// 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 . //! Light Transaction Queue. //! //! Manages local transactions, //! but stores all local transactions, removing only on invalidated nonce. //! //! Under the assumption that light nodes will have a relatively limited set of //! accounts for which they create transactions, this queue is structured in an //! address-wise manner. use std::collections::{BTreeMap, HashMap}; use std::collections::hash_map::Entry; use ethcore::error::{TransactionError, TransactionImportResult}; use ethcore::transaction::{Condition, PendingTransaction, SignedTransaction}; use bigint::prelude::U256; use bigint::hash::{H256, H256FastMap}; use util::Address; // Knowledge of an account's current nonce. #[derive(Debug, Clone, PartialEq, Eq)] enum CurrentNonce { // Assumed current nonce. Assumed(U256), // Known current nonce. Known(U256), } impl CurrentNonce { // whether this nonce is assumed fn is_assumed(&self) -> bool { match *self { CurrentNonce::Assumed(_) => true, CurrentNonce::Known(_) => false, } } // whether this nonce is known for certain from an external source. fn is_known(&self) -> bool { !self.is_assumed() } // the current nonce's value. fn value(&self) -> &U256 { match *self { CurrentNonce::Assumed(ref val) => val, CurrentNonce::Known(ref val) => val, } } } #[derive(Debug, Clone, PartialEq, Eq)] struct TransactionInfo { hash: H256, nonce: U256, condition: Option, } impl<'a> From<&'a PendingTransaction> for TransactionInfo { fn from(tx: &'a PendingTransaction) -> Self { TransactionInfo { hash: tx.hash(), nonce: tx.nonce.clone(), condition: tx.condition.clone(), } } } // transactions associated with a specific account. #[derive(Debug, Clone, PartialEq, Eq)] struct AccountTransactions { // believed current nonce (gotten from initial given TX or `cull` calls). cur_nonce: CurrentNonce, current: Vec, // ordered "current" transactions (cur_nonce onwards) future: BTreeMap, // "future" transactions. } impl AccountTransactions { fn is_empty(&self) -> bool { self.current.is_empty() && self.future.is_empty() } fn next_nonce(&self) -> U256 { self.current.last().map(|last| last.nonce + 1.into()) .unwrap_or_else(|| *self.cur_nonce.value()) } // attempt to move transactions from the future queue into the current queue. fn adjust_future(&mut self) { let mut next_nonce = self.next_nonce(); loop { match self.future.remove(&next_nonce) { Some(tx) => self.current.push(tx), None => break, } next_nonce = next_nonce + 1.into(); } } } /// Light transaction queue. See module docs for more details. #[derive(Debug, Default, Clone, PartialEq, Eq)] pub struct TransactionQueue { by_account: HashMap, by_hash: H256FastMap, } impl TransactionQueue { /// Import a pending transaction to be queued. pub fn import(&mut self, tx: PendingTransaction) -> Result { let sender = tx.sender(); let hash = tx.hash(); let nonce = tx.nonce; let tx_info = TransactionInfo::from(&tx); if self.by_hash.contains_key(&hash) { return Err(TransactionError::AlreadyImported) } let res = match self.by_account.entry(sender) { Entry::Vacant(entry) => { entry.insert(AccountTransactions { cur_nonce: CurrentNonce::Assumed(nonce), current: vec![tx_info], future: BTreeMap::new(), }); TransactionImportResult::Current } Entry::Occupied(mut entry) => { let acct_txs = entry.get_mut(); if &nonce < acct_txs.cur_nonce.value() { // don't accept txs from before known current nonce. if acct_txs.cur_nonce.is_known() { return Err(TransactionError::Old) } // lower our assumption until corrected later. acct_txs.cur_nonce = CurrentNonce::Assumed(nonce); } match acct_txs.current.binary_search_by(|x| x.nonce.cmp(&nonce)) { Ok(idx) => { trace!(target: "txqueue", "Replacing existing transaction from {} with nonce {}", sender, nonce); let old = ::std::mem::replace(&mut acct_txs.current[idx], tx_info); self.by_hash.remove(&old.hash); TransactionImportResult::Current } Err(idx) => { let cur_len = acct_txs.current.len(); let incr_nonce = nonce + 1.into(); // current is sorted with one tx per nonce, // so if a tx with given nonce wasn't found that means it is either // earlier in nonce than all other "current" transactions or later. assert!(idx == 0 || idx == cur_len); if idx == 0 && acct_txs.current.first().map_or(false, |f| f.nonce != incr_nonce) { let old_cur = ::std::mem::replace(&mut acct_txs.current, vec![tx_info]); trace!(target: "txqueue", "Moving {} transactions with nonce > {} to future", old_cur.len(), incr_nonce); for future in old_cur { let future_nonce = future.nonce; acct_txs.future.insert(future_nonce, future); } TransactionImportResult::Current } else if idx == cur_len && acct_txs.current.last().map_or(false, |f| f.nonce + 1.into() != nonce) { trace!(target: "txqueue", "Queued future transaction for {}, nonce={}", sender, nonce); let future_nonce = nonce; acct_txs.future.insert(future_nonce, tx_info); TransactionImportResult::Future } else { trace!(target: "txqueue", "Queued current transaction for {}, nonce={}", sender, nonce); // insert, then check if we've filled any gaps. acct_txs.current.insert(idx, tx_info); acct_txs.adjust_future(); TransactionImportResult::Current } } } } }; self.by_hash.insert(hash, tx); Ok(res) } /// Get pending transaction by hash. pub fn transaction(&self, hash: &H256) -> Option { self.by_hash.get(hash).map(|tx| (&**tx).clone()) } /// Get the next nonce for a given address based on what's within the queue. /// If the address has no queued transactions, then `None` will be returned /// and the next nonce will have to be deduced via other means. pub fn next_nonce(&self, address: &Address) -> Option { self.by_account.get(address).map(AccountTransactions::next_nonce) } /// Get all transactions ready to be propagated. /// `best_block_number` and `best_block_timestamp` are used to filter out conditionally /// propagated transactions. /// /// Returned transactions are batched by sender, in order of ascending nonce. pub fn ready_transactions(&self, best_block_number: u64, best_block_timestamp: u64) -> Vec { self.by_account.values() .flat_map(|acct_txs| { acct_txs.current.iter().take_while(|tx| match tx.condition { None => true, Some(Condition::Number(blk_num)) => blk_num <= best_block_number, Some(Condition::Timestamp(time)) => time <= best_block_timestamp, }).map(|info| info.hash) }) .filter_map(|hash| match self.by_hash.get(&hash) { Some(tx) => Some(tx.clone()), None => { warn!(target: "txqueue", "Inconsistency detected between `by_hash` and `by_account`: {} not stored.", hash); None } }) .collect() } /// Get all transactions not ready to be propagated. /// `best_block_number` and `best_block_timestamp` are used to filter out conditionally /// propagated transactions. /// /// Returned transactions are batched by sender, in order of ascending nonce. pub fn future_transactions(&self, best_block_number: u64, best_block_timestamp: u64) -> Vec { self.by_account.values() .flat_map(|acct_txs| { acct_txs.current.iter().skip_while(|tx| match tx.condition { None => true, Some(Condition::Number(blk_num)) => blk_num <= best_block_number, Some(Condition::Timestamp(time)) => time <= best_block_timestamp, }).chain(acct_txs.future.values()).map(|info| info.hash) }) .filter_map(|hash| match self.by_hash.get(&hash) { Some(tx) => Some(tx.clone()), None => { warn!(target: "txqueue", "Inconsistency detected between `by_hash` and `by_account`: {} not stored.", hash); None } }) .collect() } /// Addresses for which we store transactions. pub fn queued_senders(&self) -> Vec
{ self.by_account.keys().cloned().collect() } /// Cull out all transactions by the given address which are invalidated by the given nonce. pub fn cull(&mut self, address: Address, cur_nonce: U256) { let mut removed_hashes = vec![]; if let Entry::Occupied(mut entry) = self.by_account.entry(address) { { let acct_txs = entry.get_mut(); acct_txs.cur_nonce = CurrentNonce::Known(cur_nonce); // cull old "future" keys. let old_future: Vec<_> = acct_txs.future.keys().take_while(|&&k| k < cur_nonce).cloned().collect(); for old in old_future { let hash = acct_txs.future.remove(&old) .expect("key extracted from keys iterator; known to exist; qed") .hash; removed_hashes.push(hash); } // then cull from "current". let valid_pos = acct_txs.current.iter().position(|tx| tx.nonce >= cur_nonce); match valid_pos { None => removed_hashes.extend(acct_txs.current.drain(..).map(|tx| tx.hash)), Some(valid) => removed_hashes.extend(acct_txs.current.drain(..valid).map(|tx| tx.hash)), } // now try and move stuff out of future into current. acct_txs.adjust_future(); } if entry.get_mut().is_empty() { trace!(target: "txqueue", "No more queued transactions for {} after nonce {}", address, cur_nonce); entry.remove(); } } trace!(target: "txqueue", "Culled {} old transactions from sender {} (nonce={})", removed_hashes.len(), address, cur_nonce); for hash in removed_hashes { self.by_hash.remove(&hash); } } } #[cfg(test)] mod tests { use super::TransactionQueue; use util::Address; use ethcore::transaction::{Transaction, PendingTransaction, Condition}; #[test] fn queued_senders() { let sender = Address::default(); let mut txq = TransactionQueue::default(); let tx = Transaction::default().fake_sign(sender); txq.import(tx.into()).unwrap(); assert_eq!(txq.queued_senders(), vec![sender]); txq.cull(sender, 1.into()); assert_eq!(txq.queued_senders(), vec![]); assert!(txq.by_hash.is_empty()); } #[test] fn next_nonce() { let sender = Address::default(); let mut txq = TransactionQueue::default(); for i in (0..5).chain(10..15) { let mut tx = Transaction::default(); tx.nonce = i.into(); let tx = tx.fake_sign(sender); txq.import(tx.into()).unwrap(); } // current: 0..5, future: 10..15 assert_eq!(txq.ready_transactions(0, 0).len(), 5); assert_eq!(txq.next_nonce(&sender).unwrap(), 5.into()); txq.cull(sender, 8.into()); // current: empty, future: 10..15 assert_eq!(txq.ready_transactions(0, 0).len(), 0); assert_eq!(txq.next_nonce(&sender).unwrap(), 8.into()); txq.cull(sender, 10.into()); // current: 10..15, future: empty assert_eq!(txq.ready_transactions(0, 0).len(), 5); assert_eq!(txq.next_nonce(&sender).unwrap(), 15.into()); } #[test] fn current_to_future() { let sender = Address::default(); let mut txq = TransactionQueue::default(); for i in 5..10 { let mut tx = Transaction::default(); tx.nonce = i.into(); let tx = tx.fake_sign(sender); txq.import(tx.into()).unwrap(); } assert_eq!(txq.ready_transactions(0, 0).len(), 5); assert_eq!(txq.next_nonce(&sender).unwrap(), 10.into()); for i in 0..3 { let mut tx = Transaction::default(); tx.nonce = i.into(); let tx = tx.fake_sign(sender); txq.import(tx.into()).unwrap(); } assert_eq!(txq.ready_transactions(0, 0).len(), 3); assert_eq!(txq.next_nonce(&sender).unwrap(), 3.into()); for i in 3..5 { let mut tx = Transaction::default(); tx.nonce = i.into(); let tx = tx.fake_sign(sender); txq.import(tx.into()).unwrap(); } assert_eq!(txq.ready_transactions(0, 0).len(), 10); assert_eq!(txq.next_nonce(&sender).unwrap(), 10.into()); } #[test] fn conditional() { let mut txq = TransactionQueue::default(); let sender = Address::default(); for i in 0..5 { let mut tx = Transaction::default(); tx.nonce = i.into(); let tx = tx.fake_sign(sender); txq.import(match i { 3 => PendingTransaction::new(tx, Some(Condition::Number(100))), 4 => PendingTransaction::new(tx, Some(Condition::Timestamp(1234))), _ => tx.into(), }).unwrap(); } assert_eq!(txq.ready_transactions(0, 0).len(), 3); assert_eq!(txq.ready_transactions(0, 1234).len(), 3); assert_eq!(txq.ready_transactions(100, 0).len(), 4); assert_eq!(txq.ready_transactions(100, 1234).len(), 5); } #[test] fn cull_from_future() { let sender = Address::default(); let mut txq = TransactionQueue::default(); for i in (0..1).chain(3..10) { let mut tx = Transaction::default(); tx.nonce = i.into(); let tx = tx.fake_sign(sender); txq.import(tx.into()).unwrap(); } txq.cull(sender, 6.into()); assert_eq!(txq.ready_transactions(0, 0).len(), 4); assert_eq!(txq.next_nonce(&sender).unwrap(), 10.into()); } #[test] fn import_old() { let sender = Address::default(); let mut txq = TransactionQueue::default(); let mut tx_a = Transaction::default(); tx_a.nonce = 3.into(); let mut tx_b = Transaction::default(); tx_b.nonce = 2.into(); txq.import(tx_a.fake_sign(sender).into()).unwrap(); txq.cull(sender, 3.into()); assert!(txq.import(tx_b.fake_sign(sender).into()).is_err()) } #[test] fn replace_is_removed() { let sender = Address::default(); let mut txq = TransactionQueue::default(); let tx_b: PendingTransaction = Transaction::default().fake_sign(sender).into(); let tx_a: PendingTransaction = { let mut tx_a = Transaction::default(); tx_a.gas_price = tx_b.gas_price + 1.into(); tx_a.fake_sign(sender).into() }; let hash = tx_a.hash(); txq.import(tx_a).unwrap(); txq.import(tx_b).unwrap(); assert!(txq.transaction(&hash).is_none()); } #[test] fn future_transactions() { let sender = Address::default(); let mut txq = TransactionQueue::default(); for i in (0..1).chain(3..10) { let mut tx = Transaction::default(); tx.nonce = i.into(); let tx = tx.fake_sign(sender); txq.import(tx.into()).unwrap(); } assert_eq!(txq.future_transactions(0, 0).len(), 7); assert_eq!(txq.next_nonce(&sender).unwrap(), 1.into()); } }