// Copyright 2023 The go-ethereum Authors // This file is part of the go-ethereum library. // // The go-ethereum library is free software: you can redistribute it and/or modify // it under the terms of the GNU Lesser General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // The go-ethereum library 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 Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public License // along with the go-ethereum library. If not, see . package blobpool import ( "bytes" "container/heap" "math" "sort" "github.com/ethereum/go-ethereum/common" "github.com/holiman/uint256" ) // evictHeap is a helper data structure to keep track of the cheapest bottleneck // transaction from each account to determine which account to evict from. // // The heap internally tracks a slice of cheapest transactions from each account // and a mapping from addresses to indices for direct removals/updates. // // The goal of the heap is to decide which account has the worst bottleneck to // evict transactions from. type evictHeap struct { metas map[common.Address][]*blobTxMeta // Pointer to the blob pool's index for price retrievals basefeeJumps float64 // Pre-calculated absolute dynamic fee jumps for the base fee blobfeeJumps float64 // Pre-calculated absolute dynamic fee jumps for the blob fee addrs []common.Address // Heap of addresses to retrieve the cheapest out of index map[common.Address]int // Indices into the heap for replacements } // newPriceHeap creates a new heap of cheapest accounts in the blob pool to evict // from in case of over saturation. func newPriceHeap(basefee *uint256.Int, blobfee *uint256.Int, index map[common.Address][]*blobTxMeta) *evictHeap { heap := &evictHeap{ metas: index, index: make(map[common.Address]int), } // Populate the heap in account sort order. Not really needed in practice, // but it makes the heap initialization deterministic and less annoying to // test in unit tests. addrs := make([]common.Address, 0, len(index)) for addr := range index { addrs = append(addrs, addr) } sort.Slice(addrs, func(i, j int) bool { return bytes.Compare(addrs[i][:], addrs[j][:]) < 0 }) for _, addr := range addrs { heap.index[addr] = len(heap.addrs) heap.addrs = append(heap.addrs, addr) } heap.reinit(basefee, blobfee, true) return heap } // reinit updates the pre-calculated dynamic fee jumps in the price heap and runs // the sorting algorithm from scratch on the entire heap. func (h *evictHeap) reinit(basefee *uint256.Int, blobfee *uint256.Int, force bool) { // If the update is mostly the same as the old, don't sort pointlessly basefeeJumps := dynamicFeeJumps(basefee) blobfeeJumps := dynamicFeeJumps(blobfee) if !force && math.Abs(h.basefeeJumps-basefeeJumps) < 0.01 && math.Abs(h.blobfeeJumps-blobfeeJumps) < 0.01 { // TODO(karalabe): 0.01 enough, maybe should be smaller? Maybe this optimization is moot? return } // One or both of the dynamic fees jumped, resort the pool h.basefeeJumps = basefeeJumps h.blobfeeJumps = blobfeeJumps heap.Init(h) } // Len implements sort.Interface as part of heap.Interface, returning the number // of accounts in the pool which can be considered for eviction. func (h *evictHeap) Len() int { return len(h.addrs) } // Less implements sort.Interface as part of heap.Interface, returning which of // the two requested accounts has a cheaper bottleneck. func (h *evictHeap) Less(i, j int) bool { txsI := h.metas[h.addrs[i]] txsJ := h.metas[h.addrs[j]] lastI := txsI[len(txsI)-1] lastJ := txsJ[len(txsJ)-1] prioI := evictionPriority(h.basefeeJumps, lastI.evictionExecFeeJumps, h.blobfeeJumps, lastI.evictionBlobFeeJumps) if prioI > 0 { prioI = 0 } prioJ := evictionPriority(h.basefeeJumps, lastJ.evictionExecFeeJumps, h.blobfeeJumps, lastJ.evictionBlobFeeJumps) if prioJ > 0 { prioJ = 0 } if prioI == prioJ { return lastI.evictionExecTip.Lt(lastJ.evictionExecTip) } return prioI < prioJ } // Swap implements sort.Interface as part of heap.Interface, maintaining both the // order of the accounts according to the heap, and the account->item slot mapping // for replacements. func (h *evictHeap) Swap(i, j int) { h.index[h.addrs[i]], h.index[h.addrs[j]] = h.index[h.addrs[j]], h.index[h.addrs[i]] h.addrs[i], h.addrs[j] = h.addrs[j], h.addrs[i] } // Push implements heap.Interface, appending an item to the end of the account // ordering as well as the address to item slot mapping. func (h *evictHeap) Push(x any) { h.index[x.(common.Address)] = len(h.addrs) h.addrs = append(h.addrs, x.(common.Address)) } // Pop implements heap.Interface, removing and returning the last element of the // heap. // // Note, use `heap.Pop`, not `evictHeap.Pop`. This method is used by Go's heap, // to provide the functionality, it does not embed it. func (h *evictHeap) Pop() any { // Remove the last element from the heap size := len(h.addrs) addr := h.addrs[size-1] h.addrs = h.addrs[:size-1] // Unindex the removed element and return delete(h.index, addr) return addr }