// Copyright 2015, 2016 Ethcore (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 . //! Blockchain block. use common::*; use engines::Engine; use state::*; use verification::PreverifiedBlock; use trace::FlatTrace; use factory::Factories; /// A block, encoded as it is on the block chain. #[derive(Default, Debug, Clone, PartialEq)] pub struct Block { /// The header of this block. pub header: Header, /// The transactions in this block. pub transactions: Vec, /// The uncles of this block. pub uncles: Vec
, } impl Block { /// Returns true if the given bytes form a valid encoding of a block in RLP. pub fn is_good(b: &[u8]) -> bool { UntrustedRlp::new(b).as_val::().is_ok() } /// Get the RLP-encoding of the block with or without the seal. pub fn rlp_bytes(&self, seal: Seal) -> Bytes { let mut block_rlp = RlpStream::new_list(3); self.header.stream_rlp(&mut block_rlp, seal); block_rlp.append(&self.transactions); block_rlp.append(&self.uncles); block_rlp.out() } } impl Decodable for Block { fn decode(decoder: &D) -> Result where D: Decoder { if decoder.as_raw().len() != try!(decoder.as_rlp().payload_info()).total() { return Err(DecoderError::RlpIsTooBig); } let d = decoder.as_rlp(); if d.item_count() != 3 { return Err(DecoderError::RlpIncorrectListLen); } Ok(Block { header: try!(d.val_at(0)), transactions: try!(d.val_at(1)), uncles: try!(d.val_at(2)), }) } } /// Internal type for a block's common elements. #[derive(Clone)] pub struct ExecutedBlock { base: Block, receipts: Vec, transactions_set: HashSet, state: State, traces: Option>>, } /// A set of references to `ExecutedBlock` fields that are publicly accessible. pub struct BlockRefMut<'a> { /// Block header. pub header: &'a mut Header, /// Block transactions. pub transactions: &'a [SignedTransaction], /// Block uncles. pub uncles: &'a [Header], /// Transaction receipts. pub receipts: &'a [Receipt], /// State. pub state: &'a mut State, /// Traces. pub traces: &'a Option>>, } /// A set of immutable references to `ExecutedBlock` fields that are publicly accessible. pub struct BlockRef<'a> { /// Block header. pub header: &'a Header, /// Block transactions. pub transactions: &'a [SignedTransaction], /// Block uncles. pub uncles: &'a [Header], /// Transaction receipts. pub receipts: &'a [Receipt], /// State. pub state: &'a State, /// Traces. pub traces: &'a Option>>, } impl ExecutedBlock { /// Create a new block from the given `state`. fn new(state: State, tracing: bool) -> ExecutedBlock { ExecutedBlock { base: Default::default(), receipts: Default::default(), transactions_set: Default::default(), state: state, traces: if tracing {Some(Vec::new())} else {None}, } } /// Get a structure containing individual references to all public fields. pub fn fields_mut(&mut self) -> BlockRefMut { BlockRefMut { header: &mut self.base.header, transactions: &self.base.transactions, uncles: &self.base.uncles, state: &mut self.state, receipts: &self.receipts, traces: &self.traces, } } /// Get a structure containing individual references to all public fields. pub fn fields(&self) -> BlockRef { BlockRef { header: &self.base.header, transactions: &self.base.transactions, uncles: &self.base.uncles, state: &self.state, receipts: &self.receipts, traces: &self.traces, } } } /// Trait for a object that is a `ExecutedBlock`. pub trait IsBlock { /// Get the `ExecutedBlock` associated with this object. fn block(&self) -> &ExecutedBlock; /// Get the base `Block` object associated with this. fn base(&self) -> &Block { &self.block().base } /// Get the header associated with this object's block. fn header(&self) -> &Header { &self.block().base.header } /// Get the final state associated with this object's block. fn state(&self) -> &State { &self.block().state } /// Get all information on transactions in this block. fn transactions(&self) -> &[SignedTransaction] { &self.block().base.transactions } /// Get all information on receipts in this block. fn receipts(&self) -> &[Receipt] { &self.block().receipts } /// Get all information concerning transaction tracing in this block. fn traces(&self) -> &Option>> { &self.block().traces } /// Get all uncles in this block. fn uncles(&self) -> &[Header] { &self.block().base.uncles } } /// Trait for a object that has a state database. pub trait Drain { /// Drop this object and return the underlieing database. fn drain(self) -> Box; } impl IsBlock for ExecutedBlock { fn block(&self) -> &ExecutedBlock { self } } /// Block that is ready for transactions to be added. /// /// It's a bit like a Vec, except that whenever a transaction is pushed, we execute it and /// maintain the system `state()`. We also archive execution receipts in preparation for later block creation. pub struct OpenBlock<'x> { block: ExecutedBlock, engine: &'x Engine, last_hashes: Arc, } /// Just like `OpenBlock`, except that we've applied `Engine::on_close_block`, finished up the non-seal header fields, /// and collected the uncles. /// /// There is no function available to push a transaction. #[derive(Clone)] pub struct ClosedBlock { block: ExecutedBlock, uncle_bytes: Bytes, last_hashes: Arc, unclosed_state: State, } /// Just like `ClosedBlock` except that we can't reopen it and it's faster. /// /// We actually store the post-`Engine::on_close_block` state, unlike in `ClosedBlock` where it's the pre. #[derive(Clone)] pub struct LockedBlock { block: ExecutedBlock, uncle_bytes: Bytes, } /// A block that has a valid seal. /// /// The block's header has valid seal arguments. The block cannot be reversed into a `ClosedBlock` or `OpenBlock`. pub struct SealedBlock { block: ExecutedBlock, uncle_bytes: Bytes, } impl<'x> OpenBlock<'x> { #[cfg_attr(feature="dev", allow(too_many_arguments))] /// Create a new `OpenBlock` ready for transaction pushing. pub fn new( engine: &'x Engine, factories: Factories, tracing: bool, db: Box, parent: &Header, last_hashes: Arc, author: Address, gas_range_target: (U256, U256), extra_data: Bytes, ) -> Result { let state = try!(State::from_existing(db, parent.state_root().clone(), engine.account_start_nonce(), factories)); let mut r = OpenBlock { block: ExecutedBlock::new(state, tracing), engine: engine, last_hashes: last_hashes, }; r.block.base.header.parent_hash = parent.hash(); r.block.base.header.number = parent.number + 1; r.block.base.header.author = author; r.block.base.header.set_timestamp_now(parent.timestamp()); r.block.base.header.extra_data = extra_data; r.block.base.header.note_dirty(); engine.populate_from_parent(&mut r.block.base.header, parent, gas_range_target.0, gas_range_target.1); engine.on_new_block(&mut r.block); Ok(r) } /// Alter the author for the block. pub fn set_author(&mut self, author: Address) { self.block.base.header.set_author(author); } /// Alter the timestamp of the block. pub fn set_timestamp(&mut self, timestamp: u64) { self.block.base.header.set_timestamp(timestamp); } /// Alter the difficulty for the block. pub fn set_difficulty(&mut self, a: U256) { self.block.base.header.set_difficulty(a); } /// Alter the gas limit for the block. pub fn set_gas_limit(&mut self, a: U256) { self.block.base.header.set_gas_limit(a); } /// Alter the gas limit for the block. pub fn set_gas_used(&mut self, a: U256) { self.block.base.header.set_gas_used(a); } /// Alter the uncles hash the block. pub fn set_uncles_hash(&mut self, h: H256) { self.block.base.header.set_uncles_hash(h); } /// Alter transactions root for the block. pub fn set_transactions_root(&mut self, h: H256) { self.block.base.header.set_transactions_root(h); } /// Alter the receipts root for the block. pub fn set_receipts_root(&mut self, h: H256) { self.block.base.header.set_receipts_root(h); } /// Alter the extra_data for the block. pub fn set_extra_data(&mut self, extra_data: Bytes) -> Result<(), BlockError> { if extra_data.len() > self.engine.maximum_extra_data_size() { Err(BlockError::ExtraDataOutOfBounds(OutOfBounds{min: None, max: Some(self.engine.maximum_extra_data_size()), found: extra_data.len()})) } else { self.block.base.header.set_extra_data(extra_data); Ok(()) } } /// Add an uncle to the block, if possible. /// /// NOTE Will check chain constraints and the uncle number but will NOT check /// that the header itself is actually valid. pub fn push_uncle(&mut self, valid_uncle_header: Header) -> Result<(), BlockError> { if self.block.base.uncles.len() + 1 > self.engine.maximum_uncle_count() { return Err(BlockError::TooManyUncles(OutOfBounds{min: None, max: Some(self.engine.maximum_uncle_count()), found: self.block.base.uncles.len() + 1})); } // TODO: check number // TODO: check not a direct ancestor (use last_hashes for that) self.block.base.uncles.push(valid_uncle_header); Ok(()) } /// Get the environment info concerning this block. pub fn env_info(&self) -> EnvInfo { // TODO: memoise. EnvInfo { number: self.block.base.header.number, author: self.block.base.header.author.clone(), timestamp: self.block.base.header.timestamp, difficulty: self.block.base.header.difficulty.clone(), last_hashes: self.last_hashes.clone(), gas_used: self.block.receipts.last().map_or(U256::zero(), |r| r.gas_used), gas_limit: self.block.base.header.gas_limit.clone(), } } /// Push a transaction into the block. /// /// If valid, it will be executed, and archived together with the receipt. pub fn push_transaction(&mut self, t: SignedTransaction, h: Option) -> Result<&Receipt, Error> { if self.block.transactions_set.contains(&t.hash()) { return Err(From::from(TransactionError::AlreadyImported)); } let env_info = self.env_info(); // info!("env_info says gas_used={}", env_info.gas_used); match self.block.state.apply(&env_info, self.engine, &t, self.block.traces.is_some()) { Ok(outcome) => { self.block.transactions_set.insert(h.unwrap_or_else(||t.hash())); self.block.base.transactions.push(t); let t = outcome.trace; self.block.traces.as_mut().map(|traces| traces.push(t)); self.block.receipts.push(outcome.receipt); Ok(self.block.receipts.last().unwrap()) } Err(x) => Err(From::from(x)) } } /// Turn this into a `ClosedBlock`. A `BlockChain` must be provided in order to figure out the uncles. pub fn close(self) -> ClosedBlock { let mut s = self; let unclosed_state = s.block.state.clone(); s.engine.on_close_block(&mut s.block); s.block.base.header.transactions_root = ordered_trie_root(s.block.base.transactions.iter().map(|e| e.rlp_bytes().to_vec()).collect()); let uncle_bytes = s.block.base.uncles.iter().fold(RlpStream::new_list(s.block.base.uncles.len()), |mut s, u| {s.append_raw(&u.rlp(Seal::With), 1); s} ).out(); s.block.base.header.uncles_hash = uncle_bytes.sha3(); s.block.base.header.state_root = s.block.state.root().clone(); s.block.base.header.receipts_root = ordered_trie_root(s.block.receipts.iter().map(|r| r.rlp_bytes().to_vec()).collect()); s.block.base.header.log_bloom = s.block.receipts.iter().fold(LogBloom::zero(), |mut b, r| {b = &b | &r.log_bloom; b}); //TODO: use |= operator s.block.base.header.gas_used = s.block.receipts.last().map_or(U256::zero(), |r| r.gas_used); s.block.base.header.note_dirty(); ClosedBlock { block: s.block, uncle_bytes: uncle_bytes, last_hashes: s.last_hashes, unclosed_state: unclosed_state, } } /// Turn this into a `LockedBlock`. A BlockChain must be provided in order to figure out the uncles. pub fn close_and_lock(self) -> LockedBlock { let mut s = self; s.engine.on_close_block(&mut s.block); if s.block.base.header.transactions_root.is_zero() || s.block.base.header.transactions_root == SHA3_NULL_RLP { s.block.base.header.transactions_root = ordered_trie_root(s.block.base.transactions.iter().map(|e| e.rlp_bytes().to_vec()).collect()); } let uncle_bytes = s.block.base.uncles.iter().fold(RlpStream::new_list(s.block.base.uncles.len()), |mut s, u| {s.append_raw(&u.rlp(Seal::With), 1); s} ).out(); if s.block.base.header.uncles_hash.is_zero() { s.block.base.header.uncles_hash = uncle_bytes.sha3(); } if s.block.base.header.receipts_root.is_zero() || s.block.base.header.receipts_root == SHA3_NULL_RLP { s.block.base.header.receipts_root = ordered_trie_root(s.block.receipts.iter().map(|r| r.rlp_bytes().to_vec()).collect()); } s.block.base.header.state_root = s.block.state.root().clone(); s.block.base.header.log_bloom = s.block.receipts.iter().fold(LogBloom::zero(), |mut b, r| {b = &b | &r.log_bloom; b}); //TODO: use |= operator s.block.base.header.gas_used = s.block.receipts.last().map_or(U256::zero(), |r| r.gas_used); s.block.base.header.note_dirty(); LockedBlock { block: s.block, uncle_bytes: uncle_bytes, } } } impl<'x> IsBlock for OpenBlock<'x> { fn block(&self) -> &ExecutedBlock { &self.block } } impl<'x> IsBlock for ClosedBlock { fn block(&self) -> &ExecutedBlock { &self.block } } impl<'x> IsBlock for LockedBlock { fn block(&self) -> &ExecutedBlock { &self.block } } impl ClosedBlock { /// Get the hash of the header without seal arguments. pub fn hash(&self) -> H256 { self.header().rlp_sha3(Seal::Without) } /// Turn this into a `LockedBlock`, unable to be reopened again. pub fn lock(self) -> LockedBlock { LockedBlock { block: self.block, uncle_bytes: self.uncle_bytes, } } /// Given an engine reference, reopen the `ClosedBlock` into an `OpenBlock`. pub fn reopen<'a>(self, engine: &'a Engine) -> OpenBlock<'a> { // revert rewards (i.e. set state back at last transaction's state). let mut block = self.block; block.state = self.unclosed_state; OpenBlock { block: block, engine: engine, last_hashes: self.last_hashes, } } } impl LockedBlock { /// Get the hash of the header without seal arguments. pub fn hash(&self) -> H256 { self.header().rlp_sha3(Seal::Without) } /// Provide a valid seal in order to turn this into a `SealedBlock`. /// /// NOTE: This does not check the validity of `seal` with the engine. pub fn seal(self, engine: &Engine, seal: Vec) -> Result { let mut s = self; if seal.len() != engine.seal_fields() { return Err(BlockError::InvalidSealArity(Mismatch{expected: engine.seal_fields(), found: seal.len()})); } s.block.base.header.set_seal(seal); Ok(SealedBlock { block: s.block, uncle_bytes: s.uncle_bytes }) } /// Provide a valid seal in order to turn this into a `SealedBlock`. /// This does check the validity of `seal` with the engine. /// Returns the `ClosedBlock` back again if the seal is no good. pub fn try_seal(self, engine: &Engine, seal: Vec) -> Result { let mut s = self; s.block.base.header.set_seal(seal); match engine.verify_block_seal(&s.block.base.header) { Err(_) => Err(s), _ => Ok(SealedBlock { block: s.block, uncle_bytes: s.uncle_bytes }), } } } impl Drain for LockedBlock { /// Drop this object and return the underlieing database. fn drain(self) -> Box { self.block.state.drop().1 } } impl SealedBlock { /// Get the RLP-encoding of the block. pub fn rlp_bytes(&self) -> Bytes { let mut block_rlp = RlpStream::new_list(3); self.block.base.header.stream_rlp(&mut block_rlp, Seal::With); block_rlp.append(&self.block.base.transactions); block_rlp.append_raw(&self.uncle_bytes, 1); block_rlp.out() } } impl Drain for SealedBlock { /// Drop this object and return the underlieing database. fn drain(self) -> Box { self.block.state.drop().1 } } impl IsBlock for SealedBlock { fn block(&self) -> &ExecutedBlock { &self.block } } /// Enact the block given by block header, transactions and uncles #[cfg_attr(feature="dev", allow(too_many_arguments))] pub fn enact( header: &Header, transactions: &[SignedTransaction], uncles: &[Header], engine: &Engine, tracing: bool, db: Box, parent: &Header, last_hashes: Arc, factories: Factories, ) -> Result { { if ::log::max_log_level() >= ::log::LogLevel::Trace { let s = try!(State::from_existing(db.boxed_clone(), parent.state_root().clone(), engine.account_start_nonce(), factories.clone())); trace!("enact(): root={}, author={}, author_balance={}\n", s.root(), header.author(), s.balance(&header.author())); } } let mut b = try!(OpenBlock::new(engine, factories, tracing, db, parent, last_hashes, Address::new(), (3141562.into(), 31415620.into()), vec![])); b.set_difficulty(*header.difficulty()); b.set_gas_limit(*header.gas_limit()); b.set_timestamp(header.timestamp()); b.set_author(header.author().clone()); b.set_extra_data(header.extra_data().clone()).unwrap_or_else(|e| warn!("Couldn't set extradata: {}. Ignoring.", e)); b.set_uncles_hash(header.uncles_hash().clone()); b.set_transactions_root(header.transactions_root().clone()); b.set_receipts_root(header.receipts_root().clone()); for t in transactions { try!(b.push_transaction(t.clone(), None)); } for u in uncles { try!(b.push_uncle(u.clone())); } Ok(b.close_and_lock()) } /// Enact the block given by `block_bytes` using `engine` on the database `db` with given `parent` block header #[cfg_attr(feature="dev", allow(too_many_arguments))] pub fn enact_bytes( block_bytes: &[u8], engine: &Engine, tracing: bool, db: Box, parent: &Header, last_hashes: Arc, factories: Factories, ) -> Result { let block = BlockView::new(block_bytes); let header = block.header(); enact(&header, &block.transactions(), &block.uncles(), engine, tracing, db, parent, last_hashes, factories) } /// Enact the block given by `block_bytes` using `engine` on the database `db` with given `parent` block header #[cfg_attr(feature="dev", allow(too_many_arguments))] pub fn enact_verified( block: &PreverifiedBlock, engine: &Engine, tracing: bool, db: Box, parent: &Header, last_hashes: Arc, factories: Factories, ) -> Result { let view = BlockView::new(&block.bytes); enact(&block.header, &block.transactions, &view.uncles(), engine, tracing, db, parent, last_hashes, factories) } /// Enact the block given by `block_bytes` using `engine` on the database `db` with given `parent` block header. Seal the block aferwards #[cfg_attr(feature="dev", allow(too_many_arguments))] pub fn enact_and_seal( block_bytes: &[u8], engine: &Engine, tracing: bool, db: Box, parent: &Header, last_hashes: Arc, factories: Factories, ) -> Result { let header = BlockView::new(block_bytes).header_view(); Ok(try!(try!(enact_bytes(block_bytes, engine, tracing, db, parent, last_hashes, factories)).seal(engine, header.seal()))) } #[cfg(test)] mod tests { use tests::helpers::*; use super::*; use common::*; #[test] fn open_block() { use spec::*; let spec = Spec::new_test(); let genesis_header = spec.genesis_header(); let mut db_result = get_temp_journal_db(); let mut db = db_result.take(); spec.ensure_db_good(db.as_hashdb_mut()).unwrap(); let last_hashes = Arc::new(vec![genesis_header.hash()]); let b = OpenBlock::new(&*spec.engine, Default::default(), false, db, &genesis_header, last_hashes, Address::zero(), (3141562.into(), 31415620.into()), vec![]).unwrap(); let b = b.close_and_lock(); let _ = b.seal(&*spec.engine, vec![]); } #[test] fn enact_block() { use spec::*; let spec = Spec::new_test(); let engine = &*spec.engine; let genesis_header = spec.genesis_header(); let mut db_result = get_temp_journal_db(); let mut db = db_result.take(); spec.ensure_db_good(db.as_hashdb_mut()).unwrap(); let last_hashes = Arc::new(vec![genesis_header.hash()]); let b = OpenBlock::new(engine, Default::default(), false, db, &genesis_header, last_hashes.clone(), Address::zero(), (3141562.into(), 31415620.into()), vec![]).unwrap() .close_and_lock().seal(engine, vec![]).unwrap(); let orig_bytes = b.rlp_bytes(); let orig_db = b.drain(); let mut db_result = get_temp_journal_db(); let mut db = db_result.take(); spec.ensure_db_good(db.as_hashdb_mut()).unwrap(); let e = enact_and_seal(&orig_bytes, engine, false, db, &genesis_header, last_hashes, Default::default()).unwrap(); assert_eq!(e.rlp_bytes(), orig_bytes); let db = e.drain(); assert_eq!(orig_db.keys(), db.keys()); assert!(orig_db.keys().iter().filter(|k| orig_db.get(k.0) != db.get(k.0)).next() == None); } #[test] fn enact_block_with_uncle() { use spec::*; let spec = Spec::new_test(); let engine = &*spec.engine; let genesis_header = spec.genesis_header(); let mut db_result = get_temp_journal_db(); let mut db = db_result.take(); spec.ensure_db_good(db.as_hashdb_mut()).unwrap(); let last_hashes = Arc::new(vec![genesis_header.hash()]); let mut open_block = OpenBlock::new(engine, Default::default(), false, db, &genesis_header, last_hashes.clone(), Address::zero(), (3141562.into(), 31415620.into()), vec![]).unwrap(); let mut uncle1_header = Header::new(); uncle1_header.extra_data = b"uncle1".to_vec(); let mut uncle2_header = Header::new(); uncle2_header.extra_data = b"uncle2".to_vec(); open_block.push_uncle(uncle1_header).unwrap(); open_block.push_uncle(uncle2_header).unwrap(); let b = open_block.close_and_lock().seal(engine, vec![]).unwrap(); let orig_bytes = b.rlp_bytes(); let orig_db = b.drain(); let mut db_result = get_temp_journal_db(); let mut db = db_result.take(); spec.ensure_db_good(db.as_hashdb_mut()).unwrap(); let e = enact_and_seal(&orig_bytes, engine, false, db, &genesis_header, last_hashes, Default::default()).unwrap(); let bytes = e.rlp_bytes(); assert_eq!(bytes, orig_bytes); let uncles = BlockView::new(&bytes).uncles(); assert_eq!(uncles[1].extra_data, b"uncle2"); let db = e.drain(); assert_eq!(orig_db.keys(), db.keys()); assert!(orig_db.keys().iter().filter(|k| orig_db.get(k.0) != db.get(k.0)).next() == None); } }