mirror of
https://gitlab.com/pulsechaincom/erigon-pulse.git
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509 lines
17 KiB
Go
509 lines
17 KiB
Go
// Copyright 2016 The go-ethereum Authors
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// This file is part of the go-ethereum library.
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//
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// The go-ethereum library is free software: you can redistribute it and/or modify
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// it under the terms of the GNU Lesser General Public License as published by
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// the Free Software Foundation, either version 3 of the License, or
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// (at your option) any later version.
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//
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// The go-ethereum library is distributed in the hope that it will be useful,
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// but WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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// GNU Lesser General Public License for more details.
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//
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// You should have received a copy of the GNU Lesser General Public License
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// along with the go-ethereum library. If not, see <http://www.gnu.org/licenses/>.
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package core
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import (
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"container/heap"
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"math"
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"math/big"
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"sort"
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"github.com/ethereum/go-ethereum/common"
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"github.com/ethereum/go-ethereum/core/types"
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"github.com/ethereum/go-ethereum/log"
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)
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// nonceHeap is a heap.Interface implementation over 64bit unsigned integers for
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// retrieving sorted transactions from the possibly gapped future queue.
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type nonceHeap []uint64
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func (h nonceHeap) Len() int { return len(h) }
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func (h nonceHeap) Less(i, j int) bool { return h[i] < h[j] }
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func (h nonceHeap) Swap(i, j int) { h[i], h[j] = h[j], h[i] }
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func (h *nonceHeap) Push(x interface{}) {
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*h = append(*h, x.(uint64))
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}
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func (h *nonceHeap) Pop() interface{} {
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old := *h
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n := len(old)
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x := old[n-1]
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*h = old[0 : n-1]
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return x
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}
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// txSortedMap is a nonce->transaction hash map with a heap based index to allow
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// iterating over the contents in a nonce-incrementing way.
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type txSortedMap struct {
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items map[uint64]*types.Transaction // Hash map storing the transaction data
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index *nonceHeap // Heap of nonces of all the stored transactions (non-strict mode)
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cache types.Transactions // Cache of the transactions already sorted
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}
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// newTxSortedMap creates a new nonce-sorted transaction map.
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func newTxSortedMap() *txSortedMap {
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return &txSortedMap{
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items: make(map[uint64]*types.Transaction),
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index: new(nonceHeap),
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}
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}
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// Get retrieves the current transactions associated with the given nonce.
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func (m *txSortedMap) Get(nonce uint64) *types.Transaction {
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return m.items[nonce]
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}
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// Put inserts a new transaction into the map, also updating the map's nonce
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// index. If a transaction already exists with the same nonce, it's overwritten.
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func (m *txSortedMap) Put(tx *types.Transaction) {
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nonce := tx.Nonce()
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if m.items[nonce] == nil {
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heap.Push(m.index, nonce)
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}
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m.items[nonce], m.cache = tx, nil
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}
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// Forward removes all transactions from the map with a nonce lower than the
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// provided threshold. Every removed transaction is returned for any post-removal
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// maintenance.
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func (m *txSortedMap) Forward(threshold uint64) types.Transactions {
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var removed types.Transactions
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// Pop off heap items until the threshold is reached
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for m.index.Len() > 0 && (*m.index)[0] < threshold {
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nonce := heap.Pop(m.index).(uint64)
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removed = append(removed, m.items[nonce])
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delete(m.items, nonce)
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}
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// If we had a cached order, shift the front
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if m.cache != nil {
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m.cache = m.cache[len(removed):]
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}
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return removed
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}
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// Filter iterates over the list of transactions and removes all of them for which
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// the specified function evaluates to true.
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func (m *txSortedMap) Filter(filter func(*types.Transaction) bool) types.Transactions {
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var removed types.Transactions
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// Collect all the transactions to filter out
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for nonce, tx := range m.items {
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if filter(tx) {
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removed = append(removed, tx)
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delete(m.items, nonce)
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}
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}
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// If transactions were removed, the heap and cache are ruined
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if len(removed) > 0 {
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*m.index = make([]uint64, 0, len(m.items))
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for nonce := range m.items {
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*m.index = append(*m.index, nonce)
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}
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heap.Init(m.index)
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m.cache = nil
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}
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return removed
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}
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// Cap places a hard limit on the number of items, returning all transactions
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// exceeding that limit.
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func (m *txSortedMap) Cap(threshold int) types.Transactions {
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// Short circuit if the number of items is under the limit
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if len(m.items) <= threshold {
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return nil
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}
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// Otherwise gather and drop the highest nonce'd transactions
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var drops types.Transactions
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sort.Sort(*m.index)
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for size := len(m.items); size > threshold; size-- {
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drops = append(drops, m.items[(*m.index)[size-1]])
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delete(m.items, (*m.index)[size-1])
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}
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*m.index = (*m.index)[:threshold]
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heap.Init(m.index)
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// If we had a cache, shift the back
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if m.cache != nil {
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m.cache = m.cache[:len(m.cache)-len(drops)]
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}
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return drops
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}
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// Remove deletes a transaction from the maintained map, returning whether the
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// transaction was found.
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func (m *txSortedMap) Remove(nonce uint64) bool {
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// Short circuit if no transaction is present
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_, ok := m.items[nonce]
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if !ok {
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return false
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}
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// Otherwise delete the transaction and fix the heap index
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for i := 0; i < m.index.Len(); i++ {
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if (*m.index)[i] == nonce {
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heap.Remove(m.index, i)
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break
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}
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}
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delete(m.items, nonce)
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m.cache = nil
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return true
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}
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// Ready retrieves a sequentially increasing list of transactions starting at the
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// provided nonce that is ready for processing. The returned transactions will be
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// removed from the list.
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//
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// Note, all transactions with nonces lower than start will also be returned to
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// prevent getting into and invalid state. This is not something that should ever
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// happen but better to be self correcting than failing!
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func (m *txSortedMap) Ready(start uint64) types.Transactions {
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// Short circuit if no transactions are available
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if m.index.Len() == 0 || (*m.index)[0] > start {
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return nil
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}
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// Otherwise start accumulating incremental transactions
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var ready types.Transactions
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for next := (*m.index)[0]; m.index.Len() > 0 && (*m.index)[0] == next; next++ {
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ready = append(ready, m.items[next])
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delete(m.items, next)
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heap.Pop(m.index)
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}
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m.cache = nil
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return ready
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}
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// Len returns the length of the transaction map.
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func (m *txSortedMap) Len() int {
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return len(m.items)
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}
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// Flatten creates a nonce-sorted slice of transactions based on the loosely
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// sorted internal representation. The result of the sorting is cached in case
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// it's requested again before any modifications are made to the contents.
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func (m *txSortedMap) Flatten() types.Transactions {
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// If the sorting was not cached yet, create and cache it
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if m.cache == nil {
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m.cache = make(types.Transactions, 0, len(m.items))
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for _, tx := range m.items {
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m.cache = append(m.cache, tx)
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}
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sort.Sort(types.TxByNonce(m.cache))
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}
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// Copy the cache to prevent accidental modifications
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txs := make(types.Transactions, len(m.cache))
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copy(txs, m.cache)
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return txs
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}
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// txList is a "list" of transactions belonging to an account, sorted by account
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// nonce. The same type can be used both for storing contiguous transactions for
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// the executable/pending queue; and for storing gapped transactions for the non-
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// executable/future queue, with minor behavioral changes.
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type txList struct {
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strict bool // Whether nonces are strictly continuous or not
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txs *txSortedMap // Heap indexed sorted hash map of the transactions
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costcap *big.Int // Price of the highest costing transaction (reset only if exceeds balance)
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gascap uint64 // Gas limit of the highest spending transaction (reset only if exceeds block limit)
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}
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// newTxList create a new transaction list for maintaining nonce-indexable fast,
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// gapped, sortable transaction lists.
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func newTxList(strict bool) *txList {
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return &txList{
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strict: strict,
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txs: newTxSortedMap(),
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costcap: new(big.Int),
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}
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}
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// Overlaps returns whether the transaction specified has the same nonce as one
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// already contained within the list.
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func (l *txList) Overlaps(tx *types.Transaction) bool {
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return l.txs.Get(tx.Nonce()) != nil
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}
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// Add tries to insert a new transaction into the list, returning whether the
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// transaction was accepted, and if yes, any previous transaction it replaced.
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//
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// If the new transaction is accepted into the list, the lists' cost and gas
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// thresholds are also potentially updated.
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func (l *txList) Add(tx *types.Transaction, priceBump uint64) (bool, *types.Transaction) {
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// If there's an older better transaction, abort
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old := l.txs.Get(tx.Nonce())
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if old != nil {
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threshold := new(big.Int).Div(new(big.Int).Mul(old.GasPrice(), big.NewInt(100+int64(priceBump))), big.NewInt(100))
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// Have to ensure that the new gas price is higher than the old gas
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// price as well as checking the percentage threshold to ensure that
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// this is accurate for low (Wei-level) gas price replacements
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if old.GasPrice().Cmp(tx.GasPrice()) >= 0 || threshold.Cmp(tx.GasPrice()) > 0 {
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return false, nil
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}
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}
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// Otherwise overwrite the old transaction with the current one
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l.txs.Put(tx)
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if cost := tx.Cost(); l.costcap.Cmp(cost) < 0 {
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l.costcap = cost
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}
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if gas := tx.Gas(); l.gascap < gas {
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l.gascap = gas
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}
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return true, old
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}
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// Forward removes all transactions from the list with a nonce lower than the
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// provided threshold. Every removed transaction is returned for any post-removal
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// maintenance.
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func (l *txList) Forward(threshold uint64) types.Transactions {
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return l.txs.Forward(threshold)
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}
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// Filter removes all transactions from the list with a cost or gas limit higher
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// than the provided thresholds. Every removed transaction is returned for any
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// post-removal maintenance. Strict-mode invalidated transactions are also
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// returned.
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//
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// This method uses the cached costcap and gascap to quickly decide if there's even
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// a point in calculating all the costs or if the balance covers all. If the threshold
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// is lower than the costgas cap, the caps will be reset to a new high after removing
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// the newly invalidated transactions.
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func (l *txList) Filter(costLimit *big.Int, gasLimit uint64) (types.Transactions, types.Transactions) {
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// If all transactions are below the threshold, short circuit
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if l.costcap.Cmp(costLimit) <= 0 && l.gascap <= gasLimit {
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return nil, nil
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}
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l.costcap = new(big.Int).Set(costLimit) // Lower the caps to the thresholds
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l.gascap = gasLimit
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// Filter out all the transactions above the account's funds
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removed := l.txs.Filter(func(tx *types.Transaction) bool { return tx.Cost().Cmp(costLimit) > 0 || tx.Gas() > gasLimit })
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// If the list was strict, filter anything above the lowest nonce
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var invalids types.Transactions
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if l.strict && len(removed) > 0 {
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lowest := uint64(math.MaxUint64)
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for _, tx := range removed {
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if nonce := tx.Nonce(); lowest > nonce {
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lowest = nonce
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}
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}
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invalids = l.txs.Filter(func(tx *types.Transaction) bool { return tx.Nonce() > lowest })
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}
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return removed, invalids
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}
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// Cap places a hard limit on the number of items, returning all transactions
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// exceeding that limit.
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func (l *txList) Cap(threshold int) types.Transactions {
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return l.txs.Cap(threshold)
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}
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// Remove deletes a transaction from the maintained list, returning whether the
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// transaction was found, and also returning any transaction invalidated due to
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// the deletion (strict mode only).
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func (l *txList) Remove(tx *types.Transaction) (bool, types.Transactions) {
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// Remove the transaction from the set
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nonce := tx.Nonce()
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if removed := l.txs.Remove(nonce); !removed {
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return false, nil
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}
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// In strict mode, filter out non-executable transactions
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if l.strict {
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return true, l.txs.Filter(func(tx *types.Transaction) bool { return tx.Nonce() > nonce })
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}
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return true, nil
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}
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// Ready retrieves a sequentially increasing list of transactions starting at the
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// provided nonce that is ready for processing. The returned transactions will be
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// removed from the list.
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//
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// Note, all transactions with nonces lower than start will also be returned to
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// prevent getting into and invalid state. This is not something that should ever
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// happen but better to be self correcting than failing!
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func (l *txList) Ready(start uint64) types.Transactions {
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return l.txs.Ready(start)
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}
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// Len returns the length of the transaction list.
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func (l *txList) Len() int {
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return l.txs.Len()
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}
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// Empty returns whether the list of transactions is empty or not.
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func (l *txList) Empty() bool {
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return l.Len() == 0
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}
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// Flatten creates a nonce-sorted slice of transactions based on the loosely
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// sorted internal representation. The result of the sorting is cached in case
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// it's requested again before any modifications are made to the contents.
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func (l *txList) Flatten() types.Transactions {
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return l.txs.Flatten()
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}
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// priceHeap is a heap.Interface implementation over transactions for retrieving
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// price-sorted transactions to discard when the pool fills up.
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type priceHeap []*types.Transaction
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func (h priceHeap) Len() int { return len(h) }
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func (h priceHeap) Less(i, j int) bool { return h[i].GasPrice().Cmp(h[j].GasPrice()) < 0 }
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func (h priceHeap) Swap(i, j int) { h[i], h[j] = h[j], h[i] }
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func (h *priceHeap) Push(x interface{}) {
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*h = append(*h, x.(*types.Transaction))
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}
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func (h *priceHeap) Pop() interface{} {
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old := *h
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n := len(old)
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x := old[n-1]
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*h = old[0 : n-1]
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return x
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}
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// txPricedList is a price-sorted heap to allow operating on transactions pool
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// contents in a price-incrementing way.
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type txPricedList struct {
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all *map[common.Hash]*types.Transaction // Pointer to the map of all transactions
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items *priceHeap // Heap of prices of all the stored transactions
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stales int // Number of stale price points to (re-heap trigger)
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}
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// newTxPricedList creates a new price-sorted transaction heap.
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func newTxPricedList(all *map[common.Hash]*types.Transaction) *txPricedList {
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return &txPricedList{
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all: all,
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items: new(priceHeap),
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}
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}
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// Put inserts a new transaction into the heap.
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func (l *txPricedList) Put(tx *types.Transaction) {
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heap.Push(l.items, tx)
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}
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// Removed notifies the prices transaction list that an old transaction dropped
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// from the pool. The list will just keep a counter of stale objects and update
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// the heap if a large enough ratio of transactions go stale.
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func (l *txPricedList) Removed() {
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// Bump the stale counter, but exit if still too low (< 25%)
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l.stales++
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if l.stales <= len(*l.items)/4 {
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return
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}
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// Seems we've reached a critical number of stale transactions, reheap
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reheap := make(priceHeap, 0, len(*l.all))
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l.stales, l.items = 0, &reheap
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for _, tx := range *l.all {
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*l.items = append(*l.items, tx)
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}
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heap.Init(l.items)
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}
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// Cap finds all the transactions below the given price threshold, drops them
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// from the priced list and returs them for further removal from the entire pool.
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func (l *txPricedList) Cap(threshold *big.Int, local *accountSet) types.Transactions {
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drop := make(types.Transactions, 0, 128) // Remote underpriced transactions to drop
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save := make(types.Transactions, 0, 64) // Local underpriced transactions to keep
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for len(*l.items) > 0 {
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// Discard stale transactions if found during cleanup
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tx := heap.Pop(l.items).(*types.Transaction)
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if _, ok := (*l.all)[tx.Hash()]; !ok {
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l.stales--
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continue
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}
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// Stop the discards if we've reached the threshold
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if tx.GasPrice().Cmp(threshold) >= 0 {
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save = append(save, tx)
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break
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}
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// Non stale transaction found, discard unless local
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if local.containsTx(tx) {
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save = append(save, tx)
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} else {
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drop = append(drop, tx)
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}
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}
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for _, tx := range save {
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heap.Push(l.items, tx)
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}
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return drop
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}
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// Underpriced checks whether a transaction is cheaper than (or as cheap as) the
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// lowest priced transaction currently being tracked.
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func (l *txPricedList) Underpriced(tx *types.Transaction, local *accountSet) bool {
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// Local transactions cannot be underpriced
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if local.containsTx(tx) {
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return false
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}
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// Discard stale price points if found at the heap start
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for len(*l.items) > 0 {
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head := []*types.Transaction(*l.items)[0]
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if _, ok := (*l.all)[head.Hash()]; !ok {
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l.stales--
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heap.Pop(l.items)
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continue
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}
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break
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}
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// Check if the transaction is underpriced or not
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if len(*l.items) == 0 {
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log.Error("Pricing query for empty pool") // This cannot happen, print to catch programming errors
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return false
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}
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cheapest := []*types.Transaction(*l.items)[0]
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return cheapest.GasPrice().Cmp(tx.GasPrice()) >= 0
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}
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// Discard finds a number of most underpriced transactions, removes them from the
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// priced list and returns them for further removal from the entire pool.
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func (l *txPricedList) Discard(count int, local *accountSet) types.Transactions {
|
|
drop := make(types.Transactions, 0, count) // Remote underpriced transactions to drop
|
|
save := make(types.Transactions, 0, 64) // Local underpriced transactions to keep
|
|
|
|
for len(*l.items) > 0 && count > 0 {
|
|
// Discard stale transactions if found during cleanup
|
|
tx := heap.Pop(l.items).(*types.Transaction)
|
|
if _, ok := (*l.all)[tx.Hash()]; !ok {
|
|
l.stales--
|
|
continue
|
|
}
|
|
// Non stale transaction found, discard unless local
|
|
if local.containsTx(tx) {
|
|
save = append(save, tx)
|
|
} else {
|
|
drop = append(drop, tx)
|
|
count--
|
|
}
|
|
}
|
|
for _, tx := range save {
|
|
heap.Push(l.items, tx)
|
|
}
|
|
return drop
|
|
}
|