Option { unimplemented!() } /// Get the hash of given block's number. fn block_hash(&self, index: BlockNumber) -> Option { self.numbers.get(&index).cloned() } fn block_receipts(&self, _hash: &H256) -> Option { unimplemented!() } fn blocks_with_bloom(&self, _bloom: &H2048, _from_block: BlockNumber, _to_block: BlockNumber) -> Vec { unimplemented!() } fn logs(&self, _blocks: Vec, _matches: F, _limit: Option) -> Vec where F: Fn(&LogEntry) -> bool, Self: Sized { unimplemented!() } } fn basic_test(bytes: &[u8], engine: &EthEngine) -> Result<(), Error> { let header = BlockView::new(bytes).header(); verify_block_basic(&header, bytes, engine) } fn family_test(bytes: &[u8], engine: &EthEngine, bc: &BC) -> Result<(), Error> where BC: BlockProvider { let view = BlockView::new(bytes); let header = view.header(); let transactions: Vec<_> = view.transactions() .into_iter() .map(SignedTransaction::new) .collect::>()?; // TODO: client is really meant to be used for state query here by machine // additions that need access to state (tx filter in specific) // no existing tests need access to test, so having this not function // is fine. let client = ::client::TestBlockChainClient::default(); let parent = bc.block_header(header.parent_hash()) .ok_or(BlockError::UnknownParent(header.parent_hash().clone()))?; let full_params: FullFamilyParams = ( bytes, &transactions[..], bc as &BlockProvider, &client as &::client::BlockChainClient ); verify_block_family(&header, &parent, engine, Some(full_params)) } fn unordered_test(bytes: &[u8], engine: &EthEngine) -> Result<(), Error> { let header = BlockView::new(bytes).header(); verify_block_unordered(header, bytes.to_vec(), engine, false)?; Ok(()) } #[test] fn test_verify_block() { use rlp::RlpStream; // Test against morden let mut good = Header::new(); let spec = Spec::new_test(); let engine = &*spec.engine; let min_gas_limit = engine.params().min_gas_limit; good.set_gas_limit(min_gas_limit); good.set_timestamp(40); good.set_number(10); let keypair = Random.generate().unwrap(); let tr1 = Transaction { action: Action::Create, value: U256::from(0), data: Bytes::new(), gas: U256::from(30_000), gas_price: U256::from(40_000), nonce: U256::one() }.sign(keypair.secret(), None); let tr2 = Transaction { action: Action::Create, value: U256::from(0), data: Bytes::new(), gas: U256::from(30_000), gas_price: U256::from(40_000), nonce: U256::from(2) }.sign(keypair.secret(), None); let good_transactions = [ tr1.clone(), tr2.clone() ]; let diff_inc = U256::from(0x40); let mut parent6 = good.clone(); parent6.set_number(6); let mut parent7 = good.clone(); parent7.set_number(7); parent7.set_parent_hash(parent6.hash()); parent7.set_difficulty(parent6.difficulty().clone() + diff_inc); parent7.set_timestamp(parent6.timestamp() + 10); let mut parent8 = good.clone(); parent8.set_number(8); parent8.set_parent_hash(parent7.hash()); parent8.set_difficulty(parent7.difficulty().clone() + diff_inc); parent8.set_timestamp(parent7.timestamp() + 10); let mut good_uncle1 = good.clone(); good_uncle1.set_number(9); good_uncle1.set_parent_hash(parent8.hash()); good_uncle1.set_difficulty(parent8.difficulty().clone() + diff_inc); good_uncle1.set_timestamp(parent8.timestamp() + 10); good_uncle1.extra_data_mut().push(1u8); let mut good_uncle2 = good.clone(); good_uncle2.set_number(8); good_uncle2.set_parent_hash(parent7.hash()); good_uncle2.set_difficulty(parent7.difficulty().clone() + diff_inc); good_uncle2.set_timestamp(parent7.timestamp() + 10); good_uncle2.extra_data_mut().push(2u8); let good_uncles = vec![ good_uncle1.clone(), good_uncle2.clone() ]; let mut uncles_rlp = RlpStream::new(); uncles_rlp.append_list(&good_uncles); let good_uncles_hash = keccak(uncles_rlp.as_raw()); let good_transactions_root = ordered_trie_root(good_transactions.iter().map(|t| ::rlp::encode::(t).into_vec())); let mut parent = good.clone(); parent.set_number(9); parent.set_timestamp(parent8.timestamp() + 10); parent.set_parent_hash(parent8.hash()); parent.set_difficulty(parent8.difficulty().clone() + diff_inc); good.set_parent_hash(parent.hash()); good.set_difficulty(parent.difficulty().clone() + diff_inc); good.set_timestamp(parent.timestamp() + 10); let mut bc = TestBlockChain::new(); bc.insert(create_test_block(&good)); bc.insert(create_test_block(&parent)); bc.insert(create_test_block(&parent6)); bc.insert(create_test_block(&parent7)); bc.insert(create_test_block(&parent8)); check_ok(basic_test(&create_test_block(&good), engine)); let mut header = good.clone(); header.set_transactions_root(good_transactions_root.clone()); header.set_uncles_hash(good_uncles_hash.clone()); check_ok(basic_test(&create_test_block_with_data(&header, &good_transactions, &good_uncles), engine)); header.set_gas_limit(min_gas_limit - From::from(1)); check_fail(basic_test(&create_test_block(&header), engine), InvalidGasLimit(OutOfBounds { min: Some(min_gas_limit), max: None, found: header.gas_limit().clone() })); header = good.clone(); header.set_number(BlockNumber::max_value()); check_fail(basic_test(&create_test_block(&header), engine), RidiculousNumber(OutOfBounds { max: Some(BlockNumber::max_value()), min: None, found: header.number() })); header = good.clone(); let gas_used = header.gas_limit().clone() + 1.into(); header.set_gas_used(gas_used); check_fail(basic_test(&create_test_block(&header), engine), TooMuchGasUsed(OutOfBounds { max: Some(header.gas_limit().clone()), min: None, found: header.gas_used().clone() })); header = good.clone(); header.extra_data_mut().resize(engine.maximum_extra_data_size() + 1, 0u8); check_fail(basic_test(&create_test_block(&header), engine), ExtraDataOutOfBounds(OutOfBounds { max: Some(engine.maximum_extra_data_size()), min: None, found: header.extra_data().len() })); header = good.clone(); header.extra_data_mut().resize(engine.maximum_extra_data_size() + 1, 0u8); check_fail(basic_test(&create_test_block(&header), engine), ExtraDataOutOfBounds(OutOfBounds { max: Some(engine.maximum_extra_data_size()), min: None, found: header.extra_data().len() })); header = good.clone(); header.set_uncles_hash(good_uncles_hash.clone()); check_fail(basic_test(&create_test_block_with_data(&header, &good_transactions, &good_uncles), engine), InvalidTransactionsRoot(Mismatch { expected: good_transactions_root.clone(), found: header.transactions_root().clone() })); header = good.clone(); header.set_transactions_root(good_transactions_root.clone()); check_fail(basic_test(&create_test_block_with_data(&header, &good_transactions, &good_uncles), engine), InvalidUnclesHash(Mismatch { expected: good_uncles_hash.clone(), found: header.uncles_hash().clone() })); check_ok(family_test(&create_test_block(&good), engine, &bc)); check_ok(family_test(&create_test_block_with_data(&good, &good_transactions, &good_uncles), engine, &bc)); header = good.clone(); header.set_parent_hash(H256::random()); check_fail(family_test(&create_test_block_with_data(&header, &good_transactions, &good_uncles), engine, &bc), UnknownParent(header.parent_hash().clone())); header = good.clone(); header.set_timestamp(10); check_fail(family_test(&create_test_block_with_data(&header, &good_transactions, &good_uncles), engine, &bc), InvalidTimestamp(OutOfBounds { max: None, min: Some(parent.timestamp() + 1), found: header.timestamp() })); header = good.clone(); header.set_timestamp(2450000000); check_fail_timestamp(basic_test(&create_test_block_with_data(&header, &good_transactions, &good_uncles), engine), false); header = good.clone(); header.set_timestamp(get_time().sec as u64 + 20); check_fail_timestamp(basic_test(&create_test_block_with_data(&header, &good_transactions, &good_uncles), engine), true); header = good.clone(); header.set_timestamp(get_time().sec as u64 + 10); header.set_uncles_hash(good_uncles_hash.clone()); header.set_transactions_root(good_transactions_root.clone()); check_ok(basic_test(&create_test_block_with_data(&header, &good_transactions, &good_uncles), engine)); header = good.clone(); header.set_number(9); check_fail(family_test(&create_test_block_with_data(&header, &good_transactions, &good_uncles), engine, &bc), InvalidNumber(Mismatch { expected: parent.number() + 1, found: header.number() })); header = good.clone(); let mut bad_uncles = good_uncles.clone(); bad_uncles.push(good_uncle1.clone()); check_fail(family_test(&create_test_block_with_data(&header, &good_transactions, &bad_uncles), engine, &bc), TooManyUncles(OutOfBounds { max: Some(engine.maximum_uncle_count(header.number())), min: None, found: bad_uncles.len() })); header = good.clone(); bad_uncles = vec![ good_uncle1.clone(), good_uncle1.clone() ]; check_fail(family_test(&create_test_block_with_data(&header, &good_transactions, &bad_uncles), engine, &bc), DuplicateUncle(good_uncle1.hash())); header = good.clone(); header.set_gas_limit(0.into()); header.set_difficulty("0000000000000000000000000000000000000000000000000000000000020000".parse::().unwrap()); match family_test(&create_test_block(&header), engine, &bc) { Err(Error::Block(InvalidGasLimit(_))) => {}, Err(_) => { panic!("should be invalid difficulty fail"); }, _ => { panic!("Should be error, got Ok"); }, } // TODO: some additional uncle checks } #[test] fn dust_protection() { use ethkey::{Generator, Random}; use transaction::{Transaction, Action}; use machine::EthereumMachine; use engines::NullEngine; let mut params = CommonParams::default(); params.dust_protection_transition = 0; params.nonce_cap_increment = 2; let mut header = Header::default(); header.set_number(1); let keypair = Random.generate().unwrap(); let bad_transactions: Vec<_> = (0..3).map(|i| Transaction { action: Action::Create, value: U256::zero(), data: Vec::new(), gas: 0.into(), gas_price: U256::zero(), nonce: i.into(), }.sign(keypair.secret(), None)).collect(); let good_transactions = [bad_transactions[0].clone(), bad_transactions[1].clone()]; let machine = EthereumMachine::regular(params, BTreeMap::new()); let engine = NullEngine::new(Default::default(), machine); check_fail(unordered_test(&create_test_block_with_data(&header, &bad_transactions, &[]), &engine), TooManyTransactions(keypair.address())); unordered_test(&create_test_block_with_data(&header, &good_transactions, &[]), &engine).unwrap(); } }